Compute Finite Strain in Cartesian System

Compute a strain increment and rotation increment for finite strains.

Description

This class is used to compute the strain increment, total strain, and incremental rotation for finite strain problems. The finite strain approach used is the incremental corotational form (Rashid, 1993). This approach computes logarithmic strains and strain increments.

Incremental Configurations

In this form, the generic time increment under consideration is such that $(1)var element = document.getElementById("moose-equation-a8ff803a-474e-451b-8d9c-c9675dbeda30");katex.render(" t \\in [t_n, t_{n+1}]", element, {displayMode:true,throwOnError:false,macros:{"\\eqc":"\\,,","\\eqp":"\\,.","\\pd":"\\frac{\\partial #1}{\\partial #2}","\\pr":"\\left(#1\\right)","\\ddt":"\\frac{d #1}{d t}"}});$ The configurations of the material element under consideration at $var element = document.getElementById("moose-equation-4350e501-05bf-4af7-b072-259e518ccdbf");katex.render("t = t_n", element, {displayMode:false,throwOnError:false,macros:{"\\eqc":"\\,,","\\eqp":"\\,.","\\pd":"\\frac{\\partial #1}{\\partial #2}","\\pr":"\\left(#1\\right)","\\ddt":"\\frac{d #1}{d t}"}});$ and $var element = document.getElementById("moose-equation-f60bfa58-8f92-49d4-b76b-a05dc01d0e50");katex.render("t = t_{n+1}", element, {displayMode:false,throwOnError:false,macros:{"\\eqc":"\\,,","\\eqp":"\\,.","\\pd":"\\frac{\\partial #1}{\\partial #2}","\\pr":"\\left(#1\\right)","\\ddt":"\\frac{d #1}{d t}"}});$ are denoted by $var element = document.getElementById("moose-equation-fc5c4c3a-2dc3-4f93-8ac4-45ba611e70ec");katex.render("\\kappa_n", element, {displayMode:false,throwOnError:false,macros:{"\\eqc":"\\,,","\\eqp":"\\,.","\\pd":"\\frac{\\partial #1}{\\partial #2}","\\pr":"\\left(#1\\right)","\\ddt":"\\frac{d #1}{d t}"}});$ , and $var element = document.getElementById("moose-equation-ac452a91-fd36-4cae-8028-b4f2909cbb0b");katex.render("\\kappa_{n + 1}", element, {displayMode:false,throwOnError:false,macros:{"\\eqc":"\\,,","\\eqp":"\\,.","\\pd":"\\frac{\\partial #1}{\\partial #2}","\\pr":"\\left(#1\\right)","\\ddt":"\\frac{d #1}{d t}"}});$ , respectively for the previous and the current incremental configurations.

Deformation Gradient Definition

The deformation gradient represents the change in a material element from the reference configuration to the current configuration (Malvern, 1969). In the incremental formulation used in the ComputeFiniteStrain class, the incremental deformation gradient represents the change in the material element from the previous configuration, $var element = document.getElementById("moose-equation-2b006bee-4c14-46d6-ba75-c00f8b995abf");katex.render("\\kappa_n", element, {displayMode:false,throwOnError:false,macros:{"\\eqc":"\\,,","\\eqp":"\\,.","\\pd":"\\frac{\\partial #1}{\\partial #2}","\\pr":"\\left(#1\\right)","\\ddt":"\\frac{d #1}{d t}"}});$ , to the current configuration, $var element = document.getElementById("moose-equation-1af475a6-8fd8-4076-a8e7-f4483a785b19");katex.render("\\kappa_{n+1}", element, {displayMode:false,throwOnError:false,macros:{"\\eqc":"\\,,","\\eqp":"\\,.","\\pd":"\\frac{\\partial #1}{\\partial #2}","\\pr":"\\left(#1\\right)","\\ddt":"\\frac{d #1}{d t}"}});$ . Mathematically this relationship is given as $var element = document.getElementById("moose-equation-f93554c4-3c8a-4126-b854-e6eeb84ae9e3");katex.render(" \\hat{\\boldsymbol{F}} = \\frac{\\partial{\\boldsymbol{x}_{n+1}}}{\\partial{\\boldsymbol{x}_n}},", element, {displayMode:true,throwOnError:false,macros:{"\\eqc":"\\,,","\\eqp":"\\,.","\\pd":"\\frac{\\partial #1}{\\partial #2}","\\pr":"\\left(#1\\right)","\\ddt":"\\frac{d #1}{d t}"}});$ where $var element = document.getElementById("moose-equation-2ea1c16a-5e17-418a-9d0a-e0b895102281");katex.render("\\boldsymbol{x}_{n+1}", element, {displayMode:false,throwOnError:false,macros:{"\\eqc":"\\,,","\\eqp":"\\,.","\\pd":"\\frac{\\partial #1}{\\partial #2}","\\pr":"\\left(#1\\right)","\\ddt":"\\frac{d #1}{d t}"}});$ is the position vector of materials points in $var element = document.getElementById("moose-equation-b4757e99-c9d2-45af-b1ca-268ec464a9b3");katex.render("\\kappa_{n+1}", element, {displayMode:false,throwOnError:false,macros:{"\\eqc":"\\,,","\\eqp":"\\,.","\\pd":"\\frac{\\partial #1}{\\partial #2}","\\pr":"\\left(#1\\right)","\\ddt":"\\frac{d #1}{d t}"}});$ , and $var element = document.getElementById("moose-equation-84c2d883-e568-4b9a-a8a2-61876845cc5d");katex.render("\\boldsymbol{x}_{n}", element, {displayMode:false,throwOnError:false,macros:{"\\eqc":"\\,,","\\eqp":"\\,.","\\pd":"\\frac{\\partial #1}{\\partial #2}","\\pr":"\\left(#1\\right)","\\ddt":"\\frac{d #1}{d t}"}});$ is the position vector of materials points in $var element = document.getElementById("moose-equation-8453d0e2-2104-4088-90dc-a6bb3ef0eaad");katex.render("\\kappa_{n}", element, {displayMode:false,throwOnError:false,macros:{"\\eqc":"\\,,","\\eqp":"\\,.","\\pd":"\\frac{\\partial #1}{\\partial #2}","\\pr":"\\left(#1\\right)","\\ddt":"\\frac{d #1}{d t}"}});$ .

note:Incremental vs Total Deformation Gradient

Note that $var element = document.getElementById("moose-equation-c4f31d5e-2559-498d-a922-fb168a66649a");katex.render("\\hat{\\boldsymbol{F}}", element, {displayMode:false,throwOnError:false,macros:{"\\eqc":"\\,,","\\eqp":"\\,.","\\pd":"\\frac{\\partial #1}{\\partial #2}","\\pr":"\\left(#1\\right)","\\ddt":"\\frac{d #1}{d t}"}});$ is NOT the deformation gradient, but rather the incremental deformation gradient of $var element = document.getElementById("moose-equation-d197882e-b5ad-468b-9ddb-355218725943");katex.render("\\kappa_{n+1}", element, {displayMode:false,throwOnError:false,macros:{"\\eqc":"\\,,","\\eqp":"\\,.","\\pd":"\\frac{\\partial #1}{\\partial #2}","\\pr":"\\left(#1\\right)","\\ddt":"\\frac{d #1}{d t}"}});$ with respect to $var element = document.getElementById("moose-equation-968ac07f-392b-43c5-a115-3348e41a5ba0");katex.render("\\kappa_n", element, {displayMode:false,throwOnError:false,macros:{"\\eqc":"\\,,","\\eqp":"\\,.","\\pd":"\\frac{\\partial #1}{\\partial #2}","\\pr":"\\left(#1\\right)","\\ddt":"\\frac{d #1}{d t}"}});$ . Thus $var element = document.getElementById("moose-equation-e35874f6-229d-41b1-947c-7b70a1907e24");katex.render("\\hat{\\boldsymbol{F}} = \\boldsymbol{F}_{n+1} \\boldsymbol{F}_n^{-1}", element, {displayMode:false,throwOnError:false,macros:{"\\eqc":"\\,,","\\eqp":"\\,.","\\pd":"\\frac{\\partial #1}{\\partial #2}","\\pr":"\\left(#1\\right)","\\ddt":"\\frac{d #1}{d t}"}});$ , where $var element = document.getElementById("moose-equation-9ba445ba-711d-4942-b282-e312e87afaf3");katex.render("\\boldsymbol{F}_n", element, {displayMode:false,throwOnError:false,macros:{"\\eqc":"\\,,","\\eqp":"\\,.","\\pd":"\\frac{\\partial #1}{\\partial #2}","\\pr":"\\left(#1\\right)","\\ddt":"\\frac{d #1}{d t}"}});$ is the total deformation gradient at time $var element = document.getElementById("moose-equation-9a31e735-4d98-4f4b-9d65-fa50be5f8154");katex.render("t_n", element, {displayMode:false,throwOnError:false,macros:{"\\eqc":"\\,,","\\eqp":"\\,.","\\pd":"\\frac{\\partial #1}{\\partial #2}","\\pr":"\\left(#1\\right)","\\ddt":"\\frac{d #1}{d t}"}});$ .

Following the explanation of this procedure given by Zhang et al. (2018), the incremental deformation gradient can be multiplicatively decomposed into an incremental rotation tensor, $var element = document.getElementById("moose-equation-0708887b-c5cd-4f23-a242-cf5057e6a81e");katex.render("\\boldsymbol{\\hat{R}}", element, {displayMode:false,throwOnError:false,macros:{"\\eqc":"\\,,","\\eqp":"\\,.","\\pd":"\\frac{\\partial #1}{\\partial #2}","\\pr":"\\left(#1\\right)","\\ddt":"\\frac{d #1}{d t}"}});$ , and the incremental right stretch tensor, $var element = document.getElementById("moose-equation-5f26abb3-f078-44b2-8a41-352822753ed2");katex.render("\\boldsymbol{\\hat{U}}", element, {displayMode:false,throwOnError:false,macros:{"\\eqc":"\\,,","\\eqp":"\\,.","\\pd":"\\frac{\\partial #1}{\\partial #2}","\\pr":"\\left(#1\\right)","\\ddt":"\\frac{d #1}{d t}"}});$ $(2)var element = document.getElementById("moose-equation-2b755d64-c648-4112-9a1f-4594de75c445");katex.render(" \\boldsymbol{\\hat{F}} = \\boldsymbol{\\hat{R}} \\cdot \\boldsymbol{\\hat{U}}", element, {displayMode:true,throwOnError:false,macros:{"\\eqc":"\\,,","\\eqp":"\\,.","\\pd":"\\frac{\\partial #1}{\\partial #2}","\\pr":"\\left(#1\\right)","\\ddt":"\\frac{d #1}{d t}"}});$ where $var element = document.getElementById("moose-equation-73ee1e41-c060-4f46-8537-f8434d7e680c");katex.render("\\boldsymbol{\\hat{R}}", element, {displayMode:false,throwOnError:false,macros:{"\\eqc":"\\,,","\\eqp":"\\,.","\\pd":"\\frac{\\partial #1}{\\partial #2}","\\pr":"\\left(#1\\right)","\\ddt":"\\frac{d #1}{d t}"}});$ is a proper orthogonal rotation tensor and the stretch tensor, $var element = document.getElementById("moose-equation-6b7331f5-1e28-49d5-abc9-db2033977a62");katex.render("\\boldsymbol{\\hat{U}}", element, {displayMode:false,throwOnError:false,macros:{"\\eqc":"\\,,","\\eqp":"\\,.","\\pd":"\\frac{\\partial #1}{\\partial #2}","\\pr":"\\left(#1\\right)","\\ddt":"\\frac{d #1}{d t}"}});$ , is symmetric and positive definite. The incremental right Cauchy-Green deformation tensor, $var element = document.getElementById("moose-equation-fbf5e300-3492-4ae9-84c4-bf5c34b7cc6c");katex.render("\\boldsymbol{\\hat{C}}", element, {displayMode:false,throwOnError:false,macros:{"\\eqc":"\\,,","\\eqp":"\\,.","\\pd":"\\frac{\\partial #1}{\\partial #2}","\\pr":"\\left(#1\\right)","\\ddt":"\\frac{d #1}{d t}"}});$ , can be given in terms of $var element = document.getElementById("moose-equation-b0c0597a-7206-433b-b228-39ac526331b8");katex.render("\\boldsymbol{\\hat{U}}", element, {displayMode:false,throwOnError:false,macros:{"\\eqc":"\\,,","\\eqp":"\\,.","\\pd":"\\frac{\\partial #1}{\\partial #2}","\\pr":"\\left(#1\\right)","\\ddt":"\\frac{d #1}{d t}"}});$ by substituting Eq. (2) into the definition for $var element = document.getElementById("moose-equation-605d3e31-f924-4e9d-8722-76edcad96522");katex.render("\\boldsymbol{\\hat{C}}", element, {displayMode:false,throwOnError:false,macros:{"\\eqc":"\\,,","\\eqp":"\\,.","\\pd":"\\frac{\\partial #1}{\\partial #2}","\\pr":"\\left(#1\\right)","\\ddt":"\\frac{d #1}{d t}"}});$ from Malvern (1969): $(3)var element = document.getElementById("moose-equation-1176ada4-de91-4435-b2af-c7bb71b27dbf");katex.render(" \\boldsymbol{\\hat{C}} = \\boldsymbol{\\hat{F}}^T \\cdot \\boldsymbol{\\hat{F}} = \\boldsymbol{\\hat{U}}^T \\cdot \\boldsymbol{\\hat{R}}^T \\cdot \\boldsymbol{\\hat{R}} \\cdot \\boldsymbol{\\hat{U}} = \\boldsymbol{\\hat{U}}^2", element, {displayMode:true,throwOnError:false,macros:{"\\eqc":"\\,,","\\eqp":"\\,.","\\pd":"\\frac{\\partial #1}{\\partial #2}","\\pr":"\\left(#1\\right)","\\ddt":"\\frac{d #1}{d t}"}});$ where the orthogonal nature of $var element = document.getElementById("moose-equation-c30710c9-c11d-411e-9949-1a629a05b51e");katex.render("\\boldsymbol{\\hat{R}}", element, {displayMode:false,throwOnError:false,macros:{"\\eqc":"\\,,","\\eqp":"\\,.","\\pd":"\\frac{\\partial #1}{\\partial #2}","\\pr":"\\left(#1\\right)","\\ddt":"\\frac{d #1}{d t}"}});$ enables the simplification given above. Thus $var element = document.getElementById("moose-equation-c34920ea-2e4f-4319-9447-cf16db139b2c");katex.render("\\boldsymbol{\\hat{U}}", element, {displayMode:false,throwOnError:false,macros:{"\\eqc":"\\,,","\\eqp":"\\,.","\\pd":"\\frac{\\partial #1}{\\partial #2}","\\pr":"\\left(#1\\right)","\\ddt":"\\frac{d #1}{d t}"}});$ can be computed from $var element = document.getElementById("moose-equation-ec94d0a4-9e94-4da1-8b2e-210801542f4a");katex.render("\\boldsymbol{\\hat{C}}", element, {displayMode:false,throwOnError:false,macros:{"\\eqc":"\\,,","\\eqp":"\\,.","\\pd":"\\frac{\\partial #1}{\\partial #2}","\\pr":"\\left(#1\\right)","\\ddt":"\\frac{d #1}{d t}"}});$ as $(4)var element = document.getElementById("moose-equation-27de87b5-fb5e-463f-a043-278b834e3e88");katex.render(" \\boldsymbol{\\hat{U}} = \\boldsymbol{\\hat{C}}^\\frac{1}{2}", element, {displayMode:true,throwOnError:false,macros:{"\\eqc":"\\,,","\\eqp":"\\,.","\\pd":"\\frac{\\partial #1}{\\partial #2}","\\pr":"\\left(#1\\right)","\\ddt":"\\frac{d #1}{d t}"}});$ which can be evaluated by performing a spectral decomposition of $var element = document.getElementById("moose-equation-92c817c0-1c3a-4bfd-b573-98e1a5e009a1");katex.render("\\boldsymbol{\\hat{C}}", element, {displayMode:false,throwOnError:false,macros:{"\\eqc":"\\,,","\\eqp":"\\,.","\\pd":"\\frac{\\partial #1}{\\partial #2}","\\pr":"\\left(#1\\right)","\\ddt":"\\frac{d #1}{d t}"}});$ . Once $var element = document.getElementById("moose-equation-47493d16-0429-4ccb-aa08-b595360705c1");katex.render("\\boldsymbol{\\hat{U}}", element, {displayMode:false,throwOnError:false,macros:{"\\eqc":"\\,,","\\eqp":"\\,.","\\pd":"\\frac{\\partial #1}{\\partial #2}","\\pr":"\\left(#1\\right)","\\ddt":"\\frac{d #1}{d t}"}});$ has been computed, the multiplicative decomposition of the deformation gradient is used to find the incremental rotation tensor $var element = document.getElementById("moose-equation-da5ffe6d-d94b-406c-b99a-539f5d78dfa9");katex.render("\\boldsymbol{\\hat{R}}", element, {displayMode:false,throwOnError:false,macros:{"\\eqc":"\\,,","\\eqp":"\\,.","\\pd":"\\frac{\\partial #1}{\\partial #2}","\\pr":"\\left(#1\\right)","\\ddt":"\\frac{d #1}{d t}"}});$ and the stretching rate $var element = document.getElementById("moose-equation-922eeda1-6c84-4f08-b4fa-402875fd543f");katex.render("\\boldsymbol{D}", element, {displayMode:false,throwOnError:false,macros:{"\\eqc":"\\,,","\\eqp":"\\,.","\\pd":"\\frac{\\partial #1}{\\partial #2}","\\pr":"\\left(#1\\right)","\\ddt":"\\frac{d #1}{d t}"}});$ . Following Rashid (1993), the stretching rate tensor can be expressed in terms of the 'incremental' right Cauchy-Green deformation tensor $(5)var element = document.getElementById("moose-equation-57ea0733-8bf0-4852-9d57-1fd1429a7d3d");katex.render(" \\boldsymbol{D} = \\frac{1}{\\Delta t}\\log({\\hat{\\boldsymbol{C}}^{1/2}})", element, {displayMode:true,throwOnError:false,macros:{"\\eqc":"\\,,","\\eqp":"\\,.","\\pd":"\\frac{\\partial #1}{\\partial #2}","\\pr":"\\left(#1\\right)","\\ddt":"\\frac{d #1}{d t}"}});$

This incremental stretching rate tensor can then be used as the work conjugate for a stress measure, or used to compute another strain measure. The most computationally expensive part of this procedure is the spectral decomposition of $var element = document.getElementById("moose-equation-74df1556-7d69-420b-8aa7-c0f20f5e2380");katex.render("\\boldsymbol{\\hat{C}}", element, {displayMode:false,throwOnError:false,macros:{"\\eqc":"\\,,","\\eqp":"\\,.","\\pd":"\\frac{\\partial #1}{\\partial #2}","\\pr":"\\left(#1\\right)","\\ddt":"\\frac{d #1}{d t}"}});$ to find $var element = document.getElementById("moose-equation-6aacf1db-6faf-4985-8c78-a8ab3149393e");katex.render("\\boldsymbol{\\hat{U}}", element, {displayMode:false,throwOnError:false,macros:{"\\eqc":"\\,,","\\eqp":"\\,.","\\pd":"\\frac{\\partial #1}{\\partial #2}","\\pr":"\\left(#1\\right)","\\ddt":"\\frac{d #1}{d t}"}});$ . This decomposition can be computed exactly using an Eigensolution, yet an approximation of this can be computed with much lower computational expense using a Taylor expansion procedure. This class provides options to perform this calculation either way, and the Taylor expansion is the default.

This class also provides an additional option for computing the stretching rate tensor $var element = document.getElementById("moose-equation-ae7c8a91-3c94-4980-b59f-35fcc0158a8b");katex.render("\\boldsymbol{D}", element, {displayMode:false,throwOnError:false,macros:{"\\eqc":"\\,,","\\eqp":"\\,.","\\pd":"\\frac{\\partial #1}{\\partial #2}","\\pr":"\\left(#1\\right)","\\ddt":"\\frac{d #1}{d t}"}});$ and incremental rotation tensor $var element = document.getElementById("moose-equation-607b2799-6ce6-4b97-a265-66cc923cdce7");katex.render("\\boldsymbol{\\hat{R}}", element, {displayMode:false,throwOnError:false,macros:{"\\eqc":"\\,,","\\eqp":"\\,.","\\pd":"\\frac{\\partial #1}{\\partial #2}","\\pr":"\\left(#1\\right)","\\ddt":"\\frac{d #1}{d t}"}});$ using the method of Hughes and Winget (1980). This method involves evaluating the displacement field at the midpoint of the timestep, and as a result, requires updating stress and strain measures at the old configuration rather than the current.

Taylor Expansion

The stretching rate tensor $var element = document.getElementById("moose-equation-bc39a910-efa4-441e-bf7c-1b7365fa937f");katex.render("\\boldsymbol{D}", element, {displayMode:false,throwOnError:false,macros:{"\\eqc":"\\,,","\\eqp":"\\,.","\\pd":"\\frac{\\partial #1}{\\partial #2}","\\pr":"\\left(#1\\right)","\\ddt":"\\frac{d #1}{d t}"}});$ and incremental rotation matrix $var element = document.getElementById("moose-equation-4dc96f2a-7393-4ad6-bfdc-49061b96e601");katex.render("\\hat{\\boldsymbol{R}}", element, {displayMode:false,throwOnError:false,macros:{"\\eqc":"\\,,","\\eqp":"\\,.","\\pd":"\\frac{\\partial #1}{\\partial #2}","\\pr":"\\left(#1\\right)","\\ddt":"\\frac{d #1}{d t}"}});$ can be approximated using Taylor expansion as Rashid (1993): the approximated stretching rate tensor $var element = document.getElementById("moose-equation-d3cfa818-79a9-462a-9923-146c96614bb4");katex.render("\\boldsymbol{D}^{a} = \\frac{1}{\\Delta t}\\left[ -\\frac{1}{2}(\\hat{\\boldsymbol{C}}^{-1} - \\boldsymbol{I}) + \\frac{1}{4}(\\hat{\\boldsymbol{C}}^{-1} - \\boldsymbol{I})^{2} - \\frac{1}{6}(\\hat{\\boldsymbol{C}}^{-1} - \\boldsymbol{I})^{3} + ... \\right]", element, {displayMode:true,throwOnError:false,macros:{"\\eqc":"\\,,","\\eqp":"\\,.","\\pd":"\\frac{\\partial #1}{\\partial #2}","\\pr":"\\left(#1\\right)","\\ddt":"\\frac{d #1}{d t}"}});$ the approximated rotation matrix $var element = document.getElementById("moose-equation-02e54c13-5cf6-421e-864e-ce409a241af2");katex.render("\\hat{R}_{ij}^{a} = \\delta_{ij}\\cos \\theta^{a} + \\frac{1-\\cos \\theta^{a}}{4Q} \\alpha_{i}\\alpha_{j} - \\frac{\\sin \\theta^{a}}{2\\sqrt{Q}}\\epsilon_{ijk}\\alpha_{k}", element, {displayMode:true,throwOnError:false,macros:{"\\eqc":"\\,,","\\eqp":"\\,.","\\pd":"\\frac{\\partial #1}{\\partial #2}","\\pr":"\\left(#1\\right)","\\ddt":"\\frac{d #1}{d t}"}});$ with $var element = document.getElementById("moose-equation-3036b3d6-51e2-4cf2-a6f6-01d0328a4aa8");katex.render("\\begin{aligned} \\sin^{2} \\theta^{a} =& Q \\\\[1.5em] \\frac{\\sin \\theta^{a}}{2\\sqrt{Q}} =& \\frac{1}{2}\\left[ \\frac{PQ(3-Q)+P^{3}+Q^{2}}{(P+Q)^{3}} \\right]^{1/2}\\\\[1.5em] \\frac{1-\\cos \\theta^{a}}{4Q} =& \\frac{1}{8} + Q\\frac{P^{2}-12(P-1)}{32P^2} + Q^{2}\\frac{(P-2)(P^{2}-10P+32)}{64P^3}\\\\[1.5em] +& Q^{3}\\frac{1104-992P+376P^{2}-72P^{3}+5P^{4}}{512P^{4}}\\\\[1.5em] \\cos^{2} \\theta^{a} =& P + \\frac{3P^{2}[1-(P+Q)]}{(P+Q)^{2}} - \\frac{2P^{3}[1-(P+Q)]}{(P+Q)^{3}}\\\\[1.5em] P =& \\frac{1}{4}(tr(\\hat{\\boldsymbol{F}}^{-1}) - 1)^{2} \\end{aligned}", element, {displayMode:true,throwOnError:false,macros:{"\\eqc":"\\,,","\\eqp":"\\,.","\\pd":"\\frac{\\partial #1}{\\partial #2}","\\pr":"\\left(#1\\right)","\\ddt":"\\frac{d #1}{d t}"}});$ The sign of $var element = document.getElementById("moose-equation-f67df220-824b-45c5-a4dc-3a96c3314364");katex.render("\\cos \\theta^{a}", element, {displayMode:false,throwOnError:false,macros:{"\\eqc":"\\,,","\\eqp":"\\,.","\\pd":"\\frac{\\partial #1}{\\partial #2}","\\pr":"\\left(#1\\right)","\\ddt":"\\frac{d #1}{d t}"}});$ is set by examining the sign of $var element = document.getElementById("moose-equation-d6e7dd99-6806-4b41-80c8-854f9aab595c");katex.render("(tr(\\hat{\\boldsymbol{F}}^{-1}) - 1)", element, {displayMode:false,throwOnError:false,macros:{"\\eqc":"\\,,","\\eqp":"\\,.","\\pd":"\\frac{\\partial #1}{\\partial #2}","\\pr":"\\left(#1\\right)","\\ddt":"\\frac{d #1}{d t}"}});$ .

Eigen-Solution

The stretching rate tensor can be calculated by the eigenvalues $var element = document.getElementById("moose-equation-aa84bb57-e10e-43a2-993d-75cecb622c6b");katex.render("\\lambda", element, {displayMode:false,throwOnError:false,macros:{"\\eqc":"\\,,","\\eqp":"\\,.","\\pd":"\\frac{\\partial #1}{\\partial #2}","\\pr":"\\left(#1\\right)","\\ddt":"\\frac{d #1}{d t}"}});$ and eigenvectors $var element = document.getElementById("moose-equation-8e790901-ed78-4fb5-af3d-130237505c03");katex.render("\\boldsymbol{v}", element, {displayMode:false,throwOnError:false,macros:{"\\eqc":"\\,,","\\eqp":"\\,.","\\pd":"\\frac{\\partial #1}{\\partial #2}","\\pr":"\\left(#1\\right)","\\ddt":"\\frac{d #1}{d t}"}});$ of $var element = document.getElementById("moose-equation-fafb94ce-510f-4be7-bd4b-ecae73f5987b");katex.render("\\hat{\\boldsymbol{C}}", element, {displayMode:false,throwOnError:false,macros:{"\\eqc":"\\,,","\\eqp":"\\,.","\\pd":"\\frac{\\partial #1}{\\partial #2}","\\pr":"\\left(#1\\right)","\\ddt":"\\frac{d #1}{d t}"}});$ . $var element = document.getElementById("moose-equation-f49bd368-91c7-42b7-9cf5-2971e8b22441");katex.render("\\boldsymbol{D} = \\log{\\sqrt{\\lambda_{1}}}\\boldsymbol{N}_{1} + \\log{\\sqrt{\\lambda_{2}}}\\boldsymbol{N}_{2} + \\log{\\sqrt{\\lambda_{3}}}\\boldsymbol{N}_{3}", element, {displayMode:true,throwOnError:false,macros:{"\\eqc":"\\,,","\\eqp":"\\,.","\\pd":"\\frac{\\partial #1}{\\partial #2}","\\pr":"\\left(#1\\right)","\\ddt":"\\frac{d #1}{d t}"}});$ with $var element = document.getElementById("moose-equation-964acfbe-1b0e-4946-902d-79d68f96b16d");katex.render("\\lambda", element, {displayMode:false,throwOnError:false,macros:{"\\eqc":"\\,,","\\eqp":"\\,.","\\pd":"\\frac{\\partial #1}{\\partial #2}","\\pr":"\\left(#1\\right)","\\ddt":"\\frac{d #1}{d t}"}});$ being the eigenvalue and $var element = document.getElementById("moose-equation-fbaa54d8-04c2-45f7-b2b6-6be1993cee1a");katex.render("\\boldsymbol{N}", element, {displayMode:false,throwOnError:false,macros:{"\\eqc":"\\,,","\\eqp":"\\,.","\\pd":"\\frac{\\partial #1}{\\partial #2}","\\pr":"\\left(#1\\right)","\\ddt":"\\frac{d #1}{d t}"}});$ matrix being constructed from the corresponding eigenvector. $var element = document.getElementById("moose-equation-bab83a43-59cb-4b77-8413-11651c995686");katex.render("\\boldsymbol{N}_{i} = \\boldsymbol{v}_{i}\\boldsymbol{v}_{i}^{T}", element, {displayMode:true,throwOnError:false,macros:{"\\eqc":"\\,,","\\eqp":"\\,.","\\pd":"\\frac{\\partial #1}{\\partial #2}","\\pr":"\\left(#1\\right)","\\ddt":"\\frac{d #1}{d t}"}});$ the 'incremental' stretching tensor $var element = document.getElementById("moose-equation-44d8dc31-9bf5-4417-b7cf-d18336900a4c");katex.render("\\hat{\\boldsymbol{U}} = \\sqrt{\\lambda_{1}}\\boldsymbol{N}_{1} + \\sqrt{\\lambda_{2}}\\boldsymbol{N}_{2} + \\sqrt{\\lambda_{3}}\\boldsymbol{N}_{3}", element, {displayMode:true,throwOnError:false,macros:{"\\eqc":"\\,,","\\eqp":"\\,.","\\pd":"\\frac{\\partial #1}{\\partial #2}","\\pr":"\\left(#1\\right)","\\ddt":"\\frac{d #1}{d t}"}});$ and thus $var element = document.getElementById("moose-equation-a208d194-f46a-4504-9bf8-cb52e3c68a2d");katex.render("\\hat{\\boldsymbol{R}} = \\hat{\\boldsymbol{F}} \\hat{\\boldsymbol{U}}^{-1}", element, {displayMode:true,throwOnError:false,macros:{"\\eqc":"\\,,","\\eqp":"\\,.","\\pd":"\\frac{\\partial #1}{\\partial #2}","\\pr":"\\left(#1\\right)","\\ddt":"\\frac{d #1}{d t}"}});$

Hughes-Winget Approximation

As also described in Rashid (1993), the stretching rate tensor $var element = document.getElementById("moose-equation-26259a0d-9750-43c7-817e-e05d84eb268e");katex.render("\\boldsymbol{D}", element, {displayMode:false,throwOnError:false,macros:{"\\eqc":"\\,,","\\eqp":"\\,.","\\pd":"\\frac{\\partial #1}{\\partial #2}","\\pr":"\\left(#1\\right)","\\ddt":"\\frac{d #1}{d t}"}});$ and incremental rotation matrix $var element = document.getElementById("moose-equation-b1cacb32-49b7-4024-b8c0-1bd8351cd302");katex.render("\\hat{\\boldsymbol{R}}", element, {displayMode:false,throwOnError:false,macros:{"\\eqc":"\\,,","\\eqp":"\\,.","\\pd":"\\frac{\\partial #1}{\\partial #2}","\\pr":"\\left(#1\\right)","\\ddt":"\\frac{d #1}{d t}"}});$ in for the Hughes-Winget method are based on the spatial gradient $var element = document.getElementById("moose-equation-9230b4b1-49f0-401f-8dc2-7068918cfbc4");katex.render("\\boldsymbol{G}", element, {displayMode:false,throwOnError:false,macros:{"\\eqc":"\\,,","\\eqp":"\\,.","\\pd":"\\frac{\\partial #1}{\\partial #2}","\\pr":"\\left(#1\\right)","\\ddt":"\\frac{d #1}{d t}"}});$ of the displacement field evaluated at the mid-point of the time step $var element = document.getElementById("moose-equation-b7391114-54b3-4925-b0e3-6ab6e04ead1f");katex.render("\\boldsymbol{G} = 2\\left( \\hat{\\boldsymbol{F}} - \\boldsymbol{I}\\right) \\left( \\hat{\\boldsymbol{F}} + \\boldsymbol{I}\\right)^{-1}", element, {displayMode:true,throwOnError:false,macros:{"\\eqc":"\\,,","\\eqp":"\\,.","\\pd":"\\frac{\\partial #1}{\\partial #2}","\\pr":"\\left(#1\\right)","\\ddt":"\\frac{d #1}{d t}"}});$ The approximate stretching rate tensor can then be computed as $var element = document.getElementById("moose-equation-32c4e8e9-4d01-46ca-a4fb-8d882b28e057");katex.render("\\boldsymbol{D} = \\frac{1}{2 \\Delta t}\\left(\\boldsymbol{G} + \\boldsymbol{G}^{T} \\right)", element, {displayMode:true,throwOnError:false,macros:{"\\eqc":"\\,,","\\eqp":"\\,.","\\pd":"\\frac{\\partial #1}{\\partial #2}","\\pr":"\\left(#1\\right)","\\ddt":"\\frac{d #1}{d t}"}});$ and the incremental rotation matrix is approximated by $var element = document.getElementById("moose-equation-8c836542-d535-49c3-988b-a27d2075d65d");katex.render("\\hat{\\boldsymbol{R}} = \\left(\\boldsymbol{I} + \\frac{1}{2}\\omega \\right) \\left(\\boldsymbol{I} - \\frac{1}{2}\\omega \\right)^{-1}", element, {displayMode:true,throwOnError:false,macros:{"\\eqc":"\\,,","\\eqp":"\\,.","\\pd":"\\frac{\\partial #1}{\\partial #2}","\\pr":"\\left(#1\\right)","\\ddt":"\\frac{d #1}{d t}"}});$ where $var element = document.getElementById("moose-equation-e3c589cc-5701-42a8-8437-b86935b886a3");katex.render("\\omega = \\frac{1}{2}\\left(\\boldsymbol{G} - \\boldsymbol{G}^{T} \\right)", element, {displayMode:false,throwOnError:false,macros:{"\\eqc":"\\,,","\\eqp":"\\,.","\\pd":"\\frac{\\partial #1}{\\partial #2}","\\pr":"\\left(#1\\right)","\\ddt":"\\frac{d #1}{d t}"}});$ .

Volumetric Locking Correction

In ComputeFiniteStrain, $var element = document.getElementById("moose-equation-5a58d60f-1fcf-4e64-aef2-ea9a234f957b");katex.render("\\hat{\\boldsymbol{F}}", element, {displayMode:false,throwOnError:false,macros:{"\\eqc":"\\,,","\\eqp":"\\,.","\\pd":"\\frac{\\partial #1}{\\partial #2}","\\pr":"\\left(#1\\right)","\\ddt":"\\frac{d #1}{d t}"}});$ is calculated in the computeStrain method, including a volumetric locking correction of $var element = document.getElementById("moose-equation-b99b784b-71d9-4168-a669-5189c4a40e7f");katex.render("\\hat{\\boldsymbol{F}}_{corr} = \\hat{\\boldsymbol{F}} \\left( \\frac{|\\mathrm{av}_{el}(\\hat{\\boldsymbol{F}})|}{|\\hat{\\boldsymbol{F}}|} \\right)^{\\frac{1}{3}},", element, {displayMode:true,throwOnError:false,macros:{"\\eqc":"\\,,","\\eqp":"\\,.","\\pd":"\\frac{\\partial #1}{\\partial #2}","\\pr":"\\left(#1\\right)","\\ddt":"\\frac{d #1}{d t}"}});$ where $var element = document.getElementById("moose-equation-88649fa0-fb26-45cc-8faa-9f98b650d61d");katex.render("\\mathrm{av}_{el}()", element, {displayMode:false,throwOnError:false,macros:{"\\eqc":"\\,,","\\eqp":"\\,.","\\pd":"\\frac{\\partial #1}{\\partial #2}","\\pr":"\\left(#1\\right)","\\ddt":"\\frac{d #1}{d t}"}});$ is the average value for the entire element. The strain increment and the rotation increment are calculated in computeQpStrain(). Once the strain increment is calculated, it is added to the total strain from $var element = document.getElementById("moose-equation-8d81ab65-7614-47c0-bc5c-0fb2dfa05a14");katex.render("t_n", element, {displayMode:false,throwOnError:false,macros:{"\\eqc":"\\,,","\\eqp":"\\,.","\\pd":"\\frac{\\partial #1}{\\partial #2}","\\pr":"\\left(#1\\right)","\\ddt":"\\frac{d #1}{d t}"}});$ . The total strain from $var element = document.getElementById("moose-equation-9854e3aa-52ad-4924-a3cd-b5d7cf780e3d");katex.render("t_{n+1}", element, {displayMode:false,throwOnError:false,macros:{"\\eqc":"\\,,","\\eqp":"\\,.","\\pd":"\\frac{\\partial #1}{\\partial #2}","\\pr":"\\left(#1\\right)","\\ddt":"\\frac{d #1}{d t}"}});$ must then be rotated using the rotation increment.

Example Input File Syntax

The finite strain calculator can be activated in the input file through the use of the Solid Mechanics Physics, as shown below.

[Physics]
  [SolidMechanics]
    [QuasiStatic]
      [./all]
        strain = FINITE
        add_variables = true
      [../]
    [../]
  [../]
[]

note:Use of the Solid Mechanics QuasiStatic Physics Recommended

The Solid Mechanics Physics is designed to automatically determine and set the strain and stress divergence parameters correctly for the selected strain formulation. We recommend that users employ the Solid Mechanics Physics whenever possible to ensure consistency between the test function gradients and the strain formulation selected.

Although not recommended, it is possible to directly use the ComputeFiniteStrain material in the input file.

[./strain]
  type = ComputeFiniteStrain
  block = 0
  displacements = 'disp_x disp_y disp_z'
[../]

When directly using ComputeFiniteStrain in an input file as shown above, the StressDivergenceTensors kernel must be modified from the default by setting the parameter use_displaced_mesh = true. This setting is required to maintain consistency in the test function gradients and the strain formulation. For a complete discussion of the stress divergence kernel settings and the corresponding strain classes, see the section on Consistency Between Stress and Strain in the SolidMechanics module overview. In addition, be aware of the loading cycle limitations while using finite strains as outlined in the section Large Strain Closed Loop Loading Cycle.

Input Parameters

displacementsThe displacements appropriate for the simulation geometry and coordinate system
C++ Type:std::vector<VariableName>
Controllable:No
Description:The displacements appropriate for the simulation geometry and coordinate system

Required Parameters

base_nameOptional parameter that allows the user to define multiple mechanics material systems on the same block, i.e. for multiple phases
C++ Type:std::string
Controllable:No
Description:Optional parameter that allows the user to define multiple mechanics material systems on the same block, i.e. for multiple phases
blockThe list of blocks (ids or names) that this object will be applied
C++ Type:std::vector<SubdomainName>
Controllable:No
Description:The list of blocks (ids or names) that this object will be applied
boundaryThe list of boundaries (ids or names) from the mesh where this object applies
C++ Type:std::vector<BoundaryName>
Controllable:No
Description:The list of boundaries (ids or names) from the mesh where this object applies
computeTrueWhen false, MOOSE will not call compute methods on this material. The user must call computeProperties() after retrieving the MaterialBase via MaterialBasePropertyInterface::getMaterialBase(). Non-computed MaterialBases are not sorted for dependencies.
Default:True
C++ Type:bool
Controllable:No
Description:When false, MOOSE will not call compute methods on this material. The user must call computeProperties() after retrieving the MaterialBase via MaterialBasePropertyInterface::getMaterialBase(). Non-computed MaterialBases are not sorted for dependencies.
constant_onNONEWhen ELEMENT, MOOSE will only call computeQpProperties() for the 0th quadrature point, and then copy that value to the other qps.When SUBDOMAIN, MOOSE will only call computeQpProperties() for the 0th quadrature point, and then copy that value to the other qps. Evaluations on element qps will be skipped
Default:NONE
C++ Type:MooseEnum
Options:NONE, ELEMENT, SUBDOMAIN
Controllable:No
Description:When ELEMENT, MOOSE will only call computeQpProperties() for the 0th quadrature point, and then copy that value to the other qps.When SUBDOMAIN, MOOSE will only call computeQpProperties() for the 0th quadrature point, and then copy that value to the other qps. Evaluations on element qps will be skipped
declare_suffixAn optional suffix parameter that can be appended to any declared properties. The suffix will be prepended with a '_' character.
C++ Type:MaterialPropertyName
Controllable:No
Description:An optional suffix parameter that can be appended to any declared properties. The suffix will be prepended with a '_' character.
decomposition_methodTaylorExpansionMethods to calculate the strain and rotation increments
Default:TaylorExpansion
C++ Type:MooseEnum
Options:TaylorExpansion, EigenSolution, HughesWinget
Controllable:No
Description:Methods to calculate the strain and rotation increments
eigenstrain_namesList of eigenstrains to be applied in this strain calculation
C++ Type:std::vector<MaterialPropertyName>
Controllable:No
Description:List of eigenstrains to be applied in this strain calculation
global_strainOptional material property holding a global strain tensor applied to the mesh as a whole
C++ Type:MaterialPropertyName
Controllable:No
Description:Optional material property holding a global strain tensor applied to the mesh as a whole
prop_getter_suffixAn optional suffix parameter that can be appended to any attempt to retrieve/get material properties. The suffix will be prepended with a '_' character.
C++ Type:MaterialPropertyName
Controllable:No
Description:An optional suffix parameter that can be appended to any attempt to retrieve/get material properties. The suffix will be prepended with a '_' character.
use_interpolated_stateFalseFor the old and older state use projected material properties interpolated at the quadrature points. To set up projection use the ProjectedStatefulMaterialStorageAction.
Default:False
C++ Type:bool
Controllable:No
Description:For the old and older state use projected material properties interpolated at the quadrature points. To set up projection use the ProjectedStatefulMaterialStorageAction.
volumetric_locking_correctionFalseFlag to correct volumetric locking
Default:False
C++ Type:bool
Controllable:No
Description:Flag to correct volumetric locking

Optional Parameters

control_tagsAdds user-defined labels for accessing object parameters via control logic.
C++ Type:std::vector<std::string>
Controllable:No
Description:Adds user-defined labels for accessing object parameters via control logic.
enableTrueSet the enabled status of the MooseObject.
Default:True
C++ Type:bool
Controllable:Yes
Description:Set the enabled status of the MooseObject.
implicitTrueDetermines whether this object is calculated using an implicit or explicit form
Default:True
C++ Type:bool
Controllable:No
Description:Determines whether this object is calculated using an implicit or explicit form
seed0The seed for the master random number generator
Default:0
C++ Type:unsigned int
Controllable:No
Description:The seed for the master random number generator

Advanced Parameters

output_propertiesList of material properties, from this material, to output (outputs must also be defined to an output type)
C++ Type:std::vector<std::string>
Controllable:No
Description:List of material properties, from this material, to output (outputs must also be defined to an output type)
outputsnone Vector of output names where you would like to restrict the output of variables(s) associated with this object
Default:none
C++ Type:std::vector<OutputName>
Controllable:No
Description:Vector of output names where you would like to restrict the output of variables(s) associated with this object

Outputs Parameters

Input Files

(modules/solid_mechanics/test/tests/multi/three_surface16.i)
(modules/solid_mechanics/test/tests/mohr_coulomb/planar_hard4.i)
(modules/solid_mechanics/test/tests/crystal_plasticity/monolithic_material_based/crysp.i)
(modules/solid_mechanics/test/tests/multi/special_joint1.i)
(modules/solid_mechanics/test/tests/crystal_plasticity/monolithic_material_based/cp_slip_rate_integ/crysp_linesearch.i)
(modules/solid_mechanics/test/tests/elem_prop_read_user_object/prop_elem_read.i)
(modules/solid_mechanics/test/tests/multi/three_surface20.i)
(modules/contact/test/tests/verification/hertz_cyl/quart_symm_q8/hertz_cyl_qsym_1deg_template1.i)
(modules/solid_mechanics/test/tests/mohr_coulomb/small_deform6.i)
(modules/combined/test/tests/cavity_pressure/initial_temperature.i)
(modules/contact/test/tests/pdass_problems/ironing.i)
(modules/solid_mechanics/test/tests/elastic_patch/elastic_patch.i)
(modules/contact/test/tests/verification/hertz_cyl/quart_symm_q4/hertz_cyl_qsym_1deg_template1.i)
(modules/solid_mechanics/test/tests/multi/paper3.i)
(modules/solid_mechanics/test/tests/mohr_coulomb/many_deforms_cap.i)
(modules/contact/test/tests/mortar_aux_kernels/block-dynamics-aux-vel.i)
(modules/solid_mechanics/test/tests/multi/two_surface01.i)
(modules/solid_mechanics/test/tests/crystal_plasticity/monolithic_material_based/crysp_read_slip_prop.i)
(modules/solid_mechanics/test/tests/crystal_plasticity/monolithic_material_based/crysp_fileread.i)
(modules/contact/test/tests/verification/patch_tests/brick_1/brick1_template2.i)
(modules/solid_mechanics/test/tests/multi/three_surface04.i)
(modules/contact/test/tests/verification/hertz_cyl/half_symm_q8/hertz_cyl_half_1deg_template1.i)
(modules/solid_mechanics/test/tests/multi/three_surface09.i)
(modules/solid_mechanics/test/tests/drucker_prager/random_hyperbolic.i)
(modules/contact/test/tests/pdass_problems/ironing_penalty_al.i)
(modules/contact/test/tests/verification/patch_tests/brick_2/brick2_template2.i)
(modules/contact/test/tests/verification/patch_tests/brick_3/brick3_mu_0_2_pen.i)
(modules/solid_mechanics/test/tests/multi/three_surface02.i)
(modules/contact/test/tests/verification/patch_tests/brick_2/brick2_template1.i)
(modules/contact/test/tests/verification/hertz_cyl/half_symm_q8/hertz_cyl_half_1deg_template3.i)
(modules/contact/test/tests/mortar_dynamics/block-dynamics.i)
(modules/combined/test/tests/cavity_pressure/additional_volume.i)
(modules/solid_mechanics/test/tests/multi/two_surface02.i)
(modules/solid_mechanics/test/tests/crystal_plasticity/user_object_based/use_substep_dt.i)
(modules/combined/test/tests/eigenstrain/variable_finite.i)
(modules/solid_mechanics/test/tests/multi/three_surface05.i)
(modules/solid_mechanics/test/tests/capped_mohr_coulomb/random5.i)
(modules/solid_mechanics/examples/bridge/bridge_large_strain.i)
(modules/solid_mechanics/test/tests/mohr_coulomb/random_planar.i)
(modules/solid_mechanics/test/tests/hyperelastic_viscoplastic/one_elem_multi.i)
(modules/solid_mechanics/test/tests/j2_plasticity/hard1.i)
(modules/fsi/test/tests/fsi_acoustics/3D_struc_acoustic/3D_struc_acoustic.i)
(modules/contact/test/tests/verification/patch_tests/brick_4/brick4_template2.i)
(modules/contact/test/tests/explicit_dynamics/settlement.i)
(modules/solid_mechanics/test/tests/finite_strain_tensor_mechanics_tests/finite_strain_patch.i)
(modules/contact/test/tests/mortar_aux_kernels/block-dynamics-aux-fretting-wear-test-projection_angle.i)
(modules/solid_mechanics/test/tests/crystal_plasticity/user_object_based/user_object_Voce_BCC.i)
(modules/contact/test/tests/verification/patch_tests/brick_1/brick1_mu_0_2_pen.i)
(modules/solid_mechanics/test/tests/multi/three_surface14.i)
(modules/solid_mechanics/test/tests/hyperelastic_viscoplastic/one_elem_base.i)
(modules/solid_mechanics/test/tests/mohr_coulomb/except3.i)
(modules/xfem/test/tests/moving_interface/moving_bimaterial_finite_strain_cut_mesh.i)
(modules/solid_mechanics/test/tests/multi/three_surface11.i)
(modules/solid_mechanics/test/tests/mohr_coulomb/small_deform4.i)
(modules/solid_mechanics/test/tests/crystal_plasticity/monolithic_material_based/crysp_cutback.i)
(modules/solid_mechanics/test/tests/mohr_coulomb/small_deform_hard2.i)
(modules/solid_mechanics/test/tests/mohr_coulomb/random.i)
(modules/contact/test/tests/verification/patch_tests/brick_3/brick3_template2.i)
(modules/xfem/test/tests/moving_interface/moving_bimaterial_finite_strain_esm.i)
(modules/contact/test/tests/mortar_dynamics/block-dynamics-action.i)
(modules/solid_mechanics/test/tests/hyperelastic_viscoplastic/one_elem.i)
(modules/solid_mechanics/test/tests/jacobian_damper/cube_load.i)
(modules/solid_mechanics/test/tests/crystal_plasticity/monolithic_material_based/crysp_user_object.i)
(modules/contact/test/tests/verification/patch_tests/brick_3/brick3_template1.i)
(modules/solid_mechanics/test/tests/stress_recovery/patch/patch_finite_stress.i)
(modules/solid_mechanics/test/tests/visco/visco_finite_strain.i)
(modules/solid_mechanics/test/tests/multi/three_surface06.i)
(modules/solid_mechanics/test/tests/mohr_coulomb/except2.i)
(modules/solid_mechanics/test/tests/crystal_plasticity/monolithic_material_based/crysp_substep.i)
(modules/solid_mechanics/test/tests/mohr_coulomb/planar_hard5.i)
(modules/solid_mechanics/test/tests/mohr_coulomb/small_deform1_uo.i)
(modules/solid_mechanics/test/tests/crystal_plasticity/monolithic_material_based/crysp_save_euler.i)
(modules/xfem/test/tests/moving_interface/moving_bimaterial_finite_strain.i)
(modules/solid_mechanics/test/tests/elem_prop_read_user_object/prop_grain_read_3d.i)
(modules/solid_mechanics/test/tests/mohr_coulomb/planar_hard3.i)
(modules/solid_mechanics/test/tests/j2_plasticity/hard2.i)
(modules/solid_mechanics/test/tests/multi/three_surface01.i)
(modules/contact/test/tests/pdass_problems/ironing_penalty.i)
(modules/contact/test/tests/pdass_problems/ironing_penalty_action.i)
(modules/contact/test/tests/mortar_dynamics/block-dynamics-friction-action.i)
(modules/contact/test/tests/explicit_dynamics/test_balance.i)
(modules/combined/test/tests/j2_plasticity_vs_LSH/necking/j2_hard1_necking.i)
(modules/solid_mechanics/test/tests/isotropicSD_plasticity/isotropicSD.i)
(modules/solid_mechanics/test/tests/crystal_plasticity/user_object_based/user_object.i)
(modules/solid_mechanics/test/tests/multi/three_surface10.i)
(modules/fsi/test/tests/fsi_acoustics/1D_struc_acoustic/1D_struc_acoustic.i)
(modules/solid_mechanics/test/tests/crystal_plasticity/user_object_based/exception.i)
(modules/combined/test/tests/poro_mechanics/borehole_highres.i)
(modules/contact/test/tests/mortar_dynamics/block-dynamics-friction.i)
(modules/solid_mechanics/test/tests/multi/two_surface05.i)
(modules/contact/test/tests/verification/patch_tests/mindlin/cylinder_friction_node_face.i)
(modules/solid_mechanics/test/tests/volumetric_deform_grad/volumetric_strain_interface.i)
(modules/solid_mechanics/test/tests/mohr_coulomb/small_deform5.i)
(modules/contact/test/tests/verification/patch_tests/brick_2/brick2_aug.i)
(modules/solid_mechanics/test/tests/crystal_plasticity/user_object_based/substep.i)
(modules/solid_mechanics/test/tests/multi/three_surface13.i)
(modules/contact/test/tests/mortar_aux_kernels/block-dynamics-aux-wear-vel.i)
(modules/solid_mechanics/test/tests/multi/three_surface15.i)
(modules/solid_mechanics/test/tests/initial_stress/mc_tensile.i)
(modules/xfem/test/tests/moving_interface/moving_bimaterial_finite_strain_esm_using_cut_mesh.i)
(modules/contact/test/tests/mortar_aux_kernels/block-dynamics-aux-wear.i)
(modules/solid_mechanics/test/tests/finite_strain_tensor_mechanics_tests/elastic_rotation.i)
(modules/solid_mechanics/test/tests/multi/four_surface14.i)
(modules/solid_mechanics/test/tests/ad_elastic/finite_elastic-noad.i)
(modules/solid_mechanics/test/tests/multi/paper1.i)
(modules/solid_mechanics/test/tests/auxkernels/principalstress.i)
(modules/solid_mechanics/test/tests/mohr_coulomb/small_deform3.i)
(modules/solid_mechanics/test/tests/multi/three_surface07.i)
(modules/contact/test/tests/verification/hertz_cyl/half_symm_q4/hertz_cyl_half_1deg_template1.i)
(modules/solid_mechanics/test/tests/crystal_plasticity/user_object_based/patch_recovery.i)
(modules/solid_mechanics/test/tests/volumetric_deform_grad/elastic_stress.i)
(modules/solid_mechanics/test/tests/crystal_plasticity/user_object_based/save_euler.i)
(modules/solid_mechanics/test/tests/action/custom_output.i)
(modules/solid_mechanics/test/tests/multi/three_surface08.i)
(modules/contact/test/tests/mortar_dynamics/block-dynamics-reference.i)
(modules/solid_mechanics/test/tests/crystal_plasticity/user_object_based/fileread.i)
(modules/solid_mechanics/test/tests/multi/three_surface03.i)
(modules/solid_mechanics/test/tests/j2_plasticity/small_deform1.i)
(modules/solid_mechanics/test/tests/multi/six_surface14.i)
(modules/solid_mechanics/test/tests/mohr_coulomb/small_deform_hard3.i)
(modules/contact/test/tests/mortar_aux_kernels/block-dynamics-aux-fretting-wear-test.i)
(modules/solid_mechanics/test/tests/mohr_coulomb/planar3.i)
(modules/contact/test/tests/verification/patch_tests/brick_2/brick2_mu_0_2_pen.i)
(modules/solid_mechanics/test/tests/j2_plasticity/small_deform3.i)
(modules/solid_mechanics/test/tests/isotropicSD_plasticity/powerRuleHardening.i)
(modules/solid_mechanics/test/tests/mohr_coulomb/except4.i)
(modules/solid_mechanics/test/tests/mohr_coulomb/except1.i)
(modules/solid_mechanics/test/tests/mohr_coulomb/small_deform_hard_cubic.i)
(modules/solid_mechanics/test/tests/crystal_plasticity/monolithic_material_based/crysp_linesearch.i)
(modules/solid_mechanics/test/tests/multi/three_surface21.i)
(modules/contact/test/tests/pdass_problems/cylinder_friction.i)
(modules/solid_mechanics/test/tests/crystal_plasticity/monolithic_material_based/cp_slip_rate_integ/crysp.i)
(modules/contact/test/tests/verification/patch_tests/brick_4/brick4_mu_0_2_pen.i)
(modules/solid_mechanics/test/tests/j2_plasticity/solid_mechanics_j2plasticity.i)
(modules/contact/test/tests/pdass_problems/cylinder_friction_penalty.i)
(modules/contact/test/tests/verification/patch_tests/brick_1/brick1_aug.i)
(modules/solid_mechanics/test/tests/multi/two_surface04.i)
(modules/solid_mechanics/test/tests/crystal_plasticity/user_object_based/linesearch.i)
(modules/solid_mechanics/test/tests/crystal_plasticity/monolithic_material_based/cp_slip_rate_integ/crysp_substep.i)
(modules/contact/test/tests/verification/hertz_cyl/half_symm_q4/hertz_cyl_half_1deg_template3.i)
(modules/solid_mechanics/test/tests/j2_plasticity/small_deform2.i)
(modules/solid_mechanics/test/tests/mohr_coulomb/small_deform_hard1.i)
(modules/combined/test/tests/cavity_pressure/3d.i)
(modules/contact/test/tests/verification/patch_tests/brick_1/brick1_template1.i)
(modules/solid_mechanics/test/tests/multi/three_surface12.i)
(modules/solid_mechanics/test/tests/auxkernels/ranktwoscalaraux.i)
(modules/solid_mechanics/test/tests/mohr_coulomb/small_deform2.i)
(modules/solid_mechanics/test/tests/mohr_coulomb/uni_axial1.i)
(modules/solid_mechanics/test/tests/multi/four_surface24.i)
(modules/solid_mechanics/test/tests/hyperelastic_viscoplastic/one_elem_linear_harden.i)
(modules/contact/test/tests/verification/overclosure_removal/overclosure.i)
(modules/solid_mechanics/test/tests/multi/special_rock1.i)
(modules/solid_mechanics/test/tests/multi/three_surface00.i)
(modules/solid_mechanics/test/tests/multi/eight_surface14.i)
(modules/solid_mechanics/test/tests/multi/three_surface22.i)
(modules/solid_mechanics/test/tests/mohr_coulomb/planar1.i)
(modules/solid_mechanics/test/tests/mohr_coulomb/planar_hard2.i)
(modules/solid_mechanics/test/tests/multi/rock1.i)
(modules/combined/test/tests/poro_mechanics/borehole_lowres.i)
(modules/contact/test/tests/glued/glued_contact_mechanical_constraint_test.i)
(modules/solid_mechanics/test/tests/crystal_plasticity/user_object_based/prop_block_read.i)
(modules/solid_mechanics/test/tests/elem_prop_read_user_object/prop_grain_read.i)
(modules/contact/test/tests/verification/patch_tests/brick_4/brick4_template1.i)
(modules/solid_mechanics/test/tests/multi/two_surface03.i)
(modules/combined/test/tests/cavity_pressure/multiple_postprocessors.i)

Child Objects

(modules/solid_mechanics/include/materials/Compute2DFiniteStrain.h)
(modules/solid_mechanics/include/materials/Compute1DFiniteStrain.h)
(modules/solid_mechanics/include/materials/ComputeRSphericalFiniteStrain.h)

References

Thomas JR Hughes and James Winget. Finite rotation effects in numerical integration of rate constitutive equations arising in large-deformation analysis. International journal for numerical methods in engineering, 15(12):1862–1867, 1980.

@article{hughes1980finite,
    author = "Hughes, Thomas JR and Winget, James",
    title = "Finite rotation effects in numerical integration of rate constitutive equations arising in large-deformation analysis",
    journal = "International journal for numerical methods in engineering",
    volume = "15",
    number = "12",
    pages = "1862--1867",
    year = "1980",
    publisher = "Wiley Online Library"
}

Lawrence E Malvern. Introduction to the Mechanics of a Continuous Medium. Prentice-Hall, 1969.

MM Rashid. Incremental kinematics for finite element applications. International Journal for Numerical Methods in Engineering, 36(23):3937–3956, 1993.

@article{rashid1993incremental,
    author = "Rashid, MM",
    title = "Incremental kinematics for finite element applications",
    journal = "International Journal for Numerical Methods in Engineering",
    volume = "36",
    number = "23",
    pages = "3937--3956",
    year = "1993",
    publisher = "Wiley Online Library"
}

Ziyu Zhang, Wen Jiang, John E Dolbow, and Benjamin W Spencer. A modified moment-fitted integration scheme for x-fem applications with history-dependent material data. Computational Mechanics, pages 1–20, 2018.

@article{zhang2018modified,
    author = "Zhang, Ziyu and Jiang, Wen and Dolbow, John E and Spencer, Benjamin W",
    title = "A modified moment-fitted integration scheme for X-FEM applications with history-dependent material data",
    journal = "Computational Mechanics",
    pages = "1--20",
    year = "2018",
    publisher = "Springer"
}

(modules/solid_mechanics/test/tests/finite_strain_elastic/finite_strain_elastic_new_test.i)

[Mesh]
  type = GeneratedMesh
  dim = 3
  elem_type = HEX8
[]

[GlobalParams]
  displacements = 'disp_x disp_y disp_z'
[]

[Functions]
  [./tdisp]
    type = ParsedFunction
    expression = '0.01 * t'
  [../]
[]

[Physics]
  [SolidMechanics]
    [QuasiStatic]
      [./all]
        strain = FINITE
        add_variables = true
      [../]
    [../]
  [../]
[]

[BCs]
  [./symmy]
    type = DirichletBC
    variable = disp_y
    boundary = bottom
    value = 0
  [../]
  [./symmx]
    type = DirichletBC
    variable = disp_x
    boundary = left
    value = 0
  [../]
  [./symmz]
    type = DirichletBC
    variable = disp_z
    boundary = back
    value = 0
  [../]
  [./tdisp]
    type = FunctionDirichletBC
    variable = disp_z
    boundary = front
    function = tdisp
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeElasticityTensor
    C_ijkl = '1.684e5 0.176e5 0.176e5 1.684e5 0.176e5 1.684e5 0.754e5 0.754e5 0.754e5'
    fill_method = symmetric9
  [../]
  [./stress]
    type = ComputeFiniteStrainElasticStress
  [../]
[]

[Preconditioning]
  [./smp]
    type = SMP
    full = true
  [../]
[]

[Executioner]
  type = Transient
  dt = 0.05

  #Preconditioned JFNK (default)
  solve_type = 'PJFNK'

  petsc_options_iname = -pc_hypre_type
  petsc_options_value = boomeramg
  nl_abs_tol = 1e-10
  nl_rel_step_tol = 1e-10
  dtmax = 10.0
  nl_rel_tol = 1e-10
  end_time = 1
  dtmin = 0.05
  num_steps = 10
  nl_abs_step_tol = 1e-10
[]

[Outputs]
  exodus = true
[]

(modules/solid_mechanics/test/tests/volumetric_deform_grad/elastic_stress.i)

[Mesh]
  type = GeneratedMesh
  dim = 3
  elem_type = HEX8
  displacements = 'disp_x disp_y disp_z'
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./disp_z]
  [../]
[]

[Kernels]
  [SolidMechanics]
    displacements = 'disp_x disp_y disp_z'
    use_displaced_mesh = true
  [../]
[]

[AuxVariables]
  [./stress_zz]
    order = CONSTANT
    family = MONOMIAL
    block = 0
  [../]
[]

[AuxKernels]
  [./stress_zz]
    type = RankTwoAux
    variable = stress_zz
    rank_two_tensor = stress
    index_j = 2
    index_i = 2
    execute_on = timestep_end
    block = 0
  [../]
[]

[BCs]
  [./symmy]
    type = DirichletBC
    variable = disp_y
    boundary = bottom
    value = 0
  [../]
  [./symmx]
    type = DirichletBC
    variable = disp_x
    boundary = left
    value = 0
  [../]
  [./symmz]
    type = DirichletBC
    variable = disp_z
    boundary = back
    value = 0
  [../]
  [./tdisp]
    type = FunctionDirichletBC
    variable = disp_z
    boundary = front
    function = '0.01*t'
  [../]
[]

[Materials]
  [./strain]
    type = ComputeFiniteStrain
    block = 0
    displacements = 'disp_x disp_y disp_z'
  [../]
  [./elastic_stress]
    type = ComputeDeformGradBasedStress
    deform_grad_name = deformation_gradient
    elasticity_tensor_name = elasticity_tensor
    stress_name = stress
    jacobian_name = Jacobian_mult
    block = 0
  [../]
  [./elasticity_tensor]
    type = ComputeElasticityTensor
    block = 0
    C_ijkl = '2.8e5 1.2e5 1.2e5 2.8e5 1.2e5 2.8e5 0.8e5 0.8e5 0.8e5'
    fill_method = symmetric9
  [../]
[]

[Postprocessors]
  [./stress_zz]
    type = ElementAverageValue
    variable = stress_zz
    block = 'ANY_BLOCK_ID 0'
  [../]
[]

[Preconditioning]
  [./smp]
    type = SMP
    full = true
  [../]
[]

[Executioner]
  type = Transient
  dt = 0.02
  #Preconditioned JFNK (default)
  solve_type = 'PJFNK'
  petsc_options_iname = '-pc_type -pc_hypre_type -ksp_gmres_restart'
  petsc_options_value = 'hypre boomeramg 101'
  dtmax = 10.0
  nl_rel_tol = 1e-10
  dtmin = 0.02
  num_steps = 10
[]

[Outputs]
  csv = true
[]

(modules/solid_mechanics/test/tests/multi/three_surface16.i)

# Plasticit models:
# SimpleTester0 with a = 0 and b = 1 and strength = 1
# SimpleTester1 with a = 1 and b = 0 and strength = 1
# SimpleTester2 with a = 1 and b = 1 and strength = 3
#
# Lame lambda = 0 (Poisson=0).  Lame mu = 0.5E6
#
# A single element is stretched by 3.0E-6m in y direction and 2.1E-6 in z direction.
# trial stress_yy = 3.0 and stress_zz = 2.1
#
# A complicated return will follow, with various contraints being
# deactivated, kuhn-tucker failing, line-searching, etc, but
# the result should be
# stress_yy=1=stress_zz, and internal0=1.1 internal1=2

[Mesh]
  type = GeneratedMesh
  dim = 3
  nx = 1
  ny = 1
  nz = 1
  xmin = -0.5
  xmax = 0.5
  ymin = -0.5
  ymax = 0.5
  zmin = -0.5
  zmax = 0.5
[]


[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./disp_z]
  [../]
[]

[Kernels]
  [SolidMechanics]
    displacements = 'disp_x disp_y disp_z'
  [../]
[]


[BCs]
  [./x]
    type = FunctionDirichletBC
    variable = disp_x
    boundary = 'front back'
    function = '0E-6*x'
  [../]
  [./y]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = 'front back'
    function = '3.0E-6*y'
  [../]
  [./z]
    type = FunctionDirichletBC
    variable = disp_z
    boundary = 'front back'
    function = '2.1E-6*z'
  [../]
[]

[AuxVariables]
  [./stress_xx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_zz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./f0]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./f1]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./f2]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./int0]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./int1]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./int2]
    order = CONSTANT
    family = MONOMIAL
  [../]
[]

[AuxKernels]
  [./stress_xx]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xx
    index_i = 0
    index_j = 0
  [../]
  [./stress_xy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xy
    index_i = 0
    index_j = 1
  [../]
  [./stress_xz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xz
    index_i = 0
    index_j = 2
  [../]
  [./stress_yy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yy
    index_i = 1
    index_j = 1
  [../]
  [./stress_yz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yz
    index_i = 1
    index_j = 2
  [../]
  [./stress_zz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_zz
    index_i = 2
    index_j = 2
  [../]
  [./f0]
    type = MaterialStdVectorAux
    property = plastic_yield_function
    index = 0
    variable = f0
  [../]
  [./f1]
    type = MaterialStdVectorAux
    property = plastic_yield_function
    index = 1
    variable = f1
  [../]
  [./f2]
    type = MaterialStdVectorAux
    property = plastic_yield_function
    index = 2
    variable = f2
  [../]
  [./int0]
    type = MaterialStdVectorAux
    property = plastic_internal_parameter
    factor = 1E6
    index = 0
    variable = int0
  [../]
  [./int1]
    type = MaterialStdVectorAux
    property = plastic_internal_parameter
    factor = 1E6
    index = 1
    variable = int1
  [../]
  [./int2]
    type = MaterialStdVectorAux
    property = plastic_internal_parameter
    factor = 1E6
    index = 2
    variable = int2
  [../]
[]

[Postprocessors]
  [./s_xx]
    type = PointValue
    point = '0 0 0'
    variable = stress_xx
  [../]
  [./s_xy]
    type = PointValue
    point = '0 0 0'
    variable = stress_xy
  [../]
  [./s_xz]
    type = PointValue
    point = '0 0 0'
    variable = stress_xz
  [../]
  [./s_yy]
    type = PointValue
    point = '0 0 0'
    variable = stress_yy
  [../]
  [./s_yz]
    type = PointValue
    point = '0 0 0'
    variable = stress_yz
  [../]
  [./s_zz]
    type = PointValue
    point = '0 0 0'
    variable = stress_zz
  [../]
  [./f0]
    type = PointValue
    point = '0 0 0'
    variable = f0
  [../]
  [./f1]
    type = PointValue
    point = '0 0 0'
    variable = f1
  [../]
  [./f2]
    type = PointValue
    point = '0 0 0'
    variable = f2
  [../]
  [./int0]
    type = PointValue
    point = '0 0 0'
    variable = int0
  [../]
  [./int1]
    type = PointValue
    point = '0 0 0'
    variable = int1
  [../]
  [./int2]
    type = PointValue
    point = '0 0 0'
    variable = int2
  [../]
[]

[UserObjects]
  [./simple0]
    type = SolidMechanicsPlasticSimpleTester
    a = 0
    b = 1
    strength = 1
    yield_function_tolerance = 1.0E-6
    internal_constraint_tolerance = 1.0E-6
  [../]
  [./simple1]
    type = SolidMechanicsPlasticSimpleTester
    a = 1
    b = 0
    strength = 1
    yield_function_tolerance = 1.0E-6
    internal_constraint_tolerance = 1.0E-6
  [../]
  [./simple2]
    type = SolidMechanicsPlasticSimpleTester
    a = 1
    b = 1
    strength = 3
    yield_function_tolerance = 1.0E-6
    internal_constraint_tolerance = 1.0E-6
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeElasticityTensor
    block = 0
    fill_method = symmetric_isotropic
    C_ijkl = '0 0.5E6'
  [../]
  [./strain]
    type = ComputeFiniteStrain
    block = 0
    displacements = 'disp_x disp_y disp_z'
  [../]
  [./multi]
    type = ComputeMultiPlasticityStress
    block = 0
    ep_plastic_tolerance = 1E-9
    plastic_models = 'simple0 simple1 simple2'
    max_NR_iterations = 4
    min_stepsize = 1
    debug_fspb = crash
    debug_jac_at_stress = '10 0 0 0 10 0 0 0 10'
    debug_jac_at_pm = '1 1 1'
    debug_jac_at_intnl = '1 1 1'
    debug_stress_change = 1E-5
    debug_pm_change = '1E-6 1E-6 1E-6'
    debug_intnl_change = '1E-6 1E-6 1E-6'
  [../]
[]


[Executioner]
  end_time = 1
  dt = 1
  type = Transient
[]


[Outputs]
  file_base = three_surface16
  exodus = false
  [./csv]
    type = CSV
    [../]
[]

(modules/solid_mechanics/test/tests/mohr_coulomb/planar_hard4.i)

# apply repeated stretches in x direction, and smaller stretches along the y and z directions,
# so that sigma_II = sigma_III,
# which means that lode angle = -30deg.
# Both return to the edge (at lode_angle=-30deg, ie 000101) and tip are experienced.
#
# It is checked that the yield functions are less than their tolerance values
# It is checked that the cohesion hardens correctly

[Mesh]
  type = GeneratedMesh
  dim = 3
  nx = 1
  ny = 1
  nz = 1
  xmin = -0.5
  xmax = 0.5
  ymin = -0.5
  ymax = 0.5
  zmin = -0.5
  zmax = 0.5
[]


[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./disp_z]
  [../]
[]

[Kernels]
  [SolidMechanics]
    displacements = 'disp_x disp_y disp_z'
  [../]
[]


[BCs]
  [./x]
    type = FunctionDirichletBC
    variable = disp_x
    boundary = 'front back'
    function = '0.05E-6*x*t'
  [../]
  [./y]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = 'front back'
    function = '0.05E-6*y*t'
  [../]
  [./z]
    type = FunctionDirichletBC
    variable = disp_z
    boundary = 'front back'
    function = '1E-6*z*t'
  [../]
[]

[Functions]
  [./should_be_zero_fcn]
    type = ParsedFunction
    expression = 'if((a<1E-5)&(b<1E-5)&(c<1E-5)&(d<1E-5)&(g<1E-5)&(h<1E-5),0,abs(a)+abs(b)+abs(c)+abs(d)+abs(g)+abs(h))'
    symbol_names = 'a b c d g h'
    symbol_values = 'f0 f1 f2 f3 f4 f5'
  [../]
  [./coh_analytic]
    type = ParsedFunction
    expression = '20-10*exp(-1E5*intnl)'
    symbol_names = intnl
    symbol_values = internal
  [../]
  [./coh_from_yieldfcns]
    type = ParsedFunction
    expression = '(f0+f1-(sxx+syy)*sin(phi))/(-2)/cos(phi)'
    symbol_names = 'f0 f1 sxx syy phi'
    symbol_values = 'f0 f1 s_xx s_yy 0.8726646'
  [../]
  [./should_be_zero_coh]
    type = ParsedFunction
    expression = 'if(abs(a-b)<1E-6,0,1E6*abs(a-b))'
    symbol_names = 'a b'
    symbol_values = 'Coh_analytic Coh_moose'
  [../]
[]

[AuxVariables]
  [./stress_xx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_zz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./mc_int]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./yield_fcn0]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./yield_fcn1]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./yield_fcn2]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./yield_fcn3]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./yield_fcn4]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./yield_fcn5]
    order = CONSTANT
    family = MONOMIAL
  [../]
[]

[AuxKernels]
  [./stress_xx]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xx
    index_i = 0
    index_j = 0
  [../]
  [./stress_xy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xy
    index_i = 0
    index_j = 1
  [../]
  [./stress_xz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xz
    index_i = 0
    index_j = 2
  [../]
  [./stress_yy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yy
    index_i = 1
    index_j = 1
  [../]
  [./stress_yz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yz
    index_i = 1
    index_j = 2
  [../]
  [./stress_zz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_zz
    index_i = 2
    index_j = 2
  [../]
  [./mc_int_auxk]
    type = MaterialStdVectorAux
    index = 0
    property = plastic_internal_parameter
    variable = mc_int
  [../]
  [./yield_fcn0]
    type = MaterialStdVectorAux
    index = 0
    property = plastic_yield_function
    variable = yield_fcn0
  [../]
  [./yield_fcn1]
    type = MaterialStdVectorAux
    index = 1
    property = plastic_yield_function
    variable = yield_fcn1
  [../]
  [./yield_fcn2]
    type = MaterialStdVectorAux
    index = 2
    property = plastic_yield_function
    variable = yield_fcn2
  [../]
  [./yield_fcn3]
    type = MaterialStdVectorAux
    index = 3
    property = plastic_yield_function
    variable = yield_fcn3
  [../]
  [./yield_fcn4]
    type = MaterialStdVectorAux
    index = 4
    property = plastic_yield_function
    variable = yield_fcn4
  [../]
  [./yield_fcn5]
    type = MaterialStdVectorAux
    index = 5
    property = plastic_yield_function
    variable = yield_fcn5
  [../]
[]

[Postprocessors]
  [./s_xx]
    type = PointValue
    point = '0 0 0'
    variable = stress_xx
  [../]
  [./s_xy]
    type = PointValue
    point = '0 0 0'
    variable = stress_xy
  [../]
  [./s_xz]
    type = PointValue
    point = '0 0 0'
    variable = stress_xz
  [../]
  [./s_yy]
    type = PointValue
    point = '0 0 0'
    variable = stress_yy
  [../]
  [./s_yz]
    type = PointValue
    point = '0 0 0'
    variable = stress_yz
  [../]
  [./s_zz]
    type = PointValue
    point = '0 0 0'
    variable = stress_zz
  [../]
  [./internal]
    type = PointValue
    point = '0 0 0'
    variable = mc_int
  [../]
  [./f0]
    type = PointValue
    point = '0 0 0'
    variable = yield_fcn0
  [../]
  [./f1]
    type = PointValue
    point = '0 0 0'
    variable = yield_fcn1
  [../]
  [./f2]
    type = PointValue
    point = '0 0 0'
    variable = yield_fcn2
  [../]
  [./f3]
    type = PointValue
    point = '0 0 0'
    variable = yield_fcn3
  [../]
  [./f4]
    type = PointValue
    point = '0 0 0'
    variable = yield_fcn4
  [../]
  [./f5]
   type = PointValue
    point = '0 0 0'
    variable = yield_fcn5
  [../]
  [./yfcns_should_be_zero]
    type = FunctionValuePostprocessor
    function = should_be_zero_fcn
  [../]
  [./Coh_analytic]
    type = FunctionValuePostprocessor
    function = coh_analytic
  [../]
  [./Coh_moose]
    type = FunctionValuePostprocessor
    function = coh_from_yieldfcns
  [../]
  [./cohesion_difference_should_be_zero]
    type = FunctionValuePostprocessor
    function = should_be_zero_coh
  [../]
[]

[UserObjects]
  [./mc_coh]
    type = SolidMechanicsHardeningExponential
    value_0 = 10
    value_residual = 20
    rate = 1E5
  [../]
  [./mc_phi]
    type = SolidMechanicsHardeningConstant
    value = 0.8726646
  [../]
  [./mc_psi]
    type = SolidMechanicsHardeningConstant
    value = 1 #0.8726646 # 50deg
  [../]
  [./mc]
    type = SolidMechanicsPlasticMohrCoulombMulti
    cohesion = mc_coh
    friction_angle = mc_phi
    dilation_angle = mc_psi
    use_custom_returnMap = true
    yield_function_tolerance = 1E-5
    internal_constraint_tolerance = 1E-9
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeElasticityTensor
    block = 0
    fill_method = symmetric_isotropic
    C_ijkl = '0 1E7'
  [../]
  [./strain]
    type = ComputeFiniteStrain
    block = 0
    displacements = 'disp_x disp_y disp_z'
  [../]
  [./mc]
    type = ComputeMultiPlasticityStress
    block = 0
    ep_plastic_tolerance = 1E-12
    plastic_models = mc
  [../]
[]


[Executioner]
  end_time = 10
  dt = 2
  type = Transient
[]


[Outputs]
  file_base = planar_hard4
  exodus = false
  [./csv]
    type = CSV
    hide = 'f0 f1 f2 f3 f4 f5 s_xy s_xz s_yz Coh_analytic Coh_moose'
    execute_on = 'timestep_end'
  [../]
[]

(modules/solid_mechanics/test/tests/crystal_plasticity/monolithic_material_based/crysp.i)

[Mesh]
  type = GeneratedMesh
  dim = 3
  elem_type = HEX8
  displacements = 'ux uy uz'
[]

[Variables]
  [./ux]
    block = 0
  [../]
  [./uy]
    block = 0
  [../]
  [./uz]
    block = 0
  [../]
[]

[AuxVariables]
  [./stress_zz]
    order = CONSTANT
    family = MONOMIAL
    block = 0
  [../]
  [./fp_zz]
    order = CONSTANT
    family = MONOMIAL
    block = 0
  [../]
  [./rotout]
    order = CONSTANT
    family = MONOMIAL
    block = 0
  [../]
  [./e_zz]
    order = CONSTANT
    family = MONOMIAL
    block = 0
  [../]
  [./gss1]
    order = CONSTANT
    family = MONOMIAL
    block = 0
  [../]
[]

[Functions]
  [./tdisp]
    type = ParsedFunction
    expression = 0.01*t
  [../]
[]

[Kernels]
  [SolidMechanics]
    displacements = 'ux uy uz'
    use_displaced_mesh = true
  [../]
[]

[AuxKernels]
  [./stress_zz]
    type = RankTwoAux
    variable = stress_zz
    rank_two_tensor = stress
    index_j = 2
    index_i = 2
    execute_on = timestep_end
    block = 0
  [../]
  [./fp_zz]
    type = RankTwoAux
    variable = fp_zz
    rank_two_tensor = fp
    index_j = 2
    index_i = 2
    execute_on = timestep_end
    block = 0
  [../]
  [./e_zz]
    type = RankTwoAux
    variable = e_zz
    rank_two_tensor = lage
    index_j = 2
    index_i = 2
    execute_on = timestep_end
    block = 0
  [../]
  [./gss1]
    type = MaterialStdVectorAux
    variable = gss1
    property = gss
    index = 0
    execute_on = timestep_end
    block = 0
  [../]
[]

[BCs]
  [./symmy]
    type = DirichletBC
    variable = uy
    boundary = bottom
    value = 0
  [../]
  [./symmx]
    type = DirichletBC
    variable = ux
    boundary = left
    value = 0
  [../]
  [./symmz]
    type = DirichletBC
    variable = uz
    boundary = back
    value = 0
  [../]
  [./tdisp]
    type = FunctionDirichletBC
    variable = uz
    boundary = front
    function = tdisp
  [../]
[]

[Materials]
  [./crysp]
    type = FiniteStrainCrystalPlasticity
    block = 0
    gtol = 1e-2
    slip_sys_file_name = input_slip_sys.txt
    nss = 12
    num_slip_sys_flowrate_props = 2 #Number of properties in a slip system
    flowprops = '1 4 0.001 0.1 5 8 0.001 0.1 9 12 0.001 0.1'
    hprops = '1.0 541.5 60.8 109.8 2.5'
    gprops = '1 4 60.8 5 8 60.8 9 12 60.8'
    tan_mod_type = exact
  [../]
  [./elasticity_tensor]
    type = ComputeElasticityTensorCP
    block = 0
    C_ijkl = '1.684e5 1.214e5 1.214e5 1.684e5 1.214e5 1.684e5 0.754e5 0.754e5 0.754e5'
    fill_method = symmetric9
  [../]
  [./strain]
    type = ComputeFiniteStrain
    block = 0
    displacements = 'ux uy uz'
  [../]
[]

[Postprocessors]
  [./stress_zz]
    type = ElementAverageValue
    variable = stress_zz
    block = 'ANY_BLOCK_ID 0'
  [../]
  [./fp_zz]
    type = ElementAverageValue
    variable = fp_zz
    block = 'ANY_BLOCK_ID 0'
  [../]
  [./e_zz]
    type = ElementAverageValue
    variable = e_zz
    block = 'ANY_BLOCK_ID 0'
  [../]
  [./gss1]
    type = ElementAverageValue
    variable = gss1
    block = 'ANY_BLOCK_ID 0'
  [../]
[]

[Preconditioning]
  [./smp]
    type = SMP
    full = true
  [../]
[]

[Executioner]
  type = Transient

  #Preconditioned JFNK (default)
  solve_type = 'PJFNK'

  petsc_options_iname = '-pc_type'
  petsc_options_value = 'lu'

  nl_rel_tol = 1e-10
  nl_abs_tol = 1e-10

  dt = 0.05
  dtmax = 10.0
  dtmin = 0.05

  num_steps = 10
[]

[Outputs]
  file_base = out
  exodus = true
[]

(modules/solid_mechanics/test/tests/multi/special_joint1.i)

# Plasticity models:
# WeakPlaneTensile with strength = 1000Pa
# WeakPlaneShear with cohesion = 0.1MPa and friction angle = 25
#
# Lame lambda = 1GPa.  Lame mu = 1.3GPa
#
# A line of elements is perturbed randomly, and return to the yield surface at each quadpoint is checked

[Mesh]
  type = GeneratedMesh
  dim = 3
  nx = 1000
  ny = 125
  nz = 1
  xmin = 0
  xmax = 1000
  ymin = 0
  ymax = 125
  zmin = 0
  zmax = 1
[]

[GlobalParams]
  volumetric_locking_correction=true
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./disp_z]
  [../]
[]

[Kernels]
  [SolidMechanics]
    displacements = 'disp_x disp_y disp_z'
  [../]
[]


[ICs]
  [./x]
    type = RandomIC
    min = -0.1
    max = 0.1
    variable = disp_x
  [../]
  [./y]
    type = RandomIC
    min = -0.1
    max = 0.1
    variable = disp_y
  [../]
  [./z]
    type = RandomIC
    min = -0.1
    max = 0.1
    variable = disp_z
  [../]
[]

[BCs]
  [./x]
    type = FunctionDirichletBC
    variable = disp_x
    boundary = 'front back'
    function = '0'
  [../]
  [./y]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = 'front back'
    function = '0'
  [../]
  [./z]
    type = FunctionDirichletBC
    variable = disp_z
    boundary = 'front back'
    function = '0'
  [../]
[]

[AuxVariables]
  [./stress_xx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_zz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./linesearch]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./ld]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./constr_added]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./iter]
    order = CONSTANT
    family = MONOMIAL
  [../]
[]

[AuxKernels]
  [./stress_xx]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xx
    index_i = 0
    index_j = 0
  [../]
  [./stress_xy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xy
    index_i = 0
    index_j = 1
  [../]
  [./stress_xz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xz
    index_i = 0
    index_j = 2
  [../]
  [./stress_yy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yy
    index_i = 1
    index_j = 1
  [../]
  [./stress_yz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yz
    index_i = 1
    index_j = 2
  [../]
  [./stress_zz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_zz
    index_i = 2
    index_j = 2
  [../]
  [./linesearch]
    type = MaterialRealAux
    property = plastic_linesearch_needed
    variable = linesearch
  [../]
  [./ld]
    type = MaterialRealAux
    property = plastic_linear_dependence_encountered
    variable = ld
  [../]
  [./constr_added]
    type = MaterialRealAux
    property = plastic_constraints_added
    variable = constr_added
  [../]
  [./iter]
    type = MaterialRealAux
    property = plastic_NR_iterations
    variable = iter
  [../]
[]

[Postprocessors]
  [./max_iter]
    type = ElementExtremeValue
    variable = iter
    outputs = console
  [../]
  [./av_linesearch]
    type = ElementAverageValue
    variable = linesearch
    outputs = 'console csv'
  [../]
  [./av_ld]
    type = ElementAverageValue
    variable = ld
    outputs = 'console csv'
  [../]
  [./av_constr_added]
    type = ElementAverageValue
    variable = constr_added
    outputs = 'console csv'
  [../]
  [./av_iter]
    type = ElementAverageValue
    variable = iter
    outputs = 'console csv'
  [../]
[]

[UserObjects]
  [./wpt_str]
    type = SolidMechanicsHardeningConstant
    value = 1000
  [../]
  [./wpt]
    type = SolidMechanicsPlasticWeakPlaneTensile
    tensile_strength = wpt_str
    yield_function_tolerance = 1.0
    internal_constraint_tolerance = 1.0E-7
  [../]

  [./wps_c]
    type = SolidMechanicsHardeningConstant
    value = 1.0E5
  [../]
  [./wps_tan_phi]
    type = SolidMechanicsHardeningConstant
    value = 0.466
  [../]
  [./wps_tan_psi]
    type = SolidMechanicsHardeningConstant
    value = 0.087
  [../]
  [./wps]
    type = SolidMechanicsPlasticWeakPlaneShear
    cohesion = wps_c
    tan_friction_angle = wps_tan_phi
    tan_dilation_angle = wps_tan_psi
    smoother = 0
    yield_function_tolerance = 1.0
    internal_constraint_tolerance = 1.0E-7
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeElasticityTensor
    block = 0
    fill_method = symmetric_isotropic
    C_ijkl = '1.0E9 1.3E9'
  [../]
  [./strain]
    type = ComputeFiniteStrain
    block = 0
    displacements = 'disp_x disp_y disp_z'
  [../]
  [./multi]
    type = ComputeMultiPlasticityStress
    block = 0
    ep_plastic_tolerance = 1E-7

    plastic_models = 'wpt wps'
    max_NR_iterations = 5
    specialIC = 'joint'
    deactivation_scheme = 'safe'
    min_stepsize = 1
    max_stepsize_for_dumb = 1

    debug_fspb = crash
    debug_jac_at_stress = '10 0 0 0 10 0 0 0 10'
    debug_jac_at_pm = '1 1 1 1'
    debug_jac_at_intnl = '1 1 1 1'
    debug_stress_change = 1E1
    debug_pm_change = '1E-6 1E-6 1E-6 1E-6'
    debug_intnl_change = '1E-6 1E-6 1E-6 1E-6'
  [../]
[]


[Executioner]
  end_time = 1
  dt = 1
  type = Transient
[]


[Outputs]
  file_base = special_joint1
  exodus = false
  csv = true
[]

(modules/solid_mechanics/test/tests/crystal_plasticity/monolithic_material_based/cp_slip_rate_integ/crysp_linesearch.i)

[Mesh]
  type = GeneratedMesh
  dim = 3
  elem_type = HEX8
  displacements = 'disp_x disp_y disp_z'
[]

[Variables]
  [./disp_x]
    block = 0
  [../]
  [./disp_y]
    block = 0
  [../]
  [./disp_z]
    block = 0
  [../]
[]

[AuxVariables]
  [./stress_zz]
    order = CONSTANT
    family = MONOMIAL
    block = 0
  [../]
  [./fp_zz]
    order = CONSTANT
    family = MONOMIAL
    block = 0
  [../]
  [./e_zz]
    order = CONSTANT
    family = MONOMIAL
    block = 0
  [../]
  [./gss1]
    order = CONSTANT
    family = MONOMIAL
    block = 0
  [../]
[]

[Functions]
  [./tdisp]
    type = ParsedFunction
    expression = 0.0001*t
  [../]
[]

[Kernels]
  [SolidMechanics]
    displacements = 'disp_x disp_y disp_z'
    use_displaced_mesh = true
  [../]
[]

[AuxKernels]
  [./stress_zz]
    type = RankTwoAux
    variable = stress_zz
    rank_two_tensor = stress
    index_j = 2
    index_i = 2
    execute_on = timestep_end
    block = 0
  [../]
  [./fp_zz]
    type = RankTwoAux
    variable = fp_zz
    rank_two_tensor = fp
    index_j = 2
    index_i = 2
    execute_on = timestep_end
    block = 0
  [../]
  [./e_zz]
    type = RankTwoAux
    variable = e_zz
    rank_two_tensor = lage
    index_j = 2
    index_i = 2
    execute_on = timestep_end
    block = 0
  [../]
  [./gss1]
    type = MaterialStdVectorAux
    variable = gss1
    property = gss
    index = 0
    execute_on = timestep_end
    block = 0
  [../]
[]

[BCs]
  [./symmy]
    type = DirichletBC
    variable = disp_y
    boundary = bottom
    value = 0
  [../]
  [./symmx]
    type = DirichletBC
    variable = disp_x
    boundary = left
    value = 0
  [../]
  [./symmz]
    type = DirichletBC
    variable = disp_z
    boundary = back
    value = 0
  [../]
  [./tdisp]
    type = FunctionDirichletBC
    variable = disp_z
    boundary = front
    function = tdisp
  [../]
[]

[Materials]
  [./crysp]
    type = FiniteStrainCPSlipRateRes
    block = 0
    slip_sys_file_name = input_slip_sys.txt
    nss = 12
    num_slip_sys_flowrate_props = 2 #Number of properties in a slip system
    flowprops = '1 4 0.001 0.01 5 8 0.001 0.01 9 12 0.001 0.01'
    hprops = '1.0 541.5 60.8 109.8 2.5'
    gprops = '1 4 60.8 5 8 60.8 9 12 60.8'
    tan_mod_type = exact
    slip_incr_tol = 1
    maximum_substep_iteration = 12
    use_line_search = true
    rtol = 1e-8
    abs_tol = 1e-12
    line_search_method = 'BISECTION'
  [../]
  [./elasticity_tensor]
    type = ComputeElasticityTensorCP
    block = 0
    C_ijkl = '1.684e5 1.214e5 1.214e5 1.684e5 1.214e5 1.684e5 0.754e5 0.754e5 0.754e5'
    fill_method = symmetric9
  [../]
  [./strain]
    type = ComputeFiniteStrain
    block = 0
    displacements = 'disp_x disp_y disp_z'
  [../]
[]

[Postprocessors]
  [./stress_zz]
    type = ElementAverageValue
    variable = stress_zz
    block = 'ANY_BLOCK_ID 0'
  [../]
  [./fp_zz]
    type = ElementAverageValue
    variable = fp_zz
    block = 'ANY_BLOCK_ID 0'
  [../]
  [./e_zz]
    type = ElementAverageValue
    variable = e_zz
    block = 'ANY_BLOCK_ID 0'
  [../]
  [./gss1]
    type = ElementAverageValue
    variable = gss1
    block = 'ANY_BLOCK_ID 0'
  [../]
[]

[Preconditioning]
  [./smp]
    type = SMP
    full = true
  [../]
[]

[Executioner]
  type = Transient

  #Preconditioned JFNK (default)
  solve_type = 'PJFNK'

  petsc_options_iname = '-pc_type'
  petsc_options_value = 'lu'

  nl_rel_tol = 1e-10
  nl_abs_tol = 1e-10

  dt = 10
  dtmin = 0.05
  dtmax = 1e4

  num_steps = 10
[]

[Outputs]
  file_base = crysp_linesearch_out
  exodus = true
  print_linear_residuals = true
  perf_graph = true
[]

(modules/solid_mechanics/test/tests/elem_prop_read_user_object/prop_elem_read.i)

[Mesh]
  type = GeneratedMesh
  dim = 2
  elem_type = QUAD4
  displacements = 'disp_x disp_y'
  nx = 2
  ny = 2
[]

[Variables]
  [./disp_x]
    block = 0
  [../]
  [./disp_y]
    block = 0
  [../]
[]

[GlobalParams]
  volumetric_locking_correction=true
[]

[AuxVariables]
  [./stress_yy]
    order = CONSTANT
    family = MONOMIAL
    block = 0
  [../]
  [./e_yy]
    order = CONSTANT
    family = MONOMIAL
    block = 0
  [../]
[]

[Functions]
  [./tdisp]
    type = ParsedFunction
    expression = 0.05*t
  [../]
[]

[UserObjects]
  [./prop_read]
    type = PropertyReadFile
    prop_file_name = 'input_file.txt'
    # Enter file data as prop#1, prop#2, .., prop#nprop
    nprop = 4
    read_type = element
  [../]
[]

[AuxKernels]
  [./stress_yy]
    type = RankTwoAux
    variable = stress_yy
    rank_two_tensor = stress
    index_j = 1
    index_i = 1
    execute_on = timestep_end
    block = 0
  [../]
  [./e_yy]
    type = RankTwoAux
    variable = e_yy
    rank_two_tensor = elastic_strain
    index_j = 1
    index_i = 1
    execute_on = timestep_end
    block = 0
  [../]
[]

[BCs]
  [./fix_x]
    type = DirichletBC
    variable = disp_x
    boundary = 'left'
    value = 0
  [../]
  [./fix_y]
    type = DirichletBC
    variable = disp_y
    boundary = 'bottom'
    value = 0
  [../]
  [./tdisp]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = top
    function = tdisp
  [../]
[]

[Materials]
  [./elasticity_tensor_with_Euler]
    type = ComputeElasticityTensorCP
    block = 0
    C_ijkl = '1.684e5 0.176e5 0.176e5 1.684e5 0.176e5 1.684e5 0.754e5 0.754e5 0.754e5'
    fill_method = symmetric9
    read_prop_user_object = prop_read
  [../]
  [./strain]
    type = ComputeFiniteStrain
    block = 0
    displacements = 'disp_x disp_y'
  [../]
  [./stress]
    type = ComputeFiniteStrainElasticStress
    block = 0
  [../]
[]

[Postprocessors]
  [./stress_yy]
    type = ElementAverageValue
    variable = stress_yy
    block = 'ANY_BLOCK_ID 0'
  [../]
  [./e_yy]
    type = ElementAverageValue
    variable = e_yy
    block = 'ANY_BLOCK_ID 0'
  [../]
[]

[Preconditioning]
  [./smp]
    type = SMP
    full = true
  [../]
[]

[Executioner]
  type = Transient
  dt = 0.05

  #Preconditioned JFNK (default)
  solve_type = 'PJFNK'

  petsc_options_iname = -pc_hypre_type
  petsc_options_value = boomerang
  nl_abs_tol = 1e-10
  nl_rel_step_tol = 1e-10
  dtmax = 10.0
  nl_rel_tol = 1e-10
  end_time = 1
  dtmin = 0.05
  num_steps = 1
  nl_abs_step_tol = 1e-10

[]

[Outputs]
  file_base = prop_elem_read_out
  exodus = true
[]

[Kernels]
  [SolidMechanics]
    displacements = 'disp_x disp_y'
    use_displaced_mesh = true
  [../]
[]

(modules/solid_mechanics/test/tests/multi/three_surface20.i)

# Plasticit models:
# SimpleTester0 with a = 0 and b = 1 and strength = 1
# SimpleTester1 with a = 1 and b = 0 and strength = 1
# SimpleTester2 with a = 1 and b = 1 and strength = 1.5
#
# Lame lambda = 0 (Poisson=0).  Lame mu = 0.5E6
#
# A single element is stretched by 1.1E-6m in y direction and 1.7E-6 in z direction.
# trial stress_yy = 1.1 and stress_zz = 1.7
#
# Then all yield functions will activate
# However, there is linear dependence.  SimpleTester1 will be rutned off.
# The algorithm will return to
# stress_yy=0.5 and stress_zz=1
# internal0=0.1, internal2=0.6


[Mesh]
  type = GeneratedMesh
  dim = 3
  nx = 1
  ny = 1
  nz = 1
  xmin = -0.5
  xmax = 0.5
  ymin = -0.5
  ymax = 0.5
  zmin = -0.5
  zmax = 0.5
[]


[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./disp_z]
  [../]
[]

[Kernels]
  [SolidMechanics]
    displacements = 'disp_x disp_y disp_z'
  [../]
[]


[BCs]
  [./x]
    type = FunctionDirichletBC
    variable = disp_x
    boundary = 'front back'
    function = '0E-6*x'
  [../]
  [./y]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = 'front back'
    function = '1.1E-6*y'
  [../]
  [./z]
    type = FunctionDirichletBC
    variable = disp_z
    boundary = 'front back'
    function = '1.7E-6*z'
  [../]
[]

[AuxVariables]
  [./stress_xx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_zz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./f0]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./f1]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./f2]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./int0]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./int1]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./int2]
    order = CONSTANT
    family = MONOMIAL
  [../]
[]

[AuxKernels]
  [./stress_xx]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xx
    index_i = 0
    index_j = 0
  [../]
  [./stress_xy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xy
    index_i = 0
    index_j = 1
  [../]
  [./stress_xz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xz
    index_i = 0
    index_j = 2
  [../]
  [./stress_yy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yy
    index_i = 1
    index_j = 1
  [../]
  [./stress_yz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yz
    index_i = 1
    index_j = 2
  [../]
  [./stress_zz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_zz
    index_i = 2
    index_j = 2
  [../]
  [./f0]
    type = MaterialStdVectorAux
    property = plastic_yield_function
    index = 0
    variable = f0
  [../]
  [./f1]
    type = MaterialStdVectorAux
    property = plastic_yield_function
    index = 1
    variable = f1
  [../]
  [./f2]
    type = MaterialStdVectorAux
    property = plastic_yield_function
    index = 2
    variable = f2
  [../]
  [./int0]
    type = MaterialStdVectorAux
    property = plastic_internal_parameter
    factor = 1E6
    index = 0
    variable = int0
  [../]
  [./int1]
    type = MaterialStdVectorAux
    property = plastic_internal_parameter
    factor = 1E6
    index = 1
    variable = int1
  [../]
  [./int2]
    type = MaterialStdVectorAux
    property = plastic_internal_parameter
    factor = 1E6
    index = 2
    variable = int2
  [../]
[]

[Postprocessors]
  [./s_xx]
    type = PointValue
    point = '0 0 0'
    variable = stress_xx
  [../]
  [./s_xy]
    type = PointValue
    point = '0 0 0'
    variable = stress_xy
  [../]
  [./s_xz]
    type = PointValue
    point = '0 0 0'
    variable = stress_xz
  [../]
  [./s_yy]
    type = PointValue
    point = '0 0 0'
    variable = stress_yy
  [../]
  [./s_yz]
    type = PointValue
    point = '0 0 0'
    variable = stress_yz
  [../]
  [./s_zz]
    type = PointValue
    point = '0 0 0'
    variable = stress_zz
  [../]
  [./f0]
    type = PointValue
    point = '0 0 0'
    variable = f0
  [../]
  [./f1]
    type = PointValue
    point = '0 0 0'
    variable = f1
  [../]
  [./f2]
    type = PointValue
    point = '0 0 0'
    variable = f2
  [../]
  [./int0]
    type = PointValue
    point = '0 0 0'
    variable = int0
  [../]
  [./int1]
    type = PointValue
    point = '0 0 0'
    variable = int1
  [../]
  [./int2]
    type = PointValue
    point = '0 0 0'
    variable = int2
  [../]
[]

[UserObjects]
  [./simple0]
    type = SolidMechanicsPlasticSimpleTester
    a = 0
    b = 1
    strength = 1
    yield_function_tolerance = 1.0E-9
    internal_constraint_tolerance = 1.0E-9
  [../]
  [./simple1]
    type = SolidMechanicsPlasticSimpleTester
    a = 1
    b = 0
    strength = 1
    yield_function_tolerance = 1.0E-9
    internal_constraint_tolerance = 1.0E-9
  [../]
  [./simple2]
    type = SolidMechanicsPlasticSimpleTester
    a = 1
    b = 1
    strength = 1.5
    yield_function_tolerance = 1.0E-9
    internal_constraint_tolerance = 1.0E-9
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeElasticityTensor
    block = 0
    fill_method = symmetric_isotropic
    C_ijkl = '0 0.5E6'
  [../]
  [./strain]
    type = ComputeFiniteStrain
    block = 0
    displacements = 'disp_x disp_y disp_z'
  [../]
  [./multi]
    type = ComputeMultiPlasticityStress
    block = 0
    ep_plastic_tolerance = 1E-9
    plastic_models = 'simple0 simple1 simple2'
    max_NR_iterations = 2
    min_stepsize = 1
    debug_fspb = crash
    debug_jac_at_stress = '10 0 0 0 10 0 0 0 10'
    debug_jac_at_pm = '1 1'
    debug_jac_at_intnl = '1 1'
    debug_stress_change = 1E-5
    debug_pm_change = '1E-6 1E-6'
    debug_intnl_change = '1E-6 1E-6'
  [../]
[]


[Executioner]
  end_time = 1
  dt = 1
  type = Transient
[]


[Outputs]
  file_base = three_surface20
  exodus = false
  [./csv]
    type = CSV
    [../]
[]

(modules/contact/test/tests/verification/hertz_cyl/quart_symm_q8/hertz_cyl_qsym_1deg_template1.i)

[GlobalParams]
  order = SECOND
  volumetric_locking_correction = false
  displacements = 'disp_x disp_y'
[]

[Mesh]
  file = hertz_cyl_qsym_1deg_q8.e
[]

[Problem]
  type = ReferenceResidualProblem
  extra_tag_vectors = 'ref'
  reference_vector = 'ref'
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
[]

[AuxVariables]
  [./stress_xx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./saved_x]
  [../]
  [./saved_y]
  [../]
  [./diag_saved_x]
  [../]
  [./diag_saved_y]
  [../]
  [./inc_slip_x]
  [../]
  [./inc_slip_y]
  [../]
  [./accum_slip_x]
  [../]
  [./accum_slip_y]
  [../]
  [./tang_force_x]
  [../]
  [./tang_force_y]
  [../]
[]

[Functions]
  [./disp_ramp_vert]
    type = PiecewiseLinear
    x = '0. 1. 2.'
    y = '0. -0.0020 -0.0020'
  [../]
  [./disp_ramp_zero]
    type = PiecewiseLinear
    x = '0. 1. 2.'
    y = '0. 0.0 0.0'
  [../]
[]

[Kernels]
  [./TensorMechanics]
    use_displaced_mesh = true
    save_in = 'saved_x saved_y'
    extra_vector_tags = 'ref'
  [../]
[]

[AuxKernels]
  [./stress_xx]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xx
    index_i = 0
    index_j = 0
    execute_on = timestep_end
  [../]
  [./stress_yy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yy
    index_i = 1
    index_j = 1
    execute_on = timestep_end
  [../]
  [./stress_xy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xy
    index_i = 0
    index_j = 1
    execute_on = timestep_end
  [../]
  [./inc_slip_x]
    type = PenetrationAux
    variable = inc_slip_x
    execute_on = timestep_end
    boundary = 4
    paired_boundary = 3
  [../]
  [./inc_slip_y]
    type = PenetrationAux
    variable = inc_slip_y
    execute_on = timestep_end
    boundary = 4
    paired_boundary = 3
  [../]
  [./accum_slip_x]
    type = PenetrationAux
    variable = accum_slip_x
    execute_on = timestep_end
    boundary = 4
    paired_boundary = 3
  [../]
  [./accum_slip_y]
    type = PenetrationAux
    variable = accum_slip_y
    execute_on = timestep_end
    boundary = 4
    paired_boundary = 3
  [../]
  [./penetration]
    type = PenetrationAux
    variable = penetration
    boundary = 4
    paired_boundary = 3
  [../]
  [./tang_force_x]
    type = PenetrationAux
    variable = tang_force_x
    quantity = tangential_force_x
    boundary = 4
    paired_boundary = 3
  [../]
  [./tang_force_y]
    type = PenetrationAux
    variable = tang_force_y
    quantity = tangential_force_y
    boundary = 4
    paired_boundary = 3
  [../]
[]

[Postprocessors]
  [./bot_react_x]
    type = NodalSum
    variable = saved_x
    boundary = 1
  [../]
  [./bot_react_y]
    type = NodalSum
    variable = saved_y
    boundary = 1
  [../]
  [./top_react_x]
    type = NodalSum
    variable = saved_x
    boundary = 5
  [../]
  [./top_react_y]
    type = NodalSum
    variable = saved_y
    boundary = 5
  [../]
  [./disp_x281]
    type = NodalVariableValue
    nodeid = 280
    variable = disp_x
  [../]
  [./_dt]
    type = TimestepSize
  [../]
  [./num_lin_it]
    type = NumLinearIterations
  [../]
  [./num_nonlin_it]
    type = NumNonlinearIterations
  [../]
[]

[BCs]
  [./side_x]
    type = DirichletBC
    variable = disp_y
    boundary = '1 3'
    value = 0.0
  [../]
  [./bot_y]
    type = DirichletBC
    variable = disp_x
    boundary = '1 2 3'
    value = 0.0
  [../]
  [./top_y_disp]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = 5
    function = disp_ramp_vert
  [../]
[]

[Materials]
  [./stuff1_elas_tens]
    type = ComputeIsotropicElasticityTensor
    block = '1'
    youngs_modulus = 1e10
    poissons_ratio = 0.0
  [../]
  [./stuff1_strain]
    type = ComputeFiniteStrain
    block = '1'
  [../]
  [./stuff1_stress]
    type = ComputeFiniteStrainElasticStress
    block = '1'
  [../]
  [./stuff2_elas_tens]
    type = ComputeIsotropicElasticityTensor
    block = '2'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./stuff2_strain]
    type = ComputeFiniteStrain
    block = '2'
  [../]
  [./stuff2_stress]
    type = ComputeFiniteStrainElasticStress
    block = '2'
  [../]
  [./stuff3_elas_tens]
    type = ComputeIsotropicElasticityTensor
    block = '3'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./stuff3_strain]
    type = ComputeFiniteStrain
    block = '3'
  [../]
  [./stuff3_stress]
    type = ComputeFiniteStrainElasticStress
    block = '3'
  [../]
  [./stuff4_elas_tens]
    type = ComputeIsotropicElasticityTensor
    block = '4'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./stuff4_strain]
    type = ComputeFiniteStrain
    block = '4'
  [../]
  [./stuff4_stress]
    type = ComputeFiniteStrainElasticStress
    block = '4'
  [../]
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'

  petsc_options_iname = '-pc_type -pc_factor_mat_solver_type'
  petsc_options_value = 'lu     superlu_dist'

  line_search = 'none'

  nl_abs_tol = 1e-7
  nl_rel_tol = 1e-6
  l_max_its = 50
  nl_max_its = 100

  start_time = 0.0
  dt = 0.1
  dtmin = 0.1
  num_steps = 10
  end_time = 1.0
  l_tol = 1e-4
[]

[VectorPostprocessors]
  [./x_disp]
    type = NodalValueSampler
    variable = disp_x
    boundary = '3 4 5'
    sort_by = id
  [../]
  [./y_disp]
    type = NodalValueSampler
    variable = disp_y
    boundary = '3 4 5'
    sort_by = id
  [../]
  [./cont_press]
    type = NodalValueSampler
    variable = contact_pressure
    boundary = '4'
    sort_by = id
  [../]
[]

[Outputs]
  print_linear_residuals = true
  perf_graph = true
  [./exodus]
    type = Exodus
    elemental_as_nodal = true
  [../]
  [./console]
    type = Console
    max_rows = 5
  [../]
  [./chkfile]
    type = CSV
    show = 'bot_react_x bot_react_y disp_x281 top_react_x top_react_y x_disp y_disp cont_press'
    start_time = 0.9
    execute_vector_postprocessors_on = timestep_end
  [../]
  [./outfile]
    type = CSV
    delimiter = ' '
    execute_vector_postprocessors_on = none
  [../]
[]

[Contact]
  [./interface]
    primary = 3
    secondary = 4
    normalize_penalty = true
    tangential_tolerance = 1e-3
    penalty = 1e+11
  [../]
[]

(modules/solid_mechanics/test/tests/mohr_coulomb/small_deform6.i)

# apply repeated stretches in z direction, and smaller stretches in the x and y directions
# so that sigma_II = sigma_III,
# which means that lode angle = -30deg.
# The allows yield surface in meridional plane to be mapped out
# Using cap smoothing

[Mesh]
  type = GeneratedMesh
  dim = 3
  nx = 1
  ny = 1
  nz = 1
  xmin = -0.5
  xmax = 0.5
  ymin = -0.5
  ymax = 0.5
  zmin = -0.5
  zmax = 0.5
[]


[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./disp_z]
  [../]
[]

[Kernels]
  [SolidMechanics]
    displacements = 'disp_x disp_y disp_z'
  [../]
[]


[BCs]
  [./x]
    type = FunctionDirichletBC
    variable = disp_x
    boundary = 'front back'
    function = '0.9E-6*x*sin(t)'
  [../]
  [./y]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = 'front back'
    function = '0.9E-6*y*sin(t)'
  [../]
  [./z]
    type = FunctionDirichletBC
    variable = disp_z
    boundary = 'front back'
    function = '1E-6*z*t'
  [../]
[]

[AuxVariables]
  [./stress_xx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_zz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./mc_int]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./yield_fcn]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./iter]
    order = CONSTANT
    family = MONOMIAL
  [../]
[]

[AuxKernels]
  [./stress_xx]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xx
    index_i = 0
    index_j = 0
  [../]
  [./stress_xy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xy
    index_i = 0
    index_j = 1
  [../]
  [./stress_xz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xz
    index_i = 0
    index_j = 2
  [../]
  [./stress_yy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yy
    index_i = 1
    index_j = 1
  [../]
  [./stress_yz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yz
    index_i = 1
    index_j = 2
  [../]
  [./stress_zz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_zz
    index_i = 2
    index_j = 2
  [../]
  [./mc_int_auxk]
    type = MaterialStdVectorAux
    index = 0
    property = plastic_internal_parameter
    variable = mc_int
  [../]
  [./yield_fcn_auxk]
    type = MaterialStdVectorAux
    index = 0
    property = plastic_yield_function
    variable = yield_fcn
  [../]
  [./iter_auxk]
    type = MaterialRealAux
    property = plastic_NR_iterations
    variable = iter
  [../]
[]

[Postprocessors]
  [./s_xx]
    type = PointValue
    point = '0 0 0'
    variable = stress_xx
  [../]
  [./s_xy]
    type = PointValue
    point = '0 0 0'
    variable = stress_xy
  [../]
  [./s_xz]
    type = PointValue
    point = '0 0 0'
    variable = stress_xz
  [../]
  [./s_yy]
    type = PointValue
    point = '0 0 0'
    variable = stress_yy
  [../]
  [./s_yz]
    type = PointValue
    point = '0 0 0'
    variable = stress_yz
  [../]
  [./s_zz]
    type = PointValue
    point = '0 0 0'
    variable = stress_zz
  [../]
  [./internal]
    type = PointValue
    point = '0 0 0'
    variable = mc_int
  [../]
  [./f]
    type = PointValue
    point = '0 0 0'
    variable = yield_fcn
  [../]
  [./iter]
    type = PointValue
    point = '0 0 0'
    variable = iter
  [../]
[]

[UserObjects]
  [./mc_coh]
    type = SolidMechanicsHardeningConstant
    value = 10
  [../]
  [./mc_phi]
    type = SolidMechanicsHardeningConstant
    value = 50
    convert_to_radians = true
  [../]
  [./mc_psi]
    type = SolidMechanicsHardeningExponential
    value_0 = 0
    value_residual = 0.8726646 # 50deg
    rate = 3000.0
  [../]
  [./mc]
    type = SolidMechanicsPlasticMohrCoulomb
    cohesion = mc_coh
    friction_angle = mc_phi
    dilation_angle = mc_psi
    tip_scheme = cap
    mc_tip_smoother = 0
    cap_start = 3
    cap_rate = 0.8
    mc_edge_smoother = 20
    yield_function_tolerance = 1E-8
    internal_constraint_tolerance = 1E-9
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeElasticityTensor
    block = 0
    fill_method = symmetric_isotropic
    C_ijkl = '0 1E7'
  [../]
  [./strain]
    type = ComputeFiniteStrain
    block = 0
    displacements = 'disp_x disp_y disp_z'
  [../]
  [./mc]
    type = ComputeMultiPlasticityStress
    block = 0
    ep_plastic_tolerance = 1E-9
    plastic_models = mc
    debug_fspb = crash
  [../]
[]


[Executioner]
  end_time = 30
  dt = 1
  type = Transient
[]


[Outputs]
  file_base = small_deform6
  exodus = false
  [./csv]
    type = CSV
    [../]
[]

(modules/combined/test/tests/cavity_pressure/initial_temperature.i)

#
# Cavity Pressure Test
#
# This test is designed to compute an internal pressure based on
#   p = n * R * T / V
# where
#   p is the pressure
#   n is the amount of material in the volume (moles)
#   R is the universal gas constant
#   T is the temperature
#   V is the volume
#
# The mesh is composed of one block (1) with an interior cavity of volume 8.
#   Block 2 sits in the cavity and has a volume of 1.  Thus, the total
#   initial volume is 7.
# The test adjusts n, T, and V in the following way:
#   n => n0 + alpha * t
#   T => T0 + beta * t
#   V => V0 + gamma * t
# with
#   alpha = n0
#   beta = T0 / 2
#   gamma = -(0.003322259...) * V0
#   T0 = 240.54443866068704
#   V0 = 7
#   n0 = f(p0)
#   p0 = 100
#   R = 8.314472 J * K^(-1) * mol^(-1)
#
# So, n0 = p0 * V0 / R / T0 = 100 * 7 / 8.314472 / 240.544439
#        = 0.35
#
# The parameters combined at t = 1 gives p = 301.
#
# This test sets the initial temperature to 500, but the CavityPressure
#   is told that that initial temperature is T0.  Thus, the final solution
#   is unchanged.

[GlobalParams]
  displacements = 'disp_x disp_y disp_z'
[]

[Mesh]
  file = 3d.e
[]

[GlobalParams]
  volumetric_locking_correction = true
[]

[Functions]
  [displ_positive]
    type = PiecewiseLinear
    x = '0 1'
    y = '0 0.0029069767441859684'
  []
  [displ_negative]
    type = PiecewiseLinear
    x = '0 1'
    y = '0 -0.0029069767441859684'
  []
  [temp1]
    type = PiecewiseLinear
    x = '0 1'
    y = '1 1.5'
    scale_factor = 240.54443866068704
  []
  [material_input_function]
    type = PiecewiseLinear
    x = '0    1'
    y = '0 0.35'
  []
[]

[Variables]
  [disp_x]
  []
  [disp_y]
  []
  [disp_z]
  []
  [temp]
    initial_condition = 500
  []
  [material_input]
  []
[]

[AuxVariables]
  [pressure_residual_x]
  []
  [pressure_residual_y]
  []
  [pressure_residual_z]
  []
  [stress_xx]
    order = CONSTANT
    family = MONOMIAL
  []
  [stress_yy]
    order = CONSTANT
    family = MONOMIAL
  []
  [stress_zz]
    order = CONSTANT
    family = MONOMIAL
  []
  [stress_xy]
    order = CONSTANT
    family = MONOMIAL
  []
  [stress_yz]
    order = CONSTANT
    family = MONOMIAL
  []
  [stress_zx]
    order = CONSTANT
    family = MONOMIAL
  []
[]

[Kernels]
  [TensorMechanics]
    use_displaced_mesh = true
  []
  [heat]
    type = Diffusion
    variable = temp
    use_displaced_mesh = true
  []
  [material_input_dummy]
    type = Diffusion
    variable = material_input
    use_displaced_mesh = true
  []
[]

[AuxKernels]
  [stress_xx]
    type = RankTwoAux
    rank_two_tensor = stress
    index_i = 0
    index_j = 0
    variable = stress_xx
  []
  [stress_yy]
    type = RankTwoAux
    rank_two_tensor = stress
    index_i = 1
    index_j = 1
    variable = stress_yy
  []
  [stress_zz]
    type = RankTwoAux
    rank_two_tensor = stress
    index_i = 2
    index_j = 2
    variable = stress_zz
  []
  [stress_xy]
    type = RankTwoAux
    rank_two_tensor = stress
    index_i = 0
    index_j = 1
    variable = stress_xy
  []
  [stress_yz]
    type = RankTwoAux
    rank_two_tensor = stress
    index_i = 1
    index_j = 2
    variable = stress_yz
  []
  [stress_zx]
    type = RankTwoAux
    rank_two_tensor = stress
    index_i = 2
    index_j = 0
    variable = stress_zx
  []
[]

[BCs]
  [no_x_exterior]
    type = DirichletBC
    variable = disp_x
    boundary = '7 8'
    value = 0.0
  []
  [no_y_exterior]
    type = DirichletBC
    variable = disp_y
    boundary = '9 10'
    value = 0.0
  []
  [no_z_exterior]
    type = DirichletBC
    variable = disp_z
    boundary = '11 12'
    value = 0.0
  []
  [prescribed_left]
    type = FunctionDirichletBC
    variable = disp_x
    boundary = 13
    function = displ_positive
  []
  [prescribed_right]
    type = FunctionDirichletBC
    variable = disp_x
    boundary = 14
    function = displ_negative
  []
  [no_y]
    type = DirichletBC
    variable = disp_y
    boundary = '15 16'
    value = 0.0
  []
  [no_z]
    type = DirichletBC
    variable = disp_z
    boundary = '17 18'
    value = 0.0
  []
  [no_x_interior]
    type = DirichletBC
    variable = disp_x
    boundary = '1 2'
    value = 0.0
  []
  [no_y_interior]
    type = DirichletBC
    variable = disp_y
    boundary = '3 4'
    value = 0.0
  []
  [no_z_interior]
    type = DirichletBC
    variable = disp_z
    boundary = '5 6'
    value = 0.0
  []
  [temperatureInterior]
    type = FunctionDirichletBC
    boundary = 100
    function = temp1
    variable = temp
  []
  [MaterialInput]
    type = FunctionDirichletBC
    boundary = '100 13 14 15 16'
    function = material_input_function
    variable = material_input
  []
  [CavityPressure]
    [1]
      boundary = 100
      initial_pressure = 100
      material_input = materialInput
      R = 8.314472
      temperature = aveTempInterior
      initial_temperature = 240.54443866068704
      volume = internalVolume
      startup_time = 0.5
      output = ppress
      save_in = 'pressure_residual_x pressure_residual_y pressure_residual_z'
    []
  []
[]

[Materials]
  [elast_tensor1]
    type = ComputeElasticityTensor
    C_ijkl = '0 5'
    fill_method = symmetric_isotropic
    block = 1
  []
  [strain1]
    type = ComputeFiniteStrain
    block = 1
  []
  [stress1]
    type = ComputeFiniteStrainElasticStress
    block = 1
  []
  [elast_tensor2]
    type = ComputeElasticityTensor
    C_ijkl = '0 5'
    fill_method = symmetric_isotropic
    block = 2
  []
  [strain2]
    type = ComputeFiniteStrain
    block = 2
  []
  [stress2]
    type = ComputeFiniteStrainElasticStress
    block = 2
  []
[]

[Executioner]
  type = Transient

  petsc_options_iname = '-pc_type -sub_pc_type'
  petsc_options_value = 'asm       lu'

  nl_rel_tol = 1e-12
  l_tol = 1e-12

  l_max_its = 20

  dt = 0.5
  end_time = 1.0
  use_pre_SMO_residual = true
[]

[Postprocessors]
  [internalVolume]
    type = InternalVolume
    boundary = 100
    execute_on = 'initial linear'
  []
  [aveTempInterior]
    type = SideAverageValue
    boundary = 100
    variable = temp
    execute_on = 'initial linear'
  []
  [materialInput]
    type = SideAverageValue
    boundary = '7 8 9 10 11 12'
    variable = material_input
    execute_on = linear
  []
[]

[Outputs]
  exodus = true
[]

(modules/contact/test/tests/pdass_problems/ironing.i)

[GlobalParams]
  volumetric_locking_correction = true
  displacements = 'disp_x disp_y'
[]

[Mesh]
  [input_file]
    type = FileMeshGenerator
    file = iron.e
  []
  [secondary]
    type = LowerDBlockFromSidesetGenerator
    new_block_id = 10001
    new_block_name = 'secondary_lower'
    sidesets = '10'
    input = input_file
  []
  [primary]
    type = LowerDBlockFromSidesetGenerator
    new_block_id = 10000
    sidesets = '20'
    new_block_name = 'primary_lower'
    input = secondary
  []
  patch_update_strategy = auto
  patch_size = 20
[]

[Variables]
  [disp_x]
  []
  [disp_y]
  []
  [frictionless_normal_lm]
    order = FIRST
    family = LAGRANGE
    block = 'secondary_lower'
    use_dual = true
  []
  [tangential_lm]
    order = FIRST
    family = LAGRANGE
    block = 'secondary_lower'
    use_dual = true
  []
[]

[AuxVariables]
  [stress_xx]
    order = CONSTANT
    family = MONOMIAL
  []
  [stress_yy]
    order = CONSTANT
    family = MONOMIAL
  []
  [stress_xy]
    order = CONSTANT
    family = MONOMIAL
  []
  [saved_x]
  []
  [saved_y]
  []
  [diag_saved_x]
  []
  [diag_saved_y]
  []
  [von_mises]
    order = CONSTANT
    family = MONOMIAL
  []
[]

[Functions]
  [disp_ramp_vert]
    type = PiecewiseLinear
    x = '0. 2. 8.'
    y = '0. -1.0 -1.0'
  []
  [disp_ramp_horz]
    type = PiecewiseLinear
    x = '0. 8.' # x = '0. 2. 8.'
    y = '0. 8.' # y = '0. 0. 8'
  []
[]

[Kernels]
  [TensorMechanics]
    use_displaced_mesh = true
    save_in = 'saved_x saved_y'
    block = '1 2'
    strain = FINITE
  []
[]

[AuxKernels]
  [stress_xx]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xx
    index_i = 0
    index_j = 0
    execute_on = timestep_end
    block = '1 2'
  []
  [stress_yy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yy
    index_i = 1
    index_j = 1
    execute_on = timestep_end
    block = '1 2'
  []
  [stress_xy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xy
    index_i = 0
    index_j = 1
    execute_on = timestep_end
    block = '1 2'
  []
  [von_mises_kernel]
    #Calculates the von mises stress and assigns it to von_mises
    type = RankTwoScalarAux
    variable = von_mises
    rank_two_tensor = stress
    execute_on = timestep_end
    scalar_type = VonMisesStress
    block = '1 2'
  []
[]

[Postprocessors]
  [bot_react_x]
    type = NodalSum
    variable = saved_x
    boundary = 20
  []
  [bot_react_y]
    type = NodalSum
    variable = saved_y
    boundary = 20
  []
  [top_react_x]
    type = NodalSum
    variable = saved_x
    boundary = 10
  []
  [top_react_y]
    type = NodalSum
    variable = saved_y
    boundary = 10
  []
  [_dt]
    type = TimestepSize
  []
  [contact_pressure]
    type = NodalVariableValue
    variable = frictionless_normal_lm
    nodeid = 805
  []
[]

[BCs]
  [bot_x_disp]
    type = DirichletBC
    variable = disp_x
    boundary = '40'
    value = 0.0
    preset = false
  []
  [bot_y_disp]
    type = DirichletBC
    variable = disp_y
    boundary = '40'
    value = 0.0
    preset = false
  []
  [top_y_disp]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = '30'
    function = disp_ramp_vert
    preset = false
  []
  [top_x_disp]
    type = FunctionDirichletBC
    variable = disp_x
    boundary = '30'
    function = disp_ramp_horz
    preset = false
  []
[]

[Materials]
  [stuff1_elas_tens]
    type = ComputeIsotropicElasticityTensor
    block = '2'
    youngs_modulus = 6896
    poissons_ratio = 0.32
  []
  [stuff1_strain]
    type = ComputeFiniteStrain
    block = '2'
  []
  [stuff1_stress]
    type = ComputeFiniteStrainElasticStress
    block = '2'
  []
  [stuff2_elas_tens]
    type = ComputeIsotropicElasticityTensor
    block = '1'
    youngs_modulus = 689.6
    poissons_ratio = 0.32
  []
  [stuff2_strain]
    type = ComputeFiniteStrain
    block = '1'
  []
  [stuff2_stress]
    type = ComputeFiniteStrainElasticStress
    block = '1'
  []
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'

  petsc_options = '-snes_ksp_ew'
  petsc_options_iname = '-pc_type -pc_factor_mat_solver_type'
  petsc_options_value = 'lu     superlu_dist'
  line_search = 'none'

  nl_abs_tol = 1e-7
  nl_rel_tol = 1e-7
  l_tol = 1e-6

  l_max_its = 50
  nl_max_its = 30

  start_time = 0.0
  end_time = 0.1 # 6.5

  dt = 0.0125
  dtmin = 1e-5
[]

[Preconditioning]
  [SMP]
    type = SMP
    full = true
  []
[]

[VectorPostprocessors]
  [cont_press]
    type = NodalValueSampler
    variable = frictionless_normal_lm
    boundary = '10'
    sort_by = id
    execute_on = FINAL
  []
  [friction]
    type = NodalValueSampler
    variable = tangential_lm
    boundary = '10'
    sort_by = id
    execute_on = FINAL
  []
[]

[Outputs]
  print_linear_residuals = true
  perf_graph = true
  exodus = false
  csv = true

  [chkfile]
    type = CSV
    show = 'cont_press friction'
    start_time = 0.0
    execute_vector_postprocessors_on = FINAL
  []

  [console]
    type = Console
    max_rows = 5
  []
[]

[Debug]
  show_var_residual_norms = true
[]

[UserObjects]
  [weighted_vel_uo]
    type = LMWeightedVelocitiesUserObject
    primary_boundary = 20
    secondary_boundary = 10
    primary_subdomain = 10000
    secondary_subdomain = 10001
    lm_variable_normal = frictionless_normal_lm
    lm_variable_tangential_one = tangential_lm
    secondary_variable = disp_x
    disp_x = disp_x
    disp_y = disp_y
  []
[]

[Constraints]
  # All constraints below for mechanical contact (Mortar)
  [weighted_gap_lm]
    type = ComputeFrictionalForceLMMechanicalContact
    primary_boundary = 20
    secondary_boundary = 10
    primary_subdomain = 10000
    secondary_subdomain = 10001
    variable = frictionless_normal_lm
    disp_x = disp_x
    disp_y = disp_y
    use_displaced_mesh = true
    friction_lm = tangential_lm
    mu = 0.5
    c_t = 1.0e1
    c = 1.0e3
    weighted_gap_uo = weighted_vel_uo
    weighted_velocities_uo = weighted_vel_uo
  []
  [x]
    type = NormalMortarMechanicalContact
    primary_boundary = 20
    secondary_boundary = 10
    primary_subdomain = '10000'
    secondary_subdomain = '10001'
    variable = frictionless_normal_lm
    secondary_variable = disp_x
    component = x
    use_displaced_mesh = true
    compute_lm_residuals = false
    weighted_gap_uo = weighted_vel_uo
  []
  [y]
    type = NormalMortarMechanicalContact
    primary_boundary = 20
    secondary_boundary = 10
    primary_subdomain = '10000'
    secondary_subdomain = '10001'
    variable = frictionless_normal_lm
    secondary_variable = disp_y
    component = y
    use_displaced_mesh = true
    compute_lm_residuals = false
    weighted_gap_uo = weighted_vel_uo
  []
  [tangential_x]
    type = TangentialMortarMechanicalContact
    primary_boundary = 20
    secondary_boundary = 10
    primary_subdomain = '10000'
    secondary_subdomain = '10001'
    variable = tangential_lm
    secondary_variable = disp_x
    component = x
    use_displaced_mesh = true
    compute_lm_residuals = false
    weighted_velocities_uo = weighted_vel_uo
  []
  [tangential_y]
    type = TangentialMortarMechanicalContact
    primary_boundary = 20
    secondary_boundary = 10
    primary_subdomain = '10000'
    secondary_subdomain = '10001'
    variable = tangential_lm
    secondary_variable = disp_y
    component = y
    use_displaced_mesh = true
    compute_lm_residuals = false
    weighted_velocities_uo = weighted_vel_uo
  []
[]

(modules/solid_mechanics/test/tests/elastic_patch/elastic_patch.i)

# Patch Test

# This test is designed to compute constant xx, yy, zz, xy, yz, and zx
#  stress on a set of irregular hexes.  The mesh is composed of one
#  block with seven elements.  The elements form a unit cube with one
#  internal element.  There is a nodeset for each exterior node.

# The cube is displaced by 1e-6 units in x, 2e-6 in y, and 3e-6 in z.
#  The faces are sheared as well (1e-6, 2e-6, and 3e-6 for xy, yz, and
#  zx).  This gives a uniform strain/stress state for all six unique
#  tensor components.

# With Young's modulus at 1e6 and Poisson's ratio at 0, the shear
#  modulus is 5e5 (G=E/2/(1+nu)).  Therefore,
#
#  stress xx = 1e6 * 1e-6 = 1
#  stress yy = 1e6 * 2e-6 = 2
#  stress zz = 1e6 * 3e-6 = 3
#  stress xy = 2 * 5e5 * 1e-6 / 2 = 0.5
#             (2 * G   * gamma_xy / 2 = 2 * G * epsilon_xy)
#  stress yz = 2 * 5e5 * 2e-6 / 2 = 1
#  stress zx = 2 * 5e5 * 3e-6 / 2 = 1.5

[GlobalParams]
  displacements = 'disp_x disp_y disp_z'
  block = '1 2 3 4 5 6 7'
[]

[Mesh]#Comment
  file = elastic_patch.e
[] # Mesh

[Functions]
  [./rampConstant1]
    type = PiecewiseLinear
    x = '0. 1. 2.'
    y = '0. 1. 1.'
    scale_factor = 1e-6
  [../]
  [./rampConstant2]
    type = PiecewiseLinear
    x = '0. 1. 2.'
    y = '0. 1. 1.'
    scale_factor = 2e-6
  [../]
  [./rampConstant3]
    type = PiecewiseLinear
    x = '0. 1. 2.'
    y = '0. 1. 1.'
    scale_factor = 3e-6
  [../]
  [./rampConstant4]
    type = PiecewiseLinear
    x = '0. 1. 2.'
    y = '0. 1. 1.'
    scale_factor = 4e-6
  [../]
  [./rampConstant6]
    type = PiecewiseLinear
    x = '0. 1. 2.'
    y = '0. 1. 1.'
    scale_factor = 6e-6
  [../]
[] # Functions

[Variables]

  [./disp_x]
    order = FIRST
    family = LAGRANGE
  [../]

  [./disp_y]
    order = FIRST
    family = LAGRANGE
  [../]

  [./disp_z]
    order = FIRST
    family = LAGRANGE
  [../]

[] # Variables

[AuxVariables]

  [./stress_xx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_zz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_zx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./elastic_energy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./vonmises]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./hydrostatic]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./firstinv]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./secondinv]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./thirdinv]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./maxprincipal]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./midprincipal]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./minprincipal]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./direction]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./max_shear]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./sint]
    order = CONSTANT
    family = MONOMIAL
  [../]

[] # AuxVariables

[Kernels]
  [SolidMechanics]
    use_displaced_mesh = true
  [../]
[]

[AuxKernels]

  [./stress_xx]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xx
    index_i = 0
    index_j = 0
  [../]
  [./stress_yy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yy
    index_i = 1
    index_j = 1
  [../]
  [./stress_zz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_zz
    index_i = 2
    index_j = 2
  [../]
  [./stress_xy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xy
    index_i = 0
    index_j = 1
  [../]
  [./stress_yz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yz
    index_i = 1
    index_j = 2
  [../]
  [./stress_zx]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_zx
    index_i = 2
    index_j = 0
  [../]
  [./elastic_energy]
    type = ElasticEnergyAux
    variable = elastic_energy
  [../]
  [./vonmises]
    type = RankTwoScalarAux
    rank_two_tensor = stress
    variable = vonmises
    scalar_type = vonmisesStress
  [../]
  [./hydrostatic]
    type = RankTwoScalarAux
    rank_two_tensor = stress
    variable = hydrostatic
    scalar_type = hydrostatic
  [../]
  [./fi]
    type = RankTwoScalarAux
    rank_two_tensor = stress
    variable = firstinv
    scalar_type = firstinvariant
  [../]
  [./si]
    type = RankTwoScalarAux
    rank_two_tensor = stress
    variable = secondinv
    scalar_type = secondinvariant
  [../]
  [./ti]
    type = RankTwoScalarAux
    rank_two_tensor = stress
    variable = thirdinv
    scalar_type = thirdinvariant
  [../]
  [./maxprincipal]
    type = RankTwoScalarAux
    rank_two_tensor = stress
    variable = maxprincipal
    scalar_type = MaxPRiNCIpAl
  [../]
  [./midprincipal]
    type = RankTwoScalarAux
    rank_two_tensor = stress
    variable = midprincipal
    scalar_type = MidPRiNCIpAl
  [../]
  [./minprincipal]
    type = RankTwoScalarAux
    rank_two_tensor = stress
    variable = minprincipal
    scalar_type = MiNPRiNCIpAl
  [../]
  [./direction]
    type = RankTwoScalarAux
    rank_two_tensor = stress
    variable = direction
    scalar_type = direction
    direction = '1 1 1'
  [../]
  [./max_shear]
    type = RankTwoScalarAux
    rank_two_tensor = stress
    variable = max_shear
    scalar_type = MaxShear
  [../]
  [./sint]
    type = RankTwoScalarAux
    rank_two_tensor = stress
    variable = sint
    scalar_type = StressIntensity
  [../]


[] # AuxKernels

[BCs]

  [./node1_x]
    type = DirichletBC
    variable = disp_x
    boundary = 1
    value = 0.0
  [../]
  [./node1_y]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = 1
    function = rampConstant2
  [../]
  [./node1_z]
    type = FunctionDirichletBC
    variable = disp_z
    boundary = 1
    function = rampConstant3
  [../]

  [./node2_x]
    type = FunctionDirichletBC
    variable = disp_x
    boundary = 2
    function = rampConstant1
  [../]
  [./node2_y]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = 2
    function = rampConstant2
  [../]
  [./node2_z]
    type = FunctionDirichletBC
    variable = disp_z
    boundary = 2
    function = rampConstant6
  [../]

  [./node3_x]
    type = FunctionDirichletBC
    variable = disp_x
    boundary = 3
    function = rampConstant1
  [../]
  [./node3_y]
    type = DirichletBC
    variable = disp_y
    boundary = 3
    value = 0.0
  [../]
  [./node3_z]
    type = FunctionDirichletBC
    variable = disp_z
    boundary = 3
    function = rampConstant3
  [../]

  [./node4_x]
    type = DirichletBC
    variable = disp_x
    boundary = 4
    value = 0.0
  [../]
  [./node4_y]
    type = DirichletBC
    variable = disp_y
    boundary = 4
    value = 0.0
  [../]
  [./node4_z]
    type = DirichletBC
    variable = disp_z
    boundary = 4
    value = 0.0
  [../]

  [./node5_x]
    type = FunctionDirichletBC
    variable = disp_x
    boundary = 5
    function = rampConstant1
  [../]
  [./node5_y]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = 5
    function = rampConstant4
  [../]
  [./node5_z]
    type = FunctionDirichletBC
    variable = disp_z
    boundary = 5
    function = rampConstant3
  [../]

  [./node6_x]
    type = FunctionDirichletBC
    variable = disp_x
    boundary = 6
    function = rampConstant2
  [../]
  [./node6_y]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = 6
    function = rampConstant4
  [../]
  [./node6_z]
    type = FunctionDirichletBC
    variable = disp_z
    boundary = 6
    function = rampConstant6
  [../]

  [./node7_x]
    type = FunctionDirichletBC
    variable = disp_x
    boundary = 7
    function = rampConstant2
  [../]
  [./node7_y]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = 7
    function = rampConstant2
  [../]
  [./node7_z]
    type = FunctionDirichletBC
    variable = disp_z
    boundary = 7
    function = rampConstant3
  [../]

  [./node8_x]
    type = FunctionDirichletBC
    variable = disp_x
    boundary = 8
    function = rampConstant1
  [../]
  [./node8_y]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = 8
    function = rampConstant2
  [../]
  [./node8_z]
    type = DirichletBC
    variable = disp_z
    boundary = 8
    value = 0.0
  [../]


[] # BCs

[Materials]

  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 1e6
    poissons_ratio = 0.0
  [../]

  [./strain]
    type = ComputeFiniteStrain
  [../]

  [./stress]
    type = ComputeFiniteStrainElasticStress
  [../]

[] # Materials

[Executioner]

  type = Transient

  #Preconditioned JFNK (default)
  solve_type = 'PJFNK'

  nl_abs_tol = 1e-10

  l_max_its = 20

  start_time = 0.0
  dt = 1.0
  num_steps = 2
  end_time = 2.0
[] # Executioner

[Outputs]
  exodus = true
[] # Outputs

(modules/contact/test/tests/verification/hertz_cyl/quart_symm_q4/hertz_cyl_qsym_1deg_template1.i)

[GlobalParams]
  volumetric_locking_correction = true
  displacements = 'disp_x disp_y'
[]

[Mesh]
  file = hertz_cyl_qsym_1deg_q4.e
[]

[Problem]
  type = ReferenceResidualProblem
  extra_tag_vectors = 'ref'
  reference_vector = 'ref'
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
[]

[AuxVariables]
  [./stress_xx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./saved_x]
  [../]
  [./saved_y]
  [../]
  [./diag_saved_x]
  [../]
  [./diag_saved_y]
  [../]
  [./inc_slip_x]
  [../]
  [./inc_slip_y]
  [../]
  [./accum_slip_x]
  [../]
  [./accum_slip_y]
  [../]
  [./tang_force_x]
  [../]
  [./tang_force_y]
  [../]
[]

[Functions]
  [./disp_ramp_vert]
    type = PiecewiseLinear
    x = '0. 1. 2.'
    y = '0. -0.0020 -0.0020'
  [../]
  [./disp_ramp_zero]
    type = PiecewiseLinear
    x = '0. 1. 2.'
    y = '0. 0.0 0.0'
  [../]
[]

[Kernels]
  [./TensorMechanics]
    use_displaced_mesh = true
    save_in = 'saved_x saved_y'
    extra_vector_tags = 'ref'
  [../]
[]

[AuxKernels]
  [./stress_xx]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xx
    index_i = 0
    index_j = 0
    execute_on = timestep_end
  [../]
  [./stress_yy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yy
    index_i = 1
    index_j = 1
    execute_on = timestep_end
  [../]
  [./stress_xy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xy
    index_i = 0
    index_j = 1
    execute_on = timestep_end
  [../]
  [./inc_slip_x]
    type = PenetrationAux
    variable = inc_slip_x
    execute_on = timestep_end
    boundary = 4
    paired_boundary = 3
  [../]
  [./inc_slip_y]
    type = PenetrationAux
    variable = inc_slip_y
    execute_on = timestep_end
    boundary = 4
    paired_boundary = 3
  [../]
  [./accum_slip_x]
    type = PenetrationAux
    variable = accum_slip_x
    execute_on = timestep_end
    boundary = 4
    paired_boundary = 3
  [../]
  [./accum_slip_y]
    type = PenetrationAux
    variable = accum_slip_y
    execute_on = timestep_end
    boundary = 4
    paired_boundary = 3
  [../]
  [./penetration]
    type = PenetrationAux
    variable = penetration
    boundary = 4
    paired_boundary = 3
  [../]
  [./tang_force_x]
    type = PenetrationAux
    variable = tang_force_x
    quantity = tangential_force_x
    boundary = 4
    paired_boundary = 3
  [../]
  [./tang_force_y]
    type = PenetrationAux
    variable = tang_force_y
    quantity = tangential_force_y
    boundary = 4
    paired_boundary = 3
  [../]
[]

[Postprocessors]
  [./bot_react_x]
    type = NodalSum
    variable = saved_x
    boundary = 1
  [../]
  [./bot_react_y]
    type = NodalSum
    variable = saved_y
    boundary = 1
  [../]
  [./top_react_x]
    type = NodalSum
    variable = saved_x
    boundary = 5
  [../]
  [./top_react_y]
    type = NodalSum
    variable = saved_y
    boundary = 5
  [../]
  [./ref_resid_x]
    type = NodalL2Norm
    execute_on = timestep_end
    variable = saved_x
  [../]
  [./ref_resid_y]
    type = NodalL2Norm
    execute_on = timestep_end
    variable = saved_y
  [../]
  [./disp_x281]
    type = NodalVariableValue
    nodeid = 280
    variable = disp_x
  [../]
  [./_dt]
    type = TimestepSize
  [../]
  [./num_lin_it]
    type = NumLinearIterations
  [../]
  [./num_nonlin_it]
    type = NumNonlinearIterations
  [../]
[]

[BCs]
  [./side_x]
    type = DirichletBC
    variable = disp_y
    boundary = '1 3'
    value = 0.0
  [../]
  [./bot_y]
    type = DirichletBC
    variable = disp_x
    boundary = '1 2 3'
    value = 0.0
  [../]
  [./top_y_disp]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = 5
    function = disp_ramp_vert
  [../]
[]

[Materials]
  [./stuff1_elas_tens]
    type = ComputeIsotropicElasticityTensor
    block = '1'
    youngs_modulus = 1e10
    poissons_ratio = 0.0
  [../]
  [./stuff1_strain]
    type = ComputeFiniteStrain
    block = '1'
  [../]
  [./stuff1_stress]
    type = ComputeFiniteStrainElasticStress
    block = '1'
  [../]
  [./stuff2_elas_tens]
    type = ComputeIsotropicElasticityTensor
    block = '2'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./stuff2_strain]
    type = ComputeFiniteStrain
    block = '2'
  [../]
  [./stuff2_stress]
    type = ComputeFiniteStrainElasticStress
    block = '2'
  [../]
  [./stuff3_elas_tens]
    type = ComputeIsotropicElasticityTensor
    block = '3'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./stuff3_strain]
    type = ComputeFiniteStrain
    block = '3'
  [../]
  [./stuff3_stress]
    type = ComputeFiniteStrainElasticStress
    block = '3'
  [../]
  [./stuff4_elas_tens]
    type = ComputeIsotropicElasticityTensor
    block = '4'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./stuff4_strain]
    type = ComputeFiniteStrain
    block = '4'
  [../]
  [./stuff4_stress]
    type = ComputeFiniteStrainElasticStress
    block = '4'
  [../]
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'

  petsc_options_iname = '-pc_type -pc_factor_mat_solver_type'
  petsc_options_value = 'lu     superlu_dist'

  line_search = 'none'

  nl_abs_tol = 1e-6
  nl_rel_tol = 1e-5
  l_max_its = 50
  nl_max_its = 100

  start_time = 0.0
  dt = 0.1
  dtmin = 0.1
  num_steps = 10
  end_time = 1.0
  l_tol = 1e-3
[]

[VectorPostprocessors]
  [./x_disp]
    type = NodalValueSampler
    variable = disp_x
    boundary = '3 4 5'
    sort_by = id
  [../]
  [./y_disp]
    type = NodalValueSampler
    variable = disp_y
    boundary = '3 4 5'
    sort_by = id
  [../]
  [./cont_press]
    type = NodalValueSampler
    variable = contact_pressure
    boundary = '4'
    sort_by = id
  [../]
[]

[Outputs]
  print_linear_residuals = true
  perf_graph = true
  [./exodus]
    type = Exodus
    elemental_as_nodal = true
  [../]
  [./console]
    type = Console
    max_rows = 5
  [../]
  [./chkfile]
    type = CSV
    show = 'bot_react_x bot_react_y disp_x281 top_react_x top_react_y x_disp y_disp cont_press'
    start_time = 0.9
    execute_vector_postprocessors_on = timestep_end
  [../]
  [./outfile]
    type = CSV
    delimiter = ' '
    execute_vector_postprocessors_on = none
  [../]
[]

[Contact]
  [./interface]
    primary = 3
    secondary = 4
    model = glued
    formulation = kinematic
    normalize_penalty = true
    tangential_tolerance = 1e-3
    penalty = 1e+9
  [../]
[]

(modules/solid_mechanics/test/tests/multi/paper3.i)

# This runs the third example models described in the 'MultiSurface' plasticity paper
# Just change the deactivation_scheme
#
# Plasticity models:
# Mohr-Coulomb with cohesion = 40MPa, friction angle = 35deg, dilation angle = 5deg
# Tensile with strength = 1MPa
# WeakPlaneTensile with strength = 1000Pa
# WeakPlaneShear with cohesion = 0.1MPa and friction angle = 25, dilation angle = 5deg
#
# Lame lambda = 1.2GPa.  Lame mu = 1.2GPa (Young = 3GPa, poisson = 0.5)
#
# A line of elements is perturbed randomly, and return to the yield surface at each quadpoint is checked

[Mesh]
  type = GeneratedMesh
  dim = 3
  nx = 1000
  ny = 125
  nz = 1
  xmin = 0
  xmax = 1000
  ymin = 0
  ymax = 125
  zmin = 0
  zmax = 1
[]


[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./disp_z]
  [../]
[]

[GlobalParams]
  volumetric_locking_correction=true
[]

[Kernels]
  [SolidMechanics]
    displacements = 'disp_x disp_y disp_z'
  [../]
[]


[ICs]
  [./x]
    type = RandomIC
    min = -0.1
    max = 0.1
    variable = disp_x
  [../]
  [./y]
    type = RandomIC
    min = -0.1
    max = 0.1
    variable = disp_y
  [../]
  [./z]
    type = RandomIC
    min = -0.1
    max = 0.1
    variable = disp_z
  [../]
[]

[BCs]
  [./x]
    type = FunctionDirichletBC
    variable = disp_x
    boundary = 'front back'
    function = '0'
  [../]
  [./y]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = 'front back'
    function = '0'
  [../]
  [./z]
    type = FunctionDirichletBC
    variable = disp_z
    boundary = 'front back'
    function = '0'
  [../]
[]

[AuxVariables]
  [./stress_xx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_zz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./linesearch]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./ld]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./constr_added]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./iter]
    order = CONSTANT
    family = MONOMIAL
  [../]
[]

[AuxKernels]
  [./stress_xx]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xx
    index_i = 0
    index_j = 0
  [../]
  [./stress_xy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xy
    index_i = 0
    index_j = 1
  [../]
  [./stress_xz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xz
    index_i = 0
    index_j = 2
  [../]
  [./stress_yy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yy
    index_i = 1
    index_j = 1
  [../]
  [./stress_yz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yz
    index_i = 1
    index_j = 2
  [../]
  [./stress_zz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_zz
    index_i = 2
    index_j = 2
  [../]
  [./linesearch]
    type = MaterialRealAux
    property = plastic_linesearch_needed
    variable = linesearch
  [../]
  [./ld]
    type = MaterialRealAux
    property = plastic_linear_dependence_encountered
    variable = ld
  [../]
  [./constr_added]
    type = MaterialRealAux
    property = plastic_constraints_added
    variable = constr_added
  [../]
  [./iter]
    type = MaterialRealAux
    property = plastic_NR_iterations
    variable = iter
  [../]
[]

[Postprocessors]
  [./max_iter]
    type = ElementExtremeValue
    variable = iter
    outputs = console
  [../]
  [./av_iter]
    type = ElementAverageValue
    variable = iter
    outputs = 'console csv'
  [../]
  [./av_linesearch]
    type = ElementAverageValue
    variable = linesearch
    outputs = 'console csv'
  [../]
  [./av_ld]
    type = ElementAverageValue
    variable = ld
    outputs = 'console csv'
  [../]
  [./av_constr_added]
    type = ElementAverageValue
    variable = constr_added
    outputs = 'console csv'
  [../]
[]

[UserObjects]
  [./mc_coh]
    type = SolidMechanicsHardeningConstant
    value = 4E7
  [../]
  [./mc_phi]
    type = SolidMechanicsHardeningConstant
    value = 35
    convert_to_radians = true
  [../]
  [./mc_psi]
    type = SolidMechanicsHardeningConstant
    value = 5
    convert_to_radians = true
  [../]
  [./mc]
    type = SolidMechanicsPlasticMohrCoulombMulti
    cohesion = mc_coh
    friction_angle = mc_phi
    dilation_angle = mc_psi
    yield_function_tolerance = 1.0
    shift = 1.0
    internal_constraint_tolerance = 1.0E-7
  [../]
  [./mc_smooth]
    type = SolidMechanicsPlasticMohrCoulomb
    cohesion = mc_coh
    friction_angle = mc_phi
    dilation_angle = mc_psi
    mc_tip_smoother = 4E6
    yield_function_tolerance = 1.0
    internal_constraint_tolerance = 1.0E-7
  [../]

  [./ts]
    type = SolidMechanicsHardeningConstant
    value = 1E6
  [../]
  [./tensile]
    type = SolidMechanicsPlasticTensileMulti
    tensile_strength = ts
    yield_function_tolerance = 1.0
    shift = 1.0
    internal_constraint_tolerance = 1.0E-7
    use_custom_returnMap = false
    use_custom_cto = false
  [../]
  [./tensile_smooth]
    type = SolidMechanicsPlasticTensile
    tensile_strength = ts
    tensile_tip_smoother = 1E5
    yield_function_tolerance = 1.0
    internal_constraint_tolerance = 1.0E-7
  [../]

  [./wpt_str]
    type = SolidMechanicsHardeningConstant
    value = 1.0E3
  [../]
  [./wpt]
    type = SolidMechanicsPlasticWeakPlaneTensile
    tensile_strength = wpt_str
    yield_function_tolerance = 1.0
    internal_constraint_tolerance = 1.0E-7
  [../]

  [./wps_c]
    type = SolidMechanicsHardeningConstant
    value = 1.0E5
  [../]
  [./wps_tan_phi]
    type = SolidMechanicsHardeningConstant
    value = 0.466
  [../]
  [./wps_tan_psi]
    type = SolidMechanicsHardeningConstant
    value = 0.087
  [../]
  [./wps]
    type = SolidMechanicsPlasticWeakPlaneShear
    cohesion = wps_c
    tan_friction_angle = wps_tan_phi
    tan_dilation_angle = wps_tan_psi
    smoother = 1.0E4
    yield_function_tolerance = 1.0
    internal_constraint_tolerance = 1.0E-7
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeElasticityTensor
    block = 0
    fill_method = symmetric_isotropic
    C_ijkl = '1.2E9 1.2E9'
  [../]
  [./strain]
    type = ComputeFiniteStrain
    block = 0
    displacements = 'disp_x disp_y disp_z'
  [../]
  [./multi]
    type = ComputeMultiPlasticityStress
    block = 0
    ep_plastic_tolerance = 1E-7

    plastic_models = 'tensile_smooth mc_smooth wpt wps'
    max_NR_iterations = 30
    specialIC = 'none'
    deactivation_scheme = 'optimized'
    min_stepsize = 1E-6
    max_stepsize_for_dumb = 1E-2

    debug_fspb = crash
    debug_jac_at_stress = '10 0 0 0 10 0 0 0 10'
    debug_jac_at_pm = '1 1 1 1'
    debug_jac_at_intnl = '1 1 1 1'
    debug_stress_change = 1E1
    debug_pm_change = '1E-6 1E-6 1E-6 1E-6'
    debug_intnl_change = '1E-6 1E-6 1E-6 1E-6'
  [../]
[]


[Executioner]
  end_time = 1
  dt = 1
  type = Transient
[]


[Outputs]
  file_base = paper3
  exodus = false
  csv = true
[]

(modules/solid_mechanics/test/tests/mohr_coulomb/many_deforms_cap.i)

# apply many large deformations, checking that the algorithm returns correctly to
# the yield surface each time


[Mesh]
  type = GeneratedMesh
  dim = 3
  nx = 1
  ny = 1
  nz = 1
  xmin = -0.5
  xmax = 0.5
  ymin = -0.5
  ymax = 0.5
  zmin = -0.5
  zmax = 0.5
[]


[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./disp_z]
  [../]
[]

[Kernels]
  [SolidMechanics]
    displacements = 'disp_x disp_y disp_z'
  [../]
[]


[BCs]
  [./bottomx]
    type = DirichletBC
    variable = disp_x
    boundary = back
    value = 0.0
  [../]
  [./bottomy]
    type = DirichletBC
    variable = disp_y
    boundary = back
    value = 0.0
  [../]
  [./bottomz]
    type = DirichletBC
    variable = disp_z
    boundary = back
    value = 0.0
  [../]

  [./topx]
    type = FunctionDirichletBC
    variable = disp_x
    boundary = front
    function = '(sin(0.05*t)+x)/1E0'
  [../]
  [./topy]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = front
    function = '(cos(0.04*t)+x*y)/1E0'
  [../]
  [./topz]
    type = FunctionDirichletBC
    variable = disp_z
    boundary = front
    function = 't/1E2'
  [../]
[]

[AuxVariables]
  [./yield_fcn]
    order = CONSTANT
    family = MONOMIAL
  [../]
[]

[AuxKernels]
  [./yield_fcn_auxk]
    type = MaterialStdVectorAux
    index = 0
    property = plastic_yield_function
    variable = yield_fcn
  [../]
[]

[Postprocessors]
  [./yield_fcn_at_zero]
    type = PointValue
    point = '0 0 0'
    variable = yield_fcn
    outputs = 'console'
  [../]
  [./should_be_zero]
    type = FunctionValuePostprocessor
    function = should_be_zero_fcn
  [../]
[]

[Functions]
  [./should_be_zero_fcn]
    type = ParsedFunction
    expression = 'if(a<1E-3,0,a)'
    symbol_names = 'a'
    symbol_values = 'yield_fcn_at_zero'
  [../]
[]

[UserObjects]
  [./mc_coh]
    type = SolidMechanicsHardeningConstant
    value = 1E3
  [../]
  [./mc_phi]
    type = SolidMechanicsHardeningConstant
    value = 30
    convert_to_radians = true
  [../]
  [./mc_psi]
    type = SolidMechanicsHardeningConstant
    value = 5
    convert_to_radians = true
  [../]
  [./mc]
    type = SolidMechanicsPlasticMohrCoulomb
    cohesion = mc_coh
    friction_angle = mc_phi
    dilation_angle = mc_psi
    tip_scheme = cap
    mc_tip_smoother = 0.0
    cap_start = 1000
    cap_rate = 1E-3
    mc_edge_smoother = 10
    yield_function_tolerance = 1E-3
    internal_constraint_tolerance = 1E-6
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeElasticityTensor
    block = 0
    fill_method = symmetric_isotropic
    C_ijkl = '0 1E7'
  [../]
  [./strain]
    type = ComputeFiniteStrain
    block = 0
    displacements = 'disp_x disp_y disp_z'
  [../]
  [./mc]
    type = ComputeMultiPlasticityStress
    block = 0
    max_NR_iterations = 1000
    ep_plastic_tolerance = 1E-6
    plastic_models = mc
    debug_fspb = crash
    deactivation_scheme = safe
  [../]
[]


[Executioner]
  end_time = 1000
  dt = 1
  type = Transient
[]


[Outputs]
  file_base = many_deforms_cap
  exodus = false
  [./csv]
    type = CSV
    [../]
[]

(modules/contact/test/tests/mortar_aux_kernels/block-dynamics-aux-vel.i)

starting_point = 2e-1
offset = -0.19

[GlobalParams]
  displacements = 'disp_x disp_y'
[]

[Mesh]
  file = long-bottom-block-1elem-blocks.e
[]

[Variables]
  [disp_x]
    block = '1 2'
  []
  [disp_y]
    block = '1 2'
  []
  [normal_lm]
    block = 3
    use_dual = true
  []
[]

[ICs]
  [disp_y]
    block = 2
    variable = disp_y
    value = '${fparse starting_point + offset}'
    type = ConstantIC
  []
[]

[Kernels]
  [DynamicTensorMechanics]
    displacements = 'disp_x disp_y'
    generate_output = 'stress_xx stress_yy'
    strain = FINITE
    block = '1 2'
    zeta = 1.0
    alpha = 0.0
  []
  [inertia_x]
    type = InertialForce
    variable = disp_x
    velocity = vel_x
    acceleration = accel_x
    beta = 0.25
    gamma = 0.5
    alpha = 0
    eta = 0.0
    block = '1 2'
  []
  [inertia_y]
    type = InertialForce
    variable = disp_y
    velocity = vel_y
    acceleration = accel_y
    beta = 0.25
    gamma = 0.5
    alpha = 0
    eta = 0.0
    block = '1 2'
  []
[]

[Materials]
  [elasticity_2]
    type = ComputeIsotropicElasticityTensor
    block = '2'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  []
  [elasticity_1]
    type = ComputeIsotropicElasticityTensor
    block = '1'
    youngs_modulus = 1e8
    poissons_ratio = 0.3
  []
  [stress]
    type = ComputeFiniteStrainElasticStress
    block = '1 2'
  []
  [strain]
    type = ComputeFiniteStrain
    block = '1 2'
  []
  [density]
    type = GenericConstantMaterial
    block = '1 2'
    prop_names = 'density'
    prop_values = '7750'
  []
[]

[AuxVariables]
  [gap_vel]
    block = '3'
  []
  [vel_x]
    block = '1 2'
  []
  [accel_x]
    block = '1 2'
  []
  [vel_y]
    block = '1 2'
  []
  [accel_y]
    block = '1 2'
  []
  [vel_z]
    block = '1 2'
  []
  [accel_z]
    block = '1 2'
  []
[]

[AuxKernels]
  [gap_vel]
    type = WeightedGapVelAux
    variable = gap_vel
    primary_boundary = 20
    secondary_boundary = 10
    primary_subdomain = 4
    secondary_subdomain = 3
    disp_x = disp_x
    disp_y = disp_y
    correct_edge_dropping = true
    execute_on = 'TIMESTEP_END'
  []
  [accel_x]
    type = NewmarkAccelAux
    variable = accel_x
    displacement = disp_x
    velocity = vel_x
    beta = 0.25
    execute_on = 'linear timestep_end'
  []
  [vel_x]
    type = NewmarkVelAux
    variable = vel_x
    acceleration = accel_x
    gamma = 0.5
    execute_on = 'linear timestep_end'
  []
  [accel_y]
    type = NewmarkAccelAux
    variable = accel_y
    displacement = disp_y
    velocity = vel_y
    beta = 0.25
    execute_on = 'linear timestep_end'
  []
  [vel_y]
    type = NewmarkVelAux
    variable = vel_y
    acceleration = accel_y
    gamma = 0.5
    execute_on = 'linear timestep_end'
  []
[]

[UserObjects]
  [weighted_gap_uo]
    type = LMWeightedGapUserObject
    primary_boundary = 20
    secondary_boundary = 10
    primary_subdomain = 4
    secondary_subdomain = 3
    lm_variable = normal_lm
    disp_x = disp_x
    disp_y = disp_y
  []
[]

[Constraints]
  [weighted_gap_lm]
    type = ComputeDynamicWeightedGapLMMechanicalContact
    primary_boundary = 20
    secondary_boundary = 10
    primary_subdomain = 4
    secondary_subdomain = 3
    variable = normal_lm
    disp_x = disp_x
    disp_y = disp_y
    use_displaced_mesh = true
    c = 1e4
    capture_tolerance = 1.0e-5
    newmark_beta = 0.25
    newmark_gamma = 0.5
  []
  [normal_x]
    type = NormalMortarMechanicalContact
    primary_boundary = 20
    secondary_boundary = 10
    primary_subdomain = 4
    secondary_subdomain = 3
    variable = normal_lm
    secondary_variable = disp_x
    component = x
    use_displaced_mesh = true
    compute_lm_residuals = false
    weighted_gap_uo = weighted_gap_uo
  []
  [normal_y]
    type = NormalMortarMechanicalContact
    primary_boundary = 20
    secondary_boundary = 10
    primary_subdomain = 4
    secondary_subdomain = 3
    variable = normal_lm
    secondary_variable = disp_y
    component = y
    use_displaced_mesh = true
    compute_lm_residuals = false
    weighted_gap_uo = weighted_gap_uo
  []
[]

[BCs]
  [botx]
    type = DirichletBC
    variable = disp_x
    boundary = 40
    value = 0.0
  []
  [boty]
    type = DirichletBC
    variable = disp_y
    boundary = 40
    value = 0.0
  []
  [topy]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = 30
    function = '${starting_point} * cos(2 * pi / 4 * t) + ${offset}'
  []
  [leftx]
    type = FunctionDirichletBC
    variable = disp_x
    boundary = 50
    function = '1e-2 * t'
  []
[]

[Executioner]
  type = Transient
  end_time = 0.1
  dt = 0.05
  dtmin = 0.05
  solve_type = 'PJFNK'
  petsc_options = '-snes_converged_reason -ksp_converged_reason -pc_svd_monitor '
                  '-snes_linesearch_monitor -snes_ksp_ew'
  petsc_options_iname = '-pc_type -pc_factor_mat_solver_type -pc_factor_shift_type -pc_factor_shift_amount -mat_mffd_err '
  petsc_options_value = 'lu       superlu_dist                  NONZERO               1e-15                   1e-5'
  nl_max_its = 20
  line_search = 'none'
  snesmf_reuse_base = false

  [TimeIntegrator]
    type = NewmarkBeta
    beta = 0.25
    gamma = 0.5
  []
[]

[Debug]
  show_var_residual_norms = true
[]

[Outputs]
  exodus = true
  checkpoint = true
[]

[Preconditioning]
  [smp]
    type = SMP
    full = true
  []
[]

[Postprocessors]
  active = 'num_nl cumulative contact'
  [num_nl]
    type = NumNonlinearIterations
  []
  [cumulative]
    type = CumulativeValuePostprocessor
    postprocessor = num_nl
  []
  [contact]
    type = ContactDOFSetSize
    variable = normal_lm
    subdomain = '3'
    execute_on = 'nonlinear timestep_end'
  []
[]

(modules/solid_mechanics/test/tests/multi/two_surface01.i)

# Plasticit models:
# SimpleTester with a = 0 and b = 1 and strength = 1
# SimpleTester with a = 1 and b = 1 and strength = 2
#
# Lame lambda = 0 (Poisson=0).  Lame mu = 0.5E6
#
# A single element is stretched by 1.5E-6m in the z directions.
# stress_zz = 1.5
#
# Then only the first SimpleTester should activate, and the final stress
# should have have only nonzero component stress_zz = 1

[Mesh]
  type = GeneratedMesh
  dim = 3
  nx = 1
  ny = 1
  nz = 1
  xmin = -0.5
  xmax = 0.5
  ymin = -0.5
  ymax = 0.5
  zmin = -0.5
  zmax = 0.5
[]


[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./disp_z]
  [../]
[]

[Kernels]
  [SolidMechanics]
    displacements = 'disp_x disp_y disp_z'
  [../]
[]


[BCs]
  [./x]
    type = FunctionDirichletBC
    variable = disp_x
    boundary = 'front back'
    function = '0E-6*x'
  [../]
  [./y]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = 'front back'
    function = '0E-6*y'
  [../]
  [./z]
    type = FunctionDirichletBC
    variable = disp_z
    boundary = 'front back'
    function = '1.5E-6*z'
  [../]
[]

[AuxVariables]
  [./stress_xx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_zz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./f0]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./f1]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./int0]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./int1]
    order = CONSTANT
    family = MONOMIAL
  [../]
[]

[AuxKernels]
  [./stress_xx]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xx
    index_i = 0
    index_j = 0
  [../]
  [./stress_xy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xy
    index_i = 0
    index_j = 1
  [../]
  [./stress_xz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xz
    index_i = 0
    index_j = 2
  [../]
  [./stress_yy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yy
    index_i = 1
    index_j = 1
  [../]
  [./stress_yz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yz
    index_i = 1
    index_j = 2
  [../]
  [./stress_zz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_zz
    index_i = 2
    index_j = 2
  [../]
  [./f0]
    type = MaterialStdVectorAux
    property = plastic_yield_function
    index = 0
    variable = f0
  [../]
  [./f1]
    type = MaterialStdVectorAux
    property = plastic_yield_function
    index = 1
    variable = f1
  [../]
  [./int0]
    type = MaterialStdVectorAux
    property = plastic_internal_parameter
    factor = 1E6
    index = 0
    variable = int0
  [../]
  [./int1]
    type = MaterialStdVectorAux
    property = plastic_internal_parameter
    factor = 1E6
    index = 1
    variable = int1
  [../]
[]

[Postprocessors]
  [./s_xx]
    type = PointValue
    point = '0 0 0'
    variable = stress_xx
  [../]
  [./s_xy]
    type = PointValue
    point = '0 0 0'
    variable = stress_xy
  [../]
  [./s_xz]
    type = PointValue
    point = '0 0 0'
    variable = stress_xz
  [../]
  [./s_yy]
    type = PointValue
    point = '0 0 0'
    variable = stress_yy
  [../]
  [./s_yz]
    type = PointValue
    point = '0 0 0'
    variable = stress_yz
  [../]
  [./s_zz]
    type = PointValue
    point = '0 0 0'
    variable = stress_zz
  [../]
  [./f0]
    type = PointValue
    point = '0 0 0'
    variable = f0
  [../]
  [./f1]
    type = PointValue
    point = '0 0 0'
    variable = f1
  [../]
  [./int0]
    type = PointValue
    point = '0 0 0'
    variable = int0
  [../]
  [./int1]
    type = PointValue
    point = '0 0 0'
    variable = int1
  [../]
[]

[UserObjects]
  [./simple1]
    type = SolidMechanicsPlasticSimpleTester
    a = 0
    b = 1
    strength = 1
    yield_function_tolerance = 1.0E-9
    internal_constraint_tolerance = 1.0E-9
  [../]
  [./simple2]
    type = SolidMechanicsPlasticSimpleTester
    a = 1
    b = 1
    strength = 2
    yield_function_tolerance = 1.0E-9
    internal_constraint_tolerance = 1.0E-9
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeElasticityTensor
    block = 0
    fill_method = symmetric_isotropic
    C_ijkl = '0 0.5E6'
  [../]
  [./strain]
    type = ComputeFiniteStrain
    block = 0
    displacements = 'disp_x disp_y disp_z'
  [../]
  [./multi]
    type = ComputeMultiPlasticityStress
    block = 0
    ep_plastic_tolerance = 1E-9
    plastic_models = 'simple1 simple2'
    max_NR_iterations = 2
    min_stepsize = 1
    debug_fspb = crash
    debug_jac_at_stress = '10 0 0 0 10 0 0 0 10'
    debug_jac_at_pm = '1 1'
    debug_jac_at_intnl = '1 1'
    debug_stress_change = 1E-5
    debug_pm_change = '1E-6 1E-6'
    debug_intnl_change = '1E-6 1E-6'
  [../]
[]


[Executioner]
  end_time = 1
  dt = 1
  type = Transient
[]


[Outputs]
  file_base = two_surface01
  exodus = false
  [./csv]
    type = CSV
    [../]
[]

(modules/solid_mechanics/test/tests/crystal_plasticity/monolithic_material_based/crysp_read_slip_prop.i)

[Mesh]
  type = GeneratedMesh
  dim = 3
  elem_type = HEX8
  displacements = 'ux uy uz'
[]

[Variables]
  [./ux]
    block = 0
  [../]
  [./uy]
    block = 0
  [../]
  [./uz]
    block = 0
  [../]
[]

[AuxVariables]
  [./stress_zz]
    order = CONSTANT
    family = MONOMIAL
    block = 0
  [../]
  [./fp_zz]
    order = CONSTANT
    family = MONOMIAL
    block = 0
  [../]
  [./rotout]
    order = CONSTANT
    family = MONOMIAL
    block = 0
  [../]
  [./e_zz]
    order = CONSTANT
    family = MONOMIAL
    block = 0
  [../]
  [./gss1]
    order = CONSTANT
    family = MONOMIAL
    block = 0
  [../]
[]

[Functions]
  [./tdisp]
    type = ParsedFunction
    expression = 0.01*t
  [../]
[]

[Kernels]
  [SolidMechanics]
    displacements = 'ux uy uz'
    use_displaced_mesh = true
  [../]
[]

[AuxKernels]
  [./stress_zz]
    type = RankTwoAux
    variable = stress_zz
    rank_two_tensor = stress
    index_j = 2
    index_i = 2
    execute_on = timestep_end
    block = 0
  [../]
  [./fp_zz]
    type = RankTwoAux
    variable = fp_zz
    rank_two_tensor = fp
    index_j = 2
    index_i = 2
    execute_on = timestep_end
    block = 0
  [../]
  [./e_zz]
    type = RankTwoAux
    variable = e_zz
    rank_two_tensor = lage
    index_j = 2
    index_i = 2
    execute_on = timestep_end
    block = 0
  [../]
  [./gss1]
    type = MaterialStdVectorAux
    variable = gss1
    property = gss
    index = 0
    execute_on = timestep_end
    block = 0
  [../]
[]

[BCs]
  [./symmy]
    type = DirichletBC
    variable = uy
    boundary = bottom
    value = 0
  [../]
  [./symmx]
    type = DirichletBC
    variable = ux
    boundary = left
    value = 0
  [../]
  [./symmz]
    type = DirichletBC
    variable = uz
    boundary = back
    value = 0
  [../]
  [./tdisp]
    type = FunctionDirichletBC
    variable = uz
    boundary = front
    function = tdisp
  [../]
[]

[Materials]
  [./crysp]
    type = FiniteStrainCrystalPlasticity
    block = 0
    gtol = 1e-2
    slip_sys_file_name = input_slip_sys_prop.txt
    nss = 12
    num_slip_sys_flowrate_props = 2 #Number of properties in a slip system
    flowprops = '1 4 0.001 0.1 5 8 0.001 0.1 9 12 0.001 0.1'
    hprops = '1.0 541.5 60.8 109.8 2.5'
    tan_mod_type = exact
    intvar_read_type = slip_sys_file
    num_slip_sys_props = 1
  [../]
  [./elasticity_tensor]
    type = ComputeElasticityTensorCP
    block = 0
    C_ijkl = '1.684e5 1.214e5 1.214e5 1.684e5 1.214e5 1.684e5 0.754e5 0.754e5 0.754e5'
    fill_method = symmetric9
  [../]
  [./strain]
    type = ComputeFiniteStrain
    block = 0
    displacements = 'ux uy uz'
  [../]
[]

[Postprocessors]
  [./stress_zz]
    type = ElementAverageValue
    variable = stress_zz
    block = 'ANY_BLOCK_ID 0'
  [../]
  [./fp_zz]
    type = ElementAverageValue
    variable = fp_zz
    block = 'ANY_BLOCK_ID 0'
  [../]
  [./e_zz]
    type = ElementAverageValue
    variable = e_zz
    block = 'ANY_BLOCK_ID 0'
  [../]
  [./gss1]
    type = ElementAverageValue
    variable = gss1
    block = 'ANY_BLOCK_ID 0'
  [../]
[]

[Preconditioning]
  [./smp]
    type = SMP
    full = true
  [../]
[]

[Executioner]
  type = Transient

  #Preconditioned JFNK (default)
  solve_type = 'PJFNK'

  petsc_options_iname = '-pc_type'
  petsc_options_value = 'lu'

  nl_rel_tol = 1e-10
  nl_abs_tol = 1e-10

  dt = 0.05
  dtmax = 10.0
  dtmin = 0.05

  num_steps = 10
[]

[Outputs]
  file_base = crysp_read_slip_prop_out
  exodus = true
[]

(modules/solid_mechanics/test/tests/crystal_plasticity/monolithic_material_based/crysp_fileread.i)

[Mesh]
  type = GeneratedMesh
  dim = 3
  nx=1
  ny=1
  nz=1
  xmin=0.0
  xmax=1.0
  ymin=0.0
  ymax=1.0
  zmin=0.0
  zmax=1.0
  elem_type = HEX8
  displacements = 'disp_x disp_y disp_z'
[]

[Variables]
  [./disp_x]
    block = 0
  [../]
  [./disp_y]
    block = 0
  [../]
  [./disp_z]
    block = 0
  [../]
[]

[AuxVariables]
  [./stress_zz]
    order = CONSTANT
    family = MONOMIAL
    block = 0
  [../]
  [./fp_zz]
    order = CONSTANT
    family = MONOMIAL
    block = 0
  [../]
  [./rotout]
    order = CONSTANT
    family = MONOMIAL
    block = 0
  [../]
  [./e_zz]
    order = CONSTANT
    family = MONOMIAL
    block = 0
  [../]
  [./gss1]
    order = CONSTANT
    family = MONOMIAL
    block = 0
  [../]
[]

[Functions]
  [./tdisp]
    type = ParsedFunction
    expression = 0.01*t
  [../]
[]

[Kernels]
  [SolidMechanics]
    displacements = 'disp_x disp_y disp_z'
    use_displaced_mesh = true
  [../]
[]

[AuxKernels]
  [./stress_zz]
    type = RankTwoAux
    variable = stress_zz
    rank_two_tensor = stress
    index_j = 2
    index_i = 2
    execute_on = timestep_end
    block = 0
  [../]
  [./fp_zz]
    type = RankTwoAux
    variable = fp_zz
    rank_two_tensor = fp
    index_j = 2
    index_i = 2
    execute_on = 'initial timestep_end'
    block = 0
  [../]
  [./e_zz]
    type = RankTwoAux
    variable = e_zz
    rank_two_tensor = lage
    index_j = 2
    index_i = 2
    execute_on = timestep_end
    block = 0
  [../]
  [./gss1]
    type = MaterialStdVectorAux
    variable = gss1
    property = gss
    index = 0
    execute_on = 'initial timestep_end'
    block = 0
  [../]
[]

[BCs]
  [./symmy]
    type = DirichletBC
    variable = disp_y
    boundary = bottom
    value = 0
  [../]
  [./symmx]
    type = DirichletBC
    variable = disp_x
    boundary = left
    value = 0
  [../]
  [./symmz]
    type = DirichletBC
    variable = disp_z
    boundary = back
    value = 0
  [../]
  [./tdisp]
    type = FunctionDirichletBC
    variable = disp_z
    boundary = front
    function = tdisp
  [../]
[]

[Materials]
  [./crysp]
    type = FiniteStrainCrystalPlasticity
    block = 0
    gtol = 1e-2
    slip_sys_file_name = input_slip_sys.txt
    slip_sys_res_prop_file_name = input_slip_sys_res.txt
    slip_sys_flow_prop_file_name = input_slip_sys_flow_prop.txt
    hprops = '1.0 541.5 60.8 109.8 2.5'
    nss = 12
    intvar_read_type = slip_sys_res_file
  [../]
  [./elasticity_tensor]
    type = ComputeElasticityTensorCP
    block = 0
    C_ijkl = '1.684e5 1.214e5 1.214e5 1.684e5 1.214e5 1.684e5 0.754e5 0.754e5 0.754e5'
    fill_method = symmetric9
  [../]
  [./strain]
    type = ComputeFiniteStrain
    block = 0
    displacements = 'disp_x disp_y disp_z'
  [../]
[]

[Postprocessors]
  [./stress_zz]
    type = ElementAverageValue
    variable = stress_zz
    execute_on = 'initial timestep_end'
  [../]
  [./fp_zz]
    type = ElementAverageValue
    variable = fp_zz
    execute_on = 'initial timestep_end'
  [../]
  [./e_zz]
    type = ElementAverageValue
    variable = e_zz
    execute_on = 'initial timestep_end'
  [../]
  [./gss1]
    type = ElementAverageValue
    variable = gss1
    execute_on = 'initial timestep_end'
  [../]
[]

[Preconditioning]
  [./smp]
    type = SMP
    full = true
  [../]
[]

[Executioner]
  type = Transient

  #Preconditioned JFNK (default)
  solve_type = 'PJFNK'

  petsc_options_iname = '-pc_type'
  petsc_options_value = 'lu'

  nl_rel_tol = 1e-10
  nl_abs_tol = 1e-10

  dt = 0.05
  dtmax = 10.0
  dtmin = 0.05

  num_steps = 10
[]

[Outputs]
  file_base = crysp_fileread_out
  exodus = true
[]

(modules/contact/test/tests/verification/patch_tests/brick_1/brick1_template2.i)

[GlobalParams]
  volumetric_locking_correction = true
  displacements = 'disp_x disp_y disp_z'
[]

[Mesh]
  file = brick1_mesh.e
[]

[Problem]
  type = AugmentedLagrangianContactProblem
  maximum_lagrangian_update_iterations = 200
  extra_tag_vectors = 'ref'
  reference_vector = 'ref'
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./disp_z]
  [../]
[]

[AuxVariables]
  [./stress_xx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_zz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./penetration]
  [../]
  [./saved_x]
  [../]
  [./saved_y]
  [../]
  [./saved_z]
  [../]
  [./diag_saved_x]
  [../]
  [./diag_saved_y]
  [../]
  [./diag_saved_z]
  [../]
  [./inc_slip_x]
  [../]
  [./inc_slip_y]
  [../]
  [./inc_slip_z]
  [../]
  [./accum_slip_x]
  [../]
  [./accum_slip_y]
  [../]
  [./accum_slip_z]
  [../]
[]

[Kernels]
  [./TensorMechanics]
    use_displaced_mesh = true
    save_in = 'saved_x saved_y saved_z'
    extra_vector_tags = 'ref'
  [../]
[]

[AuxKernels]
  [./stress_xx]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xx
    index_i = 0
    index_j = 0
    execute_on = timestep_end
  [../]
  [./stress_yy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yy
    index_i = 1
    index_j = 1
    execute_on = timestep_end
  [../]
  [./stress_xy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xy
    index_i = 0
    index_j = 1
    execute_on = timestep_end
  [../]
  [./stress_zz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_zz
    index_i = 2
    index_j = 2
    execute_on = timestep_end
  [../]
  [./inc_slip_x]
    type = PenetrationAux
    variable = inc_slip_x
    execute_on = timestep_begin
    boundary = 4
    paired_boundary = 3
  [../]
  [./inc_slip_y]
    type = PenetrationAux
    variable = inc_slip_y
    execute_on = timestep_begin
    boundary = 4
    paired_boundary = 3
  [../]
  [./accum_slip_x]
    type = PenetrationAux
    variable = accum_slip_x
    execute_on = timestep_end
    boundary = 4
    paired_boundary = 3
  [../]
  [./accum_slip_y]
    type = PenetrationAux
    variable = accum_slip_y
    execute_on = timestep_end
    boundary = 4
    paired_boundary = 3
  [../]
  [./penetration]
    type = PenetrationAux
    variable = penetration
    boundary = 4
    paired_boundary = 3
  [../]
[]

[Postprocessors]
  [./bot_react_x]
    type = NodalSum
    variable = saved_x
    boundary = 1
  [../]
  [./bot_react_y]
    type = NodalSum
    variable = saved_y
    boundary = 1
  [../]
  [./top_react_x]
    type = NodalSum
    variable = saved_x
    boundary = 5
  [../]
  [./top_react_y]
    type = NodalSum
    variable = saved_y
    boundary = 5
  [../]
  [./ref_resid_x]
    type = NodalL2Norm
    execute_on = timestep_end
    variable = saved_x
  [../]
  [./ref_resid_y]
    type = NodalL2Norm
    execute_on = timestep_end
    variable = saved_y
  [../]
  [./sigma_yy]
    type = ElementAverageValue
    variable = stress_yy
  [../]
  [./sigma_zz]
    type = ElementAverageValue
    variable = stress_zz
  [../]
  [./disp_x5]
    type = NodalVariableValue
    nodeid = 4
    variable = disp_x
  [../]
  [./disp_x8]
    type = NodalVariableValue
    nodeid = 7
    variable = disp_x
  [../]
  [./disp_x13]
    type = NodalVariableValue
    nodeid = 12
    variable = disp_x
  [../]
  [./disp_x16]
    type = NodalVariableValue
    nodeid = 15
    variable = disp_x
  [../]
  [./disp_y5]
    type = NodalVariableValue
    nodeid = 4
    variable = disp_y
  [../]
  [./disp_y8]
    type = NodalVariableValue
    nodeid = 7
    variable = disp_y
  [../]
  [./disp_y13]
    type = NodalVariableValue
    nodeid = 12
    variable = disp_y
  [../]
  [./disp_y16]
    type = NodalVariableValue
    nodeid = 15
    variable = disp_y
  [../]
  [./_dt]
    type = TimestepSize
  [../]
  [./num_lin_it]
    type = NumLinearIterations
  [../]
  [./num_nonlin_it]
    type = NumNonlinearIterations
  [../]
[]

[BCs]
  [./bot_y]
    type = DirichletBC
    variable = disp_y
    boundary = 1
    value = 0.0
  [../]
  [./side_x]
    type = DirichletBC
    variable = disp_x
    boundary = 2
    value = 0.0
  [../]
  [./back_z]
    type = DirichletBC
    variable = disp_z
    boundary = 6
    value = 0.0
  [../]
  [./top_press]
    type = Pressure
    variable = disp_y
    boundary = 5
    factor = 109.89
  [../]
[]

[Materials]
  [./bot_elas_tens]
    type = ComputeIsotropicElasticityTensor
    block = '1'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./bot_strain]
    type = ComputeFiniteStrain
    block = '1'
  [../]
  [./bot_stress]
    type = ComputeFiniteStrainElasticStress
    block = '1'
  [../]
  [./top_elas_tens]
    type = ComputeIsotropicElasticityTensor
    block = '2'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./top_strain]
    type = ComputeFiniteStrain
    block = '2'
  [../]
  [./top_stress]
    type = ComputeFiniteStrainElasticStress
    block = '2'
  [../]
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'

  petsc_options_iname = '-pc_type -pc_factor_mat_solver_type'
  petsc_options_value = 'lu     superlu_dist'

  line_search = 'none'

  nl_abs_tol = 1e-9
  nl_rel_tol = 1e-8
  l_max_its = 50
  nl_max_its = 100
  dt = 1.0
  end_time = 1.0
  num_steps = 10
  dtmin = 1.0
  l_tol = 1e-5
[]

[VectorPostprocessors]
  [./x_disp]
    type = NodalValueSampler
    variable = disp_x
    boundary = '1 3 4 5'
    sort_by = id
  [../]
  [./y_disp]
    type = NodalValueSampler
    variable = disp_y
    boundary = '1 3 4 5'
    sort_by = id
  [../]
  [./cont_press]
    type = NodalValueSampler
    variable = contact_pressure
    boundary = '3'
    sort_by = id
  [../]
[]

[Outputs]
  print_linear_residuals = true
  perf_graph = true
  [./exodus]
    type = Exodus
    elemental_as_nodal = true
  [../]
  [./console]
    type = Console
    max_rows = 5
  [../]
  [./chkfile]
    type = CSV
    show = 'bot_react_x bot_react_y disp_x5 disp_x8 disp_x13 disp_x16 disp_y5 disp_y8 disp_y13 disp_y16 stress_yy stress_zz top_react_x top_react_y x_disp y_disp cont_press'
    execute_vector_postprocessors_on = timestep_end
  [../]
  [./outfile]
    type = CSV
    delimiter = ' '
    execute_vector_postprocessors_on = none
  [../]
[]

[Contact]
  [./leftright]
    secondary = 3
    primary = 4
    normalize_penalty = true
    tangential_tolerance = 1e-3
    penalty = 5e+9
    al_penetration_tolerance = 1e-8
  [../]
[]

(modules/solid_mechanics/test/tests/multi/three_surface04.i)

# Plasticit models:
# SimpleTester0 with a = 0 and b = 1 and strength = 1
# SimpleTester1 with a = 1 and b = 0 and strength = 1
# SimpleTester2 with a = 1 and b = 1 and strength = 1.5
#
# Lame lambda = 0 (Poisson=0).  Lame mu = 0.5E6
#
# A single element is stretched by 0.8E-6m in y direction and 1.5E-6 in z direction.
# trial stress_yy = 0.8 and stress_zz = 1.5
#
# Then SimpleTester0 and SimpleTester2 should activate and the algorithm will return to
# the corner stress_yy=0.5, stress_zz=1
# internal0 should be 0.2, and internal2 should be 0.3

[Mesh]
  type = GeneratedMesh
  dim = 3
  nx = 1
  ny = 1
  nz = 1
  xmin = -0.5
  xmax = 0.5
  ymin = -0.5
  ymax = 0.5
  zmin = -0.5
  zmax = 0.5
[]


[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./disp_z]
  [../]
[]

[Kernels]
  [SolidMechanics]
    displacements = 'disp_x disp_y disp_z'
  [../]
[]


[BCs]
  [./x]
    type = FunctionDirichletBC
    variable = disp_x
    boundary = 'front back'
    function = '0E-6*x'
  [../]
  [./y]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = 'front back'
    function = '0.8E-6*y'
  [../]
  [./z]
    type = FunctionDirichletBC
    variable = disp_z
    boundary = 'front back'
    function = '1.5E-6*z'
  [../]
[]

[AuxVariables]
  [./stress_xx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_zz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./f0]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./f1]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./f2]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./int0]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./int1]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./int2]
    order = CONSTANT
    family = MONOMIAL
  [../]
[]

[AuxKernels]
  [./stress_xx]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xx
    index_i = 0
    index_j = 0
  [../]
  [./stress_xy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xy
    index_i = 0
    index_j = 1
  [../]
  [./stress_xz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xz
    index_i = 0
    index_j = 2
  [../]
  [./stress_yy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yy
    index_i = 1
    index_j = 1
  [../]
  [./stress_yz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yz
    index_i = 1
    index_j = 2
  [../]
  [./stress_zz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_zz
    index_i = 2
    index_j = 2
  [../]
  [./f0]
    type = MaterialStdVectorAux
    property = plastic_yield_function
    index = 0
    variable = f0
  [../]
  [./f1]
    type = MaterialStdVectorAux
    property = plastic_yield_function
    index = 1
    variable = f1
  [../]
  [./f2]
    type = MaterialStdVectorAux
    property = plastic_yield_function
    index = 2
    variable = f2
  [../]
  [./int0]
    type = MaterialStdVectorAux
    property = plastic_internal_parameter
    factor = 1E6
    index = 0
    variable = int0
  [../]
  [./int1]
    type = MaterialStdVectorAux
    property = plastic_internal_parameter
    factor = 1E6
    index = 1
    variable = int1
  [../]
  [./int2]
    type = MaterialStdVectorAux
    property = plastic_internal_parameter
    factor = 1E6
    index = 2
    variable = int2
  [../]
[]

[Postprocessors]
  [./s_xx]
    type = PointValue
    point = '0 0 0'
    variable = stress_xx
  [../]
  [./s_xy]
    type = PointValue
    point = '0 0 0'
    variable = stress_xy
  [../]
  [./s_xz]
    type = PointValue
    point = '0 0 0'
    variable = stress_xz
  [../]
  [./s_yy]
    type = PointValue
    point = '0 0 0'
    variable = stress_yy
  [../]
  [./s_yz]
    type = PointValue
    point = '0 0 0'
    variable = stress_yz
  [../]
  [./s_zz]
    type = PointValue
    point = '0 0 0'
    variable = stress_zz
  [../]
  [./f0]
    type = PointValue
    point = '0 0 0'
    variable = f0
  [../]
  [./f1]
    type = PointValue
    point = '0 0 0'
    variable = f1
  [../]
  [./f2]
    type = PointValue
    point = '0 0 0'
    variable = f2
  [../]
  [./int0]
    type = PointValue
    point = '0 0 0'
    variable = int0
  [../]
  [./int1]
    type = PointValue
    point = '0 0 0'
    variable = int1
  [../]
  [./int2]
    type = PointValue
    point = '0 0 0'
    variable = int2
  [../]
[]

[UserObjects]
  [./simple0]
    type = SolidMechanicsPlasticSimpleTester
    a = 0
    b = 1
    strength = 1
    yield_function_tolerance = 1.0E-9
    internal_constraint_tolerance = 1.0E-9
  [../]
  [./simple1]
    type = SolidMechanicsPlasticSimpleTester
    a = 1
    b = 0
    strength = 1
    yield_function_tolerance = 1.0E-9
    internal_constraint_tolerance = 1.0E-9
  [../]
  [./simple2]
    type = SolidMechanicsPlasticSimpleTester
    a = 1
    b = 1
    strength = 1.5
    yield_function_tolerance = 1.0E-9
    internal_constraint_tolerance = 1.0E-9
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeElasticityTensor
    block = 0
    fill_method = symmetric_isotropic
    C_ijkl = '0 0.5E6'
  [../]
  [./strain]
    type = ComputeFiniteStrain
    block = 0
    displacements = 'disp_x disp_y disp_z'
  [../]
  [./multi]
    type = ComputeMultiPlasticityStress
    block = 0
    ep_plastic_tolerance = 1E-9
    plastic_models = 'simple0 simple1 simple2'
    max_NR_iterations = 2
    min_stepsize = 1
    debug_fspb = crash
    debug_jac_at_stress = '10 0 0 0 10 0 0 0 10'
    debug_jac_at_pm = '1 1'
    debug_jac_at_intnl = '1 1'
    debug_stress_change = 1E-5
    debug_pm_change = '1E-6 1E-6'
    debug_intnl_change = '1E-6 1E-6'
  [../]
[]


[Executioner]
  end_time = 1
  dt = 1
  type = Transient
[]


[Outputs]
  file_base = three_surface04
  exodus = false
  [./csv]
    type = CSV
    [../]
[]

(modules/contact/test/tests/verification/hertz_cyl/half_symm_q8/hertz_cyl_half_1deg_template1.i)

[GlobalParams]
  order = SECOND
  volumetric_locking_correction = false
  displacements = 'disp_x disp_y'
[]

[Mesh]
  file = hertz_cyl_half_1deg.e
[]

[Problem]
  type = ReferenceResidualProblem
  extra_tag_vectors = 'ref'
  reference_vector = 'ref'
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
[]

[AuxVariables]
  [./stress_xx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./saved_x]
  [../]
  [./saved_y]
  [../]
  [./diag_saved_x]
  [../]
  [./diag_saved_y]
  [../]
  [./inc_slip_x]
  [../]
  [./inc_slip_y]
  [../]
  [./accum_slip_x]
  [../]
  [./accum_slip_y]
  [../]
  [./tang_force_x]
  [../]
  [./tang_force_y]
  [../]
[]

[Functions]
  [./disp_ramp_vert]
    type = PiecewiseLinear
    x = '0. 1. 3.5'
    y = '0. -0.0020 -0.0020'
  [../]
  [./disp_ramp_horz]
    type = PiecewiseLinear
    x = '0. 1. 3.5'
    y = '0. 0.0 0.0014'
  [../]
[]

[Kernels]
  [./TensorMechanics]
    use_displaced_mesh = true
    save_in = 'saved_x saved_y'
    extra_vector_tags = 'ref'
  [../]
[]

[AuxKernels]
  [./stress_xx]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xx
    index_i = 0
    index_j = 0
    execute_on = timestep_end
  [../]
  [./stress_yy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yy
    index_i = 1
    index_j = 1
    execute_on = timestep_end
  [../]
  [./stress_xy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xy
    index_i = 0
    index_j = 1
    execute_on = timestep_end
  [../]
  [./inc_slip_x]
    type = PenetrationAux
    variable = inc_slip_x
    execute_on = timestep_end
    boundary = 3
    paired_boundary = 2
  [../]
  [./inc_slip_y]
    type = PenetrationAux
    variable = inc_slip_y
    execute_on = timestep_end
    boundary = 3
    paired_boundary = 2
  [../]
  [./accum_slip_x]
    type = PenetrationAux
    variable = accum_slip_x
    execute_on = timestep_end
    boundary = 3
    paired_boundary = 2
  [../]
  [./accum_slip_y]
    type = PenetrationAux
    variable = accum_slip_y
    execute_on = timestep_end
    boundary = 3
    paired_boundary = 2
  [../]
  [./tang_force_x]
    type = PenetrationAux
    variable = tang_force_x
    quantity = tangential_force_x
    boundary = 3
    paired_boundary = 2
  [../]
  [./tang_force_y]
    type = PenetrationAux
    variable = tang_force_y
    quantity = tangential_force_y
    boundary = 3
    paired_boundary = 2
  [../]
  [./penetration]
    type = PenetrationAux
    variable = penetration
    boundary = 3
    paired_boundary = 2
  [../]
[]

[Postprocessors]
  [./bot_react_x]
    type = NodalSum
    variable = saved_x
    boundary = 1
  [../]
  [./bot_react_y]
    type = NodalSum
    variable = saved_y
    boundary = 1
  [../]
  [./top_react_x]
    type = NodalSum
    variable = saved_x
    boundary = 4
  [../]
  [./top_react_y]
    type = NodalSum
    variable = saved_y
    boundary = 4
  [../]
  [./disp_x639]
    type = NodalVariableValue
    nodeid = 638
    variable = disp_x
  [../]
  [./disp_y639]
    type = NodalVariableValue
    nodeid = 638
    variable = disp_y
  [../]
  [./_dt]
    type = TimestepSize
  [../]
  [./num_lin_it]
    type = NumLinearIterations
  [../]
  [./num_nonlin_it]
    type = NumNonlinearIterations
  [../]
[]

[BCs]
  [./side_x]
    type = DirichletBC
    variable = disp_y
    boundary = '1 2'
    value = 0.0
  [../]
  [./bot_y]
    type = DirichletBC
    variable = disp_x
    boundary = '1 2'
    value = 0.0
  [../]
  [./top_y_disp]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = 4
    function = disp_ramp_vert
  [../]
  [./top_x_disp]
    type = FunctionDirichletBC
    variable = disp_x
    boundary = 4
    function = disp_ramp_horz
  [../]
[]

[Materials]
  [./stuff1_elas_tens]
    type = ComputeIsotropicElasticityTensor
    block = '1'
    youngs_modulus = 1e10
    poissons_ratio = 0.0
  [../]
  [./stuff1_strain]
    type = ComputeFiniteStrain
    block = '1'
  [../]
  [./stuff1_stress]
    type = ComputeFiniteStrainElasticStress
    block = '1'
  [../]
  [./stuff2_elas_tens]
    type = ComputeIsotropicElasticityTensor
    block = '2'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./stuff2_strain]
    type = ComputeFiniteStrain
    block = '2'
  [../]
  [./stuff2_stress]
    type = ComputeFiniteStrainElasticStress
    block = '2'
  [../]
  [./stuff3_elas_tens]
    type = ComputeIsotropicElasticityTensor
    block = '3'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./stuff3_strain]
    type = ComputeFiniteStrain
    block = '3'
  [../]
  [./stuff3_stress]
    type = ComputeFiniteStrainElasticStress
    block = '3'
  [../]
  [./stuff4_elas_tens]
    type = ComputeIsotropicElasticityTensor
    block = '4'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./stuff4_strain]
    type = ComputeFiniteStrain
    block = '4'
  [../]
  [./stuff4_stress]
    type = ComputeFiniteStrainElasticStress
    block = '4'
  [../]
  [./stuff5_elas_tens]
    type = ComputeIsotropicElasticityTensor
    block = '5'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./stuff5_strain]
    type = ComputeFiniteStrain
    block = '5'
  [../]
  [./stuff5_stress]
    type = ComputeFiniteStrainElasticStress
    block = '5'
  [../]
  [./stuff6_elas_tens]
    type = ComputeIsotropicElasticityTensor
    block = '6'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./stuff6_strain]
    type = ComputeFiniteStrain
    block = '6'
  [../]
  [./stuff6_stress]
    type = ComputeFiniteStrainElasticStress
    block = '6'
  [../]
  [./stuff7_elas_tens]
    type = ComputeIsotropicElasticityTensor
    block = '7'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./stuff7_strain]
    type = ComputeFiniteStrain
    block = '7'
  [../]
  [./stuff7_stress]
    type = ComputeFiniteStrainElasticStress
    block = '7'
  [../]
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'

  petsc_options_iname = '-pc_type -pc_factor_mat_solver_type'
  petsc_options_value = 'lu     superlu_dist'

  line_search = 'none'

  nl_abs_tol = 1e-6
  nl_rel_tol = 1e-5
  l_max_its = 100
  nl_max_its = 200

  start_time = 0.0
  end_time = 3.5
  l_tol = 1e-3
  dt = 0.1
  dtmin = 0.1
[]

[Preconditioning]
  [./SMP]
    type = SMP
    full = true
  [../]
[]

[VectorPostprocessors]
  [./x_disp]
    type = NodalValueSampler
    variable = disp_x
    boundary = '3 4'
    sort_by = id
  [../]
  [./y_disp]
    type = NodalValueSampler
    variable = disp_y
    boundary = '3 4'
    sort_by = id
  [../]
  [./cont_press]
    type = NodalValueSampler
    variable = contact_pressure
    boundary = '3'
    sort_by = id
  [../]
[]

[Outputs]
  print_linear_residuals = true
  perf_graph = true
  [./exodus]
    type = Exodus
    elemental_as_nodal = true
  [../]
  [./console]
    type = Console
    max_rows = 5
  [../]
  [./chkfile]
    type = CSV
    show = 'x_disp y_disp cont_press'
    start_time = 0.9
    execute_vector_postprocessors_on = timestep_end
  [../]
  [./chkfile2]
    type = CSV
    show = 'bot_react_x bot_react_y disp_x639 disp_y639 top_react_x top_react_y'
    start_time = 0.9
    execute_vector_postprocessors_on = timestep_end
  [../]
  [./outfile]
    type = CSV
    delimiter = ' '
    execute_vector_postprocessors_on = none
  [../]
[]

[Contact]
  [./interface]
    primary = 2
    secondary = 3
    normalize_penalty = true
    tangential_tolerance = 1e-3
    penalty = 1e+10
  [../]
[]

(modules/solid_mechanics/test/tests/multi/three_surface09.i)

# Plasticit models:
# SimpleTester0 with a = 0 and b = 1 and strength = 1
# SimpleTester1 with a = 1 and b = 0 and strength = 1
# SimpleTester2 with a = 1 and b = 1 and strength = 1.5
#
# Lame lambda = 0 (Poisson=0).  Lame mu = 0.5E6
#
# A single element is stretched by 2.0E-6m in y direction and 0.0E-6 in z direction.
# trial stress_yy = 2.0 and stress_zz = 0.0
#
# Then SimpleTester1 and SimpleTester2 should activate and the algorithm will return to
# the corner stress_yy=1.0, stress_zz=0.5
# However, this will mean that internal2<0, so SimpleTester2 will be deactivated
# and the algorithm will return to stress_yy=1
# internal1 should be 1.0, and internal2 should be 0

[Mesh]
  type = GeneratedMesh
  dim = 3
  nx = 1
  ny = 1
  nz = 1
  xmin = -0.5
  xmax = 0.5
  ymin = -0.5
  ymax = 0.5
  zmin = -0.5
  zmax = 0.5
[]


[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./disp_z]
  [../]
[]

[Kernels]
  [SolidMechanics]
    displacements = 'disp_x disp_y disp_z'
  [../]
[]


[BCs]
  [./x]
    type = FunctionDirichletBC
    variable = disp_x
    boundary = 'front back'
    function = '0E-6*x'
  [../]
  [./y]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = 'front back'
    function = '2.0E-6*y'
  [../]
  [./z]
    type = FunctionDirichletBC
    variable = disp_z
    boundary = 'front back'
    function = '0.0E-6*z'
  [../]
[]

[AuxVariables]
  [./stress_xx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_zz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./f0]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./f1]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./f2]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./int0]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./int1]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./int2]
    order = CONSTANT
    family = MONOMIAL
  [../]
[]

[AuxKernels]
  [./stress_xx]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xx
    index_i = 0
    index_j = 0
  [../]
  [./stress_xy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xy
    index_i = 0
    index_j = 1
  [../]
  [./stress_xz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xz
    index_i = 0
    index_j = 2
  [../]
  [./stress_yy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yy
    index_i = 1
    index_j = 1
  [../]
  [./stress_yz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yz
    index_i = 1
    index_j = 2
  [../]
  [./stress_zz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_zz
    index_i = 2
    index_j = 2
  [../]
  [./f0]
    type = MaterialStdVectorAux
    property = plastic_yield_function
    index = 0
    variable = f0
  [../]
  [./f1]
    type = MaterialStdVectorAux
    property = plastic_yield_function
    index = 1
    variable = f1
  [../]
  [./f2]
    type = MaterialStdVectorAux
    property = plastic_yield_function
    index = 2
    variable = f2
  [../]
  [./int0]
    type = MaterialStdVectorAux
    property = plastic_internal_parameter
    factor = 1E6
    index = 0
    variable = int0
  [../]
  [./int1]
    type = MaterialStdVectorAux
    property = plastic_internal_parameter
    factor = 1E6
    index = 1
    variable = int1
  [../]
  [./int2]
    type = MaterialStdVectorAux
    property = plastic_internal_parameter
    factor = 1E6
    index = 2
    variable = int2
  [../]
[]

[Postprocessors]
  [./s_xx]
    type = PointValue
    point = '0 0 0'
    variable = stress_xx
  [../]
  [./s_xy]
    type = PointValue
    point = '0 0 0'
    variable = stress_xy
  [../]
  [./s_xz]
    type = PointValue
    point = '0 0 0'
    variable = stress_xz
  [../]
  [./s_yy]
    type = PointValue
    point = '0 0 0'
    variable = stress_yy
  [../]
  [./s_yz]
    type = PointValue
    point = '0 0 0'
    variable = stress_yz
  [../]
  [./s_zz]
    type = PointValue
    point = '0 0 0'
    variable = stress_zz
  [../]
  [./f0]
    type = PointValue
    point = '0 0 0'
    variable = f0
  [../]
  [./f1]
    type = PointValue
    point = '0 0 0'
    variable = f1
  [../]
  [./f2]
    type = PointValue
    point = '0 0 0'
    variable = f2
  [../]
  [./int0]
    type = PointValue
    point = '0 0 0'
    variable = int0
  [../]
  [./int1]
    type = PointValue
    point = '0 0 0'
    variable = int1
  [../]
  [./int2]
    type = PointValue
    point = '0 0 0'
    variable = int2
  [../]
[]

[UserObjects]
  [./simple0]
    type = SolidMechanicsPlasticSimpleTester
    a = 0
    b = 1
    strength = 1
    yield_function_tolerance = 1.0E-9
    internal_constraint_tolerance = 1.0E-9
  [../]
  [./simple1]
    type = SolidMechanicsPlasticSimpleTester
    a = 1
    b = 0
    strength = 1
    yield_function_tolerance = 1.0E-9
    internal_constraint_tolerance = 1.0E-9
  [../]
  [./simple2]
    type = SolidMechanicsPlasticSimpleTester
    a = 1
    b = 1
    strength = 1.5
    yield_function_tolerance = 1.0E-9
    internal_constraint_tolerance = 1.0E-9
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeElasticityTensor
    block = 0
    fill_method = symmetric_isotropic
    C_ijkl = '0 0.5E6'
  [../]
  [./strain]
    type = ComputeFiniteStrain
    block = 0
    displacements = 'disp_x disp_y disp_z'
  [../]
  [./multi]
    type = ComputeMultiPlasticityStress
    block = 0
    ep_plastic_tolerance = 1E-9
    plastic_models = 'simple0 simple1 simple2'
    max_NR_iterations = 2
    min_stepsize = 1
    debug_fspb = crash
    debug_jac_at_stress = '10 0 0 0 10 0 0 0 10'
    debug_jac_at_pm = '1 1'
    debug_jac_at_intnl = '1 1'
    debug_stress_change = 1E-5
    debug_pm_change = '1E-6 1E-6'
    debug_intnl_change = '1E-6 1E-6'
  [../]
[]


[Executioner]
  end_time = 1
  dt = 1
  type = Transient
[]


[Outputs]
  file_base = three_surface09
  exodus = false
  [./csv]
    type = CSV
    [../]
[]

(modules/solid_mechanics/test/tests/drucker_prager/random_hyperbolic.i)

# drucker-prager hyperbolic.
# apply many random large deformations, checking that the algorithm returns correctly to
# the yield surface each time.


[Mesh]
  type = GeneratedMesh
  dim = 3
  nx = 100
  ny = 125
  nz = 1
  xmin = 0
  xmax = 100
  ymin = 0
  ymax = 125
  zmin = 0
  zmax = 1
[]


[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./disp_z]
  [../]
[]

[Kernels]
  [SolidMechanics]
    displacements = 'disp_x disp_y disp_z'
  [../]
[]


[ICs]
  [./x]
    type = RandomIC
    min = -0.1
    max = 0.1
    variable = disp_x
  [../]
  [./y]
    type = RandomIC
    min = -0.1
    max = 0.1
    variable = disp_y
  [../]
  [./z]
    type = RandomIC
    min = -0.1
    max = 0.1
    variable = disp_z
  [../]
[]

[BCs]
  [./x]
    type = FunctionDirichletBC
    variable = disp_x
    boundary = 'front back'
    function = '0'
  [../]
  [./y]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = 'front back'
    function = '0'
  [../]
  [./z]
    type = FunctionDirichletBC
    variable = disp_z
    boundary = 'front back'
    function = '0'
  [../]
[]

[AuxVariables]
  [./yield_fcn]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./iter]
    order = CONSTANT
    family = MONOMIAL
  [../]
[]

[AuxKernels]
  [./yield_fcn_auxk]
    type = MaterialStdVectorAux
    index = 0
    property = plastic_yield_function
    variable = yield_fcn
  [../]
  [./iter]
    type = MaterialRealAux
    property = plastic_NR_iterations
    variable = iter
  [../]
[]

[Postprocessors]
  [./yield_fcn_at_zero]
    type = PointValue
    point = '0 0 0'
    variable = yield_fcn
    outputs = 'console'
  [../]
  [./should_be_zero]
    type = FunctionValuePostprocessor
    function = should_be_zero_fcn
  [../]
  [./av_iter]
    type = ElementAverageValue
    variable = iter
    outputs = 'console'
  [../]
[]

[Functions]
  [./should_be_zero_fcn]
    type = ParsedFunction
    expression = 'if(a<1E-3,0,a)'
    symbol_names = 'a'
    symbol_values = 'yield_fcn_at_zero'
  [../]
[]

[UserObjects]
  [./mc_coh]
    type = SolidMechanicsHardeningConstant
    value = 1E3
  [../]
  [./mc_phi]
    type = SolidMechanicsHardeningConstant
    value = 30
    convert_to_radians = true
  [../]
  [./mc_psi]
    type = SolidMechanicsHardeningConstant
    value = 5
    convert_to_radians = true
  [../]
  [./dp]
    type = SolidMechanicsPlasticDruckerPragerHyperbolic
    mc_cohesion = mc_coh
    mc_friction_angle = mc_phi
    mc_dilation_angle = mc_psi
    smoother = 0.1E3
    yield_function_tolerance = 1E-3
    internal_constraint_tolerance = 1E-6
    use_custom_returnMap = true
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeElasticityTensor
    block = 0
    fill_method = symmetric_isotropic
    C_ijkl = '0.7E7 1E7'
  [../]
  [./strain]
    type = ComputeFiniteStrain
    block = 0
    displacements = 'disp_x disp_y disp_z'
  [../]
  [./dp]
    type = ComputeMultiPlasticityStress
    block = 0
    max_NR_iterations = 1000
    ep_plastic_tolerance = 1E-6
    min_stepsize = 1E-3
    plastic_models = dp
    debug_fspb = crash
    deactivation_scheme = safe
  [../]
[]


[Executioner]
  end_time = 1
  dt = 1
  type = Transient
[]


[Outputs]
  file_base = random_hyperbolic
  exodus = false
  [./csv]
    type = CSV
    [../]
[]

(modules/contact/test/tests/pdass_problems/ironing_penalty_al.i)

[GlobalParams]
  volumetric_locking_correction = true
  displacements = 'disp_x disp_y'
[]

[Mesh]
  [input_file]
    type = FileMeshGenerator
    file = iron.e
  []
  [secondary]
    type = LowerDBlockFromSidesetGenerator
    new_block_id = 10001
    new_block_name = 'secondary_lower'
    sidesets = '10'
    input = input_file
  []
  [primary]
    type = LowerDBlockFromSidesetGenerator
    new_block_id = 10000
    sidesets = '20'
    new_block_name = 'primary_lower'
    input = secondary
  []
  patch_update_strategy = auto
  patch_size = 20
  allow_renumbering = false
[]

[Variables]
  [disp_x]
  []
  [disp_y]
  []
[]

[AuxVariables]
  [penalty_normal_pressure]
    order = FIRST
    family = LAGRANGE
  []
  [penalty_frictional_pressure]
    order = FIRST
    family = LAGRANGE
  []
  [accumulated_slip_one]
    order = FIRST
    family = LAGRANGE
  []
  [tangential_vel_one]
    order = FIRST
    family = LAGRANGE
  []
  [real_weighted_gap]
    order = FIRST
    family = LAGRANGE
  []
  [stress_xx]
    order = CONSTANT
    family = MONOMIAL
  []
  [stress_yy]
    order = CONSTANT
    family = MONOMIAL
  []
  [stress_xy]
    order = CONSTANT
    family = MONOMIAL
  []
  [saved_x]
  []
  [saved_y]
  []
  [diag_saved_x]
  []
  [diag_saved_y]
  []
  [von_mises]
    order = CONSTANT
    family = MONOMIAL
  []
[]

[Functions]
  [disp_ramp_vert]
    type = PiecewiseLinear
    x = '0. 2. 8.'
    y = '0. -1.0 -1.0'
  []
  [disp_ramp_horz]
    type = PiecewiseLinear
    x = '0. 8.'
    y = '0. 8.'
  []
[]

[Kernels]
  [TensorMechanics]
    use_displaced_mesh = true
    save_in = 'saved_x saved_y'
    block = '1 2'
    strain = FINITE
  []
[]

[AuxKernels]
  [penalty_normal_pressure_auxk]
    type = PenaltyMortarUserObjectAux
    variable = penalty_normal_pressure
    user_object = friction_uo
    contact_quantity = normal_pressure
  []
  [penalty_frictional_pressure_auxk]
    type = PenaltyMortarUserObjectAux
    variable = penalty_frictional_pressure
    user_object = friction_uo
    contact_quantity = tangential_pressure_one
  []
  [penalty_accumulated_slip_auxk]
    type = PenaltyMortarUserObjectAux
    variable = accumulated_slip_one
    user_object = friction_uo
    contact_quantity = accumulated_slip_one
  []
  [penalty_tangential_vel_auxk]
    type = PenaltyMortarUserObjectAux
    variable = tangential_vel_one
    user_object = friction_uo
    contact_quantity = tangential_velocity_one
  []
  [real_weighted_gap_auxk]
    type = PenaltyMortarUserObjectAux
    variable = real_weighted_gap
    user_object = friction_uo
    contact_quantity = normal_gap
  []
  [stress_xx]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xx
    index_i = 0
    index_j = 0
    execute_on = timestep_end
    block = '1 2'
  []
  [stress_yy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yy
    index_i = 1
    index_j = 1
    execute_on = timestep_end
    block = '1 2'
  []
  [stress_xy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xy
    index_i = 0
    index_j = 1
    execute_on = timestep_end
    block = '1 2'
  []
  [von_mises_kernel]
    #Calculates the von mises stress and assigns it to von_mises
    type = RankTwoScalarAux
    variable = von_mises
    rank_two_tensor = stress
    execute_on = timestep_end
    scalar_type = VonMisesStress
    block = '1 2'
  []
[]

# [VectorPostprocessors]
#   [penalty_normal_pressure]
#     type = NodalValueSampler
#     variable = penalty_normal_pressure
#     boundary = 10
#     sort_by = id
#   []
# []

[Postprocessors]
  [num_nl]
    type = NumNonlinearIterations
  []
  [cumulative]
    type = CumulativeValuePostprocessor
    postprocessor = num_nl
  []
  [force_x]
    type = NodalSum
    boundary = 30
    variable = saved_x
  []
  [force_y]
    type = NodalSum
    boundary = 30
    variable = saved_y
  []
  [gap]
    type = SideExtremeValue
    value_type = min
    variable = real_weighted_gap
    boundary = 10
  []
  [num_al]
    type = NumAugmentedLagrangeIterations
  []
[]

[BCs]
  [bot_x_disp]
    type = DirichletBC
    variable = disp_x
    boundary = '40'
    value = 0.0
    preset = false
  []
  [bot_y_disp]
    type = DirichletBC
    variable = disp_y
    boundary = '40'
    value = 0.0
    preset = false
  []
  [top_y_disp]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = '30'
    function = disp_ramp_vert
    preset = false
  []
  [top_x_disp]
    type = FunctionDirichletBC
    variable = disp_x
    boundary = '30'
    function = disp_ramp_horz
    preset = false
  []
[]

[Materials]
  [stuff1_elas_tens]
    type = ComputeIsotropicElasticityTensor
    block = '2'
    youngs_modulus = 6896
    poissons_ratio = 0.32
  []
  [stuff1_strain]
    type = ComputeFiniteStrain
    block = '2'
  []
  [stuff1_stress]
    type = ComputeFiniteStrainElasticStress
    block = '2'
  []
  [stuff2_elas_tens]
    type = ComputeIsotropicElasticityTensor
    block = '1'
    youngs_modulus = 689.6
    poissons_ratio = 0.32
  []
  [stuff2_strain]
    type = ComputeFiniteStrain
    block = '1'
  []
  [stuff2_stress]
    type = ComputeFiniteStrainElasticStress
    block = '1'
  []
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'

  petsc_options = '-snes_ksp_ew'
  petsc_options_iname = '-pc_type -pc_factor_mat_solver_type'
  petsc_options_value = 'lu     superlu_dist'
  line_search = 'none'

  nl_abs_tol = 1e-7
  nl_rel_tol = 1e-7
  l_tol = 1e-6

  l_max_its = 7
  nl_max_its = 300

  start_time = 0.0
  end_time = 6.5 # 6.5

  dt = 0.0125
  dtmin = 1e-5
  [Predictor]
    type = SimplePredictor
    scale = 1.0
  []
[]

[Preconditioning]
  [SMP]
    type = SMP
    full = true
  []
[]

[Outputs]
  print_linear_residuals = true
  perf_graph = true
  exodus = true
  csv = true
  # [chkfile]
  #   type = CSV
  #   start_time = 0.0
  #   execute_vector_postprocessors_on = FINAL
  # []

  [console]
    type = Console
    max_rows = 5
  []
[]

[Debug]
  show_var_residual_norms = true
[]

[Problem]
  type = AugmentedLagrangianContactFEProblem
[]

[UserObjects]
  [friction_uo]
    type = PenaltyFrictionUserObject
    primary_boundary = 20
    secondary_boundary = 10
    primary_subdomain = 10000
    secondary_subdomain = 10001
    disp_x = disp_x
    disp_y = disp_y
    friction_coefficient = 0.4 # with 2.0 works
    secondary_variable = disp_x
    penalty = 5e5
    penalty_friction = 1e4
    slip_tolerance = 1e-05
    penetration_tolerance = 1e-03
  []
[]

[Constraints]
  [x]
    type = NormalMortarMechanicalContact
    primary_boundary = 20
    secondary_boundary = 10
    primary_subdomain = 10000
    secondary_subdomain = 10001
    secondary_variable = disp_x
    component = x
    use_displaced_mesh = true
    compute_lm_residuals = false
    weighted_gap_uo = friction_uo
  []
  [y]
    type = NormalMortarMechanicalContact
    primary_boundary = 20
    secondary_boundary = 10
    primary_subdomain = 10000
    secondary_subdomain = 10001
    secondary_variable = disp_y
    component = y
    use_displaced_mesh = true
    compute_lm_residuals = false
    weighted_gap_uo = friction_uo
  []
  [t_x]
    type = TangentialMortarMechanicalContact
    primary_boundary = 20
    secondary_boundary = 10
    primary_subdomain = 10000
    secondary_subdomain = 10001
    secondary_variable = disp_x
    component = x
    use_displaced_mesh = true
    compute_lm_residuals = false
    weighted_velocities_uo = friction_uo
  []
  [t_y]
    type = TangentialMortarMechanicalContact
    primary_boundary = 20
    secondary_boundary = 10
    primary_subdomain = 10000
    secondary_subdomain = 10001
    secondary_variable = disp_y
    component = y
    use_displaced_mesh = true
    compute_lm_residuals = false
    weighted_velocities_uo = friction_uo
  []
[]

(modules/contact/test/tests/verification/patch_tests/brick_2/brick2_template2.i)

[GlobalParams]
  volumetric_locking_correction = true
  displacements = 'disp_x disp_y disp_z'
[]

[Mesh]
  file = brick2_mesh.e
[]

[Problem]
  type = AugmentedLagrangianContactProblem
  maximum_lagrangian_update_iterations = 200
  extra_tag_vectors = 'ref'
  reference_vector = 'ref'
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./disp_z]
  [../]
[]

[AuxVariables]
  [./stress_xx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_zz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./penetration]
  [../]
  [./saved_x]
  [../]
  [./saved_y]
  [../]
  [./saved_z]
  [../]
  [./diag_saved_x]
  [../]
  [./diag_saved_y]
  [../]
  [./diag_saved_z]
  [../]
  [./inc_slip_x]
  [../]
  [./inc_slip_y]
  [../]
  [./inc_slip_z]
  [../]
  [./accum_slip_x]
  [../]
  [./accum_slip_y]
  [../]
  [./accum_slip_z]
  [../]
[]

[Kernels]
  [./TensorMechanics]
    use_displaced_mesh = true
    save_in = 'saved_x saved_y saved_z'
    extra_vector_tags = 'ref'
  [../]
[]

[AuxKernels]
  [./stress_xx]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xx
    index_i = 0
    index_j = 0
    execute_on = timestep_end
  [../]
  [./stress_yy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yy
    index_i = 1
    index_j = 1
    execute_on = timestep_end
  [../]
  [./stress_xy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xy
    index_i = 0
    index_j = 1
    execute_on = timestep_end
  [../]
  [./stress_zz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_zz
    index_i = 2
    index_j = 2
    execute_on = timestep_end
  [../]
  [./inc_slip_x]
    type = PenetrationAux
    variable = inc_slip_x
    execute_on = timestep_begin
    boundary = 4
    paired_boundary = 3
  [../]
  [./inc_slip_y]
    type = PenetrationAux
    variable = inc_slip_y
    execute_on = timestep_begin
    boundary = 4
    paired_boundary = 3
  [../]
  [./accum_slip_x]
    type = PenetrationAux
    variable = accum_slip_x
    execute_on = timestep_end
    boundary = 4
    paired_boundary = 3
  [../]
  [./accum_slip_y]
    type = PenetrationAux
    variable = accum_slip_y
    execute_on = timestep_end
    boundary = 4
    paired_boundary = 3
  [../]
  [./penetration]
    type = PenetrationAux
    variable = penetration
    boundary = 4
    paired_boundary = 3
  [../]
[]

[Postprocessors]
  [./bot_react_x]
    type = NodalSum
    variable = saved_x
    boundary = 1
  [../]
  [./bot_react_y]
    type = NodalSum
    variable = saved_y
    boundary = 1
  [../]
  [./top_react_x]
    type = NodalSum
    variable = saved_x
    boundary = 5
  [../]
  [./top_react_y]
    type = NodalSum
    variable = saved_y
    boundary = 5
  [../]
  [./ref_resid_x]
    type = NodalL2Norm
    execute_on = timestep_end
    variable = saved_x
  [../]
  [./ref_resid_y]
    type = NodalL2Norm
    execute_on = timestep_end
    variable = saved_y
  [../]
  [./sigma_yy]
    type = ElementAverageValue
    variable = stress_yy
  [../]
  [./sigma_zz]
    type = ElementAverageValue
    variable = stress_zz
  [../]
  [./disp_x7]
    type = NodalVariableValue
    nodeid = 6
    variable = disp_x
  [../]
  [./disp_x26]
    type = NodalVariableValue
    nodeid = 25
    variable = disp_x
  [../]
  [./disp_y7]
    type = NodalVariableValue
    nodeid = 6
    variable = disp_y
  [../]
  [./disp_y26]
    type = NodalVariableValue
    nodeid = 25
    variable = disp_y
  [../]
  [./_dt]
    type = TimestepSize
  [../]
  [./num_lin_it]
    type = NumLinearIterations
  [../]
  [./num_nonlin_it]
    type = NumNonlinearIterations
  [../]
[]

[BCs]
  [./bot_y]
    type = DirichletBC
    variable = disp_y
    boundary = 1
    value = 0.0
  [../]
  [./side_x]
    type = DirichletBC
    variable = disp_x
    boundary = 2
    value = 0.0
  [../]
  [./back_z]
    type = DirichletBC
    variable = disp_z
    boundary = 6
    value = 0.0
  [../]
  [./top_press]
    type = Pressure
    variable = disp_y
    boundary = 5
    factor = 109.89
  [../]
[]

[Materials]
  [./bot_elas_tens]
    type = ComputeIsotropicElasticityTensor
    block = '1'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./bot_strain]
    type = ComputeFiniteStrain
    block = '1'
  [../]
  [./bot_stress]
    type = ComputeFiniteStrainElasticStress
    block = '1'
  [../]
  [./top_elas_tens]
    type = ComputeIsotropicElasticityTensor
    block = '2'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./top_strain]
    type = ComputeFiniteStrain
    block = '2'
  [../]
  [./top_stress]
    type = ComputeFiniteStrainElasticStress
    block = '2'
  [../]
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'

  petsc_options_iname = '-pc_type -pc_factor_mat_solver_type'
  petsc_options_value = 'lu     superlu_dist'

  line_search = 'none'

  nl_abs_tol = 1e-9
  nl_rel_tol = 1e-8
  l_max_its = 50
  nl_max_its = 100
  dt = 1.0
  end_time = 1.0
  num_steps = 10
  dtmin = 1.0
  l_tol = 1e-5

[]

[VectorPostprocessors]
  [./x_disp]
    type = NodalValueSampler
    variable = disp_x
    boundary = '1 3 4 5'
    sort_by = id
  [../]
  [./y_disp]
    type = NodalValueSampler
    variable = disp_y
    boundary = '1 3 4 5'
    sort_by = id
  [../]
  [./cont_press]
    type = NodalValueSampler
    variable = contact_pressure
    boundary = '3'
    sort_by = id
  [../]
[]

[Outputs]
  print_linear_residuals = true
  perf_graph = true
  [./exodus]
    type = Exodus
    elemental_as_nodal = true
  [../]
  [./console]
    type = Console
    max_rows = 5
  [../]
  [./chkfile]
    type = CSV
    show = 'bot_react_x bot_react_y disp_x7 disp_y7 disp_x26 disp_y26 stress_yy stress_zz top_react_x top_react_y x_disp y_disp cont_press'
    execute_vector_postprocessors_on = timestep_end
  [../]
  [./outfile]
    type = CSV
    delimiter = ' '
    execute_vector_postprocessors_on = none
  [../]
[]

[Contact]
  [./leftright]
    secondary = 3
    primary = 4
    normalize_penalty = true
    tangential_tolerance = 1e-3
    penalty = 1e+7
    al_penetration_tolerance = 1e-8
  [../]
[]

(modules/contact/test/tests/verification/patch_tests/brick_3/brick3_mu_0_2_pen.i)

[GlobalParams]
  order = SECOND
  displacements = 'disp_x disp_y disp_z'
[]

[Mesh]
  file = brick3_mesh.e
[]

[Problem]
  type = ReferenceResidualProblem
  extra_tag_vectors = 'ref'
  reference_vector = 'ref'
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./disp_z]
  [../]
[]

[AuxVariables]
  [./stress_xx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_zz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./penetration]
  [../]
  [./saved_x]
  [../]
  [./saved_y]
  [../]
  [./saved_z]
  [../]
  [./diag_saved_x]
  [../]
  [./diag_saved_y]
  [../]
  [./diag_saved_z]
  [../]
  [./inc_slip_x]
  [../]
  [./inc_slip_y]
  [../]
  [./inc_slip_z]
  [../]
  [./accum_slip_x]
  [../]
  [./accum_slip_y]
  [../]
  [./accum_slip_z]
  [../]
  [./tang_force_x]
  [../]
  [./tang_force_y]
  [../]
  [./tang_force_z]
  [../]
[]

[Kernels]
  [./TensorMechanics]
    use_displaced_mesh = true
    save_in = 'saved_x saved_y saved_z'
    extra_vector_tags = 'ref'
  [../]
[]

[AuxKernels]
  [./stress_xx]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xx
    index_i = 0
    index_j = 0
    execute_on = timestep_end
  [../]
  [./stress_yy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yy
    index_i = 1
    index_j = 1
    execute_on = timestep_end
  [../]
  [./stress_xy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xy
    index_i = 0
    index_j = 1
    execute_on = timestep_end
  [../]
  [./stress_zz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_zz
    index_i = 2
    index_j = 2
    execute_on = timestep_end
  [../]
  [./inc_slip_x]
    type = PenetrationAux
    variable = inc_slip_x
    execute_on = timestep_end
    boundary = 3
    paired_boundary = 4
  [../]
  [./inc_slip_y]
    type = PenetrationAux
    variable = inc_slip_y
    execute_on = timestep_end
    boundary = 3
    paired_boundary = 4
  [../]
  [./accum_slip_x]
    type = PenetrationAux
    variable = accum_slip_x
    execute_on = timestep_end
    boundary = 3
    paired_boundary = 4
  [../]
  [./accum_slip_y]
    type = PenetrationAux
    variable = accum_slip_y
    execute_on = timestep_end
    boundary = 3
    paired_boundary = 4
  [../]
  [./penetration]
    type = PenetrationAux
    variable = penetration
    boundary = 3
    paired_boundary = 4
  [../]
  [./tang_force_x]
    type = PenetrationAux
    variable = tang_force_x
    quantity = tangential_force_x
    boundary = 3
    paired_boundary = 4
  [../]
  [./tang_force_y]
    type = PenetrationAux
    variable = tang_force_y
    quantity = tangential_force_y
    boundary = 3
    paired_boundary = 4
  [../]
[]

[Postprocessors]
  [./bot_react_x]
    type = NodalSum
    variable = saved_x
    boundary = 1
  [../]
  [./bot_react_y]
    type = NodalSum
    variable = saved_y
    boundary = 1
  [../]
  [./top_react_x]
    type = NodalSum
    variable = saved_x
    boundary = 5
  [../]
  [./top_react_y]
    type = NodalSum
    variable = saved_y
    boundary = 5
  [../]
  [./ref_resid_x]
    type = NodalL2Norm
    execute_on = timestep_end
    variable = saved_x
  [../]
  [./ref_resid_y]
    type = NodalL2Norm
    execute_on = timestep_end
    variable = saved_y
  [../]
  [./sigma_yy]
    type = ElementAverageValue
    variable = stress_yy
  [../]
  [./sigma_zz]
    type = ElementAverageValue
    variable = stress_zz
  [../]
  [./disp_x28]
    type = NodalVariableValue
    nodeid = 27
    variable = disp_x
  [../]
  [./disp_x33]
    type = NodalVariableValue
    nodeid = 32
    variable = disp_x
  [../]
  [./disp_y28]
    type = NodalVariableValue
    nodeid = 27
    variable = disp_y
  [../]
  [./disp_y33]
    type = NodalVariableValue
    nodeid = 32
    variable = disp_y
  [../]
  [./_dt]
    type = TimestepSize
  [../]
  [./num_lin_it]
    type = NumLinearIterations
  [../]
  [./num_nonlin_it]
    type = NumNonlinearIterations
  [../]
[]

[BCs]
  [./bot_y]
    type = DirichletBC
    variable = disp_y
    boundary = 1
    value = 0.0
  [../]
  [./side_x]
    type = DirichletBC
    variable = disp_x
    boundary = 2
    value = 0.0
  [../]
  [./back_z]
    type = DirichletBC
    variable = disp_z
    boundary = 6
    value = 0.0
  [../]
  [./top_press]
    type = Pressure
    variable = disp_y
    boundary = 5
    factor = 109.89
  [../]
[]

[Materials]
  [./bot_elas_tens]
    type = ComputeIsotropicElasticityTensor
    block = '1'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./bot_strain]
    type = ComputeFiniteStrain
    block = '1'
  [../]
  [./bot_stress]
    type = ComputeFiniteStrainElasticStress
    block = '1'
  [../]
  [./top_elas_tens]
    type = ComputeIsotropicElasticityTensor
    block = '2'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./top_strain]
    type = ComputeFiniteStrain
    block = '2'
  [../]
  [./top_stress]
    type = ComputeFiniteStrainElasticStress
    block = '2'
  [../]
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'

  petsc_options_iname = '-pc_type -pc_factor_mat_solver_type'
  petsc_options_value = 'lu     superlu_dist'

  line_search = 'none'

  nl_abs_tol = 1e-9
  nl_rel_tol = 1e-8
  l_max_its = 50
  nl_max_its = 100
  dt = 1.0
  end_time = 1.0
  num_steps = 10
  dtmin = 1.0
  l_tol = 1e-5
[]

[VectorPostprocessors]
  [./x_disp]
    type = NodalValueSampler
    variable = disp_x
    boundary = '1 3 4 5'
    sort_by = id
  [../]
  [./y_disp]
    type = NodalValueSampler
    variable = disp_y
    boundary = '1 3 4 5'
    sort_by = id
  [../]
  [./cont_press]
    type = NodalValueSampler
    variable = contact_pressure
    boundary = '3'
    sort_by = id
  [../]
[]

[Outputs]
  file_base = brick3_mu_0_2_pen_out
  print_linear_residuals = true
  perf_graph = true
  [./exodus]
    type = Exodus
    elemental_as_nodal = true
  [../]
  [./console]
    type = Console
    max_rows = 5
  [../]
  [./chkfile]
    type = CSV
    file_base = brick3_mu_0_2_pen_check
    show = 'bot_react_x bot_react_y disp_x28 disp_y28 disp_x33 disp_y33 stress_yy stress_zz top_react_x top_react_y x_disp y_disp cont_press'
    execute_vector_postprocessors_on = timestep_end
  [../]
  [./outfile]
    type = CSV
    delimiter = ' '
    execute_vector_postprocessors_on = none
  [../]
[]

[Contact]
  [./leftright]
    secondary = 3
    primary = 4
    model = coulomb
    formulation = penalty
    normalize_penalty = true
    friction_coefficient = 0.2
    penalty = 1e+6
  [../]
[]

(modules/solid_mechanics/test/tests/multi/three_surface02.i)

# Plasticit models:
# SimpleTester0 with a = 0 and b = 1 and strength = 1
# SimpleTester1 with a = 1 and b = 0 and strength = 1
# SimpleTester2 with a = 1 and b = 1 and strength = 1.5
#
# Lame lambda = 0 (Poisson=0).  Lame mu = 0.5E6
#
# A single element is stretched by 0E-6m in y direction and 2.0E-6 in z direction.
# trial stress_yy = 0 and stress_zz = 2.0
#
# Then SimpleTester0 and SimpleTester2 should activate and the algorithm will return to
# the corner stress_yy=0.5, stress_zz=1, but this will require a negative plasticity
# multiplier for SimpleTester2, so it will be deactivated, and the algorithm will return to
# stress_yy = 0, stress_zz = 1
# internal0 should be 1.0, and others zero

[Mesh]
  type = GeneratedMesh
  dim = 3
  nx = 1
  ny = 1
  nz = 1
  xmin = -0.5
  xmax = 0.5
  ymin = -0.5
  ymax = 0.5
  zmin = -0.5
  zmax = 0.5
[]


[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./disp_z]
  [../]
[]

[Kernels]
  [SolidMechanics]
    displacements = 'disp_x disp_y disp_z'
  [../]
[]


[BCs]
  [./x]
    type = FunctionDirichletBC
    variable = disp_x
    boundary = 'front back'
    function = '0E-6*x'
  [../]
  [./y]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = 'front back'
    function = '0E-6*y'
  [../]
  [./z]
    type = FunctionDirichletBC
    variable = disp_z
    boundary = 'front back'
    function = '2.0E-6*z'
  [../]
[]

[AuxVariables]
  [./stress_xx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_zz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./f0]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./f1]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./f2]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./int0]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./int1]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./int2]
    order = CONSTANT
    family = MONOMIAL
  [../]
[]

[AuxKernels]
  [./stress_xx]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xx
    index_i = 0
    index_j = 0
  [../]
  [./stress_xy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xy
    index_i = 0
    index_j = 1
  [../]
  [./stress_xz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xz
    index_i = 0
    index_j = 2
  [../]
  [./stress_yy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yy
    index_i = 1
    index_j = 1
  [../]
  [./stress_yz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yz
    index_i = 1
    index_j = 2
  [../]
  [./stress_zz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_zz
    index_i = 2
    index_j = 2
  [../]
  [./f0]
    type = MaterialStdVectorAux
    property = plastic_yield_function
    index = 0
    variable = f0
  [../]
  [./f1]
    type = MaterialStdVectorAux
    property = plastic_yield_function
    index = 1
    variable = f1
  [../]
  [./f2]
    type = MaterialStdVectorAux
    property = plastic_yield_function
    index = 2
    variable = f2
  [../]
  [./int0]
    type = MaterialStdVectorAux
    property = plastic_internal_parameter
    factor = 1E6
    index = 0
    variable = int0
  [../]
  [./int1]
    type = MaterialStdVectorAux
    property = plastic_internal_parameter
    factor = 1E6
    index = 1
    variable = int1
  [../]
  [./int2]
    type = MaterialStdVectorAux
    property = plastic_internal_parameter
    factor = 1E6
    index = 2
    variable = int2
  [../]
[]

[Postprocessors]
  [./s_xx]
    type = PointValue
    point = '0 0 0'
    variable = stress_xx
  [../]
  [./s_xy]
    type = PointValue
    point = '0 0 0'
    variable = stress_xy
  [../]
  [./s_xz]
    type = PointValue
    point = '0 0 0'
    variable = stress_xz
  [../]
  [./s_yy]
    type = PointValue
    point = '0 0 0'
    variable = stress_yy
  [../]
  [./s_yz]
    type = PointValue
    point = '0 0 0'
    variable = stress_yz
  [../]
  [./s_zz]
    type = PointValue
    point = '0 0 0'
    variable = stress_zz
  [../]
  [./f0]
    type = PointValue
    point = '0 0 0'
    variable = f0
  [../]
  [./f1]
    type = PointValue
    point = '0 0 0'
    variable = f1
  [../]
  [./f2]
    type = PointValue
    point = '0 0 0'
    variable = f2
  [../]
  [./int0]
    type = PointValue
    point = '0 0 0'
    variable = int0
  [../]
  [./int1]
    type = PointValue
    point = '0 0 0'
    variable = int1
  [../]
  [./int2]
    type = PointValue
    point = '0 0 0'
    variable = int2
  [../]
[]

[UserObjects]
  [./simple0]
    type = SolidMechanicsPlasticSimpleTester
    a = 0
    b = 1
    strength = 1
    yield_function_tolerance = 1.0E-9
    internal_constraint_tolerance = 1.0E-9
  [../]
  [./simple1]
    type = SolidMechanicsPlasticSimpleTester
    a = 1
    b = 0
    strength = 1
    yield_function_tolerance = 1.0E-9
    internal_constraint_tolerance = 1.0E-9
  [../]
  [./simple2]
    type = SolidMechanicsPlasticSimpleTester
    a = 1
    b = 1
    strength = 1.5
    yield_function_tolerance = 1.0E-9
    internal_constraint_tolerance = 1.0E-9
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeElasticityTensor
    block = 0
    fill_method = symmetric_isotropic
    C_ijkl = '0 0.5E6'
  [../]
  [./strain]
    type = ComputeFiniteStrain
    block = 0
    displacements = 'disp_x disp_y disp_z'
  [../]
  [./multi]
    type = ComputeMultiPlasticityStress
    block = 0
    ep_plastic_tolerance = 1E-9
    plastic_models = 'simple0 simple1 simple2'
    max_NR_iterations = 2
    min_stepsize = 1
    debug_fspb = crash
    debug_jac_at_stress = '10 0 0 0 10 0 0 0 10'
    debug_jac_at_pm = '1 1'
    debug_jac_at_intnl = '1 1'
    debug_stress_change = 1E-5
    debug_pm_change = '1E-6 1E-6'
    debug_intnl_change = '1E-6 1E-6'
  [../]
[]


[Executioner]
  end_time = 1
  dt = 1
  type = Transient
[]


[Outputs]
  file_base = three_surface02
  exodus = false
  [./csv]
    type = CSV
    [../]
[]

(modules/contact/test/tests/verification/patch_tests/brick_2/brick2_template1.i)

[GlobalParams]
  volumetric_locking_correction = true
  displacements = 'disp_x disp_y disp_z'
[]

[Mesh]
  file = brick2_mesh.e
[]

[Problem]
  type = ReferenceResidualProblem
  extra_tag_vectors = 'ref'
  reference_vector = 'ref'
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./disp_z]
  [../]
[]

[AuxVariables]
  [./stress_xx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_zz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./penetration]
  [../]
  [./saved_x]
  [../]
  [./saved_y]
  [../]
  [./saved_z]
  [../]
  [./diag_saved_x]
  [../]
  [./diag_saved_y]
  [../]
  [./diag_saved_z]
  [../]
  [./inc_slip_x]
  [../]
  [./inc_slip_y]
  [../]
  [./inc_slip_z]
  [../]
  [./accum_slip_x]
  [../]
  [./accum_slip_y]
  [../]
  [./accum_slip_z]
  [../]
[]

[Kernels]
  [./TensorMechanics]
    use_displaced_mesh = true
    save_in = 'saved_x saved_y saved_z'
    extra_vector_tags = 'ref'
  [../]
[]

[AuxKernels]
  [./stress_xx]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xx
    index_i = 0
    index_j = 0
    execute_on = timestep_end
  [../]
  [./stress_yy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yy
    index_i = 1
    index_j = 1
    execute_on = timestep_end
  [../]
  [./stress_xy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xy
    index_i = 0
    index_j = 1
    execute_on = timestep_end
  [../]
  [./stress_zz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_zz
    index_i = 2
    index_j = 2
    execute_on = timestep_end
  [../]
  [./inc_slip_x]
    type = PenetrationAux
    variable = inc_slip_x
    execute_on = timestep_begin
    boundary = 4
    paired_boundary = 3
  [../]
  [./inc_slip_y]
    type = PenetrationAux
    variable = inc_slip_y
    execute_on = timestep_begin
    boundary = 4
    paired_boundary = 3
  [../]
  [./accum_slip_x]
    type = PenetrationAux
    variable = accum_slip_x
    execute_on = timestep_end
    boundary = 4
    paired_boundary = 3
  [../]
  [./accum_slip_y]
    type = PenetrationAux
    variable = accum_slip_y
    execute_on = timestep_end
    boundary = 4
    paired_boundary = 3
  [../]
  [./penetration]
    type = PenetrationAux
    variable = penetration
    boundary = 4
    paired_boundary = 3
  [../]
[]

[Postprocessors]
  [./bot_react_x]
    type = NodalSum
    variable = saved_x
    boundary = 1
  [../]
  [./bot_react_y]
    type = NodalSum
    variable = saved_y
    boundary = 1
  [../]
  [./top_react_x]
    type = NodalSum
    variable = saved_x
    boundary = 5
  [../]
  [./top_react_y]
    type = NodalSum
    variable = saved_y
    boundary = 5
  [../]
  [./ref_resid_x]
    type = NodalL2Norm
    execute_on = timestep_end
    variable = saved_x
  [../]
  [./ref_resid_y]
    type = NodalL2Norm
    execute_on = timestep_end
    variable = saved_y
  [../]
  [./sigma_yy]
    type = ElementAverageValue
    variable = stress_yy
  [../]
  [./sigma_zz]
    type = ElementAverageValue
    variable = stress_zz
  [../]
  [./disp_x7]
    type = NodalVariableValue
    nodeid = 6
    variable = disp_x
  [../]
  [./disp_x26]
    type = NodalVariableValue
    nodeid = 25
    variable = disp_x
  [../]
  [./disp_y7]
    type = NodalVariableValue
    nodeid = 6
    variable = disp_y
  [../]
  [./disp_y26]
    type = NodalVariableValue
    nodeid = 25
    variable = disp_y
  [../]
  [./_dt]
    type = TimestepSize
  [../]
  [./num_lin_it]
    type = NumLinearIterations
  [../]
  [./num_nonlin_it]
    type = NumNonlinearIterations
  [../]
[]

[BCs]
  [./bot_y]
    type = DirichletBC
    variable = disp_y
    boundary = 1
    value = 0.0
  [../]
  [./side_x]
    type = DirichletBC
    variable = disp_x
    boundary = 2
    value = 0.0
  [../]
  [./back_z]
    type = DirichletBC
    variable = disp_z
    boundary = 6
    value = 0.0
  [../]
  [./top_press]
    type = Pressure
    variable = disp_y
    boundary = 5
    factor = 109.89
  [../]
[]

[Materials]
  [./bot_elas_tens]
    type = ComputeIsotropicElasticityTensor
    block = '1'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./bot_strain]
    type = ComputeFiniteStrain
    block = '1'
  [../]
  [./bot_stress]
    type = ComputeFiniteStrainElasticStress
    block = '1'
  [../]
  [./top_elas_tens]
    type = ComputeIsotropicElasticityTensor
    block = '2'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./top_strain]
    type = ComputeFiniteStrain
    block = '2'
  [../]
  [./top_stress]
    type = ComputeFiniteStrainElasticStress
    block = '2'
  [../]
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'

  petsc_options_iname = '-pc_type -pc_factor_mat_solver_type'
  petsc_options_value = 'lu     superlu_dist'

  line_search = 'none'

  nl_abs_tol = 1e-9
  nl_rel_tol = 1e-8
  l_max_its = 50
  nl_max_its = 100
  dt = 1.0
  end_time = 1.0
  num_steps = 10
  dtmin = 1.0
  l_tol = 1e-5

[]

[VectorPostprocessors]
  [./x_disp]
    type = NodalValueSampler
    variable = disp_x
    boundary = '1 3 4 5'
    sort_by = id
  [../]
  [./y_disp]
    type = NodalValueSampler
    variable = disp_y
    boundary = '1 3 4 5'
    sort_by = id
  [../]
  [./cont_press]
    type = NodalValueSampler
    variable = contact_pressure
    boundary = '3'
    sort_by = id
  [../]
[]

[Outputs]
  print_linear_residuals = true
  perf_graph = true
  [./exodus]
    type = Exodus
    elemental_as_nodal = true
  [../]
  [./console]
    type = Console
    max_rows = 5
  [../]
  [./chkfile]
    type = CSV
    show = 'bot_react_x bot_react_y disp_x7 disp_y7 disp_x26 disp_y26 stress_yy stress_zz top_react_x top_react_y x_disp y_disp cont_press'
    execute_vector_postprocessors_on = timestep_end
  [../]
  [./outfile]
    type = CSV
    delimiter = ' '
    execute_vector_postprocessors_on = none
  [../]
[]

[Contact]
  [./leftright]
    secondary = 3
    primary = 4
    normalize_penalty = true
    tangential_tolerance = 1e-3
    penalty = 1e+9
  [../]
[]

(modules/contact/test/tests/verification/hertz_cyl/half_symm_q8/hertz_cyl_half_1deg_template3.i)

[GlobalParams]
  order = SECOND
  volumetric_locking_correction = false
  displacements = 'disp_x disp_y'
[]

[Mesh]
  file = hertz_cyl_half_1deg.e
[]

[Problem]
  type = ReferenceResidualProblem
  extra_tag_vectors = 'ref'
  reference_vector = 'ref'
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
[]

[AuxVariables]
  [./stress_xx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./saved_x]
  [../]
  [./saved_y]
  [../]
  [./diag_saved_x]
  [../]
  [./diag_saved_y]
  [../]
  [./inc_slip_x]
  [../]
  [./inc_slip_y]
  [../]
  [./accum_slip_x]
  [../]
  [./accum_slip_y]
  [../]
  [./tang_force_x]
  [../]
  [./tang_force_y]
  [../]
[]

[Functions]
  [./disp_ramp_vert]
    type = PiecewiseLinear
    x = '0. 1. 11.'
    y = '0. -0.0020 -0.0020'
  [../]
  [./disp_ramp_horz]
    type = PiecewiseLinear
    x = '0. 1. 11.'
    y = '0. 0.0 0.0014'
  [../]
[]

[Kernels]
  [./TensorMechanics]
    use_displaced_mesh = true
    save_in = 'saved_x saved_y'
    extra_vector_tags = 'ref'
  [../]
[]

[AuxKernels]
  [./stress_xx]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xx
    index_i = 0
    index_j = 0
    execute_on = timestep_end
  [../]
  [./stress_yy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yy
    index_i = 1
    index_j = 1
    execute_on = timestep_end
  [../]
  [./stress_xy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xy
    index_i = 0
    index_j = 1
    execute_on = timestep_end
  [../]
  [./inc_slip_x]
    type = PenetrationAux
    variable = inc_slip_x
    execute_on = timestep_end
    boundary = 3
    paired_boundary = 2
  [../]
  [./inc_slip_y]
    type = PenetrationAux
    variable = inc_slip_y
    execute_on = timestep_end
    boundary = 3
    paired_boundary = 2
  [../]
  [./accum_slip_x]
    type = PenetrationAux
    variable = accum_slip_x
    execute_on = timestep_end
    boundary = 3
    paired_boundary = 2
  [../]
  [./accum_slip_y]
    type = PenetrationAux
    variable = accum_slip_y
    execute_on = timestep_end
    boundary = 3
    paired_boundary = 2
  [../]
  [./tang_force_x]
    type = PenetrationAux
    variable = tang_force_x
    quantity = tangential_force_x
    boundary = 3
    paired_boundary = 2
  [../]
  [./tang_force_y]
    type = PenetrationAux
    variable = tang_force_y
    quantity = tangential_force_y
    boundary = 3
    paired_boundary = 2
  [../]
  [./penetration]
    type = PenetrationAux
    variable = penetration
    boundary = 3
    paired_boundary = 2
  [../]
[]

[Postprocessors]
  [./bot_react_x]
    type = NodalSum
    variable = saved_x
    boundary = 1
  [../]
  [./bot_react_y]
    type = NodalSum
    variable = saved_y
    boundary = 1
  [../]
  [./top_react_x]
    type = NodalSum
    variable = saved_x
    boundary = 4
  [../]
  [./top_react_y]
    type = NodalSum
    variable = saved_y
    boundary = 4
  [../]
  [./disp_x639]
    type = NodalVariableValue
    nodeid = 638
    variable = disp_x
  [../]
  [./disp_y639]
    type = NodalVariableValue
    nodeid = 638
    variable = disp_y
  [../]
  [./_dt]
    type = TimestepSize
  [../]
  [./num_lin_it]
    type = NumLinearIterations
  [../]
  [./num_nonlin_it]
    type = NumNonlinearIterations
  [../]
[]

[BCs]
  [./side_x]
    type = DirichletBC
    variable = disp_y
    boundary = '1 2'
    value = 0.0
  [../]
  [./bot_y]
    type = DirichletBC
    variable = disp_x
    boundary = '1 2'
    value = 0.0
  [../]
  [./top_y_disp]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = 4
    function = disp_ramp_vert
  [../]
  [./top_x_disp]
    type = FunctionDirichletBC
    variable = disp_x
    boundary = 4
    function = disp_ramp_horz
  [../]
[]

[Materials]
  [./stuff1_elas_tens]
    type = ComputeIsotropicElasticityTensor
    block = '1'
    youngs_modulus = 1e10
    poissons_ratio = 0.0
  [../]
  [./stuff1_strain]
    type = ComputeFiniteStrain
    block = '1'
  [../]
  [./stuff1_stress]
    type = ComputeFiniteStrainElasticStress
    block = '1'
  [../]
  [./stuff2_elas_tens]
    type = ComputeIsotropicElasticityTensor
    block = '2'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./stuff2_strain]
    type = ComputeFiniteStrain
    block = '2'
  [../]
  [./stuff2_stress]
    type = ComputeFiniteStrainElasticStress
    block = '2'
  [../]
  [./stuff3_elas_tens]
    type = ComputeIsotropicElasticityTensor
    block = '3'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./stuff3_strain]
    type = ComputeFiniteStrain
    block = '3'
  [../]
  [./stuff3_stress]
    type = ComputeFiniteStrainElasticStress
    block = '3'
  [../]
  [./stuff4_elas_tens]
    type = ComputeIsotropicElasticityTensor
    block = '4'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./stuff4_strain]
    type = ComputeFiniteStrain
    block = '4'
  [../]
  [./stuff4_stress]
    type = ComputeFiniteStrainElasticStress
    block = '4'
  [../]
  [./stuff5_elas_tens]
    type = ComputeIsotropicElasticityTensor
    block = '5'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./stuff5_strain]
    type = ComputeFiniteStrain
    block = '5'
  [../]
  [./stuff5_stress]
    type = ComputeFiniteStrainElasticStress
    block = '5'
  [../]
  [./stuff6_elas_tens]
    type = ComputeIsotropicElasticityTensor
    block = '6'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./stuff6_strain]
    type = ComputeFiniteStrain
    block = '6'
  [../]
  [./stuff6_stress]
    type = ComputeFiniteStrainElasticStress
    block = '6'
  [../]
  [./stuff7_elas_tens]
    type = ComputeIsotropicElasticityTensor
    block = '7'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./stuff7_strain]
    type = ComputeFiniteStrain
    block = '7'
  [../]
  [./stuff7_stress]
    type = ComputeFiniteStrainElasticStress
    block = '7'
  [../]
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'

  petsc_options_iname = '-pc_type -pc_factor_mat_solver_type'
  petsc_options_value = 'lu     superlu_dist'

  line_search = 'none'

  nl_abs_tol = 1e-7
  nl_rel_tol = 1e-6
  l_max_its = 100
  nl_max_its = 200

  start_time = 0.0
  end_time = 2.0
  l_tol = 5e-4
  dt = 0.1
  dtmin = 0.1
[]

[Preconditioning]
  [./SMP]
    type = SMP
    full = true
  [../]
[]

[VectorPostprocessors]
  [./x_disp]
    type = NodalValueSampler
    variable = disp_x
    boundary = '3 4'
    sort_by = id
  [../]
  [./y_disp]
    type = NodalValueSampler
    variable = disp_y
    boundary = '3 4'
    sort_by = id
  [../]
  [./cont_press]
    type = NodalValueSampler
    variable = contact_pressure
    boundary = '3'
    sort_by = id
  [../]
[]

[Outputs]
  print_linear_residuals = true
  perf_graph = true
  [./exodus]
    type = Exodus
    elemental_as_nodal = true
  [../]
  [./console]
    type = Console
    max_rows = 5
  [../]
  [./chkfile]
    type = CSV
    show = 'x_disp y_disp cont_press'
    start_time = 0.9
    execute_vector_postprocessors_on = timestep_end
  [../]
  [./chkfile2]
    type = CSV
    show = 'bot_react_x bot_react_y disp_x639 disp_y639 top_react_x top_react_y'
    start_time = 0.9
    execute_vector_postprocessors_on = timestep_end
  [../]
  [./outfile]
    type = CSV
    delimiter = ' '
    execute_vector_postprocessors_on = none
  [../]
[]

[Contact]
  [./interface]
    primary = 2
    secondary = 3
    model = coulomb
    friction_coefficient = 0.0
    formulation = penalty
    normalize_penalty = true
    tangential_tolerance = 1e-3
    penalty = 1e+9
  [../]
[]

[Dampers]
  [./contact_slip]
    type = ContactSlipDamper
    primary = '2'
    secondary = '3'
  [../]
[]

(modules/contact/test/tests/mortar_dynamics/block-dynamics.i)

starting_point = 2e-1
offset = -0.19

[GlobalParams]
  displacements = 'disp_x disp_y'
[]

[Mesh]
  file = long-bottom-block-1elem-blocks.e
[]

[Variables]
  [disp_x]
    block = '1 2'
  []
  [disp_y]
    block = '1 2'
  []
  [normal_lm]
    block = 3
    use_dual = true
  []
[]

[ICs]
  [disp_y]
    block = 2
    variable = disp_y
    value = '${fparse starting_point + offset}'
    type = ConstantIC
  []
[]

[Kernels]
  [DynamicTensorMechanics]
    displacements = 'disp_x disp_y'
    generate_output = 'stress_xx stress_yy'
    strain = FINITE
    block = '1 2'
    zeta = 1.0
    alpha = 0.0
  []
  [inertia_x]
    type = InertialForce
    variable = disp_x
    velocity = vel_x
    acceleration = accel_x
    beta = 0.25
    gamma = 0.5
    alpha = 0
    eta = 0.0
    block = '1 2'
  []
  [inertia_y]
    type = InertialForce
    variable = disp_y
    velocity = vel_y
    acceleration = accel_y
    beta = 0.25
    gamma = 0.5
    alpha = 0
    eta = 0.0
    block = '1 2'
  []
[]

[Materials]
  [elasticity_2]
    type = ComputeIsotropicElasticityTensor
    block = '2'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  []
  [elasticity_1]
    type = ComputeIsotropicElasticityTensor
    block = '1'
    youngs_modulus = 1e8
    poissons_ratio = 0.3
  []
  [stress]
    type = ComputeFiniteStrainElasticStress
    block = '1 2'
  []
  [strain]
    type = ComputeFiniteStrain
    block = '1 2'
  []
  [density]
    type = GenericConstantMaterial
    block = '1 2'
    prop_names = 'density'
    prop_values = '7750'
  []
[]

[AuxVariables]
  [vel_x]
    block = '1 2'
  []
  [accel_x]
    block = '1 2'
  []
  [vel_y]
    block = '1 2'
  []
  [accel_y]
    block = '1 2'
  []
  [vel_z]
    block = '1 2'
  []
  [accel_z]
    block = '1 2'
  []
[]

[AuxKernels]
  [accel_x]
    type = NewmarkAccelAux
    variable = accel_x
    displacement = disp_x
    velocity = vel_x
    beta = 0.25
    execute_on = 'LINEAR timestep_end'
  []
  [vel_x]
    type = NewmarkVelAux
    variable = vel_x
    acceleration = accel_x
    gamma = 0.5
    execute_on = 'LINEAR timestep_end'
  []
  [accel_y]
    type = NewmarkAccelAux
    variable = accel_y
    displacement = disp_y
    velocity = vel_y
    beta = 0.25
    execute_on = 'LINEAR timestep_end'
  []
  [vel_y]
    type = NewmarkVelAux
    variable = vel_y
    acceleration = accel_y
    gamma = 0.5
    execute_on = 'LINEAR timestep_end'
  []
[]

# User object provides the contact force (e.g. LM)
# for the application of the generalized force
[UserObjects]
  [weighted_gap_uo]
    type = LMWeightedGapUserObject
    primary_boundary = 20
    secondary_boundary = 10
    primary_subdomain = 4
    secondary_subdomain = 3
    lm_variable = normal_lm
    disp_x = disp_x
    disp_y = disp_y
  []
[]

[Constraints]
  [weighted_gap_lm]
    type = ComputeDynamicWeightedGapLMMechanicalContact
    primary_boundary = 20
    secondary_boundary = 10
    primary_subdomain = 4
    secondary_subdomain = 3
    variable = normal_lm
    disp_x = disp_x
    disp_y = disp_y
    use_displaced_mesh = true
    c = 1e4
    capture_tolerance = 1.0e-5
    newmark_beta = 0.25
    newmark_gamma = 0.5
  []
  [normal_x]
    type = NormalMortarMechanicalContact
    primary_boundary = 20
    secondary_boundary = 10
    primary_subdomain = 4
    secondary_subdomain = 3
    variable = normal_lm
    secondary_variable = disp_x
    component = x
    use_displaced_mesh = true
    compute_lm_residuals = false
    weighted_gap_uo = weighted_gap_uo
  []
  [normal_y]
    type = NormalMortarMechanicalContact
    primary_boundary = 20
    secondary_boundary = 10
    primary_subdomain = 4
    secondary_subdomain = 3
    variable = normal_lm
    secondary_variable = disp_y
    component = y
    use_displaced_mesh = true
    compute_lm_residuals = false
    weighted_gap_uo = weighted_gap_uo
  []
[]

[BCs]
  [botx]
    type = DirichletBC
    variable = disp_x
    boundary = 40
    value = 0.0
  []
  [boty]
    type = DirichletBC
    variable = disp_y
    boundary = 40
    value = 0.0
  []
  [topy]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = 30
    function = '${starting_point} * cos(2 * pi / 4 * t) + ${offset}'
  []
  [leftx]
    type = FunctionDirichletBC
    variable = disp_x
    boundary = 50
    function = '1e-2 * t'
  []
[]

[Executioner]
  type = Transient
  end_time = 75
  dt = 0.05
  dtmin = .05
  solve_type = 'PJFNK'
  petsc_options = '-snes_converged_reason -ksp_converged_reason -pc_svd_monitor '
                  '-snes_linesearch_monitor -snes_ksp_ew'
  petsc_options_iname = '-pc_type -pc_factor_shift_type -pc_factor_shift_amount -mat_mffd_err '
  petsc_options_value = 'lu       NONZERO               1e-15                   1e-5'
  nl_max_its = 20
  line_search = 'none'
  snesmf_reuse_base = false

  [TimeIntegrator]
    type = NewmarkBeta
    beta = 0.25
    gamma = 0.5
  []
[]

[Debug]
  show_var_residual_norms = true
[]

[Outputs]
  exodus = true
  checkpoint = true
[]

[Preconditioning]
  [smp]
    type = SMP
    full = true
  []
[]

[Postprocessors]
  active = 'num_nl cumulative contact'
  [num_nl]
    type = NumNonlinearIterations
  []
  [cumulative]
    type = CumulativeValuePostprocessor
    postprocessor = num_nl
  []
  [contact]
    type = ContactDOFSetSize
    variable = normal_lm
    subdomain = '3'
    execute_on = 'nonlinear timestep_end'
  []
[]

(modules/combined/test/tests/cavity_pressure/additional_volume.i)

#
# Cavity Pressure Test
#
# This test is designed to compute an internal pressure based on
# p = n * R * / (V_cavity / T_cavity + V_add / T_add)
# where
#  p is the pressure
#  n is the amount of material in the volume (moles)
#  R is the universal gas constant
#  T_cavity is the temperature in the cavity
#  T_add is the temperature of the additional volume
#
# The mesh is composed of one block (1) with an interior cavity of volume 8.
#   Block 2 sits in the cavity and has a volume of 1.  Thus, the total
#   initial volume is 7. An additional volume of 2 is added.
#
# The test adjusts n, T, and V in the following way:
#   n => n0 + alpha * t
#   T => T0 + beta * t
#   V => V_cavity0 + gamma * t + V_add
# with
#   alpha = n0
#   beta = T0 / 2
#   gamma = -(0.003322259...) * V0
#   T0 = 240.54443866068704
#   V_cavity0 = 7
#   V_add = 2
#   T_add = 100
#   n0 = f(p0)
#   p0 = 100
#   R = 8.314472 J * K^(-1) * mol^(-1)
#
#  An additional volume of 2 with a temperature of 100.0 is included.
#
# So, n0 = p0 * (V_cavity / T_cavity + V_add / T_add) / R
#        = 100 * (7 / 240.544439 + 2 / 100) / 8.314472
#        = 0.59054
#
# The parameters combined at t = 1 gives p = 249.647.
#
# This test sets the initial temperature to 500, but the CavityPressure
#   is told that that initial temperature is T0.  Thus, the final solution
#   is unchanged.

[GlobalParams]
  displacements = 'disp_x disp_y disp_z'
[]

[Mesh]
  file = 3d.e
[]

[GlobalParams]
  volumetric_locking_correction = true
[]

[Functions]
  [displ_positive]
    type = PiecewiseLinear
    x = '0 1'
    y = '0 0.0029069767441859684'
  []
  [displ_negative]
    type = PiecewiseLinear
    x = '0 1'
    y = '0 -0.0029069767441859684'
  []
  [temp1]
    type = PiecewiseLinear
    x = '0 1'
    y = '1 1.5'
    scale_factor = 240.54443866068704
  []
  [material_input_function]
    type = PiecewiseLinear
    x = '0    1'
    y = '0 0.59054'
  []
  [additional_volume]
    type = ConstantFunction
    value = 2
  []
  [temperature_of_additional_volume]
    type = ConstantFunction
    value = 100
  []
[]

[Variables]
  [disp_x]
  []
  [disp_y]
  []
  [disp_z]
  []
  [temp]
    initial_condition = 500
  []
  [material_input]
  []
[]

[AuxVariables]
  [pressure_residual_x]
  []
  [pressure_residual_y]
  []
  [pressure_residual_z]
  []
  [stress_xx]
    order = CONSTANT
    family = MONOMIAL
  []
  [stress_yy]
    order = CONSTANT
    family = MONOMIAL
  []
  [stress_zz]
    order = CONSTANT
    family = MONOMIAL
  []
  [stress_xy]
    order = CONSTANT
    family = MONOMIAL
  []
  [stress_yz]
    order = CONSTANT
    family = MONOMIAL
  []
  [stress_zx]
    order = CONSTANT
    family = MONOMIAL
  []
[]

[Kernels]
  [TensorMechanics]
    use_displaced_mesh = true
  []
  [heat]
    type = Diffusion
    variable = temp
    use_displaced_mesh = true
  []
  [material_input_dummy]
    type = Diffusion
    variable = material_input
    use_displaced_mesh = true
  []
[]

[AuxKernels]
  [stress_xx]
    type = RankTwoAux
    rank_two_tensor = stress
    index_i = 0
    index_j = 0
    variable = stress_xx
  []
  [stress_yy]
    type = RankTwoAux
    rank_two_tensor = stress
    index_i = 1
    index_j = 1
    variable = stress_yy
  []
  [stress_zz]
    type = RankTwoAux
    rank_two_tensor = stress
    index_i = 2
    index_j = 2
    variable = stress_zz
  []
  [stress_xy]
    type = RankTwoAux
    rank_two_tensor = stress
    index_i = 0
    index_j = 1
    variable = stress_xy
  []
  [stress_yz]
    type = RankTwoAux
    rank_two_tensor = stress
    index_i = 1
    index_j = 2
    variable = stress_yz
  []
  [stress_zx]
    type = RankTwoAux
    rank_two_tensor = stress
    index_i = 2
    index_j = 0
    variable = stress_zx
  []
[]

[BCs]
  [no_x_exterior]
    type = DirichletBC
    variable = disp_x
    boundary = '7 8'
    value = 0.0
  []
  [no_y_exterior]
    type = DirichletBC
    variable = disp_y
    boundary = '9 10'
    value = 0.0
  []
  [no_z_exterior]
    type = DirichletBC
    variable = disp_z
    boundary = '11 12'
    value = 0.0
  []
  [prescribed_left]
    type = FunctionDirichletBC
    variable = disp_x
    boundary = 13
    function = displ_positive
  []
  [prescribed_right]
    type = FunctionDirichletBC
    variable = disp_x
    boundary = 14
    function = displ_negative
  []
  [no_y]
    type = DirichletBC
    variable = disp_y
    boundary = '15 16'
    value = 0.0
  []
  [no_z]
    type = DirichletBC
    variable = disp_z
    boundary = '17 18'
    value = 0.0
  []
  [no_x_interior]
    type = DirichletBC
    variable = disp_x
    boundary = '1 2'
    value = 0.0
  []
  [no_y_interior]
    type = DirichletBC
    variable = disp_y
    boundary = '3 4'
    value = 0.0
  []
  [no_z_interior]
    type = DirichletBC
    variable = disp_z
    boundary = '5 6'
    value = 0.0
  []
  [temperatureInterior]
    type = FunctionDirichletBC
    boundary = 100
    function = temp1
    variable = temp
  []
  [MaterialInput]
    type = FunctionDirichletBC
    boundary = '100 13 14 15 16'
    function = material_input_function
    variable = material_input
  []
  [CavityPressure]
    [1]
      boundary = 100
      initial_pressure = 100
      material_input = materialInput
      R = 8.314472
      temperature = aveTempInterior
      initial_temperature = 240.54443866068704
      volume = internalVolume
      startup_time = 0.5
      output = ppress
      save_in = 'pressure_residual_x pressure_residual_y pressure_residual_z'
      additional_volumes = volume1
      temperature_of_additional_volumes = temperature1
    []
  []
[]

[Materials]
  [elast_tensor1]
    type = ComputeElasticityTensor
    C_ijkl = '0 5'
    fill_method = symmetric_isotropic
    block = 1
  []
  [strain1]
    type = ComputeFiniteStrain
    block = 1
  []
  [stress1]
    type = ComputeFiniteStrainElasticStress
    block = 1
  []
  [elast_tensor2]
    type = ComputeElasticityTensor
    C_ijkl = '0 5'
    fill_method = symmetric_isotropic
    block = 2
  []
  [strain2]
    type = ComputeFiniteStrain
    block = 2
  []
  [stress2]
    type = ComputeFiniteStrainElasticStress
    block = 2
  []
[]

[Executioner]
  type = Transient

  petsc_options_iname = '-pc_type -sub_pc_type'
  petsc_options_value = 'asm       lu'

  nl_rel_tol = 1e-12
  l_tol = 1e-12

  l_max_its = 20

  dt = 0.5
  end_time = 1.0

  snesmf_reuse_base = false
  use_pre_SMO_residual = true
[]

[Postprocessors]
  [internalVolume]
    type = InternalVolume
    boundary = 100
    execute_on = 'initial linear'
  []
  [aveTempInterior]
    type = SideAverageValue
    boundary = 100
    variable = temp
    execute_on = 'initial linear'
  []
  [materialInput]
    type = SideAverageValue
    boundary = '7 8 9 10 11 12'
    variable = material_input
    execute_on = linear
  []
  [volume1]
    type = FunctionValuePostprocessor
    function = additional_volume
    execute_on = 'initial linear'
  []
  [temperature1]
    type = FunctionValuePostprocessor
    function = temperature_of_additional_volume
    execute_on = 'initial linear'
  []
[]

[Outputs]
  exodus = true
[]

(modules/solid_mechanics/test/tests/multi/two_surface02.i)

# Plasticit models:
# SimpleTester with a = 0 and b = 1 and strength = 1
# SimpleTester with a = 1 and b = 1 and strength = 2
#
# Lame lambda = 0 (Poisson=0).  Lame mu = 0.5E6
#
# A single element is stretched by 1.5E-6m in the y z directions.
# trial stress_zz = 1.5 and stress_yy = 1.5
#
# Then both  SimpleTesters should activate, and the final stress
# should have have stress_zz = 1 = stress_yy (ie, the "corner" point)
# the plastic strain for SimpleTester1 should be zero

[Mesh]
  type = GeneratedMesh
  dim = 3
  nx = 1
  ny = 1
  nz = 1
  xmin = -0.5
  xmax = 0.5
  ymin = -0.5
  ymax = 0.5
  zmin = -0.5
  zmax = 0.5
[]


[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./disp_z]
  [../]
[]

[Kernels]
  [SolidMechanics]
    displacements = 'disp_x disp_y disp_z'
  [../]
[]


[BCs]
  [./x]
    type = FunctionDirichletBC
    variable = disp_x
    boundary = 'front back'
    function = '0E-6*x'
  [../]
  [./y]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = 'front back'
    function = '1.5E-6*y'
  [../]
  [./z]
    type = FunctionDirichletBC
    variable = disp_z
    boundary = 'front back'
    function = '1.5E-6*z'
  [../]
[]

[AuxVariables]
  [./stress_xx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_zz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./f0]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./f1]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./int0]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./int1]
    order = CONSTANT
    family = MONOMIAL
  [../]
[]

[AuxKernels]
  [./stress_xx]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xx
    index_i = 0
    index_j = 0
  [../]
  [./stress_xy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xy
    index_i = 0
    index_j = 1
  [../]
  [./stress_xz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xz
    index_i = 0
    index_j = 2
  [../]
  [./stress_yy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yy
    index_i = 1
    index_j = 1
  [../]
  [./stress_yz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yz
    index_i = 1
    index_j = 2
  [../]
  [./stress_zz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_zz
    index_i = 2
    index_j = 2
  [../]
  [./f0]
    type = MaterialStdVectorAux
    property = plastic_yield_function
    index = 0
    variable = f0
  [../]
  [./f1]
    type = MaterialStdVectorAux
    property = plastic_yield_function
    index = 1
    variable = f1
  [../]
  [./int0]
    type = MaterialStdVectorAux
    property = plastic_internal_parameter
    factor = 1E6
    index = 0
    variable = int0
  [../]
  [./int1]
    type = MaterialStdVectorAux
    property = plastic_internal_parameter
    factor = 1E6
    index = 1
    variable = int1
  [../]
[]

[Postprocessors]
  [./s_xx]
    type = PointValue
    point = '0 0 0'
    variable = stress_xx
  [../]
  [./s_xy]
    type = PointValue
    point = '0 0 0'
    variable = stress_xy
  [../]
  [./s_xz]
    type = PointValue
    point = '0 0 0'
    variable = stress_xz
  [../]
  [./s_yy]
    type = PointValue
    point = '0 0 0'
    variable = stress_yy
  [../]
  [./s_yz]
    type = PointValue
    point = '0 0 0'
    variable = stress_yz
  [../]
  [./s_zz]
    type = PointValue
    point = '0 0 0'
    variable = stress_zz
  [../]
  [./f0]
    type = PointValue
    point = '0 0 0'
    variable = f0
  [../]
  [./f1]
    type = PointValue
    point = '0 0 0'
    variable = f1
  [../]
  [./int0]
    type = PointValue
    point = '0 0 0'
    variable = int0
  [../]
  [./int1]
    type = PointValue
    point = '0 0 0'
    variable = int1
  [../]
[]

[UserObjects]
  [./simple1]
    type = SolidMechanicsPlasticSimpleTester
    a = 0
    b = 1
    strength = 1
    yield_function_tolerance = 1.0E-9
    internal_constraint_tolerance = 1.0E-9
  [../]
  [./simple2]
    type = SolidMechanicsPlasticSimpleTester
    a = 1
    b = 1
    strength = 2
    yield_function_tolerance = 1.0E-9
    internal_constraint_tolerance = 1.0E-9
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeElasticityTensor
    block = 0
    fill_method = symmetric_isotropic
    C_ijkl = '0 0.5E6'
  [../]
  [./strain]
    type = ComputeFiniteStrain
    block = 0
    displacements = 'disp_x disp_y disp_z'
  [../]
  [./multi]
    type = ComputeMultiPlasticityStress
    block = 0
    ep_plastic_tolerance = 1E-9
    plastic_models = 'simple1 simple2'
    max_NR_iterations = 2
    min_stepsize = 1
    debug_fspb = crash
    debug_jac_at_stress = '10 0 0 0 10 0 0 0 10'
    debug_jac_at_pm = '1 1'
    debug_jac_at_intnl = '1 1'
    debug_stress_change = 1E-5
    debug_pm_change = '1E-6 1E-6'
    debug_intnl_change = '1E-6 1E-6'
  [../]
[]


[Executioner]
  end_time = 1
  dt = 1
  type = Transient
[]


[Outputs]
  file_base = two_surface02
  exodus = false
  [./csv]
    type = CSV
    [../]
[]

(modules/solid_mechanics/test/tests/crystal_plasticity/user_object_based/use_substep_dt.i)

[Mesh]
  type = GeneratedMesh
  dim = 3
  nx = 4
  ny = 4
  nz = 4
  elem_type = HEX8
  displacements = 'ux uy uz'
[]

[Variables]
  [ux]
  []
  [uy]
  []
  [uz]
  []
[]

[AuxVariables]
  [stress_zz]
    order = CONSTANT
    family = MONOMIAL
  []
  [pk2]
    order = CONSTANT
    family = MONOMIAL
  []
  [fp_zz]
    order = CONSTANT
    family = MONOMIAL
  []
  [rotout]
    order = CONSTANT
    family = MONOMIAL
  []
  [e_zz]
    order = CONSTANT
    family = MONOMIAL
  []
  [gss]
    order = CONSTANT
    family = MONOMIAL
  []
  [slip_increment]
    order = CONSTANT
    family = MONOMIAL
  []
[]

[Kernels]
  [SolidMechanics]
    displacements = 'ux uy uz'
    use_displaced_mesh = true
  []
[]

[AuxKernels]
  [stress_zz]
    type = RankTwoAux
    variable = stress_zz
    rank_two_tensor = stress
    index_j = 2
    index_i = 2
    execute_on = timestep_end
  []
  [pk2]
    type = RankTwoAux
    variable = pk2
    rank_two_tensor = pk2
    index_j = 2
    index_i = 2
    execute_on = timestep_end
  []
  [fp_zz]
    type = RankTwoAux
    variable = fp_zz
    rank_two_tensor = fp
    index_j = 2
    index_i = 2
    execute_on = timestep_end
  []
  [e_zz]
    type = RankTwoAux
    variable = e_zz
    rank_two_tensor = lage
    index_j = 2
    index_i = 2
    execute_on = timestep_end
  []
  [gss]
    type = MaterialStdVectorAux
    variable = gss
    property = state_var_gss
    index = 0
    execute_on = timestep_end
  []
  [slip_inc]
    type = MaterialStdVectorAux
    variable = slip_increment
    property = slip_rate_gss
    index = 0
    execute_on = timestep_end
  []
[]

[BCs]
  [symmy]
    type = DirichletBC
    variable = uy
    boundary = bottom
    value = 0
  []
  [symmx]
    type = DirichletBC
    variable = ux
    boundary = left
    value = 0
  []
  [symmz]
    type = DirichletBC
    variable = uz
    boundary = back
    value = 0
  []
  [pushy]
    type = FunctionDirichletBC
    variable = uy
    boundary = top
    function = '-0.1*t'
  []
  [pullz]
    type = FunctionDirichletBC
    variable = uz
    boundary = front
    function = '0.1*t'
  []
[]

[UserObjects]
  [slip_rate_gss]
    type = CrystalPlasticitySlipRateGSS
    variable_size = 12
    slip_sys_file_name = input_slip_sys.txt
    num_slip_sys_flowrate_props = 2
    flowprops = '1 4 0.001 0.1 5 8 0.001 0.1 9 12 0.001 0.1'
    uo_state_var_name = state_var_gss
  []
  [slip_resistance_gss]
    type = CrystalPlasticitySlipResistanceGSS
    variable_size = 12
    uo_state_var_name = state_var_gss
  []
  [state_var_gss]
    type = CrystalPlasticityStateVariable
    variable_size = 12
    groups = '0 4 8 12'
    group_values = '60.8 60.8 60.8'
    uo_state_var_evol_rate_comp_name = state_var_evol_rate_comp_gss
    scale_factor = 1.0
  []
  [state_var_evol_rate_comp_gss]
    type = CrystalPlasticityStateVarRateComponentGSS
    variable_size = 12
    hprops = '1.0 541.5 109.8 2.5'
    uo_slip_rate_name = slip_rate_gss
    uo_state_var_name = state_var_gss
  []
[]

[Materials]
  [crysp]
    type = FiniteStrainUObasedCP
    block = 0
    stol = 1e-2
    tan_mod_type = exact
    uo_slip_rates = 'slip_rate_gss'
    uo_slip_resistances = 'slip_resistance_gss'
    uo_state_vars = 'state_var_gss'
    uo_state_var_evol_rate_comps = 'state_var_evol_rate_comp_gss'
  []
  [strain]
    type = ComputeFiniteStrain
    block = 0
    displacements = 'ux uy uz'
  []
  [elasticity_tensor]
    type = ComputeElasticityTensorCP
    block = 0
    C_ijkl = '1.684e5 1.214e5 1.214e5 1.684e5 1.214e5 1.684e5 0.754e5 0.754e5 0.754e5'
    fill_method = symmetric9
  []
[]

[Postprocessors]
  [stress_zz]
    type = ElementAverageValue
    variable = stress_zz
  []
  [pk2]
    type = ElementAverageValue
    variable = pk2
  []
  [fp_zz]
    type = ElementAverageValue
    variable = fp_zz
  []
  [e_zz]
    type = ElementAverageValue
    variable = e_zz
  []
  [gss]
    type = ElementAverageValue
    variable = gss
  []
  [slip_increment]
    type = ElementAverageValue
    variable = slip_increment
  []
  [uy_avg_top]
    type = SideAverageValue
    variable = uy
    boundary = top
  []
  [uz_avg_front]
    type = SideAverageValue
    variable = uz
    boundary = front
  []
[]

[Preconditioning]
  [smp]
    type = SMP
    full = true
  []
[]

[Executioner]
  type = Transient
  dt = 0.05
  solve_type = 'NEWTON'

  petsc_options = '-snes_ksp_ew'
  petsc_options_iname = '-pc_type -pc_factor_mat_solver_package'
  petsc_options_value = ' lu       superlu_dist'

  line_search = 'none'
  nl_abs_tol = 1e-10
  nl_rel_step_tol = 1e-10
  dtmax = 10.0
  nl_rel_tol = 1e-10
  end_time = 1.0
  num_steps = 5
  dtmin = 0.001
  nl_abs_step_tol = 1e-10
[]

[Outputs]
  csv = true
[]

(modules/combined/test/tests/eigenstrain/variable_finite.i)

[Mesh]
  type = GeneratedMesh
  dim = 2
  nx = 10
  ny = 10
  xmax = 0.5
  ymax = 0.5
  elem_type = QUAD4
[]

[GlobalParams]
  displacements = 'disp_x disp_y'
[]

[Variables]
  [./disp_x]
    order = FIRST
    family = LAGRANGE
  [../]
  [./disp_y]
    order = FIRST
    family = LAGRANGE
  [../]
[]

[AuxVariables]
  [./strain11]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress11]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./c]
  [../]
  [./eigenstrain00]
    order = CONSTANT
    family = MONOMIAL
  [../]
[]

[ICs]
  [./c_IC]
    int_width = 0.15
    x1 = 0
    y1 = 0
    radius = 0.25
    outvalue = 0
    variable = c
    invalue = 1
    type = SmoothCircleIC
  [../]
[]

[Kernels]
  [./TensorMechanics]
  [../]
[]

[AuxKernels]
  [./strain11]
    type = RankTwoAux
    rank_two_tensor = mechanical_strain
    index_i = 0
    index_j = 0
    variable = strain11
  [../]
  [./stress11]
    type = RankTwoAux
    rank_two_tensor = mechanical_strain
    index_i = 1
    index_j = 1
    variable = stress11
  [../]
  [./eigenstrain00]
    type = RankTwoAux
    variable = eigenstrain00
    rank_two_tensor = eigenstrain
    index_j = 0
    index_i = 0
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeElasticityTensor
    block = 0
    C_ijkl = '1 1'
    fill_method = symmetric_isotropic
  [../]
  [./var_dependence]
    type = DerivativeParsedMaterial
    block = 0
    expression = 0.01*c^2
    coupled_variables = c
    outputs = exodus
    output_properties = 'var_dep'
    f_name = var_dep
    enable_jit = true
    derivative_order = 2
  [../]
  [./eigenstrain]
    type = ComputeVariableEigenstrain
    block = 0
    eigen_base = '1 1 1 0 0 0'
    args = c
    prefactor = var_dep
    eigenstrain_name = eigenstrain
  [../]
  [./strain]
    type = ComputeFiniteStrain
    block = 0
    displacements = 'disp_x disp_y'
    eigenstrain_names = eigenstrain
  [../]
  [./stress]
    type = ComputeFiniteStrainElasticStress
    block = 0
  [../]
[]

[BCs]
  [./bottom_y]
    type = DirichletBC
    variable = disp_y
    boundary = bottom
    value = 0
  [../]
  [./left_x]
    type = DirichletBC
    variable = disp_x
    boundary = left
    value = 0
  [../]
  [./top_y]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = top
    function = 0.0005*t
  [../]
[]

[Preconditioning]
  [./SMP]
    type = SMP
    full = true
  [../]
[]

[Executioner]
  type = Transient
  num_steps = 3
  solve_type = PJFNK
  petsc_options_iname = '-pc_type '
  petsc_options_value = lu
  l_max_its = 20
  nl_max_its = 10
  l_tol = 1.0e-4
  nl_rel_tol = 1.0e-8
  nl_abs_tol = 1.0e-9
  reset_dt = true
[]

[Outputs]
  execute_on = 'timestep_end'
  exodus = true
[]

(modules/solid_mechanics/test/tests/multi/three_surface05.i)

# Plasticit models:
# SimpleTester0 with a = 0 and b = 1 and strength = 1
# SimpleTester1 with a = 1 and b = 0 and strength = 1
# SimpleTester2 with a = 1 and b = 1 and strength = 1.5
#
# Lame lambda = 0 (Poisson=0).  Lame mu = 0.5E6
#
# A single element is stretched by 1E-6m in y direction and 1.1E-6 in z direction.
# trial stress_yy = 1 and stress_zz = 1.1
#
# Then SimpleTester0 and SimpleTester2 should activate and the algorithm will return to
# the corner stress_yy=0.5, stress_zz=1
# However, this will mean internal0 < 0, so SimpleTester0 will be deactivated and
# then the algorithm will return to
# stress_yy=0.7, stress_zz=0.8
# internal0 should be 0.0, and internal2 should be 0.3

[Mesh]
  type = GeneratedMesh
  dim = 3
  nx = 1
  ny = 1
  nz = 1
  xmin = -0.5
  xmax = 0.5
  ymin = -0.5
  ymax = 0.5
  zmin = -0.5
  zmax = 0.5
[]


[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./disp_z]
  [../]
[]

[Kernels]
  [SolidMechanics]
    displacements = 'disp_x disp_y disp_z'
  [../]
[]


[BCs]
  [./x]
    type = FunctionDirichletBC
    variable = disp_x
    boundary = 'front back'
    function = '0E-6*x'
  [../]
  [./y]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = 'front back'
    function = '1.0E-6*y'
  [../]
  [./z]
    type = FunctionDirichletBC
    variable = disp_z
    boundary = 'front back'
    function = '1.1E-6*z'
  [../]
[]

[AuxVariables]
  [./stress_xx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_zz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./f0]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./f1]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./f2]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./int0]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./int1]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./int2]
    order = CONSTANT
    family = MONOMIAL
  [../]
[]

[AuxKernels]
  [./stress_xx]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xx
    index_i = 0
    index_j = 0
  [../]
  [./stress_xy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xy
    index_i = 0
    index_j = 1
  [../]
  [./stress_xz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xz
    index_i = 0
    index_j = 2
  [../]
  [./stress_yy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yy
    index_i = 1
    index_j = 1
  [../]
  [./stress_yz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yz
    index_i = 1
    index_j = 2
  [../]
  [./stress_zz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_zz
    index_i = 2
    index_j = 2
  [../]
  [./f0]
    type = MaterialStdVectorAux
    property = plastic_yield_function
    index = 0
    variable = f0
  [../]
  [./f1]
    type = MaterialStdVectorAux
    property = plastic_yield_function
    index = 1
    variable = f1
  [../]
  [./f2]
    type = MaterialStdVectorAux
    property = plastic_yield_function
    index = 2
    variable = f2
  [../]
  [./int0]
    type = MaterialStdVectorAux
    property = plastic_internal_parameter
    factor = 1E6
    index = 0
    variable = int0
  [../]
  [./int1]
    type = MaterialStdVectorAux
    property = plastic_internal_parameter
    factor = 1E6
    index = 1
    variable = int1
  [../]
  [./int2]
    type = MaterialStdVectorAux
    property = plastic_internal_parameter
    factor = 1E6
    index = 2
    variable = int2
  [../]
[]

[Postprocessors]
  [./s_xx]
    type = PointValue
    point = '0 0 0'
    variable = stress_xx
  [../]
  [./s_xy]
    type = PointValue
    point = '0 0 0'
    variable = stress_xy
  [../]
  [./s_xz]
    type = PointValue
    point = '0 0 0'
    variable = stress_xz
  [../]
  [./s_yy]
    type = PointValue
    point = '0 0 0'
    variable = stress_yy
  [../]
  [./s_yz]
    type = PointValue
    point = '0 0 0'
    variable = stress_yz
  [../]
  [./s_zz]
    type = PointValue
    point = '0 0 0'
    variable = stress_zz
  [../]
  [./f0]
    type = PointValue
    point = '0 0 0'
    variable = f0
  [../]
  [./f1]
    type = PointValue
    point = '0 0 0'
    variable = f1
  [../]
  [./f2]
    type = PointValue
    point = '0 0 0'
    variable = f2
  [../]
  [./int0]
    type = PointValue
    point = '0 0 0'
    variable = int0
  [../]
  [./int1]
    type = PointValue
    point = '0 0 0'
    variable = int1
  [../]
  [./int2]
    type = PointValue
    point = '0 0 0'
    variable = int2
  [../]
[]

[UserObjects]
  [./simple0]
    type = SolidMechanicsPlasticSimpleTester
    a = 0
    b = 1
    strength = 1
    yield_function_tolerance = 1.0E-9
    internal_constraint_tolerance = 1.0E-9
  [../]
  [./simple1]
    type = SolidMechanicsPlasticSimpleTester
    a = 1
    b = 0
    strength = 1
    yield_function_tolerance = 1.0E-9
    internal_constraint_tolerance = 1.0E-9
  [../]
  [./simple2]
    type = SolidMechanicsPlasticSimpleTester
    a = 1
    b = 1
    strength = 1.5
    yield_function_tolerance = 1.0E-9
    internal_constraint_tolerance = 1.0E-9
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeElasticityTensor
    block = 0
    fill_method = symmetric_isotropic
    C_ijkl = '0 0.5E6'
  [../]
  [./strain]
    type = ComputeFiniteStrain
    block = 0
    displacements = 'disp_x disp_y disp_z'
  [../]
  [./multi]
    type = ComputeMultiPlasticityStress
    block = 0
    ep_plastic_tolerance = 1E-9
    plastic_models = 'simple0 simple1 simple2'
    max_NR_iterations = 2
    min_stepsize = 1
    debug_fspb = crash
    debug_jac_at_stress = '10 0 0 0 10 0 0 0 10'
    debug_jac_at_pm = '1 1'
    debug_jac_at_intnl = '1 1'
    debug_stress_change = 1E-5
    debug_pm_change = '1E-6 1E-6'
    debug_intnl_change = '1E-6 1E-6'
  [../]
[]


[Executioner]
  end_time = 1
  dt = 1
  type = Transient
[]


[Outputs]
  file_base = three_surface05
  exodus = false
  [./csv]
    type = CSV
    [../]
[]

(modules/solid_mechanics/test/tests/capped_mohr_coulomb/random5.i)

# Using CappedMohrCoulomb
# Plasticity models:
# Tensile strength = 1.5
# Compressive strength = 3.0
# Cohesion = 1.0
# Friction angle = dilation angle = 20deg
#
# Young = 1, Poisson = 0.3
#
# A line of elements is perturbed randomly, and return to the yield surface at each quadpoint is checked

[Mesh]
  type = GeneratedMesh
  dim = 3
  nx = 100
  ny = 12
  nz = 1
  xmin = 0
  xmax = 100
  ymin = 0
  ymax = 12
  zmin = 0
  zmax = 1
[]


[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./disp_z]
  [../]
[]

[Kernels]
  [SolidMechanics]
    displacements = 'disp_x disp_y disp_z'
  [../]
[]


[ICs]
  [./x]
    type = RandomIC
    min = -0.1
    max = 0.1
    variable = disp_x
  [../]
  [./y]
    type = RandomIC
    min = -0.1
    max = 0.1
    variable = disp_y
  [../]
  [./z]
    type = RandomIC
    min = -0.1
    max = 0.1
    variable = disp_z
  [../]
[]

[BCs]
  [./x]
    type = FunctionDirichletBC
    variable = disp_x
    boundary = 'front back'
    function = '0'
  [../]
  [./y]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = 'front back'
    function = '0'
  [../]
  [./z]
    type = FunctionDirichletBC
    variable = disp_z
    boundary = 'front back'
    function = '0'
  [../]
[]

[AuxVariables]
  [./Smax]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./Smid]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./Smin]
    order = CONSTANT
    family = MONOMIAL
  [../]
[]

[AuxKernels]
  [./Smax]
    type = RankTwoScalarAux
    rank_two_tensor = stress
    variable = Smax
    scalar_type = MaxPrincipal
  [../]
  [./Smid]
    type = RankTwoScalarAux
    rank_two_tensor = stress
    variable = Smid
    scalar_type = MidPrincipal
  [../]
  [./Smin]
    type = RankTwoScalarAux
    rank_two_tensor = stress
    variable = Smin
    scalar_type = MinPrincipal
  [../]
[]

[UserObjects]
  [./ts]
    type = SolidMechanicsHardeningConstant
    value = 1.5
  [../]
  [./cs]
    type = SolidMechanicsHardeningConstant
    value = 3.0
  [../]
  [./coh]
    type = SolidMechanicsHardeningConstant
    value = 1.0
  [../]
  [./phi]
    type = SolidMechanicsHardeningConstant
    value = 20
    convert_to_radians = true
  [../]
  [./psi]
    type = SolidMechanicsHardeningConstant
    value = 3
    convert_to_radians = true
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 100
    poissons_ratio = 0.3
  [../]
  [./strain]
    type = ComputeFiniteStrain
    displacements = 'disp_x disp_y disp_z'
  [../]
  [./capped_mc]
    type = CappedMohrCoulombStressUpdate
    tensile_strength = ts
    compressive_strength = cs
    cohesion = coh
    friction_angle = phi
    dilation_angle = psi
    smoothing_tol = 0.2
    yield_function_tol = 1.0E-12
    max_NR_iterations = 1000
  [../]
  [./stress]
    type = ComputeMultipleInelasticStress
    inelastic_models = capped_mc
    perform_finite_strain_rotations = false
  [../]
[]


[Executioner]
  end_time = 1
  dt = 1
  type = Transient
[]


[Outputs]
  file_base = random5
  exodus = true
[]

(modules/solid_mechanics/examples/bridge/bridge_large_strain.i)

#
# Bridge linear elasticity example
#
# This example models a bridge using linear elasticity.
# It can be either steel or concrete.
# Gravity is applied
# A pressure of 0.5 MPa is also applied
#

[Mesh]
  displacements = 'disp_x disp_y disp_z' #Define displacements for deformed mesh
  type = FileMesh #Read in mesh from file
  file = bridge.e

  boundary_id = '1 2 3 4 5 6' #Assign names to boundaries to make things clearer
  boundary_name = 'top left right bottom1 bottom2 bottom3'
[]

[GlobalParams]
  displacements = 'disp_x disp_y disp_z'
[]

[Variables]
  [./disp_x]
    order = FIRST
    family = LAGRANGE
  [../]
  [./disp_y]
    order = FIRST
    family = LAGRANGE
  [../]
  [./disp_z]
    order = FIRST
    family = LAGRANGE
  [../]
[]

[Kernels]
  [./gravity_y]
    #Gravity is applied to bridge
    type = Gravity
    variable = disp_y
    value = -9.81
  [../]
  [./SolidMechanics]
    #Stress divergence kernels
    displacements = 'disp_x disp_y disp_z'
  [../]
[]

[AuxVariables]
  [./von_mises]
    #Dependent variable used to visualize the Von Mises stress
    order = CONSTANT
    family = MONOMIAL
  [../]
[]

[AuxKernels]
  [./von_mises_kernel]
    #Calculates the von mises stress and assigns it to von_mises
    type = RankTwoScalarAux
    variable = von_mises
    rank_two_tensor = stress
    execute_on = timestep_end
    scalar_type = VonMisesStress
  [../]
[]

[BCs]
  [./Pressure]
    [./load]
      #Applies the pressure
      boundary = top
      factor = 5e5 # Pa
    [../]
  [../]
  [./anchor_x]
    #Anchors the bottom and sides against deformation in the x-direction
    type = DirichletBC
    variable = disp_x
    boundary = 'left right bottom1 bottom2 bottom3'
    value = 0.0
  [../]
  [./anchor_y]
    #Anchors the bottom and sides against deformation in the y-direction
    type = DirichletBC
    variable = disp_y
    boundary = 'left right bottom1 bottom2 bottom3'
    value = 0.0
  [../]
  [./anchor_z]
    #Anchors the bottom and sides against deformation in the z-direction
    type = DirichletBC
    variable = disp_z
    boundary = 'left right bottom1 bottom2 bottom3'
    value = 0.0
  [../]
[]

[Materials]
  active = 'density_steel stress strain elasticity_tensor_steel'
  [./elasticity_tensor_steel]
    #Creates the elasticity tensor using steel parameters
    youngs_modulus = 210e9 #Pa
    poissons_ratio = 0.3
    type = ComputeIsotropicElasticityTensor
    block = 1
  [../]
  [./elasticity_tensor_concrete]
    #Creates the elasticity tensor using concrete parameters
    youngs_modulus = 16.5e9 #Pa
    poissons_ratio = 0.2
    type = ComputeIsotropicElasticityTensor
    block = 1
  [../]
  [./strain]
    #Computes the strain, assuming small strains
    type = ComputeFiniteStrain
    block = 1
    displacements = 'disp_x disp_y disp_z'
  [../]
  [./stress]
    #Computes the stress, using linear elasticity
    type = ComputeFiniteStrainElasticStress
    block = 1
  [../]
  [./density_steel]
    #Defines the density of steel
    type = GenericConstantMaterial
    block = 1
    prop_names = density
    prop_values = 7850 # kg/m^3
  [../]
  [./density_concrete]
    #Defines the density of concrete
    type = GenericConstantMaterial
    block = 1
    prop_names = density
    prop_values = 2400 # kg/m^3
  [../]
[]

[Preconditioning]
  [./SMP]
    #Creates the entire Jacobian, for the Newton solve
    type = SMP
    full = true
  [../]
[]

[Executioner]
  #We solve a steady state problem using Newton's iteration
  type = Transient
  solve_type = NEWTON
  nl_rel_tol = 1e-9
  l_max_its = 30
  l_tol = 1e-4
  nl_max_its = 10
  petsc_options_iname = '-pc_type -pc_hypre_type -ksp_gmres_restart'
  petsc_options_value = 'hypre boomeramg 31'
  dt = 0.1
  num_steps = 1
[]

[Outputs]
  exodus = true
  perf_graph = true
[]

(modules/solid_mechanics/test/tests/mohr_coulomb/random_planar.i)

# apply many random large deformations, checking that the algorithm returns correctly to
# the yield surface each time.


[Mesh]
  type = GeneratedMesh
  dim = 3
  nx = 100
  ny = 1250
  nz = 1
  xmin = 0
  xmax = 100
  ymin = 0
  ymax = 1250
  zmin = 0
  zmax = 1
[]


[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./disp_z]
  [../]
[]

[Kernels]
  [SolidMechanics]
    displacements = 'disp_x disp_y disp_z'
  [../]
[]


[ICs]
  [./x]
    type = RandomIC
    min = -0.1
    max = 0.1
    variable = disp_x
  [../]
  [./y]
    type = RandomIC
    min = -0.1
    max = 0.1
    variable = disp_y
  [../]
  [./z]
    type = RandomIC
    min = -0.1
    max = 0.1
    variable = disp_z
  [../]
[]

[BCs]
  [./x]
    type = FunctionDirichletBC
    variable = disp_x
    boundary = 'front back'
    function = '0'
  [../]
  [./y]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = 'front back'
    function = '0'
  [../]
  [./z]
    type = FunctionDirichletBC
    variable = disp_z
    boundary = 'front back'
    function = '0'
  [../]
[]

[AuxVariables]
  [./yield_fcn]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./iter]
    order = CONSTANT
    family = MONOMIAL
  [../]
[]

[AuxKernels]
  [./yield_fcn_auxk]
    type = MaterialStdVectorAux
    index = 0
    property = plastic_yield_function
    variable = yield_fcn
  [../]
  [./iter]
    type = MaterialRealAux
    property = plastic_NR_iterations
    variable = iter
  [../]
[]

[Postprocessors]
  [./yield_fcn_at_zero]
    type = PointValue
    point = '0 0 0'
    variable = yield_fcn
    outputs = 'console'
  [../]
  [./should_be_zero]
    type = FunctionValuePostprocessor
    function = should_be_zero_fcn
  [../]
  [./av_iter]
    type = ElementAverageValue
    variable = iter
    outputs = 'console'
  [../]
[]

[Functions]
  [./should_be_zero_fcn]
    type = ParsedFunction
    expression = 'if(a<1E-3,0,a)'
    symbol_names = 'a'
    symbol_values = 'yield_fcn_at_zero'
  [../]
[]

[UserObjects]
  [./coh]
    type = SolidMechanicsHardeningCubic
    value_0 = 1000
    value_residual = 100
    internal_limit = 4
  [../]
  [./phi]
    type = SolidMechanicsHardeningCubic
    value_0 = 0.8
    value_residual = 0.3
    internal_limit = 2
  [../]
  [./psi]
    type = SolidMechanicsHardeningConstant
    value = 15
    convert_to_radians = true
  [../]
  [./mc]
    type = SolidMechanicsPlasticMohrCoulombMulti
    cohesion = coh
    friction_angle = phi
    dilation_angle = psi
    yield_function_tolerance = 1E-3
    shift = 1E-10
    internal_constraint_tolerance = 1E-6
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeElasticityTensor
    block = 0
    fill_method = symmetric_isotropic
    C_ijkl = '0.7E7 1E7'
  [../]
  [./strain]
    type = ComputeFiniteStrain
    block = 0
    displacements = 'disp_x disp_y disp_z'
  [../]
  [./mc]
    type = ComputeMultiPlasticityStress
    block = 0
    ep_plastic_tolerance = 1E-10
    plastic_models = mc
    min_stepsize = 1
    max_stepsize_for_dumb = 1
  [../]
[]


[Executioner]
  end_time = 1
  dt = 1
  type = Transient
[]


[Outputs]
  file_base = random_planar
  exodus = false
  [./csv]
    type = CSV
    [../]
[]

(modules/solid_mechanics/test/tests/hyperelastic_viscoplastic/one_elem_multi.i)

[Mesh]
  type = GeneratedMesh
  dim = 3
  elem_type = HEX8
  displacements = 'ux uy uz'
[]

[Variables]
  [./ux]
    block = 0
  [../]
  [./uy]
    block = 0
  [../]
  [./uz]
    block = 0
  [../]
[]

[Kernels]
  [SolidMechanics]
    displacements = 'ux uy uz'
    use_displaced_mesh = true
  [../]
[]

[AuxVariables]
  [./stress_zz]
    order = CONSTANT
    family = MONOMIAL
    block = 0
  [../]
  [./peeq_soft]
    order = CONSTANT
    family = MONOMIAL
    block = 0
  [../]
  [./peeq_hard]
    order = CONSTANT
    family = MONOMIAL
    block = 0
  [../]
  [./fp_zz]
    order = CONSTANT
    family = MONOMIAL
    block = 0
  [../]
[]

[AuxKernels]
  [./stress_zz]
    type = RankTwoAux
    variable = stress_zz
    rank_two_tensor = stress
    index_j = 2
    index_i = 2
    execute_on = timestep_end
    block = 0
  [../]
  [./fp_zz]
    type = RankTwoAux
    variable = fp_zz
    rank_two_tensor = fp
    index_j = 2
    index_i = 2
    execute_on = timestep_end
    block = 0
  [../]
  [./peeq_soft]
    type = MaterialRealAux
    variable = peeq_soft
    property = ep_eqv1
    execute_on = timestep_end
    block = 0
  [../]
  [./peeq_hard]
    type = MaterialRealAux
    variable = peeq_hard
    property = ep_eqv2
    execute_on = timestep_end
    block = 0
  [../]
[]

[BCs]
  [./symmy]
    type = DirichletBC
    variable = uy
    boundary = bottom
    value = 0
  [../]
  [./symmx]
    type = DirichletBC
    variable = ux
    boundary = left
    value = 0
  [../]
  [./symmz]
    type = DirichletBC
    variable = uz
    boundary = back
    value = 0
  [../]
  [./tdisp]
    type = FunctionDirichletBC
    variable = uz
    boundary = front
    function = '0.01*t'
  [../]
[]

[UserObjects]
  [./flowstress1]
    type = HEVPRambergOsgoodHardening
    yield_stress = 100
    hardening_exponent = 0.1
    reference_plastic_strain = 0.002
    intvar_prop_name = ep_eqv1
  [../]
  [./flowstress2]
    type = HEVPRambergOsgoodHardening
    yield_stress = 100
    hardening_exponent = 0.3
    reference_plastic_strain = 0.002
    intvar_prop_name = ep_eqv2
  [../]
  [./flowrate1]
    type = HEVPFlowRatePowerLawJ2
    reference_flow_rate = 0.0001
    flow_rate_exponent = 50.0
    flow_rate_tol = 1
    strength_prop_name = flowstress1
  [../]
  [./flowrate2]
    type = HEVPFlowRatePowerLawJ2
    reference_flow_rate = 0.0001
    flow_rate_exponent = 50.0
    flow_rate_tol = 1
    strength_prop_name = flowstress2
  [../]
  [./ep_eqv1]
     type = HEVPEqvPlasticStrain
     intvar_rate_prop_name = ep_eqv_rate1
  [../]
  [./ep_eqv_rate1]
     type = HEVPEqvPlasticStrainRate
     flow_rate_prop_name = flowrate1
  [../]
  [./ep_eqv2]
     type = HEVPEqvPlasticStrain
     intvar_rate_prop_name = ep_eqv_rate2
  [../]
  [./ep_eqv_rate2]
     type = HEVPEqvPlasticStrainRate
     flow_rate_prop_name = flowrate2
  [../]
[]

[Materials]
  [./strain]
    type = ComputeFiniteStrain
    block = 0
    displacements = 'ux uy uz'
  [../]
  [./viscop]
    type = FiniteStrainHyperElasticViscoPlastic
    block = 0
    resid_abs_tol = 1e-18
    resid_rel_tol = 1e-8
    maxiters = 50
    max_substep_iteration = 5
    flow_rate_user_objects = 'flowrate1 flowrate2'
    strength_user_objects = 'flowstress1 flowstress2'
    internal_var_user_objects = 'ep_eqv1 ep_eqv2'
    internal_var_rate_user_objects = 'ep_eqv_rate1 ep_eqv_rate2'
  [../]
  [./elasticity_tensor]
    type = ComputeElasticityTensor
    block = 0
    C_ijkl = '2.8e5 1.2e5 1.2e5 2.8e5 1.2e5 2.8e5 0.8e5 0.8e5 0.8e5'
    fill_method = symmetric9
  [../]
[]

[Postprocessors]
  [./stress_zz]
    type = ElementAverageValue
    variable = stress_zz
    block = 'ANY_BLOCK_ID 0'
  [../]
  [./fp_zz]
    type = ElementAverageValue
    variable = fp_zz
    block = 'ANY_BLOCK_ID 0'
  [../]
  [./peeq_soft]
    type = ElementAverageValue
    variable = peeq_soft
    block = 'ANY_BLOCK_ID 0'
  [../]
  [./peeq_hard]
    type = ElementAverageValue
    variable = peeq_hard
    block = 'ANY_BLOCK_ID 0'
  [../]
[]

[Preconditioning]
  [./smp]
    type = SMP
    full = true
  [../]
[]

[Executioner]
  type = Transient
  dt = 0.02

  #Preconditioned JFNK (default)
  solve_type = 'PJFNK'

  petsc_options_iname = -pc_hypre_type
  petsc_options_value = boomerang
  dtmax = 10.0
  nl_rel_tol = 1e-10
  dtmin = 0.02
  num_steps = 10
[]

[Outputs]
  file_base = one_elem_multi
  exodus = true
  csv = false
[]

(modules/solid_mechanics/test/tests/j2_plasticity/hard1.i)

# UserObject J2 test, with hardening, but with rate=0
# apply uniform compression in x direction to give
# trial stress_xx = -5, so sqrt(3*J2) = 5
# with zero Poisson's ratio, this should return to
# stress_xx = -3, stress_yy = -1 = stress_zz,
# for strength = 2
# (note that stress_xx - stress_yy = stress_xx - stress_zz = -2, so sqrt(3*j2) = 2,
#  and that the mean stress remains = -5/3)

[Mesh]
  type = GeneratedMesh
  dim = 3
  nx = 1
  ny = 1
  nz = 1
  xmin = -0.5
  xmax = 0.5
  ymin = -0.5
  ymax = 0.5
  zmin = -0.5
  zmax = 0.5
[]


[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./disp_z]
  [../]
[]

[Kernels]
  [SolidMechanics]
    displacements = 'disp_x disp_y disp_z'
  [../]
[]


[BCs]
  [./x]
    type = FunctionDirichletBC
    variable = disp_x
    boundary = 'front back'
    function = '-2.5E-6*x'
  [../]
  [./y]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = 'front back'
    function = '0E-6*y'
  [../]
  [./z]
    type = FunctionDirichletBC
    variable = disp_z
    boundary = 'front back'
    function = '0E-6*z'
  [../]
[]

[AuxVariables]
  [./stress_xx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_zz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./f]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./iter]
    order = CONSTANT
    family = MONOMIAL
  [../]
[]

[AuxKernels]
  [./stress_xx]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xx
    index_i = 0
    index_j = 0
  [../]
  [./stress_xy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xy
    index_i = 0
    index_j = 1
  [../]
  [./stress_xz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xz
    index_i = 0
    index_j = 2
  [../]
  [./stress_yy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yy
    index_i = 1
    index_j = 1
  [../]
  [./stress_yz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yz
    index_i = 1
    index_j = 2
  [../]
  [./stress_zz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_zz
    index_i = 2
    index_j = 2
  [../]
  [./f]
    type = MaterialStdVectorAux
    index = 0
    property = plastic_yield_function
    variable = f
  [../]
  [./iter]
    type = MaterialRealAux
    property = plastic_NR_iterations
    variable = iter
  [../]
[]

[Postprocessors]
  [./s_xx]
    type = PointValue
    point = '0 0 0'
    variable = stress_xx
  [../]
  [./s_xy]
    type = PointValue
    point = '0 0 0'
    variable = stress_xy
  [../]
  [./s_xz]
    type = PointValue
    point = '0 0 0'
    variable = stress_xz
  [../]
  [./s_yy]
    type = PointValue
    point = '0 0 0'
    variable = stress_yy
  [../]
  [./s_yz]
    type = PointValue
    point = '0 0 0'
    variable = stress_yz
  [../]
  [./s_zz]
    type = PointValue
    point = '0 0 0'
    variable = stress_zz
  [../]
  [./f]
    type = PointValue
    point = '0 0 0'
    variable = f
  [../]
  [./iter]
    type = PointValue
    point = '0 0 0'
    variable = iter
  [../]
[]

[UserObjects]
  [./str]
    type = SolidMechanicsHardeningConstant
    value = 2
  [../]
  [./j2]
    type = SolidMechanicsPlasticJ2
    yield_strength = str
    yield_function_tolerance = 1E-3
    internal_constraint_tolerance = 1E-9
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeElasticityTensor
    block = 0
    fill_method = symmetric_isotropic
    C_ijkl = '0 1E6'
  [../]
  [./strain]
    type = ComputeFiniteStrain
    block = 0
    displacements = 'disp_x disp_y disp_z'
  [../]
  [./mc]
    type = ComputeMultiPlasticityStress
    block = 0
    ep_plastic_tolerance = 1E-9
    plastic_models = j2
    debug_fspb = crash
  [../]
[]


[Executioner]
  end_time = 1
  dt = 1
  type = Transient
[]


[Outputs]
  file_base = hard1
  exodus = false
  [./csv]
    type = CSV
    [../]
[]

(modules/fsi/test/tests/fsi_acoustics/3D_struc_acoustic/3D_struc_acoustic.i)

# Test for `StructureAcousticInterface` interface kernel. The domain is 3D with lengths
# 10 X 0.1 X 0.1 meters. The fluid domain is on the right and the structural domain
# is on the left. Fluid end is subjected to a 250Hz sine wave with a single peak.
# Structural domain has the same material properties as the fluid. Interface between
# structure and fluid is located at 5.0m in the x-direction. Fluid pressure is recorded
# at (5, 0.05, 0.05). Structural stress is also recorded at the same location. Fluid
# pressure and structural stress should be almost equal and opposite to each other.
#
# Input parameters:
# Dimensions = 3
# Lengths = 10 X 0.1 X 0.1 meters
# Fluid speed of sound = 1500 m/s
# Fluid density = 1e-6 Giga kg/m^3
# Structural bulk modulus = 2.25 GPa
# Structural shear modulus = 0 GPa
# Structural density = 1e-6 Giga kg/m^3
# Fluid domain = true
# Fluid BC = single peak sine wave applied as a pressure on the fluid end
# Structural domain = true
# Structural BC = Neumann BC with value zero applied on the structural end.
# Fluid-structure interface location = 5.0m along the x-direction

[Mesh]
  [gen]
    type = GeneratedMeshGenerator
    dim = 3
    nx = 100
    ny = 1
    nz = 1
    xmax = 10
    ymax = 0.1
    zmax = 0.1
  []
  [./subdomain1]
    input = gen
    type = SubdomainBoundingBoxGenerator
    bottom_left = '5.0 0.0 0.0'
    block_id = 1
    top_right = '10.0 0.1 0.1'
  [../]
  [./interface1]
    type = SideSetsBetweenSubdomainsGenerator
    input = subdomain1
    primary_block = 1
    paired_block = 0
    new_boundary = 'interface1'
  [../]
[]

[GlobalParams]
[]

[Variables]
  [./p]
    block = 1
  [../]
  [./disp_x]
    block = 0
  [../]
  [./disp_y]
    block = 0
  [../]
  [./disp_z]
    block = 0
  [../]
[]

[AuxVariables]
  [./vel_x]
    order = FIRST
    family = LAGRANGE
    block = 0
  [../]
  [./accel_x]
    order = FIRST
    family = LAGRANGE
    block = 0
  [../]
  [./vel_y]
    order = FIRST
    family = LAGRANGE
    block = 0
  [../]
  [./accel_y]
    order = FIRST
    family = LAGRANGE
    block = 0
  [../]
  [./vel_z]
    order = FIRST
    family = LAGRANGE
    block = 0
  [../]
  [./accel_z]
    order = FIRST
    family = LAGRANGE
    block = 0
  [../]
  [./stress_xx]
    order = CONSTANT
    family = MONOMIAL
    block = 0
  [../]
  [./stress_yy]
    order = CONSTANT
    family = MONOMIAL
    block = 0
  [../]
  [./stress_zz]
    order = CONSTANT
    family = MONOMIAL
    block = 0
  [../]
  [./stress_xy]
    order = CONSTANT
    family = MONOMIAL
    block = 0
  [../]
  [./stress_xz]
    order = CONSTANT
    family = MONOMIAL
    block = 0
  [../]
  [./stress_yz]
    order = CONSTANT
    family = MONOMIAL
    block = 0
  [../]
[]

[Kernels]
  [./diffusion]
    type = Diffusion
    variable = 'p'
    block = 1
  [../]
  [./inertia]
    type = AcousticInertia
    variable = p
    block = 1
  [../]
  [./DynamicTensorMechanics]
    displacements = 'disp_x disp_y disp_z'
    block = 0
  [../]
  [./inertia_x]
    type = InertialForce
    variable = disp_x
    block = 0
  [../]
  [./inertia_y]
    type = InertialForce
    variable = disp_y
    block = 0
  [../]
  [./inertia_z]
    type = InertialForce
    variable = disp_z
    block = 0
  [../]
[]

[AuxKernels]
  [./accel_x]
    type = TestNewmarkTI
    displacement = disp_x
    variable = accel_x
    first = false
    block = 0
  [../]
  [./vel_x]
    type = TestNewmarkTI
    displacement = disp_x
    variable = vel_x
    block = 0
  [../]
  [./accel_y]
    type = TestNewmarkTI
    displacement = disp_y
    variable = accel_y
    first = false
    block = 0
  [../]
  [./vel_y]
    type = TestNewmarkTI
    displacement = disp_y
    variable = vel_y
    block = 0
  [../]
  [./accel_z]
    type = TestNewmarkTI
    displacement = disp_z
    variable = accel_z
    first = false
    block = 0
  [../]
  [./vel_z]
    type = TestNewmarkTI
    displacement = disp_z
    variable = vel_z
    block = 0
  [../]
  [./stress_xx]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xx
    index_i = 0
    index_j = 0
    block = 0
  [../]
  [./stress_yy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yy
    index_i = 1
    index_j = 1
    block = 0
  [../]
  [./stress_zz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_zz
    index_i = 2
    index_j = 2
    block = 0
  [../]
  [./stress_xy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xy
    index_i = 0
    index_j = 1
    block = 0
  [../]
  [./stress_xz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xz
    index_i = 0
    index_j = 2
    block = 0
  [../]
  [./stress_yz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yz
    index_i = 1
    index_j = 2
    block = 0
  [../]
[]

[InterfaceKernels]
  [./interface1]
    type =  StructureAcousticInterface
    variable = p
    neighbor_var = disp_x
    boundary = 'interface1'
    D = 1e-6
    component = 0
  [../]
  [./interface2]
    type =  StructureAcousticInterface
    variable = p
    neighbor_var = disp_y
    boundary = 'interface1'
    D = 1e-6
    component = 1
  [../]
  [./interface3]
    type =  StructureAcousticInterface
    variable = p
    neighbor_var = disp_z
    boundary = 'interface1'
    D = 1e-6
    component = 2
  [../]
[]

[BCs]
  [./bottom_accel]
    type = FunctionDirichletBC
    variable = p
    boundary = 'right'
    function = accel_bottom
  [../]
  [./disp_x1]
    type = NeumannBC
    boundary = 'left'
    variable = disp_x
    value = 0.0
  [../]
  [./disp_y1]
    type = NeumannBC
    boundary = 'left'
    variable = disp_y
    value = 0.0
  [../]
  [./disp_z1]
    type = NeumannBC
    boundary = 'left'
    variable = disp_z
    value = 0.0
  [../]
[]

[Functions]
  [./accel_bottom]
    type = PiecewiseLinear
    data_file = ../1D_struc_acoustic/Input_1Peak_highF.csv
    scale_factor = 1e-2
    format = 'columns'
  [../]
[]

[Materials]
  [./co_sq]
    type = GenericConstantMaterial
    prop_names = inv_co_sq
    prop_values = 4.44e-7
    block = '1'
  [../]
  [./density0]
    type = GenericConstantMaterial
    block = 0
    prop_names = density
    prop_values = 1e-6
  [../]
  [./elasticity_base]
    type = ComputeIsotropicElasticityTensor
    bulk_modulus = 2.25
    shear_modulus = 0.0
    block = 0
  [../]
  [./strain]
    type = ComputeFiniteStrain
    block = 0
    displacements = 'disp_x disp_y disp_z'
  [../]
  [./stress]
    type =  ComputeFiniteStrainElasticStress
    block = 0
  [../]
[]

[Preconditioning]
  [./andy]
    type = SMP
    full = true
  [../]
[]

[Executioner]
  type = Transient
  solve_type = 'NEWTON'
  petsc_options_iname = '-pc_type -pc_factor_mat_solver_package'
  petsc_options_value = 'lu       superlu_dist'
  start_time = 0.0
  end_time = 0.005
  dt = 0.0001
  dtmin = 0.00001
  nl_abs_tol = 1e-8
  nl_rel_tol = 1e-8
  l_tol = 1e-8
  l_max_its = 25
  timestep_tolerance = 1e-8
  automatic_scaling = true
  [TimeIntegrator]
    type = NewmarkBeta
  []
[]

[Postprocessors]
  [./p1]
    type = PointValue
    point = '5.0 0.05 0.05'
    variable = p
  [../]
  [./stress_xx]
    type = PointValue
    point = '5.0 0.05 0.05'
    variable = stress_xx
  [../]
[]

[Outputs]
  csv = true
  perf_graph = true
  print_linear_residuals = true
[]

(modules/contact/test/tests/verification/patch_tests/brick_4/brick4_template2.i)

[GlobalParams]
  order = SECOND
  displacements = 'disp_x disp_y disp_z'
[]

[Mesh]
  file = brick4_mesh.e
[]

[Problem]
  type = AugmentedLagrangianContactProblem
  maximum_lagrangian_update_iterations = 200
  extra_tag_vectors = 'ref'
  reference_vector = 'ref'
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./disp_z]
  [../]
[]

[AuxVariables]
  [./stress_xx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_zz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./penetration]
  [../]
  [./saved_x]
  [../]
  [./saved_y]
  [../]
  [./saved_z]
  [../]
  [./diag_saved_x]
  [../]
  [./diag_saved_y]
  [../]
  [./diag_saved_z]
  [../]
  [./inc_slip_x]
  [../]
  [./inc_slip_y]
  [../]
  [./inc_slip_z]
  [../]
  [./accum_slip_x]
  [../]
  [./accum_slip_y]
  [../]
  [./accum_slip_z]
  [../]
[]

[Kernels]
  [./TensorMechanics]
    use_displaced_mesh = true
    save_in = 'saved_x saved_y saved_z'
    extra_vector_tags = 'ref'
  [../]
[]

[AuxKernels]
  [./stress_xx]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xx
    index_i = 0
    index_j = 0
    execute_on = timestep_end
  [../]
  [./stress_yy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yy
    index_i = 1
    index_j = 1
    execute_on = timestep_end
  [../]
  [./stress_xy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xy
    index_i = 0
    index_j = 1
    execute_on = timestep_end
  [../]
  [./stress_zz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_zz
    index_i = 2
    index_j = 2
    execute_on = timestep_end
  [../]
  [./inc_slip_x]
    type = PenetrationAux
    variable = inc_slip_x
    execute_on = timestep_begin
    boundary = 4
    paired_boundary = 3
  [../]
  [./inc_slip_y]
    type = PenetrationAux
    variable = inc_slip_y
    execute_on = timestep_begin
    boundary = 4
    paired_boundary = 3
  [../]
  [./accum_slip_x]
    type = PenetrationAux
    variable = accum_slip_x
    execute_on = timestep_end
    boundary = 4
    paired_boundary = 3
  [../]
  [./accum_slip_y]
    type = PenetrationAux
    variable = accum_slip_y
    execute_on = timestep_end
    boundary = 4
    paired_boundary = 3
  [../]
  [./penetration]
    type = PenetrationAux
    variable = penetration
    boundary = 4
    paired_boundary = 3
  [../]
[]

[Postprocessors]
  [./bot_react_x]
    type = NodalSum
    variable = saved_x
    boundary = 1
  [../]
  [./bot_react_y]
    type = NodalSum
    variable = saved_y
    boundary = 1
  [../]
  [./top_react_x]
    type = NodalSum
    variable = saved_x
    boundary = 5
  [../]
  [./top_react_y]
    type = NodalSum
    variable = saved_y
    boundary = 5
  [../]
  [./ref_resid_x]
    type = NodalL2Norm
    execute_on = timestep_end
    variable = saved_x
  [../]
  [./ref_resid_y]
    type = NodalL2Norm
    execute_on = timestep_end
    variable = saved_y
  [../]
  [./sigma_yy]
    type = ElementAverageValue
    variable = stress_yy
  [../]
  [./sigma_zz]
    type = ElementAverageValue
    variable = stress_zz
  [../]
  [./disp_x59]
    type = NodalVariableValue
    nodeid = 58
    variable = disp_x
  [../]
  [./disp_x64]
    type = NodalVariableValue
    nodeid = 63
    variable = disp_x
  [../]
  [./disp_y59]
    type = NodalVariableValue
    nodeid = 58
    variable = disp_y
  [../]
  [./disp_y64]
    type = NodalVariableValue
    nodeid = 63
    variable = disp_y
  [../]
  [./_dt]
    type = TimestepSize
  [../]
  [./num_lin_it]
    type = NumLinearIterations
  [../]
  [./num_nonlin_it]
    type = NumNonlinearIterations
  [../]
[]

[BCs]
  [./bot_y]
    type = DirichletBC
    variable = disp_y
    boundary = 1
    value = 0.0
  [../]
  [./side_x]
    type = DirichletBC
    variable = disp_x
    boundary = 2
    value = 0.0
  [../]
  [./back_z]
    type = DirichletBC
    variable = disp_z
    boundary = 6
    value = 0.0
  [../]
  [./top_press]
    type = Pressure
    variable = disp_y
    boundary = 5
    factor = 109.89
  [../]
[]

[Materials]
  [./bot_elas_tens]
    type = ComputeIsotropicElasticityTensor
    block = '1'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./bot_strain]
    type = ComputeFiniteStrain
    block = '1'
  [../]
  [./bot_stress]
    type = ComputeFiniteStrainElasticStress
    block = '1'
  [../]
  [./top_elas_tens]
    type = ComputeIsotropicElasticityTensor
    block = '2'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./top_strain]
    type = ComputeFiniteStrain
    block = '2'
  [../]
  [./top_stress]
    type = ComputeFiniteStrainElasticStress
    block = '2'
  [../]
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'

  petsc_options_iname = '-pc_type -pc_factor_mat_solver_type'
  petsc_options_value = 'lu     superlu_dist'

  line_search = 'none'

  nl_abs_tol = 1e-7
  nl_rel_tol = 1e-6
  l_max_its = 50
  nl_max_its = 100
  dt = 1.0
  end_time = 1.0
  num_steps = 10
  dtmin = 1.0
  l_tol = 1e-4
[]

[VectorPostprocessors]
  [./x_disp]
    type = NodalValueSampler
    variable = disp_x
    boundary = '1 3 4 5'
    sort_by = id
  [../]
  [./y_disp]
    type = NodalValueSampler
    variable = disp_y
    boundary = '1 3 4 5'
    sort_by = id
  [../]
  [./cont_press]
    type = NodalValueSampler
    variable = contact_pressure
    boundary = '3'
    sort_by = id
  [../]
[]

[Outputs]
  print_linear_residuals = true
  perf_graph = true
  [./exodus]
    type = Exodus
    elemental_as_nodal = true
  [../]
  [./console]
    type = Console
    max_rows = 5
  [../]
  [./chkfile]
    type = CSV
    show = 'bot_react_x bot_react_y disp_x59 disp_y59 disp_x64 disp_y64 stress_yy stress_zz top_react_x top_react_y x_disp y_disp cont_press'
    execute_vector_postprocessors_on = timestep_end
  [../]
  [./outfile]
    type = CSV
    delimiter = ' '
    execute_vector_postprocessors_on = none
  [../]
[]

[Contact]
  [./leftright]
    secondary = 3
    primary = 4
    normalize_penalty = true
    tangential_tolerance = 1e-3
    penalty = 1e+9
    al_penetration_tolerance = 1e-8
  [../]
[]

(modules/contact/test/tests/explicit_dynamics/settlement.i)

# One element test to test the central difference time integrator in 3D.
[GlobalParams]
  displacements = 'disp_x disp_y disp_z'
  volumetric_locking_correction = true
[]

[Mesh]
  [block_one]
    type = GeneratedMeshGenerator
    dim = 3
    nx = 3
    ny = 3
    nz = 3
    xmin = 4.5
    xmax = 5.5
    ymin = 4.5
    ymax = 5.5
    zmin = 0.0001
    zmax = 1.0001
    boundary_name_prefix = 'ball'
  []
  [block_two]
    type = GeneratedMeshGenerator
    dim = 3
    nx = 2
    ny = 2
    nz = 2
    xmin = 0.0
    xmax = 10
    ymin = 0.0
    ymax = 10
    zmin = -2
    zmax = 0
    boundary_name_prefix = 'base'
    boundary_id_offset = 10
  []
  [block_one_id]
    type = SubdomainIDGenerator
    input = block_one
    subdomain_id = 1
  []
  [block_two_id]
    type = SubdomainIDGenerator
    input = block_two
    subdomain_id = 2
  []
  [combine]
    type = MeshCollectionGenerator
    inputs = ' block_one_id block_two_id'
  []
[]

[AuxVariables]
  [penetration]
  []
[]

[AuxKernels]
  [penetration]
    type = PenetrationAux
    variable = penetration
    boundary = ball_back
    paired_boundary = base_front
    quantity = distance
  []
[]

[Variables]
  [disp_x]
  []
  [disp_y]
  []
  [disp_z]
  []
[]

[AuxVariables]
  [gap_rate]
  []
  [vel_x]
  []
  [accel_x]
  []
  [vel_y]
  []
  [accel_y]
  []
  [vel_z]
  []
  [accel_z]
  []
  [stress_zz]
    family = MONOMIAL
    order = CONSTANT
  []
  [strain_zz]
    family = MONOMIAL
    order = CONSTANT
  []
  [kinetic_energy_one]
    order = CONSTANT
    family = MONOMIAL
  []
  [elastic_energy_one]
    order = CONSTANT
    family = MONOMIAL
  []
  [kinetic_energy_two]
    order = CONSTANT
    family = MONOMIAL
  []
  [elastic_energy_two]
    order = CONSTANT
    family = MONOMIAL
  []
[]

[AuxKernels]
  [stress_zz]
    type = RankTwoAux
    rank_two_tensor = stress
    index_i = 2
    index_j = 2
    variable = stress_zz
    execute_on = 'TIMESTEP_END'
  []
  [strain_zz]
    type = RankTwoAux
    rank_two_tensor = mechanical_strain
    index_i = 2
    index_j = 2
    variable = strain_zz
  []
  [accel_x]
    type = TestNewmarkTI
    variable = accel_x
    displacement = disp_x
    first = false
    execute_on = 'LINEAR TIMESTEP_BEGIN TIMESTEP_END'
  []
  [vel_x]
    type = TestNewmarkTI
    variable = vel_x
    displacement = disp_x
    execute_on = 'LINEAR TIMESTEP_BEGIN TIMESTEP_END'
  []
  [accel_y]
    type = TestNewmarkTI
    variable = accel_y
    displacement = disp_y
    first = false
    execute_on = 'LINEAR TIMESTEP_BEGIN TIMESTEP_END'
  []
  [vel_y]
    type = TestNewmarkTI
    variable = vel_y
    displacement = disp_x
    execute_on = 'LINEAR TIMESTEP_BEGIN TIMESTEP_END'
  []
  [accel_z]
    type = TestNewmarkTI
    variable = accel_z
    displacement = disp_z
    first = false
    execute_on = 'LINEAR TIMESTEP_BEGIN TIMESTEP_END'
  []
  [vel_z]
    type = TestNewmarkTI
    variable = vel_z
    displacement = disp_z
    execute_on = 'LINEAR TIMESTEP_BEGIN TIMESTEP_END'
  []
  [kinetic_energy_one]
    type = KineticEnergyAux
    block = '1'
    variable = kinetic_energy_one
    newmark_velocity_x = vel_x
    newmark_velocity_y = vel_y
    newmark_velocity_z = vel_z
    density = density
  []
  [elastic_energy_one]
    type = ElasticEnergyAux
    variable = elastic_energy_one
    block = '1'
  []
  [kinetic_energy_two]
    type = KineticEnergyAux
    block = '2'
    variable = kinetic_energy_two
    newmark_velocity_x = vel_x
    newmark_velocity_y = vel_y
    newmark_velocity_z = vel_z
    density = density
  []
  [elastic_energy_two]
    type = ElasticEnergyAux
    variable = elastic_energy_two
    block = '2'
  []
[]

[Kernels]
  [DynamicTensorMechanics]
    displacements = 'disp_x disp_y disp_z'
    stiffness_damping_coefficient = 1.0e-3
    generate_output = 'stress_zz strain_zz'
  []
  [inertia_x]
    type = InertialForce
    variable = disp_x
  []
  [inertia_y]
    type = InertialForce
    variable = disp_y
  []
  [inertia_z]
    type = InertialForce
    variable = disp_z
  []
  [gravity]
    type = Gravity
    variable = disp_z
    value = -98.10
  []
[]

[BCs]
  [x_front]
    type = DirichletBC
    variable = disp_x
    boundary = 'ball_front'
    preset = false
    value = 0.0
  []
  [y_front]
    type = DirichletBC
    variable = disp_y
    boundary = 'ball_front'
    preset = false
    value = 0.0
  []
  [x_fixed]
    type = DirichletBC
    variable = disp_x
    boundary = 'base_back'
    preset = false
    value = 0.0
  []
  [y_fixed]
    type = DirichletBC
    variable = disp_y
    boundary = 'base_back'
    preset = false
    value = 0.0
  []
  [z_fixed]
    type = DirichletBC
    variable = disp_z
    boundary = 'base_back'
    preset = false
    value = 0.0
  []
  [z_fixed_front]
    type = DirichletBC
    variable = disp_z
    boundary = 'base_front'
    preset = false
    value = 0.0
  []
[]

[ExplicitDynamicsContact]
  [my_contact]
    model = frictionless_balance
    primary = base_front
    secondary = ball_back
    vel_x = 'vel_x'
    vel_y = 'vel_y'
    vel_z = 'vel_z'
  []
[]

[Materials]
  [elasticity_tensor_block_one]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 1e6
    poissons_ratio = 0.0
    block = 1
    outputs = 'exodus'
    output_properties = __all__
  []
  [elasticity_tensor_block_two]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 1e10
    poissons_ratio = 0.0
    block = 2
    outputs = 'exodus'
    output_properties = __all__
  []
  [strain_block]
    type = ComputeFiniteStrain # ComputeIncrementalSmallStrain
    displacements = 'disp_x disp_y disp_z'
    implicit = false
  []
  [stress_block]
    type = ComputeFiniteStrainElasticStress
  []
  [density_one]
    type = GenericConstantMaterial
    prop_names = density
    prop_values = 1e1
    outputs = 'exodus'
    output_properties = 'density'
    block = '1'
  []
  [density_two]
    type = GenericConstantMaterial
    prop_names = density
    prop_values = 1e6
    outputs = 'exodus'
    output_properties = 'density'
    block = '2'
  []
  [wave_speed]
    type = WaveSpeed
    outputs = 'exodus'
    output_properties = 'wave_speed'
  []
[]

[Executioner]
  type = Transient
  start_time = -0.01
  end_time = 0.04
  dt = 1.0e-4
  timestep_tolerance = 1e-6

  [TimeIntegrator]
    type = CentralDifference
    solve_type = lumped
  []
[]

[Outputs]
  interval = 1
  exodus = true
  csv = true
  execute_on = 'TIMESTEP_END'
[]

[Postprocessors]
  [accel_58z]
    type = NodalVariableValue
    nodeid = 1
    variable = accel_z
  []
  [vel_58z]
    type = NodalVariableValue
    nodeid = 1
    variable = vel_z
  []
  [critical_time_step]
    type = CriticalTimeStep
  []
  [contact_pressure_max]
    type = NodalExtremeValue
    variable = contact_pressure
    block = '1 2'
    value_type = max
  []
  [penetration_max]
    type = NodalExtremeValue
    variable = penetration
    block = '1 2'
    value_type = max
  []
  [total_kinetic_energy_one]
    type = ElementIntegralVariablePostprocessor
    variable = kinetic_energy_one
    block = '1'
  []
  [total_elastic_energy_one]
    type = ElementIntegralVariablePostprocessor
    variable = elastic_energy_one
    block = '1'
  []
  [total_kinetic_energy_two]
    type = ElementIntegralVariablePostprocessor
    variable = kinetic_energy_two
    block = '2'
  []
  [total_elastic_energy_two]
    type = ElementIntegralVariablePostprocessor
    variable = elastic_energy_two
    block = '2'
  []
[]

(modules/solid_mechanics/test/tests/finite_strain_tensor_mechanics_tests/finite_strain_patch.i)

# Patch Test
# This test is designed to compute constant xx, yy, zz, xy, yz, and zx
# stress on a set of irregular hexes.  The mesh is composed of one
# block with seven elements.  The elements form a unit cube with one
# internal element.  There is a nodeset for each exterior node.
# The cube is displaced by 1e-6 units in x, 2e-6 in y, and 3e-6 in z.
# The faces are sheared as well (1e-6, 2e-6, and 3e-6 for xy, yz, and
# zx).  This gives a uniform strain/stress state for all six unique
# tensor components.
# With Young's modulus at 1e6 and Poisson's ratio at 0, the shear
# modulus is 5e5 (G=E/2/(1+nu)).  Therefore,
#
# stress xx = 1e6 * 1e-6 = 1
# stress yy = 1e6 * 2e-6 = 2
# stress zz = 1e6 * 3e-6 = 3
# stress xy = 2 * 5e5 * 1e-6 / 2 = 0.5
# (2 * G   * gamma_xy / 2 = 2 * G * epsilon_xy)
# stress yz = 2 * 5e5 * 2e-6 / 2 = 1
# stress zx = 2 * 5e5 * 3e-6 / 2 = 1.5

[Mesh]
  # Comment
  # Mesh
  file = patch_mesh.e
[]

[GlobalParams]
  displacements = 'disp_x disp_y disp_z'
[]

[Functions]
  # Functions
  [./rampConstant1]
    type = PiecewiseLinear
    x = '0. 1. 2.'
    y = '0. 1. 1.'
    scale_factor = 1e-6
  [../]
  [./rampConstant2]
    type = PiecewiseLinear
    x = '0. 1. 2.'
    y = '0. 1. 1.'
    scale_factor = 2e-6
  [../]
  [./rampConstant3]
    type = PiecewiseLinear
    x = '0. 1. 2.'
    y = '0. 1. 1.'
    scale_factor = 3e-6
  [../]
  [./rampConstant4]
    type = PiecewiseLinear
    x = '0. 1. 2.'
    y = '0. 1. 1.'
    scale_factor = 4e-6
  [../]
  [./rampConstant6]
    type = PiecewiseLinear
    x = '0. 1. 2.'
    y = '0. 1. 1.'
    scale_factor = 6e-6
  [../]
[]

[Variables]
  # Variables
  [./disp_x]
    order = FIRST
    family = LAGRANGE
  [../]
  [./disp_y]
    order = FIRST
    family = LAGRANGE
  [../]
  [./disp_z]
    order = FIRST
    family = LAGRANGE
  [../]
[]

[AuxVariables]
  # AuxVariables
  [./stress_xx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_zz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_zx]
    order = CONSTANT
    family = MONOMIAL
  [../]
[]

[Kernels]
  [SolidMechanics]
    use_displaced_mesh = true
  [../]
[]

[AuxKernels]
  # AuxKernels
  [./stress_xx]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xx
    index_i = 0
    index_j = 0
  [../]
  [./stress_yy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yy
    index_i = 1
    index_j = 1
  [../]
  [./stress_zz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_zz
    index_i = 2
    index_j = 2
  [../]
  [./stress_xy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xy
    index_i = 0
    index_j = 1
  [../]
  [./stress_yz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yz
    index_i = 1
    index_j = 2
  [../]
  [./stress_zx]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_zx
    index_i = 2
    index_j = 0
  [../]
[]

[BCs]
  # BCs
  [./node1_x]
    type = DirichletBC
    variable = disp_x
    boundary = 1
    value = 0.0
  [../]
  [./node1_y]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = 1
    function = rampConstant2
  [../]
  [./node1_z]
    type = FunctionDirichletBC
    variable = disp_z
    boundary = 1
    function = rampConstant3
  [../]
  [./node2_x]
    type = FunctionDirichletBC
    variable = disp_x
    boundary = 2
    function = rampConstant1
  [../]
  [./node2_y]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = 2
    function = rampConstant2
  [../]
  [./node2_z]
    type = FunctionDirichletBC
    variable = disp_z
    boundary = 2
    function = rampConstant6
  [../]
  [./node3_x]
    type = FunctionDirichletBC
    variable = disp_x
    boundary = 3
    function = rampConstant1
  [../]
  [./node3_y]
    type = DirichletBC
    variable = disp_y
    boundary = 3
    value = 0.0
  [../]
  [./node3_z]
    type = FunctionDirichletBC
    variable = disp_z
    boundary = 3
    function = rampConstant3
  [../]
  [./node4_x]
    type = DirichletBC
    variable = disp_x
    boundary = 4
    value = 0.0
  [../]
  [./node4_y]
    type = DirichletBC
    variable = disp_y
    boundary = 4
    value = 0.0
  [../]
  [./node4_z]
    type = DirichletBC
    variable = disp_z
    boundary = 4
    value = 0.0
  [../]
  [./node5_x]
    type = FunctionDirichletBC
    variable = disp_x
    boundary = 5
    function = rampConstant1
  [../]
  [./node5_y]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = 5
    function = rampConstant4
  [../]
  [./node5_z]
    type = FunctionDirichletBC
    variable = disp_z
    boundary = 5
    function = rampConstant3
  [../]
  [./node6_x]
    type = FunctionDirichletBC
    variable = disp_x
    boundary = 6
    function = rampConstant2
  [../]
  [./node6_y]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = 6
    function = rampConstant4
  [../]
  [./node6_z]
    type = FunctionDirichletBC
    variable = disp_z
    boundary = 6
    function = rampConstant6
  [../]
  [./node7_x]
    type = FunctionDirichletBC
    variable = disp_x
    boundary = 7
    function = rampConstant2
  [../]
  [./node7_y]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = 7
    function = rampConstant2
  [../]
  [./node7_z]
    type = FunctionDirichletBC
    variable = disp_z
    boundary = 7
    function = rampConstant3
  [../]
  [./node8_x]
    type = FunctionDirichletBC
    variable = disp_x
    boundary = 8
    function = rampConstant1
  [../]
  [./node8_y]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = 8
    function = rampConstant2
  [../]
  [./node8_z]
    type = DirichletBC
    variable = disp_z
    boundary = 8
    value = 0.0
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeElasticityTensor
    block = '1 2 3 4 5 6 7'
    C_ijkl = '1.0e6  0.0   0.0 1.0e6  0.0  1.0e6 0.5e6 0.5e6 0.5e6'
    fill_method = symmetric9
  [../]
  [./strain]
    type = ComputeFiniteStrain
    block = '1 2 3 4 5 6 7'
    displacements = 'disp_x disp_y disp_z'
  [../]
  [./stress]
    type = ComputeFiniteStrainElasticStress
    block = '1 2 3 4 5 6 7'
  [../]
[]

[Preconditioning]
  [./SMP]
    type = SMP
    full = true
  [../]
[]

[Executioner]
  # Executioner
  type = Transient

  solve_type = 'NEWTON'


  nl_abs_tol = 1e-10
  l_max_its = 20
  start_time = 0.0
  dt = 1.0
  num_steps = 2
  petsc_options_iname = -pc_type
  petsc_options_value = lu
  end_time = 2.0
[]

[Outputs]
  exodus = true
[] # Output

(modules/contact/test/tests/mortar_aux_kernels/block-dynamics-aux-fretting-wear-test-projection_angle.i)

starting_point = 0.5e-1
offset = -0.045

[GlobalParams]
  displacements = 'disp_x disp_y'
[]

[Mesh]
  file = long-bottom-block-1elem-blocks-multiple-projections-lowerd.e
[]

[Variables]
  [disp_x]
    block = '1 2'
  []
  [disp_y]
    block = '1 2'
  []
  [normal_lm]
    block = 3
    use_dual = true
  #  scaling = 1.0e-5
  []
  [frictional_lm]
    block = 3
    use_dual = true
  #  scaling = 1.0e-5
  []
[]

[ICs]
  [disp_y]
    block = 2
    variable = disp_y
    value = '${fparse starting_point + offset}'
    type = ConstantIC
  []
[]

[Kernels]
  [DynamicTensorMechanics]
    displacements = 'disp_x disp_y'
    generate_output = 'stress_xx stress_yy'
    strain = FINITE
    block = '1 2'
    zeta = 1.0
    hht_alpha = 0.0
  []
  [inertia_x]
    type = InertialForce
    variable = disp_x
    velocity = vel_x
    acceleration = accel_x
    beta = 0.25
    gamma = 0.5
    alpha = 0
    eta = 0.0
    block = '1 2'
  []
  [inertia_y]
    type = InertialForce
    variable = disp_y
    velocity = vel_y
    acceleration = accel_y
    beta = 0.25
    gamma = 0.5
    alpha = 0
    eta = 0.0
    block = '1 2'
  []
[]

[Materials]
  [elasticity_2]
    type = ComputeIsotropicElasticityTensor
    block = '2'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  []
  [elasticity_1]
    type = ComputeIsotropicElasticityTensor
    block = '1'
    youngs_modulus = 1e8
    poissons_ratio = 0.3
  []
  [stress]
    type = ComputeFiniteStrainElasticStress
    block = '1 2'
  []
  [strain]
    type = ComputeFiniteStrain
    block = '1 2'
  []
  [density]
    type = GenericConstantMaterial
    block = '1 2'
    prop_names = 'density'
    prop_values = '7750'
  []
[]

[AuxVariables]
  [worn_depth]
    block = '3'
  []
  [gap_vel]
    block = '3'
  []
  [vel_x]
    block = '1 2'
  []
  [accel_x]
    block = '1 2'
  []
  [vel_y]
    block = '1 2'
  []
  [accel_y]
    block = '1 2'
  []
  [vel_z]
    block = '1 2'
  []
  [accel_z]
    block = '1 2'
  []
[]

[AuxKernels]
  [gap_vel]
    type = WeightedGapVelAux
    variable = gap_vel
    primary_boundary = 20
    secondary_boundary = 10
    primary_subdomain = 4
    secondary_subdomain = 3
    disp_x = disp_x
    disp_y = disp_y
    debug_mesh = true
    minimum_projection_angle = 0.0
  []
  [worn_depth]
    type = MortarArchardsLawAux
    variable = worn_depth
    primary_boundary = 20
    secondary_boundary = 10
    primary_subdomain = 4
    secondary_subdomain = 3
    displacements = 'disp_x disp_y'
    friction_coefficient = 0.5
    energy_wear_coefficient = 1.0e-6
    normal_pressure = normal_lm
    execute_on = 'TIMESTEP_END'
    debug_mesh = true
    minimum_projection_angle = 0.0
  []
  [accel_x]
    type = NewmarkAccelAux
    variable = accel_x
    displacement = disp_x
    velocity = vel_x
    beta = 0.25
    execute_on = 'linear timestep_end'
  []
  [vel_x]
    type = NewmarkVelAux
    variable = vel_x
    acceleration = accel_x
    gamma = 0.5
    execute_on = 'linear timestep_end'
  []
  [accel_y]
    type = NewmarkAccelAux
    variable = accel_y
    displacement = disp_y
    velocity = vel_y
    beta = 0.25
    execute_on = 'linear timestep_end'
  []
  [vel_y]
    type = NewmarkVelAux
    variable = vel_y
    acceleration = accel_y
    gamma = 0.5
    execute_on = 'linear timestep_end'
  []
[]

[UserObjects]
  [weighted_vel_uo]
    type = LMWeightedVelocitiesUserObject
    primary_boundary = 20
    secondary_boundary = 10
    primary_subdomain = 4
    secondary_subdomain = 3
    secondary_variable = disp_x
    lm_variable_normal = normal_lm
    lm_variable_tangential_one = frictional_lm
    disp_x = disp_x
    disp_y = disp_y
    debug_mesh = true
  []
[]

[Constraints]
  [weighted_gap_lm]
    type = ComputeDynamicFrictionalForceLMMechanicalContact
    primary_boundary = 20
    secondary_boundary = 10
    primary_subdomain = 4
    secondary_subdomain = 3
    variable = normal_lm
    disp_x = disp_x
    disp_y = disp_y
    use_displaced_mesh = true
    wear_depth = worn_depth
    c = 1e6
    c_t = 1e6
    normalize_c = true
    mu = 0.5
    friction_lm = frictional_lm
    capture_tolerance = 1.0e-5
    newmark_beta = 0.25
    newmark_gamma = 0.5
    debug_mesh = true
    minimum_projection_angle = 0.0
  []
  [normal_x]
    type = NormalMortarMechanicalContact
    primary_boundary = 20
    secondary_boundary = 10
    primary_subdomain = 4
    secondary_subdomain = 3
    variable = normal_lm
    secondary_variable = disp_x
    component = x
    use_displaced_mesh = true
    compute_lm_residuals = false
    debug_mesh = true
    minimum_projection_angle = 0.0
    weighted_gap_uo = weighted_vel_uo
  []
  [normal_y]
    type = NormalMortarMechanicalContact
    primary_boundary = 20
    secondary_boundary = 10
    primary_subdomain = 4
    secondary_subdomain = 3
    variable = normal_lm
    secondary_variable = disp_y
    component = y
    use_displaced_mesh = true
    compute_lm_residuals = false
    debug_mesh = true
    minimum_projection_angle = 0.0
    weighted_gap_uo = weighted_vel_uo
  []
  [tangential_x]
    type = TangentialMortarMechanicalContact
    primary_boundary = 20
    secondary_boundary = 10
    primary_subdomain = 4
    secondary_subdomain = 3
    variable = frictional_lm
    secondary_variable = disp_x
    component = x
    use_displaced_mesh = true
    compute_lm_residuals = false
    debug_mesh = true
    minimum_projection_angle = 0.0
    weighted_velocities_uo = weighted_vel_uo
  []
  [tangential_y]
    type = TangentialMortarMechanicalContact
    primary_boundary = 20
    secondary_boundary = 10
    primary_subdomain = 4
    secondary_subdomain = 3
    variable = frictional_lm
    secondary_variable = disp_y
    component = y
    use_displaced_mesh = true
    compute_lm_residuals = false
    debug_mesh = true
    minimum_projection_angle = 0.0
    weighted_velocities_uo = weighted_vel_uo
  []
[]

[BCs]
  [botx]
    type = DirichletBC
    variable = disp_x
    boundary = 40
    value = 0.0
  []
  [boty]
    type = DirichletBC
    variable = disp_y
    boundary = 40
    value = 0.0
  []
  [topy]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = 30
    function = '${starting_point} * cos(4.0 * pi / 4 * t) + ${offset}'
  []
  [leftx]
    type = FunctionDirichletBC
    variable = disp_x
    boundary = 50
    function = '1e-2 * (cos(32.0 * pi / 4 * t) - 1.0)'
  []
[]

[Executioner]
  type = Transient
  end_time = 0.0
  dt = 0.05
  dtmin = .002
  solve_type = 'NEWTON'
  petsc_options = '-snes_converged_reason -ksp_converged_reason -pc_svd_monitor '
                  '-snes_linesearch_monitor -snes_ksp_ew'
  petsc_options_iname = '-pc_type -pc_factor_mat_solver_type -pc_factor_shift_type -pc_factor_shift_amount'
  petsc_options_value = 'lu       superlu_dist                  NONZERO               1e-15'
  nl_max_its = 40
  l_max_its = 15
  line_search = 'l2'
  snesmf_reuse_base = true

  [TimeIntegrator]
    type = NewmarkBeta
    beta = 0.25
    gamma = 0.5
  []
[]

[Debug]
  show_var_residual_norms = true
[]

[Outputs]
  exodus = true
  checkpoint = true
[]

[Preconditioning]
  [smp]
    type = SMP
    full = true
  []
[]

[Postprocessors]
  active = 'num_nl cumulative contact'
  [num_nl]
    type = NumNonlinearIterations
  []
  [cumulative]
    type = CumulativeValuePostprocessor
    postprocessor = num_nl
  []
  [contact]
    type = ContactDOFSetSize
    variable = normal_lm
    subdomain = '3'
    execute_on = 'nonlinear timestep_end'
  []
[]

(modules/solid_mechanics/test/tests/crystal_plasticity/user_object_based/user_object_Voce_BCC.i)

[Mesh]
  type = GeneratedMesh
  dim = 2
  elem_type = QUAD4
  displacements = 'disp_x disp_y'
  nx = 2
  ny = 2
[]

[GlobalParams]
  volumetric_locking_correction = true
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
[]

[Kernels]
  [SolidMechanics]
    displacements = 'disp_x disp_y'
    use_displaced_mesh = true
  [../]
[]

[AuxVariables]
  [./stress_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./e_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./fp_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./gss]
    order = CONSTANT
    family = MONOMIAL
  [../]
[]

[Functions]
  [./tdisp]
    type = ParsedFunction
    expression = 0.01*t
  [../]
[]

[UserObjects]
  [./prop_read]
    type = PropertyReadFile
    prop_file_name = 'euler_ang_file.txt'
    # Enter file data as prop#1, prop#2, .., prop#nprop
    nprop = 3
    read_type = element
  [../]
[]

[AuxKernels]
  [./stress_yy]
    type = RankTwoAux
    variable = stress_yy
    rank_two_tensor = stress
    index_j = 1
    index_i = 1
    execute_on = timestep_end
  [../]
  [./e_yy]
    type = RankTwoAux
    variable = e_yy
    rank_two_tensor = lage
    index_j = 1
    index_i = 1
    execute_on = timestep_end
  [../]
  [./fp_yy]
    type = RankTwoAux
    variable = fp_yy
    rank_two_tensor = fp
    index_j = 1
    index_i = 1
    execute_on = timestep_end
  [../]
  [./gss]
    type = MaterialStdVectorAux
    variable = gss
    property = state_var_gss
    index = 0
    execute_on = timestep_end
  [../]
[]

[BCs]
  [./fix_x]
    type = DirichletBC
    variable = disp_x
    boundary = 'left'
    value = 0
  [../]
  [./fix_y]
    type = DirichletBC
    variable = disp_y
    boundary = 'bottom'
    value = 0
  [../]
  [./tdisp]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = top
    function = tdisp
  [../]
[]

[UserObjects]
  [./slip_rate_gss]
    type = CrystalPlasticitySlipRateGSS
    variable_size = 48
    slip_sys_file_name = input_slip_sys_bcc48.txt
    num_slip_sys_flowrate_props = 2
    flowprops = '1 12 0.001 0.1 13 24 0.001 0.1 25 48 0.001 0.1'
    uo_state_var_name = state_var_gss
  [../]
  [./slip_resistance_gss]
    type = CrystalPlasticitySlipResistanceGSS
    variable_size = 48
    uo_state_var_name = state_var_gss
  [../]
  [./state_var_gss]
    type = CrystalPlasticityStateVariable
    variable_size = 48
    groups = '0 12 24 48'
    group_values =  '50 51 52'
    uo_state_var_evol_rate_comp_name = state_var_evol_rate_comp_voce
    scale_factor = 1.0
  [../]
  [./state_var_evol_rate_comp_voce]
    type = CrystalPlasticityStateVarRateComponentVoce
    variable_size = 48
    crystal_lattice_type = 'BCC'
    groups = '0 12 24 48'
    h0_group_values = '1 2 3'
    tau0_group_values = '50 51 52'
    tauSat_group_values = '70 81 92'
    hardeningExponent_group_values = '1 2 3'
    selfHardening_group_values ='4 5 6'
    coplanarHardening_group_values='7 8 9'
    GroupGroup_Hardening_group_values = '10 20 30
                                         40 50 60
                                         70 80 90'
    uo_slip_rate_name = slip_rate_gss
    uo_state_var_name = state_var_gss
  [../]
[]

[Materials]
  [./crysp]
    type = FiniteStrainUObasedCP
    stol = 1e-2
    tan_mod_type = exact
    uo_slip_rates = 'slip_rate_gss'
    uo_slip_resistances = 'slip_resistance_gss'
    uo_state_vars = 'state_var_gss'
    uo_state_var_evol_rate_comps = 'state_var_evol_rate_comp_voce'
  [../]
  [./strain]
    type = ComputeFiniteStrain
    displacements = 'disp_x disp_y'
  [../]
  [./elasticity_tensor]
    type = ComputeElasticityTensorCP
    C_ijkl = '1.684e5 1.214e5 1.214e5 1.684e5 1.214e5 1.684e5 0.754e5 0.754e5 0.754e5'
    fill_method = symmetric9
    read_prop_user_object = prop_read
  [../]
[]

[Postprocessors]
  [./stress_yy]
    type = ElementAverageValue
    variable = stress_yy
  [../]
  [./e_yy]
    type = ElementAverageValue
    variable = e_yy
  [../]
  [./fp_yy]
    type = ElementAverageValue
    variable = fp_yy
  [../]
  [./gss]
    type = ElementAverageValue
    variable = gss
  [../]
[]

[Preconditioning]
  [./smp]
    type = SMP
    full = true
  [../]
[]

[Executioner]
  type = Transient
  dt = 0.01
  solve_type = 'PJFNK'

  petsc_options_iname = -pc_hypre_type
  petsc_options_value = boomerang
  nl_abs_tol = 1e-10
  nl_rel_step_tol = 1e-10
  dtmax = 10.0
  nl_rel_tol = 1e-10
  end_time = 1
  dtmin = 0.01
  num_steps = 10
  nl_abs_step_tol = 1e-10
[]

[Outputs]
  exodus = true
[]

(modules/contact/test/tests/verification/patch_tests/brick_1/brick1_mu_0_2_pen.i)

[GlobalParams]
  volumetric_locking_correction = true
  displacements = 'disp_x disp_y disp_z'
[]

[Mesh]
  file = brick1_mesh.e
[]

[Problem]
  type = ReferenceResidualProblem
  extra_tag_vectors = 'ref'
  reference_vector = 'ref'
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./disp_z]
  [../]
[]

[AuxVariables]
  [./stress_xx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_zz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./penetration]
  [../]
  [./saved_x]
  [../]
  [./saved_y]
  [../]
  [./saved_z]
  [../]
  [./diag_saved_x]
  [../]
  [./diag_saved_y]
  [../]
  [./diag_saved_z]
  [../]
  [./inc_slip_x]
  [../]
  [./inc_slip_y]
  [../]
  [./inc_slip_z]
  [../]
  [./accum_slip_x]
  [../]
  [./accum_slip_y]
  [../]
  [./accum_slip_z]
  [../]
  [./tang_force_x]
  [../]
  [./tang_force_y]
  [../]
  [./tang_force_z]
  [../]
[]

[Kernels]
  [./TensorMechanics]
    use_displaced_mesh = true
    save_in = 'saved_x saved_y saved_z'
    extra_vector_tags = 'ref'
  [../]
[]

[AuxKernels]
  [./stress_xx]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xx
    index_i = 0
    index_j = 0
    execute_on = timestep_end
  [../]
  [./stress_yy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yy
    index_i = 1
    index_j = 1
    execute_on = timestep_end
  [../]
  [./stress_xy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xy
    index_i = 0
    index_j = 1
    execute_on = timestep_end
  [../]
  [./stress_zz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_zz
    index_i = 2
    index_j = 2
    execute_on = timestep_end
  [../]
  [./inc_slip_x]
    type = PenetrationAux
    variable = inc_slip_x
    execute_on = timestep_end
    boundary = 3
    paired_boundary = 4
  [../]
  [./inc_slip_y]
    type = PenetrationAux
    variable = inc_slip_y
    execute_on = timestep_end
    boundary = 3
    paired_boundary = 4
  [../]
  [./accum_slip_x]
    type = PenetrationAux
    variable = accum_slip_x
    execute_on = timestep_end
    boundary = 3
    paired_boundary = 4
  [../]
  [./accum_slip_y]
    type = PenetrationAux
    variable = accum_slip_y
    execute_on = timestep_end
    boundary = 3
    paired_boundary = 4
  [../]
  [./penetration]
    type = PenetrationAux
    variable = penetration
    boundary = 3
    paired_boundary = 4
  [../]
  [./tang_force_x]
    type = PenetrationAux
    variable = tang_force_x
    quantity = tangential_force_x
    boundary = 3
    paired_boundary = 4
  [../]
  [./tang_force_y]
    type = PenetrationAux
    variable = tang_force_y
    quantity = tangential_force_y
    boundary = 3
    paired_boundary = 4
  [../]
[]

[Postprocessors]
  [./bot_react_x]
    type = NodalSum
    variable = saved_x
    boundary = 1
  [../]
  [./bot_react_y]
    type = NodalSum
    variable = saved_y
    boundary = 1
  [../]
  [./top_react_x]
    type = NodalSum
    variable = saved_x
    boundary = 5
  [../]
  [./top_react_y]
    type = NodalSum
    variable = saved_y
    boundary = 5
  [../]
  [./ref_resid_x]
    type = NodalL2Norm
    execute_on = timestep_end
    variable = saved_x
  [../]
  [./ref_resid_y]
    type = NodalL2Norm
    execute_on = timestep_end
    variable = saved_y
  [../]
  [./sigma_yy]
    type = ElementAverageValue
    variable = stress_yy
  [../]
  [./sigma_zz]
    type = ElementAverageValue
    variable = stress_zz
  [../]
  [./disp_x5]
    type = NodalVariableValue
    nodeid = 4
    variable = disp_x
  [../]
  [./disp_x8]
    type = NodalVariableValue
    nodeid = 7
    variable = disp_x
  [../]
  [./disp_x13]
    type = NodalVariableValue
    nodeid = 12
    variable = disp_x
  [../]
  [./disp_x16]
    type = NodalVariableValue
    nodeid = 15
    variable = disp_x
  [../]
  [./disp_y5]
    type = NodalVariableValue
    nodeid = 4
    variable = disp_y
  [../]
  [./disp_y8]
    type = NodalVariableValue
    nodeid = 7
    variable = disp_y
  [../]
  [./disp_y13]
    type = NodalVariableValue
    nodeid = 12
    variable = disp_y
  [../]
  [./disp_y16]
    type = NodalVariableValue
    nodeid = 15
    variable = disp_y
  [../]
  [./_dt]
    type = TimestepSize
  [../]
  [./num_lin_it]
    type = NumLinearIterations
  [../]
  [./num_nonlin_it]
    type = NumNonlinearIterations
  [../]
[]

[BCs]
  [./bot_y]
    type = DirichletBC
    variable = disp_y
    boundary = 1
    value = 0.0
  [../]
  [./side_x]
    type = DirichletBC
    variable = disp_x
    boundary = 2
    value = 0.0
  [../]
  [./back_z]
    type = DirichletBC
    variable = disp_z
    boundary = 6
    value = 0.0
  [../]
  [./top_press]
    type = Pressure
    variable = disp_y
    boundary = 5
    factor = 109.89
  [../]
[]

[Materials]
  [./bot_elas_tens]
    type = ComputeIsotropicElasticityTensor
    block = '1'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./bot_strain]
    type = ComputeFiniteStrain
    block = '1'
  [../]
  [./bot_stress]
    type = ComputeFiniteStrainElasticStress
    block = '1'
  [../]
  [./top_elas_tens]
    type = ComputeIsotropicElasticityTensor
    block = '2'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./top_strain]
    type = ComputeFiniteStrain
    block = '2'
  [../]
  [./top_stress]
    type = ComputeFiniteStrainElasticStress
    block = '2'
  [../]
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'

  petsc_options_iname = '-pc_type -pc_factor_mat_solver_type'
  petsc_options_value = 'lu     superlu_dist'

  line_search = 'none'

  nl_abs_tol = 1e-9
  nl_rel_tol = 1e-8
  l_max_its = 50
  nl_max_its = 100
  dt = 1.0
  end_time = 1.0
  num_steps = 10
  dtmin = 1.0
  l_tol = 1e-5
[]

[VectorPostprocessors]
  [./x_disp]
    type = NodalValueSampler
    variable = disp_x
    boundary = '1 3 4 5'
    sort_by = id
  [../]
  [./y_disp]
    type = NodalValueSampler
    variable = disp_y
    boundary = '1 3 4 5'
    sort_by = id
  [../]
  [./cont_press]
    type = NodalValueSampler
    variable = contact_pressure
    boundary = '3'
    sort_by = id
  [../]
[]

[Outputs]
  file_base = brick1_mu_0_2_pen_out
  print_linear_residuals = true
  perf_graph = true
  [./exodus]
    type = Exodus
    elemental_as_nodal = true
  [../]
  [./console]
    type = Console
    max_rows = 5
  [../]
  [./chkfile]
    type = CSV
    file_base = brick1_mu_0_2_pen_check
    show = 'bot_react_x bot_react_y disp_x5 disp_x8 disp_x13 disp_x16 disp_y5 disp_y8 disp_y13 disp_y16 stress_yy stress_zz top_react_x top_react_y x_disp y_disp cont_press'
    execute_vector_postprocessors_on = timestep_end
  [../]
  [./outfile]
    type = CSV
    delimiter = ' '
    execute_vector_postprocessors_on = none
  [../]
[]

[Contact]
  [./leftright]
    secondary = 3
    primary = 4
    model = coulomb
    formulation = penalty
    normalize_penalty = true
    friction_coefficient = 0.2
    penalty = 1e+9
  [../]
[]

(modules/solid_mechanics/test/tests/multi/three_surface14.i)

# Plasticit models:
# SimpleTester0 with a = 0 and b = 1 and strength = 1
# SimpleTester1 with a = 1 and b = 0 and strength = 1
# SimpleTester2 with a = 1 and b = 1 and strength = 3
#
# Lame lambda = 0 (Poisson=0).  Lame mu = 0.5E6
#
# A single element is stretched by 2.1E-6m in y direction and 3E-6 in z direction.
# trial stress_yy = 2.1 and stress_zz = 3.0
#
# Then all three will be active, but there is linear-dependence.
# SimpleTester1 will turn off, since it is closest,
# and the algorithm will return to stress_zz=1, stress_yy=2, but
# then SimpleTester1 will be positive, so it will be turned back
# on, and then SimpleTester0 or SimpleTester2 will be turned off
# (a random choice will be made).
# If SimpleTester2 is turned
# off then algorithm returns to stress_zz=1=stress_yy, but then
# SimpleTester2 violates Kuhn-Tucker (f<0 and pm>0), so the algorithm
# will restart, and return to stress_zz=1=stress_yy, with internal0=2
# and internal1=1.1
# If SimpleTester0 is turned off then the algorithm will return to
# stress_zz=2, stress_yy=1, where f0>0.  Once again, a random choice
# of turning off SimpleTester1 or SimpleTester2 can be made.  Hence,
# oscillations can occur.  If too many oscillations occur then the algorithm
# will fail

[Mesh]
  type = GeneratedMesh
  dim = 3
  nx = 1
  ny = 1
  nz = 1
  xmin = -0.5
  xmax = 0.5
  ymin = -0.5
  ymax = 0.5
  zmin = -0.5
  zmax = 0.5
[]


[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./disp_z]
  [../]
[]

[Kernels]
  [SolidMechanics]
    displacements = 'disp_x disp_y disp_z'
  [../]
[]


[BCs]
  [./x]
    type = FunctionDirichletBC
    variable = disp_x
    boundary = 'front back'
    function = '0E-6*x'
  [../]
  [./y]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = 'front back'
    function = '2.1E-6*y'
  [../]
  [./z]
    type = FunctionDirichletBC
    variable = disp_z
    boundary = 'front back'
    function = '3.0E-6*z'
  [../]
[]

[AuxVariables]
  [./stress_xx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_zz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./f0]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./f1]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./f2]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./int0]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./int1]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./int2]
    order = CONSTANT
    family = MONOMIAL
  [../]
[]

[AuxKernels]
  [./stress_xx]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xx
    index_i = 0
    index_j = 0
  [../]
  [./stress_xy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xy
    index_i = 0
    index_j = 1
  [../]
  [./stress_xz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xz
    index_i = 0
    index_j = 2
  [../]
  [./stress_yy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yy
    index_i = 1
    index_j = 1
  [../]
  [./stress_yz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yz
    index_i = 1
    index_j = 2
  [../]
  [./stress_zz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_zz
    index_i = 2
    index_j = 2
  [../]
  [./f0]
    type = MaterialStdVectorAux
    property = plastic_yield_function
    index = 0
    variable = f0
  [../]
  [./f1]
    type = MaterialStdVectorAux
    property = plastic_yield_function
    index = 1
    variable = f1
  [../]
  [./f2]
    type = MaterialStdVectorAux
    property = plastic_yield_function
    index = 2
    variable = f2
  [../]
  [./int0]
    type = MaterialStdVectorAux
    property = plastic_internal_parameter
    factor = 1E6
    index = 0
    variable = int0
  [../]
  [./int1]
    type = MaterialStdVectorAux
    property = plastic_internal_parameter
    factor = 1E6
    index = 1
    variable = int1
  [../]
  [./int2]
    type = MaterialStdVectorAux
    property = plastic_internal_parameter
    factor = 1E6
    index = 2
    variable = int2
  [../]
[]

[Postprocessors]
  [./s_xx]
    type = PointValue
    point = '0 0 0'
    variable = stress_xx
  [../]
  [./s_xy]
    type = PointValue
    point = '0 0 0'
    variable = stress_xy
  [../]
  [./s_xz]
    type = PointValue
    point = '0 0 0'
    variable = stress_xz
  [../]
  [./s_yy]
    type = PointValue
    point = '0 0 0'
    variable = stress_yy
  [../]
  [./s_yz]
    type = PointValue
    point = '0 0 0'
    variable = stress_yz
  [../]
  [./s_zz]
    type = PointValue
    point = '0 0 0'
    variable = stress_zz
  [../]
  [./f0]
    type = PointValue
    point = '0 0 0'
    variable = f0
  [../]
  [./f1]
    type = PointValue
    point = '0 0 0'
    variable = f1
  [../]
  [./f2]
    type = PointValue
    point = '0 0 0'
    variable = f2
  [../]
  [./int0]
    type = PointValue
    point = '0 0 0'
    variable = int0
  [../]
  [./int1]
    type = PointValue
    point = '0 0 0'
    variable = int1
  [../]
  [./int2]
    type = PointValue
    point = '0 0 0'
    variable = int2
  [../]
[]

[UserObjects]
  [./simple0]
    type = SolidMechanicsPlasticSimpleTester
    a = 0
    b = 1
    strength = 1
    yield_function_tolerance = 1.0E-6
    internal_constraint_tolerance = 1.0E-6
  [../]
  [./simple1]
    type = SolidMechanicsPlasticSimpleTester
    a = 1
    b = 0
    strength = 1
    yield_function_tolerance = 1.0E-6
    internal_constraint_tolerance = 1.0E-6
  [../]
  [./simple2]
    type = SolidMechanicsPlasticSimpleTester
    a = 1
    b = 1
    strength = 3
    yield_function_tolerance = 1.0E-6
    internal_constraint_tolerance = 1.0E-6
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeElasticityTensor
    block = 0
    fill_method = symmetric_isotropic
    C_ijkl = '0 0.5E6'
  [../]
  [./strain]
    type = ComputeFiniteStrain
    block = 0
    displacements = 'disp_x disp_y disp_z'
  [../]
  [./multi]
    type = ComputeMultiPlasticityStress
    block = 0
    ep_plastic_tolerance = 1E-9
    plastic_models = 'simple0 simple1 simple2'
    max_NR_iterations = 4
    min_stepsize = 1
    debug_fspb = crash
    debug_jac_at_stress = '10 0 0 0 10 0 0 0 10'
    debug_jac_at_pm = '1 1 1'
    debug_jac_at_intnl = '1 1 1'
    debug_stress_change = 1E-5
    debug_pm_change = '1E-6 1E-6 1E-6'
    debug_intnl_change = '1E-6 1E-6 1E-6'
  [../]
[]


[Executioner]
  end_time = 1
  dt = 1
  type = Transient
[]


[Outputs]
  file_base = three_surface14
  exodus = false
  [./csv]
    type = CSV
    [../]
[]

(modules/solid_mechanics/test/tests/hyperelastic_viscoplastic/one_elem_base.i)

[Mesh]
  type = GeneratedMesh
  dim = 3
  elem_type = HEX8
  displacements = 'ux uy uz'
[]

[Variables]
  [./ux]
    block = 0
  [../]
  [./uy]
    block = 0
  [../]
  [./uz]
    block = 0
  [../]
[]

[Kernels]
  [SolidMechanics]
    displacements = 'ux uy uz'
    use_displaced_mesh = true
    base_name = test
  [../]
[]

[AuxVariables]
  [./stress_zz]
    order = CONSTANT
    family = MONOMIAL
    block = 0
  [../]
  [./peeq]
    order = CONSTANT
    family = MONOMIAL
    block = 0
  [../]
  [./fp_zz]
    order = CONSTANT
    family = MONOMIAL
    block = 0
  [../]
[]

[AuxKernels]
  [./stress_zz]
    type = RankTwoAux
    variable = stress_zz
    rank_two_tensor = test_stress
    index_j = 2
    index_i = 2
    execute_on = timestep_end
    block = 0
  [../]
  [./fp_zz]
    type = RankTwoAux
    variable = fp_zz
    rank_two_tensor = test_fp
    index_j = 2
    index_i = 2
    execute_on = timestep_end
    block = 0
  [../]
  [./peeq]
    type = MaterialRealAux
    variable = peeq
    property = ep_eqv
    execute_on = timestep_end
    block = 0
  [../]
[]

[BCs]
  [./symmy]
    type = DirichletBC
    variable = uy
    boundary = bottom
    value = 0
  [../]
  [./symmx]
    type = DirichletBC
    variable = ux
    boundary = left
    value = 0
  [../]
  [./symmz]
    type = DirichletBC
    variable = uz
    boundary = back
    value = 0
  [../]
  [./tdisp]
    type = FunctionDirichletBC
    variable = uz
    boundary = front
    function = '0.01*t'
  [../]
[]

[UserObjects]
  [./flowstress]
    type = HEVPRambergOsgoodHardening
    yield_stress = 100
    hardening_exponent = 0.1
    reference_plastic_strain = 0.002
    intvar_prop_name = ep_eqv
  [../]
  [./flowrate]
    type = HEVPFlowRatePowerLawJ2
    reference_flow_rate = 0.0001
    flow_rate_exponent = 50.0
    flow_rate_tol = 1
    strength_prop_name = flowstress
    base_name = test
  [../]
  [./ep_eqv]
     type = HEVPEqvPlasticStrain
     intvar_rate_prop_name = ep_eqv_rate
  [../]
  [./ep_eqv_rate]
     type = HEVPEqvPlasticStrainRate
     flow_rate_prop_name = flowrate
  [../]
[]

[Materials]
  [./strain]
    type = ComputeFiniteStrain
    block = 0
    displacements = 'ux uy uz'
    base_name = test
  [../]
  [./viscop]
    type = FiniteStrainHyperElasticViscoPlastic
    block = 0
    resid_abs_tol = 1e-18
    resid_rel_tol = 1e-8
    maxiters = 50
    max_substep_iteration = 5
    flow_rate_user_objects = 'flowrate'
    strength_user_objects = 'flowstress'
    internal_var_user_objects = 'ep_eqv'
    internal_var_rate_user_objects = 'ep_eqv_rate'
    base_name = test
  [../]
  [./elasticity_tensor]
    type = ComputeElasticityTensor
    block = 0
    C_ijkl = '2.8e5 1.2e5 1.2e5 2.8e5 1.2e5 2.8e5 0.8e5 0.8e5 0.8e5'
    fill_method = symmetric9
    base_name = test
  [../]
[]

[Postprocessors]
  [./stress_zz]
    type = ElementAverageValue
    variable = stress_zz
    block = 'ANY_BLOCK_ID 0'
  [../]
  [./fp_zz]
    type = ElementAverageValue
    variable = fp_zz
    block = 'ANY_BLOCK_ID 0'
  [../]
  [./peeq]
    type = ElementAverageValue
    variable = peeq
    block = 'ANY_BLOCK_ID 0'
  [../]
[]

[Preconditioning]
  [./smp]
    type = SMP
    full = true
  [../]
[]

[Executioner]
  type = Transient
  dt = 0.02
  #Preconditioned JFNK (default)
  solve_type = 'PJFNK'
  petsc_options_iname = -pc_hypre_type
  petsc_options_value = boomerang
  dtmax = 10.0
  nl_rel_tol = 1e-10
  dtmin = 0.02
  num_steps = 10
[]

[Outputs]
  file_base = one_elem_base
  exodus = true
  csv = false
[]

(modules/solid_mechanics/test/tests/mohr_coulomb/except3.i)

# checking for exception error messages on the edge smoothing
# here edge_smoother=5deg, which means the friction_angle must be <= 35.747
[Mesh]
  type = GeneratedMesh
  dim = 3
  nx = 1
  ny = 1
  nz = 1
  xmin = -0.5
  xmax = 0.5
  ymin = -0.5
  ymax = 0.5
  zmin = -0.5
  zmax = 0.5
[]


[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./disp_z]
  [../]
[]

[Kernels]
  [SolidMechanics]
    displacements = 'disp_x disp_y disp_z'
  [../]
[]


[BCs]
  [./x]
    type = FunctionDirichletBC
    variable = disp_x
    boundary = 'front back'
    function = '1E-6*x'
  [../]
  [./y]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = 'front back'
    function = '1E-6*y'
  [../]
  [./z]
    type = FunctionDirichletBC
    variable = disp_z
    boundary = 'front back'
    function = '1E-6*z'
  [../]
[]

[AuxVariables]
  [./stress_xx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_zz]
    order = CONSTANT
    family = MONOMIAL
  [../]
[]

[AuxKernels]
  [./stress_xx]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xx
    index_i = 0
    index_j = 0
  [../]
  [./stress_xy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xy
    index_i = 0
    index_j = 1
  [../]
  [./stress_xz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xz
    index_i = 0
    index_j = 2
  [../]
  [./stress_yy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yy
    index_i = 1
    index_j = 1
  [../]
  [./stress_yz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yz
    index_i = 1
    index_j = 2
  [../]
  [./stress_zz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_zz
    index_i = 2
    index_j = 2
  [../]
[]

[Postprocessors]
  [./s_xx]
    type = PointValue
    point = '0 0 0'
    variable = stress_xx
  [../]
  [./s_xy]
    type = PointValue
    point = '0 0 0'
    variable = stress_xy
  [../]
  [./s_xz]
    type = PointValue
    point = '0 0 0'
    variable = stress_xz
  [../]
  [./s_yy]
    type = PointValue
    point = '0 0 0'
    variable = stress_yy
  [../]
  [./s_yz]
    type = PointValue
    point = '0 0 0'
    variable = stress_yz
  [../]
  [./s_zz]
    type = PointValue
    point = '0 0 0'
    variable = stress_zz
  [../]
[]

[UserObjects]
  [./mc_coh]
    type = SolidMechanicsHardeningConstant
    value = 10
  [../]
  [./mc_phi]
    type = SolidMechanicsHardeningConstant
    value = 36
    convert_to_radians = true
  [../]
  [./mc_psi]
    type = SolidMechanicsHardeningConstant
    value = 5
    convert_to_radians = true
  [../]
  [./mc]
    type = SolidMechanicsPlasticMohrCoulomb
    cohesion = mc_coh
    friction_angle = mc_phi
    dilation_angle = mc_psi
    mc_tip_smoother = 1
    mc_edge_smoother = 5
    yield_function_tolerance = 1E-3
    internal_constraint_tolerance = 1E-9
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeElasticityTensor
    block = 0
    fill_method = symmetric_isotropic
    C_ijkl = '0 1E7'
  [../]
  [./strain]
    type = ComputeFiniteStrain
    block = 0
    displacements = 'disp_x disp_y disp_z'
  [../]
  [./mc]
    type = ComputeMultiPlasticityStress
    block = 0
    ep_plastic_tolerance = 1E-9
    plastic_models = mc
    debug_fspb = crash
    debug_jac_at_stress = '10 0 0 0 10 0 0 0 10'
    debug_jac_at_pm = 1
    debug_jac_at_intnl = 1
    debug_stress_change = 1E-5
    debug_pm_change = 1E-6
    debug_intnl_change = 1E-6
  [../]
[]


[Executioner]
  end_time = 1
  dt = 1
  type = Transient
[]


[Outputs]
  file_base = except3
  exodus = false
  [./csv]
    type = CSV
    [../]
[]

(modules/xfem/test/tests/moving_interface/moving_bimaterial_finite_strain_cut_mesh.i)

# This test is for two layer materials with different youngs modulus with AD
# The global stress is determined by switching the stress based on level set values
# The material interface is marked by a level set function
# The two layer materials are glued together

[GlobalParams]
  displacements = 'disp_x disp_y'
[]

[XFEM]
  output_cut_plane = true
[]

[UserObjects]
  [cut]
    type = InterfaceMeshCut2DUserObject
    mesh_file = line.e
    interface_velocity_function = -1
    heal_always = true
  []
[]

[Mesh]
  use_displaced_mesh = true
  [generated_mesh]
    type = GeneratedMeshGenerator
    dim = 2
    nx = 10
    ny = 10
    xmin = 0
    xmax = 5
    ymin = 0
    ymax = 5
    elem_type = QUAD4
  []
  [left_bottom]
    type = ExtraNodesetGenerator
    new_boundary = 'left_bottom'
    coord = '0 0'
    input = generated_mesh
  []
  [left_top]
    type = ExtraNodesetGenerator
    new_boundary = 'left_top'
    coord = '0 5'
    input = left_bottom
  []
[]

# [Functions]
#   [ls_func]
#     type = ParsedFunction
#     expression = 'y-2.73+t'
#   []
# []

[Variables]
  [disp_x]
  []
  [disp_y]
  []
[]

[AuxVariables]
  [ls]
  []
  [a_strain_xx]
    order = CONSTANT
    family = MONOMIAL
  []
  [a_strain_yy]
    order = CONSTANT
    family = MONOMIAL
  []
  [a_strain_xy]
    order = CONSTANT
    family = MONOMIAL
  []
  [b_strain_xx]
    order = CONSTANT
    family = MONOMIAL
  []
  [b_strain_yy]
    order = CONSTANT
    family = MONOMIAL
  []
  [b_strain_xy]
    order = CONSTANT
    family = MONOMIAL
  []
  [stress_xx]
    order = CONSTANT
    family = MONOMIAL
  []
  [stress_yy]
    order = CONSTANT
    family = MONOMIAL
  []
  [stress_xy]
    order = CONSTANT
    family = MONOMIAL
  []

[]

[AuxKernels]
  # [ls_function]
  #   type = FunctionAux
  #   variable = ls
  #   function = ls_func
  # []
  [a_strain_xx]
    type = RankTwoAux
    variable = a_strain_xx
    rank_two_tensor = A_total_strain
    index_i = 0
    index_j = 0
  []
  [a_strain_yy]
    type = RankTwoAux
    variable = a_strain_yy
    rank_two_tensor = A_total_strain
    index_i = 1
    index_j = 1
  []
  [a_strain_xy]
    type = RankTwoAux
    variable = a_strain_xy
    rank_two_tensor = A_total_strain
    index_i = 0
    index_j = 1
  []
  [b_strain_xx]
    type = RankTwoAux
    variable = b_strain_xx
    rank_two_tensor = B_total_strain
    index_i = 0
    index_j = 0
  []
  [b_strain_yy]
    type = RankTwoAux
    variable = b_strain_yy
    rank_two_tensor = B_total_strain
    index_i = 1
    index_j = 1
  []
  [b_strain_xy]
    type = RankTwoAux
    variable = b_strain_xy
    rank_two_tensor = B_total_strain
    index_i = 0
    index_j = 1
  []
  [stress_xx]
    type = RankTwoAux
    variable = stress_xx
    rank_two_tensor = stress
    index_i = 0
    index_j = 0
  []
  [stress_xy]
    type = RankTwoAux
    variable = stress_xy
    rank_two_tensor = stress
    index_i = 0
    index_j = 1
  []
  [stress_yy]
    type = RankTwoAux
    variable = stress_yy
    rank_two_tensor = stress
    index_i = 1
    index_j = 1
  []
[]

[Kernels]
  [solid_x]
    type = StressDivergenceTensors
    variable = disp_x
    component = 0
    use_displaced_mesh = true
  []
  [solid_y]
    type = StressDivergenceTensors
    variable = disp_y
    component = 1
    use_displaced_mesh = true
  []
[]

[Constraints]
  [dispx_constraint]
    type = XFEMSingleVariableConstraint
    use_displaced_mesh = false
    variable = disp_x
    alpha = 1e8
    geometric_cut_userobject = 'level_set_cut_uo'
  []
  [dispy_constraint]
    type = XFEMSingleVariableConstraint
    use_displaced_mesh = false
    variable = disp_y
    alpha = 1e8
    geometric_cut_userobject = 'level_set_cut_uo'
  []
[]

[BCs]
  [bottomx]
    type = DirichletBC
    boundary = bottom
    variable = disp_x
    value = 0.0
  []
  [bottomy]
    type = DirichletBC
    boundary = bottom
    variable = disp_y
    value = 0.0
  []
  [topx]
    type = FunctionDirichletBC
    boundary = top
    variable = disp_x
    function = 0.03*t
  []
  [topy]
    type = FunctionDirichletBC
    boundary = top
    variable = disp_y
    function = '0.03*t'
  []
[]

[Materials]
  [elasticity_tensor_A]
    type = ComputeIsotropicElasticityTensor
    base_name = A
    youngs_modulus = 1e9
    poissons_ratio = 0.3
  []
  [strain_A]
    type = ComputeFiniteStrain
    base_name = A
  []
  [stress_A]
    type = ComputeFiniteStrainElasticStress
    base_name = A
  []
  [elasticity_tensor_B]
    type = ComputeIsotropicElasticityTensor
    base_name = B
    youngs_modulus = 1e7
    poissons_ratio = 0.3
  []
  [strain_B]
    type = ComputeFiniteStrain
    base_name = B
  []
  [stress_B]
    type = ComputeFiniteStrainElasticStress
    base_name = B
  []
  [combined_stress]
    type = LevelSetBiMaterialRankTwo
    levelset_positive_base = 'A'
    levelset_negative_base = 'B'
    level_set_var = ls
    prop_name = stress
  []
  [combined_jacob_mult]
    type = LevelSetBiMaterialRankFour
    levelset_positive_base = 'A'
    levelset_negative_base = 'B'
    level_set_var = ls
    prop_name = Jacobian_mult
  []
[]

[Postprocessors]
  [disp_x_norm]
    type = ElementL2Norm
    variable = disp_x
  []
  [disp_y_norm]
    type = ElementL2Norm
    variable = disp_y
  []
[]

[Executioner]
  type = Transient

  solve_type = NEWTON
  petsc_options_iname = '-pc_type'
  petsc_options_value = 'lu'
  automatic_scaling = true

  # controls for nonlinear iterations
  nl_max_its = 15
  nl_rel_tol = 1e-13
  nl_abs_tol = 1e-50

  # time control
  start_time = 0.0
  dt = 0.1
  num_steps = 4

  max_xfem_update = 1
[]

[Outputs]
  print_linear_residuals = false
  exodus = true
[]

(modules/solid_mechanics/test/tests/multi/three_surface11.i)

# Plasticit models:
# SimpleTester0 with a = 0 and b = 1 and strength = 1
# SimpleTester1 with a = 1 and b = 0 and strength = 1
# SimpleTester2 with a = 1 and b = 1 and strength = 3
#
# Lame lambda = 0 (Poisson=0).  Lame mu = 0.5E6
#
# A single element is stretched by 0E-6m in y direction and 2E-6 in z direction.
# trial stress_yy = 0 and stress_zz = 2.0
#
# Then SimpleTester0 should activate and the algorithm will return to
# stress_zz=1
# internal0 should be 1.0

[Mesh]
  type = GeneratedMesh
  dim = 3
  nx = 1
  ny = 1
  nz = 1
  xmin = -0.5
  xmax = 0.5
  ymin = -0.5
  ymax = 0.5
  zmin = -0.5
  zmax = 0.5
[]


[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./disp_z]
  [../]
[]

[Kernels]
  [SolidMechanics]
    displacements = 'disp_x disp_y disp_z'
  [../]
[]


[BCs]
  [./x]
    type = FunctionDirichletBC
    variable = disp_x
    boundary = 'front back'
    function = '0E-6*x'
  [../]
  [./y]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = 'front back'
    function = '0.0E-6*y'
  [../]
  [./z]
    type = FunctionDirichletBC
    variable = disp_z
    boundary = 'front back'
    function = '2.0E-6*z'
  [../]
[]

[AuxVariables]
  [./stress_xx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_zz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./f0]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./f1]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./f2]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./int0]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./int1]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./int2]
    order = CONSTANT
    family = MONOMIAL
  [../]
[]

[AuxKernels]
  [./stress_xx]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xx
    index_i = 0
    index_j = 0
  [../]
  [./stress_xy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xy
    index_i = 0
    index_j = 1
  [../]
  [./stress_xz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xz
    index_i = 0
    index_j = 2
  [../]
  [./stress_yy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yy
    index_i = 1
    index_j = 1
  [../]
  [./stress_yz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yz
    index_i = 1
    index_j = 2
  [../]
  [./stress_zz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_zz
    index_i = 2
    index_j = 2
  [../]
  [./f0]
    type = MaterialStdVectorAux
    property = plastic_yield_function
    index = 0
    variable = f0
  [../]
  [./f1]
    type = MaterialStdVectorAux
    property = plastic_yield_function
    index = 1
    variable = f1
  [../]
  [./f2]
    type = MaterialStdVectorAux
    property = plastic_yield_function
    index = 2
    variable = f2
  [../]
  [./int0]
    type = MaterialStdVectorAux
    property = plastic_internal_parameter
    factor = 1E6
    index = 0
    variable = int0
  [../]
  [./int1]
    type = MaterialStdVectorAux
    property = plastic_internal_parameter
    factor = 1E6
    index = 1
    variable = int1
  [../]
  [./int2]
    type = MaterialStdVectorAux
    property = plastic_internal_parameter
    factor = 1E6
    index = 2
    variable = int2
  [../]
[]

[Postprocessors]
  [./s_xx]
    type = PointValue
    point = '0 0 0'
    variable = stress_xx
  [../]
  [./s_xy]
    type = PointValue
    point = '0 0 0'
    variable = stress_xy
  [../]
  [./s_xz]
    type = PointValue
    point = '0 0 0'
    variable = stress_xz
  [../]
  [./s_yy]
    type = PointValue
    point = '0 0 0'
    variable = stress_yy
  [../]
  [./s_yz]
    type = PointValue
    point = '0 0 0'
    variable = stress_yz
  [../]
  [./s_zz]
    type = PointValue
    point = '0 0 0'
    variable = stress_zz
  [../]
  [./f0]
    type = PointValue
    point = '0 0 0'
    variable = f0
  [../]
  [./f1]
    type = PointValue
    point = '0 0 0'
    variable = f1
  [../]
  [./f2]
    type = PointValue
    point = '0 0 0'
    variable = f2
  [../]
  [./int0]
    type = PointValue
    point = '0 0 0'
    variable = int0
  [../]
  [./int1]
    type = PointValue
    point = '0 0 0'
    variable = int1
  [../]
  [./int2]
    type = PointValue
    point = '0 0 0'
    variable = int2
  [../]
[]

[UserObjects]
  [./simple0]
    type = SolidMechanicsPlasticSimpleTester
    a = 0
    b = 1
    strength = 1
    yield_function_tolerance = 1.0E-9
    internal_constraint_tolerance = 1.0E-9
  [../]
  [./simple1]
    type = SolidMechanicsPlasticSimpleTester
    a = 1
    b = 0
    strength = 1
    yield_function_tolerance = 1.0E-9
    internal_constraint_tolerance = 1.0E-9
  [../]
  [./simple2]
    type = SolidMechanicsPlasticSimpleTester
    a = 1
    b = 1
    strength = 3
    yield_function_tolerance = 1.0E-9
    internal_constraint_tolerance = 1.0E-9
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeElasticityTensor
    block = 0
    fill_method = symmetric_isotropic
    C_ijkl = '0 0.5E6'
  [../]
  [./strain]
    type = ComputeFiniteStrain
    block = 0
    displacements = 'disp_x disp_y disp_z'
  [../]
  [./multi]
    type = ComputeMultiPlasticityStress
    block = 0
    ep_plastic_tolerance = 1E-9
    plastic_models = 'simple0 simple1 simple2'
    max_NR_iterations = 2
    min_stepsize = 1
    debug_fspb = crash
    debug_jac_at_stress = '10 0 0 0 10 0 0 0 10'
    debug_jac_at_pm = '1 1'
    debug_jac_at_intnl = '1 1'
    debug_stress_change = 1E-5
    debug_pm_change = '1E-6 1E-6'
    debug_intnl_change = '1E-6 1E-6'
  [../]
[]


[Executioner]
  end_time = 1
  dt = 1
  type = Transient
[]


[Outputs]
  file_base = three_surface11
  exodus = false
  [./csv]
    type = CSV
    [../]
[]

(modules/solid_mechanics/test/tests/mohr_coulomb/small_deform4.i)

# apply repeated stretches in z direction, and smaller stretches in the x and y directions
# so that sigma_II = sigma_III,
# which means that lode angle = -30deg.
# The allows yield surface in meridional plane to be mapped out

[Mesh]
  type = GeneratedMesh
  dim = 3
  nx = 1
  ny = 1
  nz = 1
  xmin = -0.5
  xmax = 0.5
  ymin = -0.5
  ymax = 0.5
  zmin = -0.5
  zmax = 0.5
[]


[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./disp_z]
  [../]
[]

[Kernels]
  [SolidMechanics]
    displacements = 'disp_x disp_y disp_z'
  [../]
[]


[BCs]
  [./x]
    type = FunctionDirichletBC
    variable = disp_x
    boundary = 'front back'
    function = '0.25E-6*x*sin(t)'
  [../]
  [./y]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = 'front back'
    function = '0.25E-6*y*sin(t)'
  [../]
  [./z]
    type = FunctionDirichletBC
    variable = disp_z
    boundary = 'front back'
    function = '1E-6*z*t'
  [../]
[]

[AuxVariables]
  [./stress_xx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_zz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./mc_int]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./yield_fcn]
    order = CONSTANT
    family = MONOMIAL
  [../]
[]

[AuxKernels]
  [./stress_xx]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xx
    index_i = 0
    index_j = 0
  [../]
  [./stress_xy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xy
    index_i = 0
    index_j = 1
  [../]
  [./stress_xz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xz
    index_i = 0
    index_j = 2
  [../]
  [./stress_yy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yy
    index_i = 1
    index_j = 1
  [../]
  [./stress_yz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yz
    index_i = 1
    index_j = 2
  [../]
  [./stress_zz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_zz
    index_i = 2
    index_j = 2
  [../]
  [./mc_int_auxk]
    type = MaterialStdVectorAux
    index = 0
    property = plastic_internal_parameter
    variable = mc_int
  [../]
  [./yield_fcn_auxk]
    type = MaterialStdVectorAux
    index = 0
    property = plastic_yield_function
    variable = yield_fcn
  [../]
[]

[Postprocessors]
  [./s_xx]
    type = PointValue
    point = '0 0 0'
    variable = stress_xx
  [../]
  [./s_xy]
    type = PointValue
    point = '0 0 0'
    variable = stress_xy
  [../]
  [./s_xz]
    type = PointValue
    point = '0 0 0'
    variable = stress_xz
  [../]
  [./s_yy]
    type = PointValue
    point = '0 0 0'
    variable = stress_yy
  [../]
  [./s_yz]
    type = PointValue
    point = '0 0 0'
    variable = stress_yz
  [../]
  [./s_zz]
    type = PointValue
    point = '0 0 0'
    variable = stress_zz
  [../]
  [./internal]
    type = PointValue
    point = '0 0 0'
    variable = mc_int
  [../]
  [./f]
    type = PointValue
    point = '0 0 0'
    variable = yield_fcn
  [../]
[]

[UserObjects]
  [./mc_coh]
    type = SolidMechanicsHardeningConstant
    value = 10
  [../]
  [./mc_phi]
    type = SolidMechanicsHardeningConstant
    value = 50
    convert_to_radians = true
  [../]
  [./mc_psi]
    type = SolidMechanicsHardeningExponential
    value_0 = 0
    value_residual = 0.8726646 # 50deg
    rate = 3000.0
  [../]
  [./mc]
    type = SolidMechanicsPlasticMohrCoulomb
    cohesion = mc_coh
    friction_angle = mc_phi
    dilation_angle = mc_psi
    mc_tip_smoother = 4
    mc_edge_smoother = 20
    yield_function_tolerance = 1E-8
    internal_constraint_tolerance = 1E-9
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeElasticityTensor
    block = 0
    fill_method = symmetric_isotropic
    C_ijkl = '0 1E7'
  [../]
  [./strain]
    type = ComputeFiniteStrain
    block = 0
    displacements = 'disp_x disp_y disp_z'
  [../]
  [./mc]
    type = ComputeMultiPlasticityStress
    block = 0
    ep_plastic_tolerance = 1E-9
    plastic_models = mc
    debug_fspb = crash
  [../]
[]


[Executioner]
  end_time = 30
  dt = 1
  type = Transient
[]


[Outputs]
  file_base = small_deform4
  exodus = false
  [./csv]
    type = CSV
    [../]
[]

(modules/solid_mechanics/test/tests/crystal_plasticity/monolithic_material_based/crysp_cutback.i)

[Mesh]
  type = GeneratedMesh
  dim = 3
  elem_type = HEX8
  displacements = 'ux uy uz'
[]

[Variables]
  [./ux]
    block = 0
  [../]
  [./uy]
    block = 0
  [../]
  [./uz]
    block = 0
  [../]
[]

[AuxVariables]
  [./stress_zz]
    order = CONSTANT
    family = MONOMIAL
    block = 0
  [../]
  [./fp_zz]
    order = CONSTANT
    family = MONOMIAL
    block = 0
  [../]
  [./rotout]
    order = CONSTANT
    family = MONOMIAL
    block = 0
  [../]
  [./e_zz]
    order = CONSTANT
    family = MONOMIAL
    block = 0
  [../]
  [./gss1]
    order = CONSTANT
    family = MONOMIAL
    block = 0
  [../]
[]

[Functions]
  [./tdisp]
    type = ParsedFunction
    expression = 0.01*t
  [../]
[]

[Kernels]
  [SolidMechanics]
    displacements = 'ux uy uz'
    use_displaced_mesh = true
  [../]
[]

[AuxKernels]
  [./stress_zz]
    type = RankTwoAux
    variable = stress_zz
    rank_two_tensor = stress
    index_j = 2
    index_i = 2
    execute_on = timestep_end
    block = 0
  [../]
  [./fp_zz]
    type = RankTwoAux
    variable = fp_zz
    rank_two_tensor = fp
    index_j = 2
    index_i = 2
    execute_on = timestep_end
    block = 0
  [../]
  [./e_zz]
    type = RankTwoAux
    variable = e_zz
    rank_two_tensor = lage
    index_j = 2
    index_i = 2
    execute_on = timestep_end
    block = 0
  [../]
  [./gss1]
    type = MaterialStdVectorAux
    variable = gss1
    property = gss
    index = 0
    execute_on = timestep_end
    block = 0
  [../]
[]

[BCs]
  [./symmy]
    type = DirichletBC
    variable = uy
    boundary = bottom
    value = 0
  [../]
  [./symmx]
    type = DirichletBC
    variable = ux
    boundary = left
    value = 0
  [../]
  [./symmz]
    type = DirichletBC
    variable = uz
    boundary = back
    value = 0
  [../]
  [./tdisp]
    type = FunctionDirichletBC
    variable = uz
    boundary = front
    function = tdisp
  [../]
[]

[Materials]
  [./crysp]
    type = FiniteStrainCrystalPlasticity
    block = 0
    gtol = 1e-2
    slip_sys_file_name = input_slip_sys.txt
    nss = 12
    num_slip_sys_flowrate_props = 2 #Number of properties in a slip system
    flowprops = '1 4 0.001 0.1 5 8 0.001 0.1 9 12 0.001 0.1'
    hprops = '1.0 541.5 60.8 109.8 2.5'
    gprops = '1 4 60.8 5 8 60.8 9 12 60.8'
    tan_mod_type = exact
    gen_random_stress_flag = true
  [../]
  [./elasticity_tensor]
    type = ComputeElasticityTensorCP
    block = 0
    C_ijkl = '1.684e5 1.214e5 1.214e5 1.684e5 1.214e5 1.684e5 0.754e5 0.754e5 0.754e5'
    fill_method = symmetric9
  [../]
  [./strain]
    type = ComputeFiniteStrain
    block = 0
    displacements = 'ux uy uz'
  [../]
[]

[Postprocessors]
  [./stress_zz]
    type = ElementAverageValue
    variable = stress_zz
    block = 'ANY_BLOCK_ID 0'
  [../]
  [./fp_zz]
    type = ElementAverageValue
    variable = fp_zz
    block = 'ANY_BLOCK_ID 0'
  [../]
  [./e_zz]
    type = ElementAverageValue
    variable = e_zz
    block = 'ANY_BLOCK_ID 0'
  [../]
  [./gss1]
    type = ElementAverageValue
    variable = gss1
    block = 'ANY_BLOCK_ID 0'
  [../]
[]

[Preconditioning]
  [./smp]
    type = SMP
    full = true
  [../]
[]

[Executioner]
  type = Transient

  solve_type = 'PJFNK'

  petsc_options_iname = '-pc_factor_shift_type'
  petsc_options_value = 'nonzero'

  nl_rel_tol = 1e-10
  nl_abs_tol = 1e-10

  dt = 1.0
  dtmax = 10.0
  dtmin = 1e-5

  num_steps = 3

  snesmf_reuse_base = false
[]

[Outputs]
  file_base = crysp_cutback_out
  exodus = true
  csv = true
  gnuplot = true
[]

(modules/solid_mechanics/test/tests/mohr_coulomb/small_deform_hard2.i)

# apply uniform stretches in x, y and z directions.
# let friction_angle = 60deg, friction_angle_residual=10deg, friction_angle_rate = 0.5E4
# With cohesion = C, friction_angle = phi, tip_smoother = T, the
# algorithm should return to
# sigma_m = (C*Cos(phi) - T)/Sin(phi)
# Or, when T=C,
# phi = 2*pi*n - 2*arctan(sigma_m/C)
# This allows checking of the relationship for phi

[Mesh]
  type = GeneratedMesh
  dim = 3
  nx = 1
  ny = 1
  nz = 1
  xmin = -0.5
  xmax = 0.5
  ymin = -0.5
  ymax = 0.5
  zmin = -0.5
  zmax = 0.5
[]


[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./disp_z]
  [../]
[]

[Kernels]
  [SolidMechanics]
    displacements = 'disp_x disp_y disp_z'
  [../]
[]


[BCs]
  [./x]
    type = FunctionDirichletBC
    variable = disp_x
    boundary = 'front back'
    function = '1E-6*x*t'
  [../]
  [./y]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = 'front back'
    function = '1E-6*y*t'
  [../]
  [./z]
    type = FunctionDirichletBC
    variable = disp_z
    boundary = 'front back'
    function = '1E-6*z*t'
  [../]
[]

[AuxVariables]
  [./stress_xx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_zz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./mc_int]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./yield_fcn]
    order = CONSTANT
    family = MONOMIAL
  [../]
[]

[AuxKernels]
  [./stress_xx]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xx
    index_i = 0
    index_j = 0
  [../]
  [./stress_xy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xy
    index_i = 0
    index_j = 1
  [../]
  [./stress_xz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xz
    index_i = 0
    index_j = 2
  [../]
  [./stress_yy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yy
    index_i = 1
    index_j = 1
  [../]
  [./stress_yz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yz
    index_i = 1
    index_j = 2
  [../]
  [./stress_zz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_zz
    index_i = 2
    index_j = 2
  [../]
  [./mc_int_auxk]
    type = MaterialStdVectorAux
    index = 0
    property = plastic_internal_parameter
    variable = mc_int
  [../]
  [./yield_fcn_auxk]
    type = MaterialStdVectorAux
    index = 0
    property = plastic_yield_function
    variable = yield_fcn
  [../]
[]

[Postprocessors]
  [./s_xx]
    type = PointValue
    point = '0 0 0'
    variable = stress_xx
  [../]
  [./s_xy]
    type = PointValue
    point = '0 0 0'
    variable = stress_xy
  [../]
  [./s_xz]
    type = PointValue
    point = '0 0 0'
    variable = stress_xz
  [../]
  [./s_yy]
    type = PointValue
    point = '0 0 0'
    variable = stress_yy
  [../]
  [./s_yz]
    type = PointValue
    point = '0 0 0'
    variable = stress_yz
  [../]
  [./s_zz]
    type = PointValue
    point = '0 0 0'
    variable = stress_zz
  [../]
  [./internal]
    type = PointValue
    point = '0 0 0'
    variable = mc_int
  [../]
  [./f]
    type = PointValue
    point = '0 0 0'
    variable = yield_fcn
  [../]
[]

[UserObjects]
  [./mc_coh]
    type = SolidMechanicsHardeningConstant
    value = 10
  [../]
  [./mc_phi]
    type = SolidMechanicsHardeningExponential
    value_0 = 1.04719755 # 60deg
    value_residual = 0.17453293 # 10deg
    rate = 0.5E4
  [../]
  [./mc_psi]
    type = SolidMechanicsHardeningConstant
    value = 5
    convert_to_radians = true
  [../]
  [./mc]
    type = SolidMechanicsPlasticMohrCoulomb
    cohesion = mc_coh
    friction_angle = mc_phi
    dilation_angle = mc_psi
    mc_tip_smoother = 10
    mc_edge_smoother = 25
    yield_function_tolerance = 1E-3
    internal_constraint_tolerance = 1E-9
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeElasticityTensor
    block = 0
    fill_method = symmetric_isotropic
    C_ijkl = '0 1E7'
  [../]
  [./strain]
    type = ComputeFiniteStrain
    block = 0
    displacements = 'disp_x disp_y disp_z'
  [../]
  [./mc]
    type = ComputeMultiPlasticityStress
    block = 0
    ep_plastic_tolerance = 1E-9
    plastic_models = mc
    debug_fspb = crash
    debug_jac_at_stress = '10 1 2 1 10 3 2 3 10'
    debug_jac_at_pm = 1
    debug_jac_at_intnl = 1E-3
    debug_stress_change = 1E-5
    debug_pm_change = 1E-6
    debug_intnl_change = 1E-6
  [../]
[]


[Executioner]
  end_time = 10
  dt = 1
  type = Transient
[]


[Outputs]
  file_base = small_deform_hard2
  exodus = false
  [./csv]
    type = CSV
    [../]
[]

(modules/solid_mechanics/test/tests/mohr_coulomb/random.i)

# apply many random large deformations, checking that the algorithm returns correctly to
# the yield surface each time.


[Mesh]
  type = GeneratedMesh
  dim = 3
  nx = 1000
  ny = 125
  nz = 1
  xmin = 0
  xmax = 1000
  ymin = 0
  ymax = 125
  zmin = 0
  zmax = 1
[]


[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./disp_z]
  [../]
[]

[Kernels]
  [SolidMechanics]
    displacements = 'disp_x disp_y disp_z'
  [../]
[]


[ICs]
  [./x]
    type = RandomIC
    min = -0.1
    max = 0.1
    variable = disp_x
  [../]
  [./y]
    type = RandomIC
    min = -0.1
    max = 0.1
    variable = disp_y
  [../]
  [./z]
    type = RandomIC
    min = -0.1
    max = 0.1
    variable = disp_z
  [../]
[]

[BCs]
  [./x]
    type = FunctionDirichletBC
    variable = disp_x
    boundary = 'front back'
    function = '0'
  [../]
  [./y]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = 'front back'
    function = '0'
  [../]
  [./z]
    type = FunctionDirichletBC
    variable = disp_z
    boundary = 'front back'
    function = '0'
  [../]
[]

[AuxVariables]
  [./yield_fcn]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./iter]
    order = CONSTANT
    family = MONOMIAL
  [../]
[]

[AuxKernels]
  [./yield_fcn_auxk]
    type = MaterialStdVectorAux
    index = 0
    property = plastic_yield_function
    variable = yield_fcn
  [../]
  [./iter]
    type = MaterialRealAux
    property = plastic_NR_iterations
    variable = iter
  [../]
[]

[Postprocessors]
  [./yield_fcn_at_zero]
    type = PointValue
    point = '0 0 0'
    variable = yield_fcn
    outputs = 'console'
  [../]
  [./should_be_zero]
    type = FunctionValuePostprocessor
    function = should_be_zero_fcn
  [../]
  [./av_iter]
    type = ElementAverageValue
    variable = iter
    outputs = 'console'
  [../]
[]

[Functions]
  [./should_be_zero_fcn]
    type = ParsedFunction
    expression = 'if(a<1E-3,0,a)'
    symbol_names = 'a'
    symbol_values = 'yield_fcn_at_zero'
  [../]
[]

[UserObjects]
  [./mc_coh]
    type = SolidMechanicsHardeningConstant
    value = 1E3
  [../]
  [./mc_phi]
    type = SolidMechanicsHardeningConstant
    value = 30
    convert_to_radians = true
  [../]
  [./mc_psi]
    type = SolidMechanicsHardeningConstant
    value = 5
    convert_to_radians = true
  [../]
  [./mc]
    type = SolidMechanicsPlasticMohrCoulomb
    cohesion = mc_coh
    friction_angle = mc_phi
    dilation_angle = mc_psi
    mc_tip_smoother = 0.1E3
    mc_edge_smoother = 25
    yield_function_tolerance = 1E-3
    internal_constraint_tolerance = 1E-6
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeElasticityTensor
    block = 0
    fill_method = symmetric_isotropic
    C_ijkl = '0.7E7 1E7'
  [../]
  [./strain]
    type = ComputeFiniteStrain
    block = 0
    displacements = 'disp_x disp_y disp_z'
  [../]
  [./mc]
    type = ComputeMultiPlasticityStress
    block = 0
    max_NR_iterations = 1000
    ep_plastic_tolerance = 1E-6
    min_stepsize = 1E-3
    plastic_models = mc
    debug_fspb = crash
    deactivation_scheme = safe
  [../]
[]


[Executioner]
  end_time = 1
  dt = 1
  type = Transient
[]


[Outputs]
  file_base = random
  exodus = false
  [./csv]
    type = CSV
    [../]
[]

(modules/contact/test/tests/verification/patch_tests/brick_3/brick3_template2.i)

[GlobalParams]
  order = SECOND
  displacements = 'disp_x disp_y disp_z'
[]

[Mesh]
  file = brick3_mesh.e
[]

[Problem]
  type = AugmentedLagrangianContactProblem
  maximum_lagrangian_update_iterations = 200
  extra_tag_vectors = 'ref'
  reference_vector = 'ref'
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./disp_z]
  [../]
[]

[AuxVariables]
  [./stress_xx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_zz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./penetration]
  [../]
  [./saved_x]
  [../]
  [./saved_y]
  [../]
  [./saved_z]
  [../]
  [./diag_saved_x]
  [../]
  [./diag_saved_y]
  [../]
  [./diag_saved_z]
  [../]
  [./inc_slip_x]
  [../]
  [./inc_slip_y]
  [../]
  [./inc_slip_z]
  [../]
  [./accum_slip_x]
  [../]
  [./accum_slip_y]
  [../]
  [./accum_slip_z]
  [../]
[]

[Kernels]
  [./TensorMechanics]
    use_displaced_mesh = true
    save_in = 'saved_x saved_y saved_z'
    extra_vector_tags = 'ref'
  [../]
[]

[AuxKernels]
  [./stress_xx]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xx
    index_i = 0
    index_j = 0
    execute_on = timestep_end
  [../]
  [./stress_yy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yy
    index_i = 1
    index_j = 1
    execute_on = timestep_end
  [../]
  [./stress_xy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xy
    index_i = 0
    index_j = 1
    execute_on = timestep_end
  [../]
  [./stress_zz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_zz
    index_i = 2
    index_j = 2
    execute_on = timestep_end
  [../]
  [./inc_slip_x]
    type = PenetrationAux
    variable = inc_slip_x
    execute_on = timestep_begin
    boundary = 4
    paired_boundary = 3
  [../]
  [./inc_slip_y]
    type = PenetrationAux
    variable = inc_slip_y
    execute_on = timestep_begin
    boundary = 4
    paired_boundary = 3
  [../]
  [./accum_slip_x]
    type = PenetrationAux
    variable = accum_slip_x
    execute_on = timestep_end
    boundary = 4
    paired_boundary = 3
  [../]
  [./accum_slip_y]
    type = PenetrationAux
    variable = accum_slip_y
    execute_on = timestep_end
    boundary = 4
    paired_boundary = 3
  [../]
  [./penetration]
    type = PenetrationAux
    variable = penetration
    boundary = 4
    paired_boundary = 3
  [../]
[]

[Postprocessors]
  [./bot_react_x]
    type = NodalSum
    variable = saved_x
    boundary = 1
  [../]
  [./bot_react_y]
    type = NodalSum
    variable = saved_y
    boundary = 1
  [../]
  [./top_react_x]
    type = NodalSum
    variable = saved_x
    boundary = 5
  [../]
  [./top_react_y]
    type = NodalSum
    variable = saved_y
    boundary = 5
  [../]
  [./ref_resid_x]
    type = NodalL2Norm
    execute_on = timestep_end
    variable = saved_x
  [../]
  [./ref_resid_y]
    type = NodalL2Norm
    execute_on = timestep_end
    variable = saved_y
  [../]
  [./sigma_yy]
    type = ElementAverageValue
    variable = stress_yy
  [../]
  [./sigma_zz]
    type = ElementAverageValue
    variable = stress_zz
  [../]
  [./disp_x28]
    type = NodalVariableValue
    nodeid = 27
    variable = disp_x
  [../]
  [./disp_x33]
    type = NodalVariableValue
    nodeid = 32
    variable = disp_x
  [../]
  [./disp_y28]
    type = NodalVariableValue
    nodeid = 27
    variable = disp_y
  [../]
  [./disp_y33]
    type = NodalVariableValue
    nodeid = 32
    variable = disp_y
  [../]
  [./_dt]
    type = TimestepSize
  [../]
  [./num_lin_it]
    type = NumLinearIterations
  [../]
  [./num_nonlin_it]
    type = NumNonlinearIterations
  [../]
[]

[BCs]
  [./bot_y]
    type = DirichletBC
    variable = disp_y
    boundary = 1
    value = 0.0
  [../]
  [./side_x]
    type = DirichletBC
    variable = disp_x
    boundary = 2
    value = 0.0
  [../]
  [./back_z]
    type = DirichletBC
    variable = disp_z
    boundary = 6
    value = 0.0
  [../]
  [./top_press]
    type = Pressure
    variable = disp_y
    boundary = 5
    factor = 109.89
  [../]
[]

[Materials]
  [./bot_elas_tens]
    type = ComputeIsotropicElasticityTensor
    block = '1'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./bot_strain]
    type = ComputeFiniteStrain
    block = '1'
  [../]
  [./bot_stress]
    type = ComputeFiniteStrainElasticStress
    block = '1'
  [../]
  [./top_elas_tens]
    type = ComputeIsotropicElasticityTensor
    block = '2'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./top_strain]
    type = ComputeFiniteStrain
    block = '2'
  [../]
  [./top_stress]
    type = ComputeFiniteStrainElasticStress
    block = '2'
  [../]
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'

  petsc_options_iname = '-pc_type -pc_factor_mat_solver_type'
  petsc_options_value = 'lu     superlu_dist'

  line_search = 'none'

  nl_abs_tol = 1e-8
  nl_rel_tol = 1e-7
  l_max_its = 50
  nl_max_its = 100
  dt = 1.0
  end_time = 1.0
  num_steps = 10
  dtmin = 1.0
  l_tol = 1e-5
[]

[VectorPostprocessors]
  [./x_disp]
    type = NodalValueSampler
    variable = disp_x
    boundary = '1 3 4 5'
    sort_by = id
  [../]
  [./y_disp]
    type = NodalValueSampler
    variable = disp_y
    boundary = '1 3 4 5'
    sort_by = id
  [../]
  [./cont_press]
    type = NodalValueSampler
    variable = contact_pressure
    boundary = '3'
    sort_by = id
  [../]
[]

[Outputs]
  print_linear_residuals = true
  perf_graph = true
  [./exodus]
    type = Exodus
    elemental_as_nodal = true
  [../]
  [./console]
    type = Console
    max_rows = 5
  [../]
  [./chkfile]
    type = CSV
    show = 'bot_react_x bot_react_y disp_x28 disp_y28 disp_x33 disp_y33 stress_yy stress_zz top_react_x top_react_y x_disp y_disp cont_press'
    execute_vector_postprocessors_on = timestep_end
  [../]
  [./outfile]
    type = CSV
    delimiter = ' '
    execute_vector_postprocessors_on = none
  [../]
[]

[Contact]
  [./leftright]
    secondary = 3
    primary = 4
    normalize_penalty = true
    tangential_tolerance = 1e-3
    penalty = 1e+7
    al_penetration_tolerance = 1e-8
  [../]
[]

(modules/xfem/test/tests/moving_interface/moving_bimaterial_finite_strain_esm.i)

# This test is for two layer materials with different youngs modulus with AD
# The global stress is determined by switching the stress based on level set values
# The material interface is marked by a level set function
# The two layer materials are glued together

[GlobalParams]
  displacements = 'disp_x disp_y'
[]

[XFEM]
  output_cut_plane = true
[]

[UserObjects]
  [level_set_cut_uo]
    type = LevelSetCutUserObject
    level_set_var = ls
    heal_always = true
  []
  [esm]
    type = CutElementSubdomainModifier
    geometric_cut_userobject = level_set_cut_uo
    apply_initial_conditions = false
  []
[]

[Mesh]
  use_displaced_mesh = true
  [generated_mesh]
    type = GeneratedMeshGenerator
    dim = 2
    nx = 10
    ny = 10
    xmin = 0
    xmax = 5
    ymin = 0
    ymax = 5
    elem_type = QUAD4
  []
  [bottom]
    type = SubdomainBoundingBoxGenerator
    input = generated_mesh
    block_id = 0
    bottom_left = '0 0 0'
    top_right = '5 2.5 0'
  []
  [top]
    type = SubdomainBoundingBoxGenerator
    input = bottom
    block_id = 1
    bottom_left = '0 2.5 0'
    top_right = '5 5 0'
  []
[]

[Functions]
  [ls_func]
    type = ParsedFunction
    expression = 'y-2.73+t'
  []
[]

[Variables]
  [disp_x]
  []
  [disp_y]
  []
[]

[AuxVariables]
  [ls]
  []
  [strain_xx]
    order = CONSTANT
    family = MONOMIAL
  []
  [strain_yy]
    order = CONSTANT
    family = MONOMIAL
  []
  [strain_xy]
    order = CONSTANT
    family = MONOMIAL
  []
  [stress_xx]
    order = CONSTANT
    family = MONOMIAL
  []
  [stress_yy]
    order = CONSTANT
    family = MONOMIAL
  []
  [stress_xy]
    order = CONSTANT
    family = MONOMIAL
  []
[]

[AuxKernels]
  [ls_function]
    type = FunctionAux
    variable = ls
    function = ls_func
  []
  [strain_xx]
    type = RankTwoAux
    variable = strain_xx
    rank_two_tensor = total_strain
    index_i = 0
    index_j = 0
  []
  [strain_yy]
    type = RankTwoAux
    variable = strain_yy
    rank_two_tensor = total_strain
    index_i = 1
    index_j = 1
  []
  [strain_xy]
    type = RankTwoAux
    variable = strain_xy
    rank_two_tensor = total_strain
    index_i = 0
    index_j = 1
  []
  [stress_xx]
    type = RankTwoAux
    variable = stress_xx
    rank_two_tensor = stress
    index_i = 0
    index_j = 0
  []
  [stress_xy]
    type = RankTwoAux
    variable = stress_xy
    rank_two_tensor = stress
    index_i = 0
    index_j = 1
  []
  [stress_yy]
    type = RankTwoAux
    variable = stress_yy
    rank_two_tensor = stress
    index_i = 1
    index_j = 1
  []
[]

[Kernels]
  [solid_x]
    type = StressDivergenceTensors
    variable = disp_x
    component = 0
    use_displaced_mesh = true
  []
  [solid_y]
    type = StressDivergenceTensors
    variable = disp_y
    component = 1
    use_displaced_mesh = true
  []
[]

[Constraints]
  [dispx_constraint]
    type = XFEMSingleVariableConstraint
    use_displaced_mesh = false
    variable = disp_x
    alpha = 1e8
    geometric_cut_userobject = 'level_set_cut_uo'
  []
  [dispy_constraint]
    type = XFEMSingleVariableConstraint
    use_displaced_mesh = false
    variable = disp_y
    alpha = 1e8
    geometric_cut_userobject = 'level_set_cut_uo'
  []
[]

[BCs]
  [bottomx]
    type = DirichletBC
    boundary = bottom
    variable = disp_x
    value = 0.0
  []
  [bottomy]
    type = DirichletBC
    boundary = bottom
    variable = disp_y
    value = 0.0
  []
  [topx]
    type = FunctionDirichletBC
    boundary = top
    variable = disp_x
    function = 0.03*t
  []
  [topy]
    type = FunctionDirichletBC
    boundary = top
    variable = disp_y
    function = '0.03*t'
  []
[]

[Materials]
  [elasticity_tensor_A]
    type = ComputeIsotropicElasticityTensor
    block = 1
    youngs_modulus = 1e9
    poissons_ratio = 0.3
  []
  [strain_A]
    type = ComputeFiniteStrain
    block = 1
  []
  [stress_A]
    type = ComputeFiniteStrainElasticStress
    block = 1
  []
  [elasticity_tensor_B]
    type = ComputeIsotropicElasticityTensor
    block = 0
    youngs_modulus = 1e7
    poissons_ratio = 0.3
  []
  [strain_B]
    type = ComputeFiniteStrain
    block = 0
  []
  [stress_B]
    type = ComputeFiniteStrainElasticStress
    block = 0
  []
[]

[Postprocessors]
  [disp_x_norm]
    type = ElementL2Norm
    variable = disp_x
  []
  [disp_y_norm]
    type = ElementL2Norm
    variable = disp_y
  []
[]

[Executioner]
  type = Transient

  solve_type = NEWTON
  petsc_options_iname = '-pc_type'
  petsc_options_value = 'lu'
  automatic_scaling = true

  # controls for nonlinear iterations
  nl_max_its = 15
  nl_rel_tol = 1e-13
  nl_abs_tol = 1e-50

  # time control
  start_time = 0.0
  dt = 0.1
  num_steps = 4

  max_xfem_update = 1
[]

[Outputs]
  print_linear_residuals = false
  exodus = true
[]

(modules/contact/test/tests/mortar_dynamics/block-dynamics-action.i)

starting_point = 2e-1
offset = -0.19

[GlobalParams]
  displacements = 'disp_x disp_y'
[]

[Mesh]
  [file]
    type = FileMeshGenerator
    file = long-bottom-block-no-lower-d.e
  []
[]

[Variables]
  [disp_x]
    block = '1 2'
  []
  [disp_y]
    block = '1 2'
  []
[]

[ICs]
  [disp_y]
    block = 2
    variable = disp_y
    value = '${fparse starting_point + offset}'
    type = ConstantIC
  []
[]

[Kernels]
  [DynamicTensorMechanics]
    displacements = 'disp_x disp_y'
    generate_output = 'stress_xx stress_yy'
    strain = FINITE
    block = '1 2'
    stiffness_damping_coefficient = 1.0
    hht_alpha = 0.0
  []
  [inertia_x]
    type = InertialForce
    variable = disp_x
    velocity = vel_x
    acceleration = accel_x
    beta = 0.25
    gamma = 0.5
    alpha = 0
    eta = 0.0
    block = '1 2'
  []
  [inertia_y]
    type = InertialForce
    variable = disp_y
    velocity = vel_y
    acceleration = accel_y
    beta = 0.25
    gamma = 0.5
    alpha = 0
    eta = 0.0
    block = '1 2'
  []
[]

[Materials]
  [elasticity_2]
    type = ComputeIsotropicElasticityTensor
    block = '2'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  []
  [elasticity_1]
    type = ComputeIsotropicElasticityTensor
    block = '1'
    youngs_modulus = 1e8
    poissons_ratio = 0.3
  []
  [stress]
    type = ComputeFiniteStrainElasticStress
    block = '1 2'
  []
  [strain]
    type = ComputeFiniteStrain
    block = '1 2'
  []
  [density]
    type = GenericConstantMaterial
    block = '1 2'
    prop_names = 'density'
    prop_values = '7750'
  []
[]

[AuxVariables]
  [vel_x]
    block = '1 2'
  []
  [accel_x]
    block = '1 2'
  []
  [vel_y]
    block = '1 2'
  []
  [accel_y]
    block = '1 2'
  []
  [vel_z]
    block = '1 2'
  []
  [accel_z]
    block = '1 2'
  []
[]

[AuxKernels]
  [accel_x]
    type = NewmarkAccelAux
    variable = accel_x
    displacement = disp_x
    velocity = vel_x
    beta = 0.25
    execute_on = 'LINEAR timestep_end'
  []
  [vel_x]
    type = NewmarkVelAux
    variable = vel_x
    acceleration = accel_x
    gamma = 0.5
    execute_on = 'LINEAR timestep_end'
  []
  [accel_y]
    type = NewmarkAccelAux
    variable = accel_y
    displacement = disp_y
    velocity = vel_y
    beta = 0.25
    execute_on = 'LINEAR timestep_end'
  []
  [vel_y]
    type = NewmarkVelAux
    variable = vel_y
    acceleration = accel_y
    gamma = 0.5
    execute_on = 'LINEAR timestep_end'
  []
[]

[Contact]
  [mechanical]
    primary = 20
    secondary = 10
    formulation = mortar
    model = frictionless
    c_normal = 1e4
    capture_tolerance = 1.0e-5
  []
[]

[BCs]
  [botx]
    type = DirichletBC
    variable = disp_x
    boundary = 40
    value = 0.0
  []
  [boty]
    type = DirichletBC
    variable = disp_y
    boundary = 40
    value = 0.0
  []
  [topy]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = 30
    function = '${starting_point} * cos(2 * pi / 4 * t) + ${offset}'
  []
  [leftx]
    type = FunctionDirichletBC
    variable = disp_x
    boundary = 50
    function = '1e-2 * t'
  []
[]

[Executioner]
  type = Transient
  end_time = 75
  dt = 0.05
  dtmin = .05
  solve_type = 'PJFNK'
  petsc_options = '-snes_converged_reason -ksp_converged_reason -pc_svd_monitor '
                  '-snes_linesearch_monitor -snes_ksp_ew'
  petsc_options_iname = '-pc_type -pc_factor_shift_type -pc_factor_shift_amount -mat_mffd_err '
  petsc_options_value = 'lu       NONZERO               1e-15                   1e-5'
  nl_max_its = 20
  line_search = 'none'
  snesmf_reuse_base = false

  [TimeIntegrator]
    type = NewmarkBeta
    beta = 0.25
    gamma = 0.5
  []
[]

[Debug]
  show_var_residual_norms = true
[]

[Outputs]
  exodus = true
  checkpoint = true
[]

[Preconditioning]
  [smp]
    type = SMP
    full = true
  []
[]

[Postprocessors]
  active = ''
  [num_nl]
    type = NumNonlinearIterations
  []
  [cumulative]
    type = CumulativeValuePostprocessor
    postprocessor = num_nl
  []
[]

(modules/solid_mechanics/test/tests/hyperelastic_viscoplastic/one_elem.i)

[Mesh]
  type = GeneratedMesh
  dim = 3
  elem_type = HEX8
  displacements = 'ux uy uz'
[]

[Variables]
  [./ux]
    block = 0
  [../]
  [./uy]
    block = 0
  [../]
  [./uz]
    block = 0
  [../]
[]

[Kernels]
  [SolidMechanics]
    displacements = 'ux uy uz'
    use_displaced_mesh = true
  [../]
[]

[AuxVariables]
  [./stress_zz]
    order = CONSTANT
    family = MONOMIAL
    block = 0
  [../]
  [./peeq]
    order = CONSTANT
    family = MONOMIAL
    block = 0
  [../]
  [./fp_zz]
    order = CONSTANT
    family = MONOMIAL
    block = 0
  [../]
[]

[AuxKernels]
  [./stress_zz]
    type = RankTwoAux
    variable = stress_zz
    rank_two_tensor = stress
    index_j = 2
    index_i = 2
    execute_on = timestep_end
    block = 0
  [../]
  [./fp_zz]
    type = RankTwoAux
    variable = fp_zz
    rank_two_tensor = fp
    index_j = 2
    index_i = 2
    execute_on = timestep_end
    block = 0
  [../]
  [./peeq]
    type = MaterialRealAux
    variable = peeq
    property = ep_eqv
    execute_on = timestep_end
    block = 0
  [../]
[]

[BCs]
  [./symmy]
    type = DirichletBC
    variable = uy
    boundary = bottom
    value = 0
  [../]
  [./symmx]
    type = DirichletBC
    variable = ux
    boundary = left
    value = 0
  [../]
  [./symmz]
    type = DirichletBC
    variable = uz
    boundary = back
    value = 0
  [../]
  [./tdisp]
    type = FunctionDirichletBC
    variable = uz
    boundary = front
    function = '0.01*t'
  [../]
[]

[UserObjects]
  [./flowstress]
    type = HEVPRambergOsgoodHardening
    yield_stress = 100
    hardening_exponent = 0.1
    reference_plastic_strain = 0.002
    intvar_prop_name = ep_eqv
  [../]
  [./flowrate]
    type = HEVPFlowRatePowerLawJ2
    reference_flow_rate = 0.0001
    flow_rate_exponent = 50.0
    flow_rate_tol = 1
    strength_prop_name = flowstress
  [../]
  [./ep_eqv]
     type = HEVPEqvPlasticStrain
     intvar_rate_prop_name = ep_eqv_rate
  [../]
  [./ep_eqv_rate]
     type = HEVPEqvPlasticStrainRate
     flow_rate_prop_name = flowrate
  [../]
[]

[Materials]
  [./strain]
    type = ComputeFiniteStrain
    block = 0
    displacements = 'ux uy uz'
  [../]
  [./viscop]
    type = FiniteStrainHyperElasticViscoPlastic
    block = 0
    resid_abs_tol = 1e-18
    resid_rel_tol = 1e-8
    maxiters = 50
    max_substep_iteration = 5
    flow_rate_user_objects = 'flowrate'
    strength_user_objects = 'flowstress'
    internal_var_user_objects = 'ep_eqv'
    internal_var_rate_user_objects = 'ep_eqv_rate'
  [../]
  [./elasticity_tensor]
    type = ComputeElasticityTensor
    block = 0
    C_ijkl = '2.8e5 1.2e5 1.2e5 2.8e5 1.2e5 2.8e5 0.8e5 0.8e5 0.8e5'
    fill_method = symmetric9
  [../]
[]

[Postprocessors]
  [./stress_zz]
    type = ElementAverageValue
    variable = stress_zz
    block = 'ANY_BLOCK_ID 0'
  [../]
  [./fp_zz]
    type = ElementAverageValue
    variable = fp_zz
    block = 'ANY_BLOCK_ID 0'
  [../]
  [./peeq]
    type = ElementAverageValue
    variable = peeq
    block = 'ANY_BLOCK_ID 0'
  [../]
[]

[Preconditioning]
  [./smp]
    type = SMP
    full = true
  [../]
[]

[Executioner]
  type = Transient
  dt = 0.02
  #Preconditioned JFNK (default)
  solve_type = 'PJFNK'
  petsc_options_iname = -pc_hypre_type
  petsc_options_value = boomerang
  dtmax = 10.0
  nl_rel_tol = 1e-10
  dtmin = 0.02
  num_steps = 10
[]

[Outputs]
  file_base = one_elem
  exodus = true
  csv = false
[]

(modules/solid_mechanics/test/tests/jacobian_damper/cube_load.i)

[Mesh]
  type = GeneratedMesh
  dim = 3
  nx = 1
  ny = 1
  nz = 1
  displacements = 'disp_x disp_y disp_z'
  # This test uses ElementalVariableValue postprocessors on specific
  # elements, so element numbering needs to stay unchanged
  allow_renumbering = false
[]

[Variables]
  [./disp_x]
    order = FIRST
    family = LAGRANGE
  [../]

  [./disp_y]
    order = FIRST
    family = LAGRANGE
  [../]

  [./disp_z]
    order = FIRST
    family = LAGRANGE
  [../]
[]

[AuxVariables]
  [./stress_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]

  [./total_strain_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
[]

[Functions]
  [./top_pull]
    type = PiecewiseLinear
    x = '0 1     2'
    y = '0 0.025 0.05'
  [../]
[]

[Kernels]
  [SolidMechanics]
    displacements = 'disp_x disp_y disp_z'
    use_displaced_mesh = true
  [../]
[]

[AuxKernels]
  [./stress_yy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yy
    index_i = 1
    index_j = 1
  [../]

  [./total_strain_yy]
    type = RankTwoAux
    rank_two_tensor = total_strain
    variable = total_strain_yy
    index_i = 1
    index_j = 1
  [../]
[]


[BCs]
  [./y_pull_function]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = 3
    function = top_pull
  [../]

  [./x_bot]
    type = DirichletBC
    variable = disp_x
    boundary = 4
    value = 0.0
  [../]

  [./y_bot]
    type = DirichletBC
    variable = disp_y
    boundary = 1
    value = 0.0
  [../]

  [./z_bot]
    type = DirichletBC
    variable = disp_z
    boundary = 0
    value = 0.0
  [../]
[]

[Postprocessors]
  [./stress_yy_el]
    type = ElementalVariableValue
    variable = stress_yy
    elementid = 0
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeIsotropicElasticityTensor
    poissons_ratio = 0.3
    youngs_modulus = 2e5
  [../]
  [./strain]
    type = ComputeFiniteStrain
    displacements = 'disp_x disp_y disp_z'
  [../]
  [./stress]
    type = ComputeFiniteStrainElasticStress
  [../]
[]

[Dampers]
  [./disp_x_damp]
    type = ElementJacobianDamper
    max_increment = 0.002
    displacements = 'disp_x disp_y disp_z'
  [../]
[]

[Executioner]
  type = Transient

  #Preconditioned JFNK (default)
  solve_type = 'PJFNK'

  petsc_options = '-snes_ksp_ew'
  petsc_options_iname = '-ksp_gmres_restart -pc_type -pc_hypre_type -pc_hypre_boomeramg_max_iter'
  petsc_options_value = '201                hypre    boomeramg      4'

  line_search = 'none'

  l_max_its = 100
  nl_max_its = 100
  nl_rel_tol = 1e-12
  nl_abs_tol = 1e-10
  l_tol = 1e-9

  start_time = 0.0
  end_time = 2
  dt = 1
[]

[Outputs]
  exodus = true
[]

(modules/solid_mechanics/test/tests/crystal_plasticity/monolithic_material_based/crysp_user_object.i)

[Mesh]
  type = GeneratedMesh
  dim = 2
  elem_type = QUAD4
  displacements = 'disp_x disp_y'
  nx = 2
  ny = 2
[]

[Variables]
  [./disp_x]
    block = 0
  [../]
  [./disp_y]
    block = 0
  [../]
[]

[GlobalParams]
  volumetric_locking_correction=true
[]

[AuxVariables]
  [./stress_yy]
    order = CONSTANT
    family = MONOMIAL
    block = 0
  [../]
  [./e_yy]
    order = CONSTANT
    family = MONOMIAL
    block = 0
  [../]
  [./fp_yy]
    order = CONSTANT
    family = MONOMIAL
    block = 0
  [../]
  [./rotout]
    order = CONSTANT
    family = MONOMIAL
    block = 0
  [../]
  [./gss1]
    order = CONSTANT
    family = MONOMIAL
    block = 0
  [../]
[]

[Functions]
  [./tdisp]
    type = ParsedFunction
    expression = 0.01*t
  [../]
[]

[UserObjects]
  [./prop_read]
    type = PropertyReadFile
    prop_file_name = 'euler_ang_file.txt'
    # Enter file data as prop#1, prop#2, .., prop#nprop
    nprop = 3
    read_type = element
  [../]
[]

[AuxKernels]
  [./stress_yy]
    type = RankTwoAux
    variable = stress_yy
    rank_two_tensor = stress
    index_j = 1
    index_i = 1
    execute_on = timestep_end
    block = 0
  [../]
  [./e_yy]
    type = RankTwoAux
    variable = e_yy
    rank_two_tensor = lage
    index_j = 1
    index_i = 1
    execute_on = timestep_end
    block = 0
  [../]
  [./fp_yy]
    type = RankTwoAux
    variable = fp_yy
    rank_two_tensor = fp
    index_j = 1
    index_i = 1
    execute_on = timestep_end
    block = 0
  [../]
  [./gss1]
    type = MaterialStdVectorAux
    variable = gss1
    property = gss
    index = 0
    execute_on = timestep_end
    block = 0
  [../]
[]

[BCs]
  [./fix_x]
    type = DirichletBC
    variable = disp_x
    boundary = 'left'
    value = 0
  [../]
  [./fix_y]
    type = DirichletBC
    variable = disp_y
    boundary = 'bottom'
    value = 0
  [../]
  [./tdisp]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = top
    function = tdisp
  [../]
[]

[Materials]
  [./crysp]
    type = FiniteStrainCrystalPlasticity
    block = 0
    gtol = 1e-2
    slip_sys_file_name = input_slip_sys.txt
    nss = 12
    num_slip_sys_flowrate_props = 2 #Number of properties in a slip system
    flowprops = '1 4 0.001 0.1 5 8 0.001 0.1 9 12 0.001 0.1'
    hprops = '1.0 541.5 60.8 109.8 2.5'
    gprops = '1 4 60.8 5 8 60.8 9 12 60.8'
    tan_mod_type = exact
  [../]
  [./strain]
    type = ComputeFiniteStrain
    block = 0
    displacements = 'disp_x disp_y'
  [../]
  [./elasticity_tensor]
    type = ComputeElasticityTensorCP
    block = 0
    C_ijkl = '1.684e5 1.214e5 1.214e5 1.684e5 1.214e5 1.684e5 0.754e5 0.754e5 0.754e5'
    fill_method = symmetric9
    read_prop_user_object = prop_read
  [../]
[]

[Postprocessors]
  [./stress_yy]
    type = ElementAverageValue
    variable = stress_yy
    block = 'ANY_BLOCK_ID 0'
  [../]
  [./e_yy]
    type = ElementAverageValue
    variable = e_yy
    block = 'ANY_BLOCK_ID 0'
  [../]
  [./fp_yy]
    type = ElementAverageValue
    variable = fp_yy
    block = 'ANY_BLOCK_ID 0'
  [../]
  [./gss1]
    type = ElementAverageValue
    variable = gss1
    block = 'ANY_BLOCK_ID 0'
  [../]
[]

[Preconditioning]
  [./smp]
    type = SMP
    full = true
  [../]
[]

[Executioner]
  type = Transient

  #Preconditioned JFNK (default)
  solve_type = 'PJFNK'

  petsc_options_iname = '-pc_type'
  petsc_options_value = 'lu'

  nl_rel_tol = 1e-10
  nl_abs_tol = 1e-10

  dt = 0.01
  dtmax = 10.0
  dtmin = 0.01

  num_steps = 10
[]

[Outputs]
  file_base = crysp_user_object_out
  exodus = true
[]

[Kernels]
  [SolidMechanics]
    displacements = 'disp_x disp_y'
    use_displaced_mesh = true
  [../]
[]

(modules/contact/test/tests/verification/patch_tests/brick_3/brick3_template1.i)

[GlobalParams]
  order = SECOND
  displacements = 'disp_x disp_y disp_z'
[]

[Mesh]
  file = brick3_mesh.e
[]

[Problem]
  type = ReferenceResidualProblem
  extra_tag_vectors = 'ref'
  reference_vector = 'ref'
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./disp_z]
  [../]
[]

[AuxVariables]
  [./stress_xx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_zz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./penetration]
  [../]
  [./saved_x]
  [../]
  [./saved_y]
  [../]
  [./saved_z]
  [../]
  [./diag_saved_x]
  [../]
  [./diag_saved_y]
  [../]
  [./diag_saved_z]
  [../]
  [./inc_slip_x]
  [../]
  [./inc_slip_y]
  [../]
  [./inc_slip_z]
  [../]
  [./accum_slip_x]
  [../]
  [./accum_slip_y]
  [../]
  [./accum_slip_z]
  [../]
[]

[Kernels]
  [./TensorMechanics]
    use_displaced_mesh = true
    save_in = 'saved_x saved_y saved_z'
    extra_vector_tags = 'ref'
  [../]
[]

[AuxKernels]
  [./stress_xx]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xx
    index_i = 0
    index_j = 0
    execute_on = timestep_end
  [../]
  [./stress_yy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yy
    index_i = 1
    index_j = 1
    execute_on = timestep_end
  [../]
  [./stress_xy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xy
    index_i = 0
    index_j = 1
    execute_on = timestep_end
  [../]
  [./stress_zz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_zz
    index_i = 2
    index_j = 2
    execute_on = timestep_end
  [../]
  [./inc_slip_x]
    type = PenetrationAux
    variable = inc_slip_x
    execute_on = timestep_begin
    boundary = 4
    paired_boundary = 3
  [../]
  [./inc_slip_y]
    type = PenetrationAux
    variable = inc_slip_y
    execute_on = timestep_begin
    boundary = 4
    paired_boundary = 3
  [../]
  [./accum_slip_x]
    type = PenetrationAux
    variable = accum_slip_x
    execute_on = timestep_end
    boundary = 4
    paired_boundary = 3
  [../]
  [./accum_slip_y]
    type = PenetrationAux
    variable = accum_slip_y
    execute_on = timestep_end
    boundary = 4
    paired_boundary = 3
  [../]
  [./penetration]
    type = PenetrationAux
    variable = penetration
    boundary = 4
    paired_boundary = 3
  [../]
[]

[Postprocessors]
  [./bot_react_x]
    type = NodalSum
    variable = saved_x
    boundary = 1
  [../]
  [./bot_react_y]
    type = NodalSum
    variable = saved_y
    boundary = 1
  [../]
  [./top_react_x]
    type = NodalSum
    variable = saved_x
    boundary = 5
  [../]
  [./top_react_y]
    type = NodalSum
    variable = saved_y
    boundary = 5
  [../]
  [./ref_resid_x]
    type = NodalL2Norm
    execute_on = timestep_end
    variable = saved_x
  [../]
  [./ref_resid_y]
    type = NodalL2Norm
    execute_on = timestep_end
    variable = saved_y
  [../]
  [./sigma_yy]
    type = ElementAverageValue
    variable = stress_yy
  [../]
  [./sigma_zz]
    type = ElementAverageValue
    variable = stress_zz
  [../]
  [./disp_x28]
    type = NodalVariableValue
    nodeid = 27
    variable = disp_x
  [../]
  [./disp_x33]
    type = NodalVariableValue
    nodeid = 32
    variable = disp_x
  [../]
  [./disp_y28]
    type = NodalVariableValue
    nodeid = 27
    variable = disp_y
  [../]
  [./disp_y33]
    type = NodalVariableValue
    nodeid = 32
    variable = disp_y
  [../]
  [./_dt]
    type = TimestepSize
  [../]
  [./num_lin_it]
    type = NumLinearIterations
  [../]
  [./num_nonlin_it]
    type = NumNonlinearIterations
  [../]
[]

[BCs]
  [./bot_y]
    type = DirichletBC
    variable = disp_y
    boundary = 1
    value = 0.0
  [../]
  [./side_x]
    type = DirichletBC
    variable = disp_x
    boundary = 2
    value = 0.0
  [../]
  [./back_z]
    type = DirichletBC
    variable = disp_z
    boundary = 6
    value = 0.0
  [../]
  [./top_press]
    type = Pressure
    variable = disp_y
    boundary = 5
    factor = 109.89
  [../]
[]

[Materials]
  [./bot_elas_tens]
    type = ComputeIsotropicElasticityTensor
    block = '1'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./bot_strain]
    type = ComputeFiniteStrain
    block = '1'
  [../]
  [./bot_stress]
    type = ComputeFiniteStrainElasticStress
    block = '1'
  [../]
  [./top_elas_tens]
    type = ComputeIsotropicElasticityTensor
    block = '2'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./top_strain]
    type = ComputeFiniteStrain
    block = '2'
  [../]
  [./top_stress]
    type = ComputeFiniteStrainElasticStress
    block = '2'
  [../]
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'

  petsc_options_iname = '-pc_type -pc_factor_mat_solver_type'
  petsc_options_value = 'lu     superlu_dist'

  line_search = 'none'

  nl_abs_tol = 1e-9
  nl_rel_tol = 1e-8
  l_max_its = 50
  nl_max_its = 100
  dt = 1.0
  end_time = 1.0
  num_steps = 10
  dtmin = 1.0
  l_tol = 1e-5
[]

[VectorPostprocessors]
  [./x_disp]
    type = NodalValueSampler
    variable = disp_x
    boundary = '1 3 4 5'
    sort_by = id
  [../]
  [./y_disp]
    type = NodalValueSampler
    variable = disp_y
    boundary = '1 3 4 5'
    sort_by = id
  [../]
  [./cont_press]
    type = NodalValueSampler
    variable = contact_pressure
    boundary = '3'
    sort_by = id
  [../]
[]

[Outputs]
  print_linear_residuals = true
  perf_graph = true
  [./exodus]
    type = Exodus
    elemental_as_nodal = true
  [../]
  [./console]
    type = Console
    max_rows = 5
  [../]
  [./chkfile]
    type = CSV
    show = 'bot_react_x bot_react_y disp_x28 disp_y28 disp_x33 disp_y33 stress_yy stress_zz top_react_x top_react_y x_disp y_disp cont_press'
    execute_vector_postprocessors_on = timestep_end
  [../]
  [./outfile]
    type = CSV
    delimiter = ' '
    execute_vector_postprocessors_on = none
  [../]
[]

[Contact]
  [./leftright]
    secondary = 3
    primary = 4
    normalize_penalty = true
    tangential_tolerance = 1e-3
    penalty = 1e+9
  [../]
[]

(modules/solid_mechanics/test/tests/stress_recovery/patch/patch_finite_stress.i)

[GlobalParams]
  displacements = 'disp_x disp_y'
[]

[Mesh]
  type = GeneratedMesh
  dim = 2
  nx = 2
  ny = 2
  elem_type = QUAD4
[]

[Variables]
  [disp_x]
    order = FIRST
    family = LAGRANGE
  []
  [disp_y]
    order = FIRST
    family = LAGRANGE
  []
[]

[AuxVariables]
  [stress_xx]
    order = FIRST
    family = MONOMIAL
  []
  [stress_yy]
    order = FIRST
    family = MONOMIAL
  []
  [stress_xx_recovered]
    order = FIRST
    family = LAGRANGE
  []
  [stress_yy_recovered]
    order = FIRST
    family = LAGRANGE
  []
[]

[AuxKernels]
  [stress_xx]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xx
    index_i = 0
    index_j = 0
    execute_on = 'timestep_end'
  []
  [stress_yy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yy
    index_i = 1
    index_j = 1
    execute_on = 'timestep_end'
  []
  [stress_xx_recovered]
    type = NodalPatchRecoveryAux
    variable = stress_xx_recovered
    nodal_patch_recovery_uo = stress_xx_patch
    execute_on = 'TIMESTEP_END'
  []
  [stress_yy_recovered]
    type = NodalPatchRecoveryAux
    variable = stress_yy_recovered
    nodal_patch_recovery_uo = stress_yy_patch
    execute_on = 'TIMESTEP_END'
  []
[]

[Kernels]
  [solid_x]
    type = StressDivergenceTensors
    variable = disp_x
    component = 0
  []
  [solid_y]
    type = StressDivergenceTensors
    variable = disp_y
    component = 1
  []
[]

[Materials]
  [strain]
    type = ComputeFiniteStrain
  []
  [Cijkl]
    type = ComputeIsotropicElasticityTensor
    poissons_ratio = 0.3
    youngs_modulus = 2.1e+5
  []
  [stress]
    type = ComputeFiniteStrainElasticStress
  []
[]

[BCs]
  [top_xdisp]
    type = FunctionDirichletBC
    variable = disp_x
    boundary = 'top'
    function = 0
  []
  [top_ydisp]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = 'top'
    function = t
  []
  [bottom_xdisp]
    type = FunctionDirichletBC
    variable = disp_x
    boundary = 'bottom'
    function = 0
  []
  [bottom_ydisp]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = 'bottom'
    function = 0
  []
[]

[UserObjects]
  [stress_xx_patch]
    type = NodalPatchRecoveryMaterialProperty
    patch_polynomial_order = FIRST
    property = 'stress'
    component = '0 0'
    execute_on = 'TIMESTEP_END'
  []
  [stress_yy_patch]
    type = NodalPatchRecoveryMaterialProperty
    patch_polynomial_order = FIRST
    property = 'stress'
    component = '1 1'
    execute_on = 'TIMESTEP_END'
  []
[]

[Preconditioning]
  [smp]
    type = SMP
    full = true
    ksp_norm = default
  []
[]

[Executioner]
  type = Transient
  solve_type = NEWTON
  petsc_options_iname = '-ksp_type -pc_type'
  petsc_options_value = 'preonly   lu'
  nl_abs_tol = 1e-8
  nl_rel_tol = 1e-8
  l_max_its = 100
  nl_max_its = 30
  dt = 0.01
  dtmin = 1e-11
  start_time = 0
  end_time = 0.05
[]

[Outputs]
  exodus = true
  print_linear_residuals = false
[]

(modules/solid_mechanics/test/tests/visco/visco_finite_strain.i)

[Mesh]
  type = GeneratedMesh
  dim = 3
  nx = 1
  ny = 1
  nz = 1
  elem_type = HEX8
  displacements = 'disp_x disp_y disp_z'
[]

[Variables]
  [./disp_x]
    order = FIRST
    family = LAGRANGE
  [../]
  [./disp_y]
    order = FIRST
    family = LAGRANGE
  [../]
  [./disp_z]
    order = FIRST
    family = LAGRANGE
  [../]
[]

[AuxVariables]
  [./stress_xx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./strain_xx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./creep_strain_xx]
    order = CONSTANT
    family = MONOMIAL
  [../]
[]

[Kernels]
  [SolidMechanics]
    displacements = 'disp_x disp_y disp_z'
    use_displaced_mesh = true
  [../]
[]

[AuxKernels]
  [./stress_xx]
    type = RankTwoAux
    variable = stress_xx
    rank_two_tensor = stress
    index_j = 0
    index_i = 0
    execute_on = timestep_end
  [../]
  [./strain_xx]
    type = RankTwoAux
    variable = strain_xx
    rank_two_tensor = total_strain
    index_j = 0
    index_i = 0
    execute_on = timestep_end
  [../]
  [./creep_strain_xx]
    type = RankTwoAux
    variable = creep_strain_xx
    rank_two_tensor = creep_strain
    index_j = 0
    index_i = 0
    execute_on = timestep_end
  [../]
[]

[BCs]
  [./symmy]
    type = DirichletBC
    variable = disp_y
    boundary = bottom
    value = 0
  [../]
  [./symmx]
    type = DirichletBC
    variable = disp_x
    boundary = left
    value = 0
  [../]
  [./symmz]
    type = DirichletBC
    variable = disp_z
    boundary = back
    value = 0
  [../]
  [./axial_load]
    type = NeumannBC
    variable = disp_x
    boundary = right
    value    = 10e6
  [../]
[]

[Materials]
  [./kelvin_voigt]
    type = GeneralizedKelvinVoigtModel
    creep_modulus = '10e9 10e9'
    creep_viscosity = '1 10'
    poisson_ratio = 0.2
    young_modulus = 10e9
  [../]
  [./stress]
    type = ComputeMultipleInelasticStress
    inelastic_models = 'creep'
  [../]
  [./creep]
    type = LinearViscoelasticStressUpdate
  [../]
  [./strain]
    type = ComputeFiniteStrain
    displacements = 'disp_x disp_y disp_z'
  [../]
[]

[UserObjects]
  [./update]
    type = LinearViscoelasticityManager
    viscoelastic_model = kelvin_voigt
  [../]
[]

[Postprocessors]
  [./stress_xx]
    type = ElementAverageValue
    variable = stress_xx
    block = 'ANY_BLOCK_ID 0'
  [../]
  [./strain_xx]
    type = ElementAverageValue
    variable = strain_xx
    block = 'ANY_BLOCK_ID 0'
  [../]
  [./creep_strain_xx]
    type = ElementAverageValue
    variable = creep_strain_xx
    block = 'ANY_BLOCK_ID 0'
  [../]
[]

[Preconditioning]
  [./smp]
    type = SMP
    full = true
  [../]
[]

[Executioner]
  type = Transient

  l_max_its  = 100
  l_tol      = 1e-8
  nl_max_its = 50
  nl_rel_tol = 1e-8
  nl_abs_tol = 1e-8

  dtmin = 0.01
  end_time = 100
  [./TimeStepper]
    type = LogConstantDT
    first_dt = 0.1
    log_dt = 0.1
  [../]

[]

[Outputs]
  file_base = visco_finite_strain_out
  exodus = true
[]

(modules/solid_mechanics/test/tests/multi/three_surface06.i)

# Plasticit models:
# SimpleTester0 with a = 0 and b = 1 and strength = 1
# SimpleTester1 with a = 1 and b = 0 and strength = 1
# SimpleTester2 with a = 1 and b = 1 and strength = 1.5
#
# Lame lambda = 0 (Poisson=0).  Lame mu = 0.5E6
#
# A single element is stretched by 1.1E-6m in y direction and 1.0E-6 in z direction.
# trial stress_yy = 1.1 and stress_zz = 1.0
#
# Then SimpleTester1 and SimpleTester2 should activate and the algorithm will return to
# the corner stress_yy=1.0, stress_zz=0.5
# However, this will mean internal1 < 0, so SimpleTester1 will be deactivated and
# then the algorithm will return to
# stress_yy=0.8, stress_zz=0.7
# internal1 should be 0.0, and internal2 should be 0.3

[Mesh]
  type = GeneratedMesh
  dim = 3
  nx = 1
  ny = 1
  nz = 1
  xmin = -0.5
  xmax = 0.5
  ymin = -0.5
  ymax = 0.5
  zmin = -0.5
  zmax = 0.5
[]


[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./disp_z]
  [../]
[]

[Kernels]
  [SolidMechanics]
    displacements = 'disp_x disp_y disp_z'
  [../]
[]


[BCs]
  [./x]
    type = FunctionDirichletBC
    variable = disp_x
    boundary = 'front back'
    function = '0E-6*x'
  [../]
  [./y]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = 'front back'
    function = '1.1E-6*y'
  [../]
  [./z]
    type = FunctionDirichletBC
    variable = disp_z
    boundary = 'front back'
    function = '1.0E-6*z'
  [../]
[]

[AuxVariables]
  [./stress_xx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_zz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./f0]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./f1]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./f2]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./int0]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./int1]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./int2]
    order = CONSTANT
    family = MONOMIAL
  [../]
[]

[AuxKernels]
  [./stress_xx]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xx
    index_i = 0
    index_j = 0
  [../]
  [./stress_xy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xy
    index_i = 0
    index_j = 1
  [../]
  [./stress_xz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xz
    index_i = 0
    index_j = 2
  [../]
  [./stress_yy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yy
    index_i = 1
    index_j = 1
  [../]
  [./stress_yz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yz
    index_i = 1
    index_j = 2
  [../]
  [./stress_zz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_zz
    index_i = 2
    index_j = 2
  [../]
  [./f0]
    type = MaterialStdVectorAux
    property = plastic_yield_function
    index = 0
    variable = f0
  [../]
  [./f1]
    type = MaterialStdVectorAux
    property = plastic_yield_function
    index = 1
    variable = f1
  [../]
  [./f2]
    type = MaterialStdVectorAux
    property = plastic_yield_function
    index = 2
    variable = f2
  [../]
  [./int0]
    type = MaterialStdVectorAux
    property = plastic_internal_parameter
    factor = 1E6
    index = 0
    variable = int0
  [../]
  [./int1]
    type = MaterialStdVectorAux
    property = plastic_internal_parameter
    factor = 1E6
    index = 1
    variable = int1
  [../]
  [./int2]
    type = MaterialStdVectorAux
    property = plastic_internal_parameter
    factor = 1E6
    index = 2
    variable = int2
  [../]
[]

[Postprocessors]
  [./s_xx]
    type = PointValue
    point = '0 0 0'
    variable = stress_xx
  [../]
  [./s_xy]
    type = PointValue
    point = '0 0 0'
    variable = stress_xy
  [../]
  [./s_xz]
    type = PointValue
    point = '0 0 0'
    variable = stress_xz
  [../]
  [./s_yy]
    type = PointValue
    point = '0 0 0'
    variable = stress_yy
  [../]
  [./s_yz]
    type = PointValue
    point = '0 0 0'
    variable = stress_yz
  [../]
  [./s_zz]
    type = PointValue
    point = '0 0 0'
    variable = stress_zz
  [../]
  [./f0]
    type = PointValue
    point = '0 0 0'
    variable = f0
  [../]
  [./f1]
    type = PointValue
    point = '0 0 0'
    variable = f1
  [../]
  [./f2]
    type = PointValue
    point = '0 0 0'
    variable = f2
  [../]
  [./int0]
    type = PointValue
    point = '0 0 0'
    variable = int0
  [../]
  [./int1]
    type = PointValue
    point = '0 0 0'
    variable = int1
  [../]
  [./int2]
    type = PointValue
    point = '0 0 0'
    variable = int2
  [../]
[]

[UserObjects]
  [./simple0]
    type = SolidMechanicsPlasticSimpleTester
    a = 0
    b = 1
    strength = 1
    yield_function_tolerance = 1.0E-9
    internal_constraint_tolerance = 1.0E-9
  [../]
  [./simple1]
    type = SolidMechanicsPlasticSimpleTester
    a = 1
    b = 0
    strength = 1
    yield_function_tolerance = 1.0E-9
    internal_constraint_tolerance = 1.0E-9
  [../]
  [./simple2]
    type = SolidMechanicsPlasticSimpleTester
    a = 1
    b = 1
    strength = 1.5
    yield_function_tolerance = 1.0E-9
    internal_constraint_tolerance = 1.0E-9
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeElasticityTensor
    block = 0
    fill_method = symmetric_isotropic
    C_ijkl = '0 0.5E6'
  [../]
  [./strain]
    type = ComputeFiniteStrain
    block = 0
    displacements = 'disp_x disp_y disp_z'
  [../]
  [./multi]
    type = ComputeMultiPlasticityStress
    block = 0
    ep_plastic_tolerance = 1E-9
    plastic_models = 'simple0 simple1 simple2'
    max_NR_iterations = 2
    min_stepsize = 1
    debug_fspb = crash
    debug_jac_at_stress = '10 0 0 0 10 0 0 0 10'
    debug_jac_at_pm = '1 1'
    debug_jac_at_intnl = '1 1'
    debug_stress_change = 1E-5
    debug_pm_change = '1E-6 1E-6'
    debug_intnl_change = '1E-6 1E-6'
  [../]
[]


[Executioner]
  end_time = 1
  dt = 1
  type = Transient
[]


[Outputs]
  file_base = three_surface06
  exodus = false
  [./csv]
    type = CSV
    [../]
[]

(modules/solid_mechanics/test/tests/mohr_coulomb/except2.i)

# checking for exception error messages
[Mesh]
  type = GeneratedMesh
  dim = 3
  nx = 1
  ny = 1
  nz = 1
  xmin = -0.5
  xmax = 0.5
  ymin = -0.5
  ymax = 0.5
  zmin = -0.5
  zmax = 0.5
[]


[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./disp_z]
  [../]
[]

[Kernels]
  [SolidMechanics]
    displacements = 'disp_x disp_y disp_z'
  [../]
[]


[BCs]
  [./x]
    type = FunctionDirichletBC
    variable = disp_x
    boundary = 'front back'
    function = '1E-6*x'
  [../]
  [./y]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = 'front back'
    function = '1E-6*y'
  [../]
  [./z]
    type = FunctionDirichletBC
    variable = disp_z
    boundary = 'front back'
    function = '1E-6*z'
  [../]
[]

[AuxVariables]
  [./stress_xx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_zz]
    order = CONSTANT
    family = MONOMIAL
  [../]
[]

[AuxKernels]
  [./stress_xx]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xx
    index_i = 0
    index_j = 0
  [../]
  [./stress_xy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xy
    index_i = 0
    index_j = 1
  [../]
  [./stress_xz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xz
    index_i = 0
    index_j = 2
  [../]
  [./stress_yy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yy
    index_i = 1
    index_j = 1
  [../]
  [./stress_yz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yz
    index_i = 1
    index_j = 2
  [../]
  [./stress_zz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_zz
    index_i = 2
    index_j = 2
  [../]
[]

[Postprocessors]
  [./s_xx]
    type = PointValue
    point = '0 0 0'
    variable = stress_xx
  [../]
  [./s_xy]
    type = PointValue
    point = '0 0 0'
    variable = stress_xy
  [../]
  [./s_xz]
    type = PointValue
    point = '0 0 0'
    variable = stress_xz
  [../]
  [./s_yy]
    type = PointValue
    point = '0 0 0'
    variable = stress_yy
  [../]
  [./s_yz]
    type = PointValue
    point = '0 0 0'
    variable = stress_yz
  [../]
  [./s_zz]
    type = PointValue
    point = '0 0 0'
    variable = stress_zz
  [../]
[]

[UserObjects]
  [./mc_coh]
    type = SolidMechanicsHardeningConstant
    value = 10
  [../]
  [./mc_phi]
    type = SolidMechanicsHardeningConstant
    value = 30
    convert_to_radians = true
  [../]
  [./mc_psi]
    type = SolidMechanicsHardeningConstant
    value = 5
    convert_to_radians = true
  [../]
  [./mc]
    type = SolidMechanicsPlasticMohrCoulomb
    cohesion = mc_coh
    friction_angle = mc_phi
    dilation_angle = mc_psi
    mc_tip_smoother = 1
    mc_edge_smoother = 25
    mc_lode_cutoff = -1.0E-6
    yield_function_tolerance = 1E-3
    internal_constraint_tolerance = 1E-9
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeElasticityTensor
    block = 0
    fill_method = symmetric_isotropic
    C_ijkl = '0 1E7'
  [../]
  [./strain]
    type = ComputeFiniteStrain
    block = 0
    displacements = 'disp_x disp_y disp_z'
  [../]
  [./mc]
    type = ComputeMultiPlasticityStress
    block = 0
    ep_plastic_tolerance = 1E-9
    plastic_models = mc
    debug_fspb = crash
    debug_jac_at_stress = '10 0 0 0 10 0 0 0 10'
    debug_jac_at_pm = 1
    debug_jac_at_intnl = 1
    debug_stress_change = 1E-5
    debug_pm_change = 1E-6
    debug_intnl_change = 1E-6
  [../]
[]


[Executioner]
  end_time = 1
  dt = 1
  type = Transient
[]


[Outputs]
  file_base = except2
  exodus = false
  [./csv]
    type = CSV
    [../]
[]

(modules/solid_mechanics/test/tests/crystal_plasticity/monolithic_material_based/crysp_substep.i)

[Mesh]
  type = GeneratedMesh
  dim = 3
  elem_type = HEX8
  displacements = 'ux uy uz'
[]

[Variables]
  [./ux]
    block = 0
  [../]
  [./uy]
    block = 0
  [../]
  [./uz]
    block = 0
  [../]
[]

[AuxVariables]
  [./stress_zz]
    order = CONSTANT
    family = MONOMIAL
    block = 0
  [../]
  [./fp_zz]
    order = CONSTANT
    family = MONOMIAL
    block = 0
  [../]
  [./rotout]
    order = CONSTANT
    family = MONOMIAL
    block = 0
  [../]
  [./e_zz]
    order = CONSTANT
    family = MONOMIAL
    block = 0
  [../]
  [./gss1]
    order = CONSTANT
    family = MONOMIAL
    block = 0
  [../]
[]

[Functions]
  [./tdisp]
    type = ParsedFunction
    expression = 0.01*t
  [../]
[]

[Kernels]
  [SolidMechanics]
    displacements = 'ux uy uz'
    use_displaced_mesh = true
  [../]
[]

[AuxKernels]
  [./stress_zz]
    type = RankTwoAux
    variable = stress_zz
    rank_two_tensor = stress
    index_j = 2
    index_i = 2
    execute_on = timestep_end
    block = 0
  [../]
  [./fp_zz]
    type = RankTwoAux
    variable = fp_zz
    rank_two_tensor = fp
    index_j = 2
    index_i = 2
    execute_on = timestep_end
    block = 0
  [../]
  [./e_zz]
    type = RankTwoAux
    variable = e_zz
    rank_two_tensor = lage
    index_j = 2
    index_i = 2
    execute_on = timestep_end
    block = 0
  [../]
  [./gss1]
    type = MaterialStdVectorAux
    variable = gss1
    property = gss
    index = 0
    execute_on = timestep_end
    block = 0
  [../]
[]

[BCs]
  [./symmy]
    type = DirichletBC
    variable = uy
    boundary = bottom
    value = 0
  [../]
  [./symmx]
    type = DirichletBC
    variable = ux
    boundary = left
    value = 0
  [../]
  [./symmz]
    type = DirichletBC
    variable = uz
    boundary = back
    value = 0
  [../]
  [./tdisp]
    type = FunctionDirichletBC
    variable = uz
    boundary = front
    function = tdisp
  [../]
[]

[Materials]
  [./crysp]
    type = FiniteStrainCrystalPlasticity
    block = 0
    gtol = 1e-2
    slip_sys_file_name = input_slip_sys.txt
    nss = 12
    num_slip_sys_flowrate_props = 2 #Number of properties in a slip system
    flowprops = '1 4 0.001 0.1 5 8 0.001 0.1 9 12 0.001 0.1'
    hprops = '1.0 541.5 60.8 109.8 2.5'
    gprops = '1 4 60.8 5 8 60.8 9 12 60.8'
    tan_mod_type = exact
    gen_random_stress_flag = false
    maximum_substep_iteration = 2
  [../]
  [./elasticity_tensor]
    type = ComputeElasticityTensorCP
    block = 0
    C_ijkl = '1.684e5 1.214e5 1.214e5 1.684e5 1.214e5 1.684e5 0.754e5 0.754e5 0.754e5'
    fill_method = symmetric9
  [../]
  [./strain]
    type = ComputeFiniteStrain
    block = 0
    displacements = 'ux uy uz'
  [../]
[]

[Postprocessors]
  [./stress_zz]
    type = ElementAverageValue
    variable = stress_zz
    block = 'ANY_BLOCK_ID 0'
  [../]
  [./fp_zz]
    type = ElementAverageValue
    variable = fp_zz
    block = 'ANY_BLOCK_ID 0'
  [../]
  [./e_zz]
    type = ElementAverageValue
    variable = e_zz
    block = 'ANY_BLOCK_ID 0'
  [../]
  [./gss1]
    type = ElementAverageValue
    variable = gss1
    block = 'ANY_BLOCK_ID 0'
  [../]
[]

[Preconditioning]
  [./smp]
    type = SMP
    full = true
  [../]
[]

[Executioner]
  type = Transient

  #Preconditioned JFNK (default)
  solve_type = 'PJFNK'

  petsc_options_iname = '-pc_type'
  petsc_options_value = 'lu'

  nl_rel_tol = 1e-10
  nl_abs_tol = 1e-10

  dt = 0.5
  dtmax = 10.0
  dtmin = 0.5

  num_steps = 3
[]

[Outputs]
  file_base = crysp_substep_out
  exodus = true
  csv = true
  gnuplot = true
[]

(modules/solid_mechanics/test/tests/mohr_coulomb/planar_hard5.i)

# apply repeated stretches in z direction, and smaller stretches along the y direction, and compression along x direction
# Both return to the plane and edge (lode angle = 30deg, ie 010100) are experienced.
#
# It is checked that the yield functions are less than their tolerance values
# It is checked that the cohesion hardens correctly

[Mesh]
  type = GeneratedMesh
  dim = 3
  nx = 1
  ny = 1
  nz = 1
  xmin = -0.5
  xmax = 0.5
  ymin = -0.5
  ymax = 0.5
  zmin = -0.5
  zmax = 0.5
[]


[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./disp_z]
  [../]
[]

[Kernels]
  [SolidMechanics]
    displacements = 'disp_x disp_y disp_z'
  [../]
[]


[BCs]
  [./x]
    type = FunctionDirichletBC
    variable = disp_x
    boundary = 'front back'
    function = '-1E-6*x*t'
  [../]
  [./y]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = 'front back'
    function = '0.05E-6*y*t'
  [../]
  [./z]
    type = FunctionDirichletBC
    variable = disp_z
    boundary = 'front back'
    function = '1E-6*z*t'
  [../]
[]

[Functions]
  [./should_be_zero_fcn]
    type = ParsedFunction
    expression = 'if((a<1E-5)&(b<1E-5)&(c<1E-5)&(d<1E-5)&(g<1E-5)&(h<1E-5),0,abs(a)+abs(b)+abs(c)+abs(d)+abs(g)+abs(h))'
    symbol_names = 'a b c d g h'
    symbol_values = 'f0 f1 f2 f3 f4 f5'
  [../]
  [./coh_analytic]
    type = ParsedFunction
    expression = '20-10*exp(-1E6*intnl)'
    symbol_names = intnl
    symbol_values = internal
  [../]
  [./coh_from_yieldfcns]
    type = ParsedFunction
    expression = '(f0+f1-(sxx+syy)*sin(phi))/(-2)/cos(phi)'
    symbol_names = 'f0 f1 sxx syy phi'
    symbol_values = 'f0 f1 s_xx s_yy 0.8726646'
  [../]
  [./should_be_zero_coh]
    type = ParsedFunction
    expression = 'if(abs(a-b)<1E-6,0,1E6*abs(a-b))'
    symbol_names = 'a b'
    symbol_values = 'Coh_analytic Coh_moose'
  [../]
[]

[AuxVariables]
  [./stress_xx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_zz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./mc_int]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./yield_fcn0]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./yield_fcn1]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./yield_fcn2]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./yield_fcn3]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./yield_fcn4]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./yield_fcn5]
    order = CONSTANT
    family = MONOMIAL
  [../]
[]

[AuxKernels]
  [./stress_xx]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xx
    index_i = 0
    index_j = 0
  [../]
  [./stress_xy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xy
    index_i = 0
    index_j = 1
  [../]
  [./stress_xz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xz
    index_i = 0
    index_j = 2
  [../]
  [./stress_yy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yy
    index_i = 1
    index_j = 1
  [../]
  [./stress_yz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yz
    index_i = 1
    index_j = 2
  [../]
  [./stress_zz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_zz
    index_i = 2
    index_j = 2
  [../]
  [./mc_int_auxk]
    type = MaterialStdVectorAux
    index = 0
    property = plastic_internal_parameter
    variable = mc_int
  [../]
  [./yield_fcn0]
    type = MaterialStdVectorAux
    index = 0
    property = plastic_yield_function
    variable = yield_fcn0
  [../]
  [./yield_fcn1]
    type = MaterialStdVectorAux
    index = 1
    property = plastic_yield_function
    variable = yield_fcn1
  [../]
  [./yield_fcn2]
    type = MaterialStdVectorAux
    index = 2
    property = plastic_yield_function
    variable = yield_fcn2
  [../]
  [./yield_fcn3]
    type = MaterialStdVectorAux
    index = 3
    property = plastic_yield_function
    variable = yield_fcn3
  [../]
  [./yield_fcn4]
    type = MaterialStdVectorAux
    index = 4
    property = plastic_yield_function
    variable = yield_fcn4
  [../]
  [./yield_fcn5]
    type = MaterialStdVectorAux
    index = 5
    property = plastic_yield_function
    variable = yield_fcn5
  [../]
[]

[Postprocessors]
  [./s_xx]
    type = PointValue
    point = '0 0 0'
    variable = stress_xx
  [../]
  [./s_xy]
    type = PointValue
    point = '0 0 0'
    variable = stress_xy
  [../]
  [./s_xz]
    type = PointValue
    point = '0 0 0'
    variable = stress_xz
  [../]
  [./s_yy]
    type = PointValue
    point = '0 0 0'
    variable = stress_yy
  [../]
  [./s_yz]
    type = PointValue
    point = '0 0 0'
    variable = stress_yz
  [../]
  [./s_zz]
    type = PointValue
    point = '0 0 0'
    variable = stress_zz
  [../]
  [./internal]
    type = PointValue
    point = '0 0 0'
    variable = mc_int
  [../]
  [./f0]
    type = PointValue
    point = '0 0 0'
    variable = yield_fcn0
  [../]
  [./f1]
    type = PointValue
    point = '0 0 0'
    variable = yield_fcn1
  [../]
  [./f2]
    type = PointValue
    point = '0 0 0'
    variable = yield_fcn2
  [../]
  [./f3]
    type = PointValue
    point = '0 0 0'
    variable = yield_fcn3
  [../]
  [./f4]
    type = PointValue
    point = '0 0 0'
    variable = yield_fcn4
  [../]
  [./f5]
   type = PointValue
    point = '0 0 0'
    variable = yield_fcn5
  [../]
  [./yfcns_should_be_zero]
    type = FunctionValuePostprocessor
    function = should_be_zero_fcn
  [../]
  [./Coh_analytic]
    type = FunctionValuePostprocessor
    function = coh_analytic
  [../]
  [./Coh_moose]
    type = FunctionValuePostprocessor
    function = coh_from_yieldfcns
  [../]
  [./cohesion_difference_should_be_zero]
    type = FunctionValuePostprocessor
    function = should_be_zero_coh
  [../]
[]

[UserObjects]
  [./mc_coh]
    type = SolidMechanicsHardeningExponential
    value_0 = 10
    value_residual = 20
    rate = 1E6
  [../]
  [./mc_phi]
    type = SolidMechanicsHardeningConstant
    value = 0.8726646
  [../]
  [./mc_psi]
    type = SolidMechanicsHardeningConstant
    value = 1 #0.8726646 # 50deg
  [../]
  [./mc]
    type = SolidMechanicsPlasticMohrCoulombMulti
    cohesion = mc_coh
    friction_angle = mc_phi
    dilation_angle = mc_psi
    use_custom_returnMap = true
    yield_function_tolerance = 1E-5
    internal_constraint_tolerance = 1E-9
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeElasticityTensor
    block = 0
    fill_method = symmetric_isotropic
    C_ijkl = '0 1E7'
  [../]
  [./strain]
    type = ComputeFiniteStrain
    block = 0
    displacements = 'disp_x disp_y disp_z'
  [../]
  [./mc]
    type = ComputeMultiPlasticityStress
    block = 0
    ep_plastic_tolerance = 1E-12
    plastic_models = mc
  [../]
[]


[Executioner]
  end_time = 5
  dt = 1
  type = Transient
[]


[Outputs]
  file_base = planar_hard5
  exodus = false
  [./csv]
    type = CSV
    hide = 'f0 f1 f2 f3 f4 f5 s_xy s_xz s_yz Coh_analytic Coh_moose'
    execute_on = 'timestep_end'
  [../]
[]

(modules/solid_mechanics/test/tests/mohr_coulomb/small_deform1_uo.i)

# apply uniform stretch in x, y and z directions.
# With cohesion = 10, friction_angle = 60deg, tip_smoother = 4, the
# algorithm should return to
# sigma_m = (10*Cos(60) - 4)/Sin(60) = 1.1547

[Mesh]
  type = GeneratedMesh
  dim = 3
  nx = 1
  ny = 1
  nz = 1
  xmin = -0.5
  xmax = 0.5
  ymin = -0.5
  ymax = 0.5
  zmin = -0.5
  zmax = 0.5
[]


[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./disp_z]
  [../]
[]

[Kernels]
  [SolidMechanics]
    displacements = 'disp_x disp_y disp_z'
  [../]
[]


[BCs]
  [./x]
    type = FunctionDirichletBC
    variable = disp_x
    boundary = 'front back'
    function = '1E-6*x'
  [../]
  [./y]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = 'front back'
    function = '1E-6*y'
  [../]
  [./z]
    type = FunctionDirichletBC
    variable = disp_z
    boundary = 'front back'
    function = '1E-6*z'
  [../]
[]

[AuxVariables]
  [./stress_xx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_zz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./f]
    order = CONSTANT
    family = MONOMIAL
  [../]
[]

[AuxKernels]
  [./stress_xx]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xx
    index_i = 0
    index_j = 0
  [../]
  [./stress_xy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xy
    index_i = 0
    index_j = 1
  [../]
  [./stress_xz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xz
    index_i = 0
    index_j = 2
  [../]
  [./stress_yy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yy
    index_i = 1
    index_j = 1
  [../]
  [./stress_yz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yz
    index_i = 1
    index_j = 2
  [../]
  [./stress_zz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_zz
    index_i = 2
    index_j = 2
  [../]
  [./f]
    type = MaterialStdVectorAux
    index = 0
    property = plastic_yield_function
    variable = f
  [../]
[]

[Postprocessors]
  [./s_xx]
    type = PointValue
    point = '0 0 0'
    variable = stress_xx
  [../]
  [./s_xy]
    type = PointValue
    point = '0 0 0'
    variable = stress_xy
  [../]
  [./s_xz]
    type = PointValue
    point = '0 0 0'
    variable = stress_xz
  [../]
  [./s_yy]
    type = PointValue
    point = '0 0 0'
    variable = stress_yy
  [../]
  [./s_yz]
    type = PointValue
    point = '0 0 0'
    variable = stress_yz
  [../]
  [./s_zz]
    type = PointValue
    point = '0 0 0'
    variable = stress_zz
  [../]
  [./f]
    type = PointValue
    point = '0 0 0'
    variable = f
  [../]
[]

[UserObjects]
  [./mc_coh]
    type = SolidMechanicsHardeningConstant
    value = 10
  [../]
  [./mc_phi]
    type = SolidMechanicsHardeningConstant
    value = 60
    convert_to_radians = true
  [../]
  [./mc_psi]
    type = SolidMechanicsHardeningConstant
    value = 5
    convert_to_radians = true
  [../]
  [./mc]
    type = SolidMechanicsPlasticMohrCoulomb
    cohesion = mc_coh
    friction_angle = mc_phi
    dilation_angle = mc_psi
    mc_tip_smoother = 4
    mc_edge_smoother = 25
    yield_function_tolerance = 1E-3
    internal_constraint_tolerance = 1E-9
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeElasticityTensor
    block = 0
    fill_method = symmetric_isotropic
    C_ijkl = '0 1E7'
  [../]
  [./strain]
    type = ComputeFiniteStrain
    block = 0
    displacements = 'disp_x disp_y disp_z'
  [../]
  [./mc]
    type = ComputeMultiPlasticityStress
    block = 0
    ep_plastic_tolerance = 1E-9
    plastic_models = mc
    debug_fspb = crash
    debug_jac_at_stress = '10 0 0 0 10 0 0 0 10'
    debug_jac_at_pm = 1
    debug_jac_at_intnl = 1
    debug_stress_change = 1E-5
    debug_pm_change = 1E-6
    debug_intnl_change = 1E-6
  [../]
[]


[Executioner]
  end_time = 1
  dt = 1
  type = Transient
[]


[Outputs]
  file_base = small_deform1_uo
  exodus = false
  [./csv]
    type = CSV
    [../]
[]

(modules/solid_mechanics/test/tests/crystal_plasticity/monolithic_material_based/crysp_save_euler.i)

[Mesh]
  type = GeneratedMesh
  dim = 2
  elem_type = QUAD4
  displacements = 'disp_x disp_y'
  nx = 2
  ny = 2
[]

[Variables]
  [./disp_x]
    block = 0
  [../]
  [./disp_y]
    block = 0
  [../]
[]

[GlobalParams]
  volumetric_locking_correction = true
[]

[AuxVariables]
  [./stress_yy]
    order = CONSTANT
    family = MONOMIAL
    block = 0
  [../]
  [./e_yy]
    order = CONSTANT
    family = MONOMIAL
    block = 0
  [../]
  [./fp_yy]
    order = CONSTANT
    family = MONOMIAL
    block = 0
  [../]
  [./rotout]
    order = CONSTANT
    family = MONOMIAL
    block = 0
  [../]
  [./gss1]
    order = CONSTANT
    family = MONOMIAL
    block = 0
  [../]
  [./euler1]
    order = CONSTANT
    family = MONOMIAL
    block = 0
  [../]
  [./euler2]
    order = CONSTANT
    family = MONOMIAL
    block = 0
  [../]
  [./euler3]
    order = CONSTANT
    family = MONOMIAL
    block = 0
  [../]
[]

[Functions]
  [./tdisp]
    type = ParsedFunction
    expression = 0.01*t
  [../]
[]

[UserObjects]
  [./prop_read]
    type = PropertyReadFile
    prop_file_name = 'euler_ang_file.txt'
    # Enter file data as prop#1, prop#2, .., prop#nprop
    nprop = 3
    read_type = element
  [../]
[]

[AuxKernels]
  [./stress_yy]
    type = RankTwoAux
    variable = stress_yy
    rank_two_tensor = stress
    index_j = 1
    index_i = 1
    execute_on = timestep_end
    block = 0
  [../]
  [./e_yy]
    type = RankTwoAux
    variable = e_yy
    rank_two_tensor = lage
    index_j = 1
    index_i = 1
    execute_on = timestep_end
    block = 0
  [../]
  [./fp_yy]
    type = RankTwoAux
    variable = fp_yy
    rank_two_tensor = fp
    index_j = 1
    index_i = 1
    execute_on = timestep_end
    block = 0
  [../]
  [./gss1]
    type = MaterialStdVectorAux
    variable = gss1
    property = gss
    index = 0
    execute_on = timestep_end
    block = 0
  [../]
  [./euler1]
    type = MaterialRealVectorValueAux
    variable = euler1
    property = Euler_angles
    component = 0
    execute_on = timestep_end
    block = 0
  [../]
  [./euler2]
    type = MaterialRealVectorValueAux
    variable = euler2
    property = Euler_angles
    component = 1
    execute_on = timestep_end
    block = 0
  [../]
  [./euler3]
    type = MaterialRealVectorValueAux
    variable = euler3
    property = Euler_angles
    component = 2
    execute_on = timestep_end
    block = 0
  [../]
[]

[BCs]
  [./fix_x]
    type = DirichletBC
    variable = disp_x
    boundary = 'left'
    value = 0
  [../]
  [./fix_y]
    type = DirichletBC
    variable = disp_y
    boundary = 'bottom'
    value = 0
  [../]
  [./tdisp]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = top
    function = tdisp
  [../]
[]

[Materials]
  [./crysp]
    type = FiniteStrainCrystalPlasticity
    block = 0
    gtol = 1e-2
    slip_sys_file_name = input_slip_sys.txt
    nss = 12
    num_slip_sys_flowrate_props = 2 #Number of properties in a slip system
    flowprops = '1 4 0.001 0.1 5 8 0.001 0.1 9 12 0.001 0.1'
    hprops = '1.0 541.5 60.8 109.8 2.5'
    gprops = '1 4 60.8 5 8 60.8 9 12 60.8'
    tan_mod_type = exact
  [../]
  [./strain]
    type = ComputeFiniteStrain
    block = 0
    displacements = 'disp_x disp_y'
  [../]
  [./elasticity_tensor]
    type = ComputeElasticityTensorCP
    block = 0
    C_ijkl = '1.684e5 1.214e5 1.214e5 1.684e5 1.214e5 1.684e5 0.754e5 0.754e5 0.754e5'
    fill_method = symmetric9
    read_prop_user_object = prop_read
  [../]
[]

[Postprocessors]
  [./stress_yy]
    type = ElementAverageValue
    variable = stress_yy
    block = 'ANY_BLOCK_ID 0'
  [../]
  [./e_yy]
    type = ElementAverageValue
    variable = e_yy
    block = 'ANY_BLOCK_ID 0'
  [../]
  [./fp_yy]
    type = ElementAverageValue
    variable = fp_yy
    block = 'ANY_BLOCK_ID 0'
  [../]
  [./gss1]
    type = ElementAverageValue
    variable = gss1
    block = 'ANY_BLOCK_ID 0'
  [../]
[]

[Preconditioning]
  [./smp]
    type = SMP
    full = true
  [../]
[]

[Executioner]
  type = Transient

  #Preconditioned JFNK (default)
  solve_type = 'PJFNK'

  petsc_options_iname = '-pc_type'
  petsc_options_value = 'lu'

  nl_rel_tol = 1e-10
  nl_abs_tol = 1e-10

  dt = 0.01
  dtmax = 10.0
  dtmin = 0.01

  num_steps = 10
[]

[Outputs]
  file_base = crysp_save_euler_out
  exodus = true
[]

[Kernels]
  [SolidMechanics]
    displacements = 'disp_x disp_y'
    use_displaced_mesh = true
  [../]
[]

(modules/xfem/test/tests/moving_interface/moving_bimaterial_finite_strain.i)

# This test is for two layer materials with different youngs modulus with AD
# The global stress is determined by switching the stress based on level set values
# The material interface is marked by a level set function
# The two layer materials are glued together

[GlobalParams]
  displacements = 'disp_x disp_y'
[]

[XFEM]
  output_cut_plane = true
[]

[UserObjects]
  [level_set_cut_uo]
    type = LevelSetCutUserObject
    level_set_var = ls
    heal_always = true
  []
[]

[Mesh]
  use_displaced_mesh = true
  [generated_mesh]
    type = GeneratedMeshGenerator
    dim = 2
    nx = 10
    ny = 10
    xmin = 0
    xmax = 5
    ymin = 0
    ymax = 5
    elem_type = QUAD4
  []
  [left_bottom]
    type = ExtraNodesetGenerator
    new_boundary = 'left_bottom'
    coord = '0 0'
    input = generated_mesh
  []
  [left_top]
    type = ExtraNodesetGenerator
    new_boundary = 'left_top'
    coord = '0 5'
    input = left_bottom
  []
[]

[Functions]
  [ls_func]
    type = ParsedFunction
    expression = 'y-2.73+t'
  []
[]

[Variables]
  [disp_x]
  []
  [disp_y]
  []
[]

[AuxVariables]
  [ls]
  []
  [a_strain_xx]
    order = CONSTANT
    family = MONOMIAL
  []
  [a_strain_yy]
    order = CONSTANT
    family = MONOMIAL
  []
  [a_strain_xy]
    order = CONSTANT
    family = MONOMIAL
  []
  [b_strain_xx]
    order = CONSTANT
    family = MONOMIAL
  []
  [b_strain_yy]
    order = CONSTANT
    family = MONOMIAL
  []
  [b_strain_xy]
    order = CONSTANT
    family = MONOMIAL
  []
  [stress_xx]
    order = CONSTANT
    family = MONOMIAL
  []
  [stress_yy]
    order = CONSTANT
    family = MONOMIAL
  []
  [stress_xy]
    order = CONSTANT
    family = MONOMIAL
  []

[]

[AuxKernels]
  [ls_function]
    type = FunctionAux
    variable = ls
    function = ls_func
  []
  [a_strain_xx]
    type = RankTwoAux
    variable = a_strain_xx
    rank_two_tensor = A_total_strain
    index_i = 0
    index_j = 0
  []
  [a_strain_yy]
    type = RankTwoAux
    variable = a_strain_yy
    rank_two_tensor = A_total_strain
    index_i = 1
    index_j = 1
  []
  [a_strain_xy]
    type = RankTwoAux
    variable = a_strain_xy
    rank_two_tensor = A_total_strain
    index_i = 0
    index_j = 1
  []
  [b_strain_xx]
    type = RankTwoAux
    variable = b_strain_xx
    rank_two_tensor = B_total_strain
    index_i = 0
    index_j = 0
  []
  [b_strain_yy]
    type = RankTwoAux
    variable = b_strain_yy
    rank_two_tensor = B_total_strain
    index_i = 1
    index_j = 1
  []
  [b_strain_xy]
    type = RankTwoAux
    variable = b_strain_xy
    rank_two_tensor = B_total_strain
    index_i = 0
    index_j = 1
  []
  [stress_xx]
    type = RankTwoAux
    variable = stress_xx
    rank_two_tensor = stress
    index_i = 0
    index_j = 0
  []
  [stress_xy]
    type = RankTwoAux
    variable = stress_xy
    rank_two_tensor = stress
    index_i = 0
    index_j = 1
  []
  [stress_yy]
    type = RankTwoAux
    variable = stress_yy
    rank_two_tensor = stress
    index_i = 1
    index_j = 1
  []
[]

[Kernels]
  [solid_x]
    type = StressDivergenceTensors
    variable = disp_x
    component = 0
    use_displaced_mesh = true
  []
  [solid_y]
    type = StressDivergenceTensors
    variable = disp_y
    component = 1
    use_displaced_mesh = true
  []
[]

[Constraints]
  [dispx_constraint]
    type = XFEMSingleVariableConstraint
    use_displaced_mesh = false
    variable = disp_x
    alpha = 1e8
    geometric_cut_userobject = 'level_set_cut_uo'
  []
  [dispy_constraint]
    type = XFEMSingleVariableConstraint
    use_displaced_mesh = false
    variable = disp_y
    alpha = 1e8
    geometric_cut_userobject = 'level_set_cut_uo'
  []
[]

[BCs]
  [bottomx]
    type = DirichletBC
    boundary = bottom
    variable = disp_x
    value = 0.0
  []
  [bottomy]
    type = DirichletBC
    boundary = bottom
    variable = disp_y
    value = 0.0
  []
  [topx]
    type = FunctionDirichletBC
    boundary = top
    variable = disp_x
    function = 0.03*t
  []
  [topy]
    type = FunctionDirichletBC
    boundary = top
    variable = disp_y
    function = '0.03*t'
  []
[]

[Materials]
  [elasticity_tensor_A]
    type = ComputeIsotropicElasticityTensor
    base_name = A
    youngs_modulus = 1e9
    poissons_ratio = 0.3
  []
  [strain_A]
    type = ComputeFiniteStrain
    base_name = A
  []
  [stress_A]
    type = ComputeFiniteStrainElasticStress
    base_name = A
  []
  [elasticity_tensor_B]
    type = ComputeIsotropicElasticityTensor
    base_name = B
    youngs_modulus = 1e7
    poissons_ratio = 0.3
  []
  [strain_B]
    type = ComputeFiniteStrain
    base_name = B
  []
  [stress_B]
    type = ComputeFiniteStrainElasticStress
    base_name = B
  []
  [combined_stress]
    type = LevelSetBiMaterialRankTwo
    levelset_positive_base = 'A'
    levelset_negative_base = 'B'
    level_set_var = ls
    prop_name = stress
  []
  [combined_jacob_mult]
    type = LevelSetBiMaterialRankFour
    levelset_positive_base = 'A'
    levelset_negative_base = 'B'
    level_set_var = ls
    prop_name = Jacobian_mult
  []
[]

[Postprocessors]
  [disp_x_norm]
    type = ElementL2Norm
    variable = disp_x
  []
  [disp_y_norm]
    type = ElementL2Norm
    variable = disp_y
  []
[]

[Executioner]
  type = Transient

  solve_type = NEWTON
  petsc_options_iname = '-pc_type'
  petsc_options_value = 'lu'
  automatic_scaling = true

  # controls for nonlinear iterations
  nl_max_its = 15
  nl_rel_tol = 1e-13
  nl_abs_tol = 1e-50

  # time control
  start_time = 0.0
  dt = 0.1
  num_steps = 4

  max_xfem_update = 1
[]

[Outputs]
  print_linear_residuals = false
  exodus = true
[]

(modules/solid_mechanics/test/tests/elem_prop_read_user_object/prop_grain_read_3d.i)

[Mesh]
  type = GeneratedMesh
  dim = 3
  elem_type = HEX8
  displacements = 'disp_x disp_y disp_z'
  nx = 30
  ny = 30
  nz = 30
[]

[Variables]
  [./disp_x]
    block = 0
  [../]
  [./disp_y]
    block = 0
  [../]
  [./disp_z]
    block = 0
  [../]
[]

[AuxVariables]
  [./stress_yy]
    order = CONSTANT
    family = MONOMIAL
    block = 0
  [../]
  [./e_yy]
    order = CONSTANT
    family = MONOMIAL
    block = 0
  [../]
[]

[Functions]
  [./tdisp]
    type = ParsedFunction
    expression = 0.05*t
  [../]
[]

[UserObjects]
  [./prop_read]
    type = PropertyReadFile
    prop_file_name = 'input_file.txt'
    nprop = 4
    read_type = grain
    ngrain = 4
  [../]
[]

[AuxKernels]
  [./stress_yy]
    type = RankTwoAux
    variable = stress_yy
    rank_two_tensor = stress
    index_j = 1
    index_i = 1
    execute_on = timestep_end
    block = 0
  [../]
  [./e_yy]
    type = RankTwoAux
    variable = e_yy
    rank_two_tensor = elastic_strain
    index_j = 1
    index_i = 1
    execute_on = timestep_end
    block = 0
  [../]
[]

[BCs]
  [./fix_x]
    type = DirichletBC
    variable = disp_x
    boundary = 'left'
    value = 0
  [../]
  [./fix_y]
    type = DirichletBC
    variable = disp_y
    boundary = 'bottom'
    value = 0
  [../]
  [./fix_z]
    type = DirichletBC
    variable = disp_z
    boundary = 'back'
    value = 0
  [../]
  [./tdisp]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = top
    function = tdisp
  [../]
[]

[Materials]
  [./elasticity_tensor_with_Euler]
    type = ComputeElasticityTensorCP
    block = 0
    C_ijkl = '1.684e5 1.214e5 1.214e5 1.684e5 1.214e5 1.684e5 0.754e5 0.754e5 0.754e5'
    fill_method = symmetric9
    read_prop_user_object = prop_read
  [../]
  [./strain]
    type = ComputeFiniteStrain
    block = 0
    displacements = 'disp_x disp_y disp_z'
  [../]
  [./stress]
    type = ComputeFiniteStrainElasticStress
    block = 0
  [../]
[]

[Postprocessors]
  [./stress_yy]
    type = ElementAverageValue
    variable = stress_yy
    block = 'ANY_BLOCK_ID 0'
  [../]
  [./e_yy]
    type = ElementAverageValue
    variable = e_yy
    block = 'ANY_BLOCK_ID 0'
  [../]
[]

[Preconditioning]
  [./smp]
    type = SMP
    full = true
  [../]
[]

[Executioner]
  type = Transient
  dt = 0.05

  #Preconditioned JFNK (default)
  solve_type = 'PJFNK'

  petsc_options_iname = -pc_hypre_type
  petsc_options_value = boomerang
  nl_abs_tol = 1e-10
  nl_rel_step_tol = 1e-10
  dtmax = 10.0
  nl_rel_tol = 1e-10
  end_time = 1
  dtmin = 0.05
  num_steps = 2
  nl_abs_step_tol = 1e-10
[]

[Outputs]
  file_base = prop_grain_read_3d_out
  exodus = true
[]

[Kernels]
  [SolidMechanics]
    displacements = 'disp_x disp_y disp_z'
    use_displaced_mesh = true
  [../]
[]

(modules/solid_mechanics/test/tests/mohr_coulomb/planar_hard3.i)

# apply repeated stretches in x z directions, and smaller stretches along the y direction,
# so that sigma_I = sigma_II,
# which means that lode angle = 30deg.
# Both return to the edge (lode angle = 30deg, ie 010100) and tip are experienced.
#
# It is checked that the yield functions are less than their tolerance values
# It is checked that the cohesion hardens correctly

[Mesh]
  type = GeneratedMesh
  dim = 3
  nx = 1
  ny = 1
  nz = 1
  xmin = -0.5
  xmax = 0.5
  ymin = -0.5
  ymax = 0.5
  zmin = -0.5
  zmax = 0.5
[]


[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./disp_z]
  [../]
[]

[Kernels]
  [SolidMechanics]
    displacements = 'disp_x disp_y disp_z'
  [../]
[]


[BCs]
  [./x]
    type = FunctionDirichletBC
    variable = disp_x
    boundary = 'front back'
    function = '1E-6*x*t'
  [../]
  [./y]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = 'front back'
    function = '0.05E-6*y*t'
  [../]
  [./z]
    type = FunctionDirichletBC
    variable = disp_z
    boundary = 'front back'
    function = '1E-6*z*t'
  [../]
[]

[Functions]
  [./should_be_zero_fcn]
    type = ParsedFunction
    expression = 'if((a<1E-5)&(b<1E-5)&(c<1E-5)&(d<1E-5)&(g<1E-5)&(h<1E-5),0,abs(a)+abs(b)+abs(c)+abs(d)+abs(g)+abs(h))'
    symbol_names = 'a b c d g h'
    symbol_values = 'f0 f1 f2 f3 f4 f5'
  [../]
  [./coh_analytic]
    type = ParsedFunction
    expression = '20-10*exp(-1E5*intnl)'
    symbol_names = intnl
    symbol_values = internal
  [../]
  [./coh_from_yieldfcns]
    type = ParsedFunction
    expression = '(f0+f1-(sxx+syy)*sin(phi))/(-2)/cos(phi)'
    symbol_names = 'f0 f1 sxx syy phi'
    symbol_values = 'f0 f1 s_xx s_yy 0.8726646'
  [../]
  [./should_be_zero_coh]
    type = ParsedFunction
    expression = 'if(abs(a-b)<1E-6,0,1E6*abs(a-b))'
    symbol_names = 'a b'
    symbol_values = 'Coh_analytic Coh_moose'
  [../]
[]

[AuxVariables]
  [./stress_xx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_zz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./mc_int]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./yield_fcn0]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./yield_fcn1]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./yield_fcn2]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./yield_fcn3]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./yield_fcn4]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./yield_fcn5]
    order = CONSTANT
    family = MONOMIAL
  [../]
[]

[AuxKernels]
  [./stress_xx]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xx
    index_i = 0
    index_j = 0
  [../]
  [./stress_xy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xy
    index_i = 0
    index_j = 1
  [../]
  [./stress_xz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xz
    index_i = 0
    index_j = 2
  [../]
  [./stress_yy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yy
    index_i = 1
    index_j = 1
  [../]
  [./stress_yz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yz
    index_i = 1
    index_j = 2
  [../]
  [./stress_zz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_zz
    index_i = 2
    index_j = 2
  [../]
  [./mc_int_auxk]
    type = MaterialStdVectorAux
    index = 0
    property = plastic_internal_parameter
    variable = mc_int
  [../]
  [./yield_fcn0]
    type = MaterialStdVectorAux
    index = 0
    property = plastic_yield_function
    variable = yield_fcn0
  [../]
  [./yield_fcn1]
    type = MaterialStdVectorAux
    index = 1
    property = plastic_yield_function
    variable = yield_fcn1
  [../]
  [./yield_fcn2]
    type = MaterialStdVectorAux
    index = 2
    property = plastic_yield_function
    variable = yield_fcn2
  [../]
  [./yield_fcn3]
    type = MaterialStdVectorAux
    index = 3
    property = plastic_yield_function
    variable = yield_fcn3
  [../]
  [./yield_fcn4]
    type = MaterialStdVectorAux
    index = 4
    property = plastic_yield_function
    variable = yield_fcn4
  [../]
  [./yield_fcn5]
    type = MaterialStdVectorAux
    index = 5
    property = plastic_yield_function
    variable = yield_fcn5
  [../]
[]

[Postprocessors]
  [./s_xx]
    type = PointValue
    point = '0 0 0'
    variable = stress_xx
  [../]
  [./s_xy]
    type = PointValue
    point = '0 0 0'
    variable = stress_xy
  [../]
  [./s_xz]
    type = PointValue
    point = '0 0 0'
    variable = stress_xz
  [../]
  [./s_yy]
    type = PointValue
    point = '0 0 0'
    variable = stress_yy
  [../]
  [./s_yz]
    type = PointValue
    point = '0 0 0'
    variable = stress_yz
  [../]
  [./s_zz]
    type = PointValue
    point = '0 0 0'
    variable = stress_zz
  [../]
  [./internal]
    type = PointValue
    point = '0 0 0'
    variable = mc_int
  [../]
  [./f0]
    type = PointValue
    point = '0 0 0'
    variable = yield_fcn0
  [../]
  [./f1]
    type = PointValue
    point = '0 0 0'
    variable = yield_fcn1
  [../]
  [./f2]
    type = PointValue
    point = '0 0 0'
    variable = yield_fcn2
  [../]
  [./f3]
    type = PointValue
    point = '0 0 0'
    variable = yield_fcn3
  [../]
  [./f4]
    type = PointValue
    point = '0 0 0'
    variable = yield_fcn4
  [../]
  [./f5]
   type = PointValue
    point = '0 0 0'
    variable = yield_fcn5
  [../]
  [./yfcns_should_be_zero]
    type = FunctionValuePostprocessor
    function = should_be_zero_fcn
  [../]
  [./Coh_analytic]
    type = FunctionValuePostprocessor
    function = coh_analytic
  [../]
  [./Coh_moose]
    type = FunctionValuePostprocessor
    function = coh_from_yieldfcns
  [../]
  [./cohesion_difference_should_be_zero]
    type = FunctionValuePostprocessor
    function = should_be_zero_coh
  [../]
[]

[UserObjects]
  [./mc_coh]
    type = SolidMechanicsHardeningExponential
    value_0 = 10
    value_residual = 20
    rate = 1E5
  [../]
  [./mc_phi]
    type = SolidMechanicsHardeningConstant
    value = 0.8726646
  [../]
  [./mc_psi]
    type = SolidMechanicsHardeningConstant
    value = 1 #0.8726646 # 50deg
  [../]
  [./mc]
    type = SolidMechanicsPlasticMohrCoulombMulti
    cohesion = mc_coh
    friction_angle = mc_phi
    dilation_angle = mc_psi
    yield_function_tolerance = 1E-5
    use_custom_returnMap = true
    internal_constraint_tolerance = 1E-9
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeElasticityTensor
    block = 0
    fill_method = symmetric_isotropic
    C_ijkl = '0 1E7'
  [../]
  [./strain]
    type = ComputeFiniteStrain
    block = 0
    displacements = 'disp_x disp_y disp_z'
  [../]
  [./mc]
    type = ComputeMultiPlasticityStress
    block = 0
    ep_plastic_tolerance = 1E-12
    plastic_models = mc
  [../]
[]


[Executioner]
  end_time = 5
  dt = 1
  type = Transient
[]


[Outputs]
  file_base = planar_hard3
  exodus = false
  [./csv]
    type = CSV
    hide = 'f0 f1 f2 f3 f4 f5 s_xy s_xz s_yz Coh_analytic Coh_moose'
    execute_on = 'timestep_end'
  [../]
[]

(modules/solid_mechanics/test/tests/j2_plasticity/hard2.i)

# UserObject J2 test, with hardening, but with rate=1E6
# apply uniform compression in x direction to give
# trial stress_xx = 5, so sqrt(3*J2) = 5
# with zero Poisson's ratio, lambda_mu = 1E6, and strength=2, strength_residual=1,
# the equations that we need to solve are:
#
# stress_yy = stress_zz  [because of the symmetry of the problem: to keep Lode angle constant]
# stress_xx - stress_yy = 1 + (2 - 1)*exp(-0.5*(1E6*q)^2)   [yield_fcn = 0]
# stress_xx + stress_yy + stress_zz = 5   [mean stress constant]
# q = gamma
# stress_xx = 1E6*2*gamma*(stress_xx - 5/3)*sqrt(3)/2/sqrt(J2), where sqrt(J2) = (1 + (2 - 1)*exp(-0.5*(1E6*q)^2))/Sqrt(3)
# so RHS = 1E6*2*gamma*(stress_xx - 5/3)*3/2/(stress_xx - stress_yy)
#
# stress_xx = 2.672
# stress_yy = 1.164
# q = 1.164E-6

[Mesh]
  type = GeneratedMesh
  dim = 3
  nx = 1
  ny = 1
  nz = 1
  xmin = -0.5
  xmax = 0.5
  ymin = -0.5
  ymax = 0.5
  zmin = -0.5
  zmax = 0.5
[]


[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./disp_z]
  [../]
[]

[Kernels]
  [SolidMechanics]
    displacements = 'disp_x disp_y disp_z'
  [../]
[]


[BCs]
  [./x]
    type = FunctionDirichletBC
    variable = disp_x
    boundary = 'front back'
    function = '2.5E-6*x'
  [../]
  [./y]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = 'front back'
    function = '0E-6*y'
  [../]
  [./z]
    type = FunctionDirichletBC
    variable = disp_z
    boundary = 'front back'
    function = '0E-6*z'
  [../]
[]

[AuxVariables]
  [./stress_xx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_zz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./f]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./iter]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./intnl]
    order = CONSTANT
    family = MONOMIAL
  [../]
[]

[AuxKernels]
  [./stress_xx]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xx
    index_i = 0
    index_j = 0
  [../]
  [./stress_xy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xy
    index_i = 0
    index_j = 1
  [../]
  [./stress_xz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xz
    index_i = 0
    index_j = 2
  [../]
  [./stress_yy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yy
    index_i = 1
    index_j = 1
  [../]
  [./stress_yz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yz
    index_i = 1
    index_j = 2
  [../]
  [./stress_zz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_zz
    index_i = 2
    index_j = 2
  [../]
  [./f]
    type = MaterialStdVectorAux
    index = 0
    property = plastic_yield_function
    variable = f
  [../]
  [./iter]
    type = MaterialRealAux
    property = plastic_NR_iterations
    variable = iter
  [../]
  [./intnl]
    type = MaterialStdVectorAux
    index = 0
    property = plastic_internal_parameter
    variable = intnl
  [../]
[]

[Postprocessors]
  [./s_xx]
    type = PointValue
    point = '0 0 0'
    variable = stress_xx
  [../]
  [./s_xy]
    type = PointValue
    point = '0 0 0'
    variable = stress_xy
  [../]
  [./s_xz]
    type = PointValue
    point = '0 0 0'
    variable = stress_xz
  [../]
  [./s_yy]
    type = PointValue
    point = '0 0 0'
    variable = stress_yy
  [../]
  [./s_yz]
    type = PointValue
    point = '0 0 0'
    variable = stress_yz
  [../]
  [./s_zz]
    type = PointValue
    point = '0 0 0'
    variable = stress_zz
  [../]
  [./f]
    type = PointValue
    point = '0 0 0'
    variable = f
  [../]
  [./iter]
    type = PointValue
    point = '0 0 0'
    variable = iter
  [../]
  [./intnl]
    type = PointValue
    point = '0 0 0'
    variable = intnl
  [../]
[]

[UserObjects]
  [./str]
    type = SolidMechanicsHardeningGaussian
    value_0 = 2
    value_residual = 1
    rate = 1E12
  [../]
  [./j2]
    type = SolidMechanicsPlasticJ2
    yield_strength = str
    yield_function_tolerance = 1E-5
    internal_constraint_tolerance = 1E-9
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeElasticityTensor
    block = 0
    fill_method = symmetric_isotropic
    C_ijkl = '0 1E6'
  [../]
  [./strain]
    type = ComputeFiniteStrain
    block = 0
    displacements = 'disp_x disp_y disp_z'
  [../]
  [./mc]
    type = ComputeMultiPlasticityStress
    block = 0
    ep_plastic_tolerance = 1E-9
    plastic_models = j2
    debug_fspb = crash
  [../]
[]


[Executioner]
  end_time = 1
  dt = 1
  type = Transient
[]


[Outputs]
  file_base = hard2
  exodus = false
  [./csv]
    type = CSV
    [../]
[]

(modules/solid_mechanics/test/tests/multi/three_surface01.i)

# Plasticit models:
# SimpleTester0 with a = 0 and b = 1 and strength = 1
# SimpleTester1 with a = 1 and b = 0 and strength = 1
# SimpleTester2 with a = 1 and b = 1 and strength = 1.5
#
# Lame lambda = 0 (Poisson=0).  Lame mu = 0.5E6
#
# A single element is stretched by 0E-6m in y direction and 1.5E-6 in z direction.
# trial stress_yy = 0 and stress_zz = 1.5
#
# Then SimpleTester0 should activate and the algorithm will return to
# stress_yy = 0, stress_zz = 1
# internal0 should be 0.5, and others zero

[Mesh]
  type = GeneratedMesh
  dim = 3
  nx = 1
  ny = 1
  nz = 1
  xmin = -0.5
  xmax = 0.5
  ymin = -0.5
  ymax = 0.5
  zmin = -0.5
  zmax = 0.5
[]


[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./disp_z]
  [../]
[]

[Kernels]
  [SolidMechanics]
    displacements = 'disp_x disp_y disp_z'
  [../]
[]


[BCs]
  [./x]
    type = FunctionDirichletBC
    variable = disp_x
    boundary = 'front back'
    function = '0E-6*x'
  [../]
  [./y]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = 'front back'
    function = '0E-6*y'
  [../]
  [./z]
    type = FunctionDirichletBC
    variable = disp_z
    boundary = 'front back'
    function = '1.5E-6*z'
  [../]
[]

[AuxVariables]
  [./stress_xx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_zz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./f0]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./f1]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./f2]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./int0]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./int1]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./int2]
    order = CONSTANT
    family = MONOMIAL
  [../]
[]

[AuxKernels]
  [./stress_xx]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xx
    index_i = 0
    index_j = 0
  [../]
  [./stress_xy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xy
    index_i = 0
    index_j = 1
  [../]
  [./stress_xz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xz
    index_i = 0
    index_j = 2
  [../]
  [./stress_yy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yy
    index_i = 1
    index_j = 1
  [../]
  [./stress_yz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yz
    index_i = 1
    index_j = 2
  [../]
  [./stress_zz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_zz
    index_i = 2
    index_j = 2
  [../]
  [./f0]
    type = MaterialStdVectorAux
    property = plastic_yield_function
    index = 0
    variable = f0
  [../]
  [./f1]
    type = MaterialStdVectorAux
    property = plastic_yield_function
    index = 1
    variable = f1
  [../]
  [./f2]
    type = MaterialStdVectorAux
    property = plastic_yield_function
    index = 2
    variable = f2
  [../]
  [./int0]
    type = MaterialStdVectorAux
    property = plastic_internal_parameter
    factor = 1E6
    index = 0
    variable = int0
  [../]
  [./int1]
    type = MaterialStdVectorAux
    property = plastic_internal_parameter
    factor = 1E6
    index = 1
    variable = int1
  [../]
  [./int2]
    type = MaterialStdVectorAux
    property = plastic_internal_parameter
    factor = 1E6
    index = 2
    variable = int2
  [../]
[]

[Postprocessors]
  [./s_xx]
    type = PointValue
    point = '0 0 0'
    variable = stress_xx
  [../]
  [./s_xy]
    type = PointValue
    point = '0 0 0'
    variable = stress_xy
  [../]
  [./s_xz]
    type = PointValue
    point = '0 0 0'
    variable = stress_xz
  [../]
  [./s_yy]
    type = PointValue
    point = '0 0 0'
    variable = stress_yy
  [../]
  [./s_yz]
    type = PointValue
    point = '0 0 0'
    variable = stress_yz
  [../]
  [./s_zz]
    type = PointValue
    point = '0 0 0'
    variable = stress_zz
  [../]
  [./f0]
    type = PointValue
    point = '0 0 0'
    variable = f0
  [../]
  [./f1]
    type = PointValue
    point = '0 0 0'
    variable = f1
  [../]
  [./f2]
    type = PointValue
    point = '0 0 0'
    variable = f2
  [../]
  [./int0]
    type = PointValue
    point = '0 0 0'
    variable = int0
  [../]
  [./int1]
    type = PointValue
    point = '0 0 0'
    variable = int1
  [../]
  [./int2]
    type = PointValue
    point = '0 0 0'
    variable = int2
  [../]
[]

[UserObjects]
  [./simple0]
    type = SolidMechanicsPlasticSimpleTester
    a = 0
    b = 1
    strength = 1
    yield_function_tolerance = 1.0E-9
    internal_constraint_tolerance = 1.0E-9
  [../]
  [./simple1]
    type = SolidMechanicsPlasticSimpleTester
    a = 1
    b = 0
    strength = 1
    yield_function_tolerance = 1.0E-9
    internal_constraint_tolerance = 1.0E-9
  [../]
  [./simple2]
    type = SolidMechanicsPlasticSimpleTester
    a = 1
    b = 1
    strength = 1.5
    yield_function_tolerance = 1.0E-9
    internal_constraint_tolerance = 1.0E-9
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeElasticityTensor
    block = 0
    fill_method = symmetric_isotropic
    C_ijkl = '0 0.5E6'
  [../]
  [./strain]
    type = ComputeFiniteStrain
    block = 0
    displacements = 'disp_x disp_y disp_z'
  [../]
  [./multi]
    type = ComputeMultiPlasticityStress
    block = 0
    ep_plastic_tolerance = 1E-9
    plastic_models = 'simple0 simple1 simple2'
    max_NR_iterations = 2
    min_stepsize = 1
    debug_fspb = crash
    debug_jac_at_stress = '10 0 0 0 10 0 0 0 10'
    debug_jac_at_pm = '1 1'
    debug_jac_at_intnl = '1 1'
    debug_stress_change = 1E-5
    debug_pm_change = '1E-6 1E-6'
    debug_intnl_change = '1E-6 1E-6'
  [../]
[]


[Executioner]
  end_time = 1
  dt = 1
  type = Transient
[]


[Outputs]
  file_base = three_surface01
  exodus = false
  [./csv]
    type = CSV
    [../]
[]

(modules/contact/test/tests/pdass_problems/ironing_penalty.i)

[GlobalParams]
  volumetric_locking_correction = true
  displacements = 'disp_x disp_y'
[]

[Mesh]
  [input_file]
    type = FileMeshGenerator
    file = iron.e
  []
  [secondary]
    type = LowerDBlockFromSidesetGenerator
    new_block_id = 10001
    new_block_name = 'secondary_lower'
    sidesets = '10'
    input = input_file
  []
  [primary]
    type = LowerDBlockFromSidesetGenerator
    new_block_id = 10000
    sidesets = '20'
    new_block_name = 'primary_lower'
    input = secondary
  []
  patch_update_strategy = auto
  patch_size = 20
  allow_renumbering = false
[]

[Variables]
  [disp_x]
  []
  [disp_y]
  []
[]

[AuxVariables]
  [penalty_normal_pressure]
    order = FIRST
    family = LAGRANGE
  []
  [penalty_frictional_pressure]
    order = FIRST
    family = LAGRANGE
  []
  [accumulated_slip_one]
    order = FIRST
    family = LAGRANGE
  []
  [tangential_vel_one]
    order = FIRST
    family = LAGRANGE
  []
  [real_weighted_gap]
    order = FIRST
    family = LAGRANGE
  []
  [stress_xx]
    order = CONSTANT
    family = MONOMIAL
  []
  [stress_yy]
    order = CONSTANT
    family = MONOMIAL
  []
  [stress_xy]
    order = CONSTANT
    family = MONOMIAL
  []
  [saved_x]
  []
  [saved_y]
  []
  [diag_saved_x]
  []
  [diag_saved_y]
  []
  [von_mises]
    order = CONSTANT
    family = MONOMIAL
  []
[]

[Functions]
  [disp_ramp_vert]
    type = PiecewiseLinear
    x = '0. 2. 8.'
    y = '0. -1.0 -1.0'
  []
  [disp_ramp_horz]
    type = PiecewiseLinear
    x = '0. 8.'
    y = '0. 8.'
  []
[]

[Kernels]
  [TensorMechanics]
    use_displaced_mesh = true
    save_in = 'saved_x saved_y'
    block = '1 2'
    strain = FINITE
  []
[]

[AuxKernels]
  [penalty_normal_pressure_auxk]
    type = PenaltyMortarUserObjectAux
    variable = penalty_normal_pressure
    user_object = friction_uo
    contact_quantity = normal_pressure
  []
  [penalty_frictional_pressure_auxk]
    type = PenaltyMortarUserObjectAux
    variable = penalty_frictional_pressure
    user_object = friction_uo
    contact_quantity = tangential_pressure_one
  []
  [penalty_accumulated_slip_auxk]
    type = PenaltyMortarUserObjectAux
    variable = accumulated_slip_one
    user_object = friction_uo
    contact_quantity = accumulated_slip_one
  []
  [penalty_tangential_vel_auxk]
    type = PenaltyMortarUserObjectAux
    variable = tangential_vel_one
    user_object = friction_uo
    contact_quantity = tangential_velocity_one
  []
  [real_weighted_gap_auxk]
    type = PenaltyMortarUserObjectAux
    variable = real_weighted_gap
    user_object = friction_uo
    contact_quantity = normal_gap
  []
  [stress_xx]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xx
    index_i = 0
    index_j = 0
    execute_on = timestep_end
    block = '1 2'
  []
  [stress_yy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yy
    index_i = 1
    index_j = 1
    execute_on = timestep_end
    block = '1 2'
  []
  [stress_xy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xy
    index_i = 0
    index_j = 1
    execute_on = timestep_end
    block = '1 2'
  []
  [von_mises_kernel]
    #Calculates the von mises stress and assigns it to von_mises
    type = RankTwoScalarAux
    variable = von_mises
    rank_two_tensor = stress
    execute_on = timestep_end
    scalar_type = VonMisesStress
    block = '1 2'
  []
[]

[VectorPostprocessors]
  [penalty_normal_pressure]
    type = NodalValueSampler
    variable = penalty_normal_pressure
    boundary = 10
    sort_by = id
  []
[]

[BCs]
  [bot_x_disp]
    type = DirichletBC
    variable = disp_x
    boundary = '40'
    value = 0.0
    preset = false
  []
  [bot_y_disp]
    type = DirichletBC
    variable = disp_y
    boundary = '40'
    value = 0.0
    preset = false
  []
  [top_y_disp]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = '30'
    function = disp_ramp_vert
    preset = false
  []
  [top_x_disp]
    type = FunctionDirichletBC
    variable = disp_x
    boundary = '30'
    function = disp_ramp_horz
    preset = false
  []
[]

[Materials]
  [stuff1_elas_tens]
    type = ComputeIsotropicElasticityTensor
    block = '2'
    youngs_modulus = 6896
    poissons_ratio = 0.32
  []
  [stuff1_strain]
    type = ComputeFiniteStrain
    block = '2'
  []
  [stuff1_stress]
    type = ComputeFiniteStrainElasticStress
    block = '2'
  []
  [stuff2_elas_tens]
    type = ComputeIsotropicElasticityTensor
    block = '1'
    youngs_modulus = 689.6
    poissons_ratio = 0.32
  []
  [stuff2_strain]
    type = ComputeFiniteStrain
    block = '1'
  []
  [stuff2_stress]
    type = ComputeFiniteStrainElasticStress
    block = '1'
  []
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'

  petsc_options = '-snes_ksp_ew'
  petsc_options_iname = '-pc_type -pc_factor_mat_solver_type'
  petsc_options_value = 'lu     superlu_dist'
  line_search = 'none'

  nl_abs_tol = 1e-7
  nl_rel_tol = 1e-7
  l_tol = 1e-6

  l_max_its = 50
  nl_max_its = 30

  start_time = 0.0
  end_time = 6.5 # 6.5

  dt = 0.0125
  dtmin = 1e-5
  [Predictor]
    type = SimplePredictor
    scale = 1.0
  []
[]

[Preconditioning]
  [SMP]
    type = SMP
    full = true
  []
[]

[Outputs]
  print_linear_residuals = true
  perf_graph = true
  exodus = true
  csv = true
  [chkfile]
    type = CSV
    start_time = 0.0
    execute_vector_postprocessors_on = FINAL
  []

  [console]
    type = Console
    max_rows = 5
  []
[]

[Debug]
  show_var_residual_norms = true
[]

[UserObjects]
  [friction_uo]
    type = PenaltyFrictionUserObject
    primary_boundary = 20
    secondary_boundary = 10
    primary_subdomain = 10000
    secondary_subdomain = 10001
    disp_x = disp_x
    disp_y = disp_y
    friction_coefficient = 0.1 # with 2.0 works
    secondary_variable = disp_x
    penalty = 1e5
    penalty_friction = 1e4
    use_physical_gap = true
  []
[]

[Constraints]
  [x]
    type = NormalMortarMechanicalContact
    primary_boundary = 20
    secondary_boundary = 10
    primary_subdomain = 10000
    secondary_subdomain = 10001
    secondary_variable = disp_x
    component = x
    use_displaced_mesh = true
    compute_lm_residuals = false
    weighted_gap_uo = friction_uo
  []
  [y]
    type = NormalMortarMechanicalContact
    primary_boundary = 20
    secondary_boundary = 10
    primary_subdomain = 10000
    secondary_subdomain = 10001
    secondary_variable = disp_y
    component = y
    use_displaced_mesh = true
    compute_lm_residuals = false
    weighted_gap_uo = friction_uo
  []
  [t_x]
    type = TangentialMortarMechanicalContact
    primary_boundary = 20
    secondary_boundary = 10
    primary_subdomain = 10000
    secondary_subdomain = 10001
    secondary_variable = disp_x
    component = x
    use_displaced_mesh = true
    compute_lm_residuals = false
    weighted_velocities_uo = friction_uo
  []
  [t_y]
    type = TangentialMortarMechanicalContact
    primary_boundary = 20
    secondary_boundary = 10
    primary_subdomain = 10000
    secondary_subdomain = 10001
    secondary_variable = disp_y
    component = y
    use_displaced_mesh = true
    compute_lm_residuals = false
    weighted_velocities_uo = friction_uo
  []
[]

(modules/contact/test/tests/pdass_problems/ironing_penalty_action.i)

[GlobalParams]
  volumetric_locking_correction = true
  displacements = 'disp_x disp_y'
[]

[Mesh]
  [input_file]
    type = FileMeshGenerator
    file = iron.e
  []

  patch_update_strategy = auto
  patch_size = 20
  allow_renumbering = false
[]

[Variables]
  [disp_x]
  []
  [disp_y]
  []
[]

[AuxVariables]
  [penalty_normal_pressure]
    order = FIRST
    family = LAGRANGE
  []
  [penalty_frictional_pressure]
    order = FIRST
    family = LAGRANGE
  []
  [accumulated_slip_one]
    order = FIRST
    family = LAGRANGE
  []
  [tangential_vel_one]
    order = FIRST
    family = LAGRANGE
  []
  [real_weighted_gap]
    order = FIRST
    family = LAGRANGE
  []
  [stress_xx]
    order = CONSTANT
    family = MONOMIAL
  []
  [stress_yy]
    order = CONSTANT
    family = MONOMIAL
  []
  [stress_xy]
    order = CONSTANT
    family = MONOMIAL
  []
  [saved_x]
  []
  [saved_y]
  []
  [diag_saved_x]
  []
  [diag_saved_y]
  []
  [von_mises]
    order = CONSTANT
    family = MONOMIAL
  []
[]

[Functions]
  [disp_ramp_vert]
    type = PiecewiseLinear
    x = '0. 2. 8.'
    y = '0. -1.0 -1.0'
  []
  [disp_ramp_horz]
    type = PiecewiseLinear
    x = '0. 8.'
    y = '0. 8.'
  []
[]

[Kernels]
  [TensorMechanics]
    use_displaced_mesh = true
    save_in = 'saved_x saved_y'
    block = '1 2'
    strain = FINITE
  []
[]

[AuxKernels]
  [penalty_normal_pressure_auxk]
    type = PenaltyMortarUserObjectAux
    variable = penalty_normal_pressure
    user_object = penalty_friction_object_contact_block
    contact_quantity = normal_pressure
  []
  [penalty_frictional_pressure_auxk]
    type = PenaltyMortarUserObjectAux
    variable = penalty_frictional_pressure
    user_object = penalty_friction_object_contact_block
    contact_quantity = tangential_pressure_one
  []
  [penalty_accumulated_slip_auxk]
    type = PenaltyMortarUserObjectAux
    variable = accumulated_slip_one
    user_object = penalty_friction_object_contact_block
    contact_quantity = accumulated_slip_one
  []
  [penalty_tangential_vel_auxk]
    type = PenaltyMortarUserObjectAux
    variable = tangential_vel_one
    user_object = penalty_friction_object_contact_block
    contact_quantity = tangential_velocity_one
  []
  [real_weighted_gap_auxk]
    type = PenaltyMortarUserObjectAux
    variable = real_weighted_gap
    user_object = penalty_friction_object_contact_block
    contact_quantity = normal_gap
  []
  [stress_xx]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xx
    index_i = 0
    index_j = 0
    execute_on = timestep_end
    block = '1 2'
  []
  [stress_yy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yy
    index_i = 1
    index_j = 1
    execute_on = timestep_end
    block = '1 2'
  []
  [stress_xy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xy
    index_i = 0
    index_j = 1
    execute_on = timestep_end
    block = '1 2'
  []
  [von_mises_kernel]
    #Calculates the von mises stress and assigns it to von_mises
    type = RankTwoScalarAux
    variable = von_mises
    rank_two_tensor = stress
    execute_on = timestep_end
    scalar_type = VonMisesStress
    block = '1 2'
  []
[]

[Contact]
  [contact_block]
    primary = 20
    secondary = 10
    friction_coefficient = 0.1
    model = coulomb
    formulation = mortar_penalty
    penalty = 1e5
    penalty_friction = 1e4
    use_dual = false
  []
[]

[VectorPostprocessors]
  [penalty_normal_pressure]
    type = NodalValueSampler
    variable = penalty_normal_pressure
    boundary = 10
    sort_by = id
  []
[]

[Postprocessors]
  [top_react_x]
    type = NodalSum
    variable = saved_x
    boundary = 30
  []
  [top_react_y]
    type = NodalSum
    variable = saved_y
    boundary = 30
  []
[]

[BCs]
  [bot_x_disp]
    type = DirichletBC
    variable = disp_x
    boundary = '40'
    value = 0.0
    preset = false
  []
  [bot_y_disp]
    type = DirichletBC
    variable = disp_y
    boundary = '40'
    value = 0.0
    preset = false
  []
  [top_y_disp]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = '30'
    function = disp_ramp_vert
    preset = false
  []
  [top_x_disp]
    type = FunctionDirichletBC
    variable = disp_x
    boundary = '30'
    function = disp_ramp_horz
    preset = false
  []
[]

[Materials]
  [stuff1_elas_tens]
    type = ComputeIsotropicElasticityTensor
    block = '2'
    youngs_modulus = 6896
    poissons_ratio = 0.32
  []
  [stuff1_strain]
    type = ComputeFiniteStrain
    block = '2'
  []
  [stuff1_stress]
    type = ComputeFiniteStrainElasticStress
    block = '2'
  []
  [stuff2_elas_tens]
    type = ComputeIsotropicElasticityTensor
    block = '1'
    youngs_modulus = 689.6
    poissons_ratio = 0.32
  []
  [stuff2_strain]
    type = ComputeFiniteStrain
    block = '1'
  []
  [stuff2_stress]
    type = ComputeFiniteStrainElasticStress
    block = '1'
  []
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'

  petsc_options = '-snes_ksp_ew'
  petsc_options_iname = '-pc_type -pc_factor_mat_solver_type'
  petsc_options_value = 'lu     superlu_dist'
  line_search = 'none'

  nl_abs_tol = 1e-7
  nl_rel_tol = 1e-7
  l_tol = 1e-6

  l_max_its = 50
  nl_max_its = 30

  start_time = 0.0
  end_time = 6.5 # 6.5

  dt = 0.0125
  dtmin = 1e-5
  [Predictor]
    type = SimplePredictor
    scale = 1.0
  []
[]

[Preconditioning]
  [SMP]
    type = SMP
    full = true
  []
[]

[Outputs]
  print_linear_residuals = true
  perf_graph = true
  exodus = true
  csv = true
  hide = 'nodal_area penetration contact_pressure'

  [chkfile]
    type = CSV
    start_time = 0.0
    execute_vector_postprocessors_on = FINAL
  []
  [console]
    type = Console
    max_rows = 5
  []
[]

[Debug]
  show_var_residual_norms = true
[]

(modules/contact/test/tests/mortar_dynamics/block-dynamics-friction-action.i)

starting_point = 2e-1
offset = -0.19

[GlobalParams]
  displacements = 'disp_x disp_y'
[]

[Mesh]
  [file]
    type = FileMeshGenerator
    file = long-bottom-block-no-lower-d.e
  []
[]

[Variables]
  [disp_x]
    block = '1 2'
  []
  [disp_y]
    block = '1 2'
  []
[]

[ICs]
  [disp_y]
    block = 2
    variable = disp_y
    value = '${fparse starting_point + offset}'
    type = ConstantIC
  []
[]

[Kernels]
  [DynamicTensorMechanics]
    displacements = 'disp_x disp_y'
    generate_output = 'stress_xx stress_yy'
    strain = FINITE
    block = '1 2'
    zeta = 0.05
    alpha = 0.0
  []
  [inertia_x]
    type = InertialForce
    variable = disp_x
    velocity = vel_x
    acceleration = accel_x
    beta = 0.25
    gamma = 0.5
    alpha = 0
    eta = 0.0
    block = '1 2'
  []
  [inertia_y]
    type = InertialForce
    variable = disp_y
    velocity = vel_y
    acceleration = accel_y
    beta = 0.25
    gamma = 0.5
    alpha = 0
    eta = 0.0
    block = '1 2'
  []
[]

[Materials]
  [elasticity_2]
    type = ComputeIsotropicElasticityTensor
    block = '2'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  []
  [elasticity_1]
    type = ComputeIsotropicElasticityTensor
    block = '1'
    youngs_modulus = 1e8
    poissons_ratio = 0.3
  []
  [stress]
    type = ComputeFiniteStrainElasticStress
    block = '1 2'
  []
  [strain]
    type = ComputeFiniteStrain
    block = '1 2'
  []
  [density]
    type = GenericConstantMaterial
    block = '1 2'
    prop_names = 'density'
    prop_values = '7750'
  []
[]

[AuxVariables]
  [vel_x]
    block = '1 2'
  []
  [accel_x]
    block = '1 2'
  []
  [vel_y]
    block = '1 2'
  []
  [accel_y]
    block = '1 2'
  []
  [vel_z]
    block = '1 2'
  []
  [accel_z]
    block = '1 2'
  []
[]

[AuxKernels]
  [accel_x]
    type = NewmarkAccelAux
    variable = accel_x
    displacement = disp_x
    velocity = vel_x
    beta = 0.25
    execute_on = 'LINEAR timestep_end'
  []
  [vel_x]
    type = NewmarkVelAux
    variable = vel_x
    acceleration = accel_x
    gamma = 0.5
    execute_on = 'LINEAR timestep_end'
  []
  [accel_y]
    type = NewmarkAccelAux
    variable = accel_y
    displacement = disp_y
    velocity = vel_y
    beta = 0.25
    execute_on = 'LINEAR timestep_end'
  []
  [vel_y]
    type = NewmarkVelAux
    variable = vel_y
    acceleration = accel_y
    gamma = 0.5
    execute_on = 'LINEAR timestep_end'
  []
[]

[Contact]
  [mechanical]
    formulation = mortar
    model = coulomb
    primary = 20
    secondary = 10
    friction_coefficient = 0.5
    c_normal = 1.0e4
    c_tangential = 1.0e4
    mortar_dynamics = true
    newmark_beta = 0.25
    newmark_gamma = 0.5
    capture_tolerance = 1.0e-5
  []
[]

[BCs]
  [botx]
    type = DirichletBC
    variable = disp_x
    boundary = 40
    value = 0.0
  []
  [boty]
    type = DirichletBC
    variable = disp_y
    boundary = 40
    value = 0.0
  []
  [topy]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = 30
    function = '${starting_point} * cos(2 * pi / 4 * t) + ${offset}'
  []
  [leftx]
    type = FunctionDirichletBC
    variable = disp_x
    boundary = 30 # 50
    function = '0' # '1e-2*t'
  []
[]

[Executioner]
  type = Transient
  end_time = 75
  dt = 0.05
  dtmin = .005
  solve_type = 'PJFNK'
  petsc_options = '-snes_converged_reason -ksp_converged_reason -pc_svd_monitor '
                  '-snes_linesearch_monitor -snes_ksp_ew'
  petsc_options_iname = '-pc_type -pc_factor_shift_type -pc_factor_shift_amount -mat_mffd_err '
  petsc_options_value = 'lu       NONZERO               1e-15                   1e-5'
  nl_max_its = 50
  line_search = 'none'
  snesmf_reuse_base = false

  [TimeIntegrator]
    type = NewmarkBeta
    beta = 0.25
    gamma = 0.5
  []
[]

[Debug]
  show_var_residual_norms = true
[]

[Outputs]
  exodus = true
[]

[VectorPostprocessors]
  [mechanical_tangential_lm]
    type = NodalValueSampler
    block = 'mechanical_secondary_subdomain'
    variable = mechanical_tangential_lm
    sort_by = 'x'
    execute_on = TIMESTEP_END
  []
[]

[Preconditioning]
  [smp]
    type = SMP
    full = true
  []
[]

(modules/contact/test/tests/explicit_dynamics/test_balance.i)

# One element test to test the central difference time integrator in 3D.
[GlobalParams]
  displacements = 'disp_x disp_y disp_z'
  volumetric_locking_correction = true
[]

[Mesh]
  [block_one]
    type = GeneratedMeshGenerator
    dim = 3
    nx = 3
    ny = 3
    nz = 3
    xmin = 4.5
    xmax = 5.5
    ymin = 4.5
    ymax = 5.5
    zmin = 0.0001
    zmax = 1.0001
    boundary_name_prefix = 'ball'
  []
  [block_two]
    type = GeneratedMeshGenerator
    dim = 3
    nx = 2
    ny = 2
    nz = 2
    xmin = 0.0
    xmax = 10
    ymin = 0.0
    ymax = 10
    zmin = -2
    zmax = 0
    boundary_name_prefix = 'base'
    boundary_id_offset = 10
  []
  [block_one_id]
    type = SubdomainIDGenerator
    input = block_one
    subdomain_id = 1
  []
  [block_two_id]
    type = SubdomainIDGenerator
    input = block_two
    subdomain_id = 2
  []
  [combine]
    type = MeshCollectionGenerator
    inputs = ' block_one_id block_two_id'
  []
  allow_renumbering = false
[]

[Variables]
  [disp_x]
  []
  [disp_y]
  []
  [disp_z]
  []
[]

[AuxVariables]
  [gap_rate]
  []
  [vel_x]
  []
  [accel_x]
  []
  [vel_y]
  []
  [accel_y]
  []
  [vel_z]
  []
  [accel_z]
  []
  [stress_zz]
    family = MONOMIAL
    order = CONSTANT
  []
  [strain_zz]
    family = MONOMIAL
    order = CONSTANT
  []
[]

[AuxKernels]
  [stress_zz]
    type = RankTwoAux
    rank_two_tensor = stress
    index_i = 2
    index_j = 2
    variable = stress_zz
    execute_on = 'TIMESTEP_END'
  []
  [strain_zz]
    type = RankTwoAux
    rank_two_tensor = mechanical_strain
    index_i = 2
    index_j = 2
    variable = strain_zz
  []
  [accel_x]
    type = TestNewmarkTI
    variable = accel_x
    displacement = disp_x
    first = false
    execute_on = 'LINEAR TIMESTEP_BEGIN TIMESTEP_END'
  []
  [vel_x]
    type = TestNewmarkTI
    variable = vel_x
    displacement = disp_x
    execute_on = 'LINEAR TIMESTEP_BEGIN TIMESTEP_END'
  []
  [accel_y]
    type = TestNewmarkTI
    variable = accel_y
    displacement = disp_y
    first = false
    execute_on = 'LINEAR TIMESTEP_BEGIN TIMESTEP_END'
  []
  [vel_y]
    type = TestNewmarkTI
    variable = vel_y
    displacement = disp_x
    execute_on = 'LINEAR TIMESTEP_BEGIN TIMESTEP_END'
  []
  [accel_z]
    type = TestNewmarkTI
    variable = accel_z
    displacement = disp_z
    first = false
    execute_on = 'LINEAR TIMESTEP_BEGIN TIMESTEP_END'
  []
  [vel_z]
    type = TestNewmarkTI
    variable = vel_z
    displacement = disp_z
    execute_on = 'LINEAR TIMESTEP_BEGIN TIMESTEP_END'
  []
[]

[Kernels]
  [DynamicTensorMechanics]
    displacements = 'disp_x disp_y disp_z'
    volumetric_locking_correction = true
    stiffness_damping_coefficient = 0.001
    generate_output = 'stress_zz strain_zz'
  []
  [inertia_x]
    type = InertialForce
    variable = disp_x
  []
  [inertia_y]
    type = InertialForce
    variable = disp_y
  []
  [inertia_z]
    type = InertialForce
    variable = disp_z
  []
[]

[Kernels]
  [gravity]
    type = Gravity
    variable = disp_z
    value = -981.0
  []
[]

[BCs]
  [x_front]
    type = DirichletBC
    variable = disp_x
    boundary = 'ball_front'
    preset = false
    value = 0.0
  []
  [y_front]
    type = DirichletBC
    variable = disp_y
    boundary = 'ball_front'
    preset = false
    value = 0.0
  []
  [x_fixed]
    type = DirichletBC
    variable = disp_x
    boundary = 'base_back'
    preset = false
    value = 0.0
  []
  [y_fixed]
    type = DirichletBC
    variable = disp_y
    boundary = 'base_back'
    preset = false
    value = 0.0
  []
  [z_fixed]
    type = DirichletBC
    variable = disp_z
    boundary = 'base_back'
    preset = false
    value = 0.0
  []
  [z_fixed_front]
    type = DirichletBC
    variable = disp_z
    boundary = 'base_front'
    preset = false
    value = 0.0
  []
[]

[ExplicitDynamicsContact]
  [my_contact]
    model = frictionless_balance
    primary = base_front
    secondary = ball_back
    vel_x = 'vel_x'
    vel_y = 'vel_y'
    vel_z = 'vel_z'
  []
[]

[Materials]
  [elasticity_tensor_block_one]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 1e6
    poissons_ratio = 0.0
    block = 1
    outputs = 'exodus'
    output_properties = __all__
  []
  [elasticity_tensor_block_two]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 1e10
    poissons_ratio = 0.0
    block = 2
    outputs = 'exodus'
    output_properties = __all__
  []
  [strain_block]
    type = ComputeFiniteStrain
    displacements = 'disp_x disp_y disp_z'
    implicit = false
  []
  [stress_block]
    type = ComputeFiniteStrainElasticStress
  []
  [density_one]
    type = GenericConstantMaterial
    prop_names = density
    prop_values = 1e1
    outputs = 'exodus'
    output_properties = 'density'
    block = '1'
  []
  [density_two]
    type = GenericConstantMaterial
    prop_names = density
    prop_values = 1e6
    outputs = 'exodus'
    output_properties = 'density'
    block = '2'
  []
  [wave_speed]
    type = WaveSpeed
    outputs = 'exodus'
    output_properties = 'wave_speed'
  []
[]

[Executioner]
  type = Transient
  start_time = -0.01
  end_time = -0.0075 # 10
  dt = 0.00001
  timestep_tolerance = 1e-6

  [TimeIntegrator]
    type = CentralDifference
    solve_type = lumped
  []
[]

[Outputs]
  interval = 50
  exodus = true
  csv = true
  checkpoint = true # for regression testing purposes
[]

[Postprocessors]
  [accel_58z]
    type = NodalVariableValue
    nodeid = 1
    variable = accel_z
  []
  [vel_58z]
    type = NodalVariableValue
    nodeid = 1
    variable = vel_z
  []
  [disp_58z]
    type = NodalVariableValue
    nodeid = 1
    variable = disp_z
  []
  [critical_time_step]
    type = CriticalTimeStep
  []
  [contact_pressure_max]
    type = NodalExtremeValue
    variable = contact_pressure
    block = '1 2'
    value_type = max
  []
[]

(modules/combined/test/tests/j2_plasticity_vs_LSH/necking/j2_hard1_necking.i)

#

[Mesh]
  file = necking_quad4.e
  displacements = 'disp_x disp_y'
[]

[Variables]
  [./disp_x]
    order = FIRST
    family = LAGRANGE
  [../]
  [./disp_y]
    order = FIRST
    family = LAGRANGE
  [../]
[]

[Kernels]
  [./TensorMechanics]
    displacements = 'disp_x disp_y'
    use_displaced_mesh = true
#    save_in_disp_x = force_x
    save_in_disp_y = force_y
  [../]
[]

[AuxVariables]
  [./stress_xx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./strain_xx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./strain_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
#  [./force_x]
#    order = FIRST
#    family = LAGRANGE
#  [../]
  [./force_y]
    order = FIRST
    family = LAGRANGE
  [../]
[]

[AuxKernels]
  [./stress_xx]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xx
    index_i = 0
    index_j = 0
  [../]
  [./stress_yy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yy
    index_i = 1
    index_j = 1
  [../]
  [./strain_xx]
    type = RankTwoAux
    rank_two_tensor = total_strain
    variable = strain_xx
    index_i = 0
    index_j = 0
  [../]
  [./strain_yy]
    type = RankTwoAux
    rank_two_tensor = total_strain
    variable = strain_yy
    index_i = 1
    index_j = 1
  [../]
[]

[BCs]
  [./left]
    type = DirichletBC
    variable = disp_x
    boundary = left
    value = 0.0
  [../]
  [./bottom]
    type = DirichletBC
    variable = disp_y
    boundary = bottom
    value = 0.0
  [../]
  [./y_top]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = top
    function = 't/5'
  [../]
[]

[UserObjects]
  [./str]
    type = TensorMechanicsHardeningConstant
    value = 2.4e2
  [../]
  [./j2]
    type = TensorMechanicsPlasticJ2
    yield_strength = str
    yield_function_tolerance = 1E-3
    internal_constraint_tolerance = 1E-9
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeElasticityTensor
    block = 1
    fill_method = symmetric_isotropic
    #with E = 2.1e5 and nu = 0.3
    #changed to SM values using E-nu to Lambda-G
    C_ijkl = '121154 80769.2'
  [../]
  [./strain]
    type = ComputeFiniteStrain
    block = 1
    displacements = 'disp_x disp_y'
  [../]
  [./mc]
    type = ComputeMultiPlasticityStress
    block = 1
    ep_plastic_tolerance = 1E-9
    plastic_models = j2
  [../]
[]

[Executioner]
  end_time = 0.2
  dt = 0.005
  type = Transient

  #Preconditioned JFNK (default)
  solve_type = 'PJFNK'

  petsc_options = '-snes_ksp_ew'
  petsc_options_iname = '-ksp_gmres_restart'
  petsc_options_value = '101'

  line_search = 'none'

  l_max_its = 100
  nl_max_its = 100
  nl_rel_tol = 1e-12
  nl_abs_tol = 1e-10
  l_tol = 1e-9
[]

[Postprocessors]
  [./stress_xx]
    type = ElementAverageValue
    variable = stress_xx
  [../]
  [./stress_yy]
    type = ElementAverageValue
    variable = stress_yy
  [../]
  [./strain_xx]
    type = ElementAverageValue
    variable = strain_xx
  [../]
  [./strain_yy]
    type = ElementAverageValue
    variable = strain_yy
  [../]
  [./disp_y]
    type = NodalSum
    variable = disp_y
    boundary = top
  [../]
  [./force_y]
    type = NodalSum
    variable = force_y
    boundary = top
  [../]
[]

[Outputs]
  exodus = true
  csv = true
  print_linear_residuals = false
  perf_graph = true
[]

(modules/solid_mechanics/test/tests/isotropicSD_plasticity/isotropicSD.i)

# UserObject IsotropicSD test, with constant hardening.
# Linear strain is applied in the x and y direction.

[Mesh]
  type = GeneratedMesh
  dim = 3
  nx = 1
  ny = 1
  nz = 1
  xmin =  -.5
  xmax = .5
  ymin = -.5
  ymax = .5
  zmin = -.5
  zmax = .5
[]


[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./disp_z]
  [../]
[]

[Kernels]
  [SolidMechanics]
    displacements = 'disp_x disp_y disp_z'
  [../]
[]


[BCs]
  [./xdisp]
    type = FunctionDirichletBC
    variable = disp_x
    boundary = 'right'
    function = '0.005*t'
  [../]
  [./ydisp]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = 'top'
    function = '0.005*t'
  [../]
  [./yfix]
    type = DirichletBC
    variable = disp_y
    boundary = 'bottom'
    value = 0
  [../]
  [./xfix]
    type = DirichletBC
    variable = disp_x
    boundary = 'left'
    value = 0
  [../]
  [./zfix]
    type = DirichletBC
    variable = disp_z
    boundary = 'back'
    value = 0
  [../]
[]

[AuxVariables]
  [./stress_xx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_zz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./plastic_xx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./plastic_xy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./plastic_xz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./plastic_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./plastic_yz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./plastic_zz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./f]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./iter]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./intnl]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./sdev]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./sdet]
    order = CONSTANT
    family = MONOMIAL
  [../]
[]

[AuxKernels]
  [./stress_xx]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xx
    index_i = 0
    index_j = 0
  [../]
  [./stress_xy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xy
    index_i = 0
    index_j = 1
  [../]
  [./stress_xz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xz
    index_i = 0
    index_j = 2
  [../]
  [./stress_yy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yy
    index_i = 1
    index_j = 1
  [../]
  [./stress_yz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yz
    index_i = 1
    index_j = 2
  [../]
  [./stress_zz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_zz
    index_i = 2
    index_j = 2
  [../]
  [./plastic_xx]
    type = RankTwoAux
    rank_two_tensor = plastic_strain
    variable = plastic_xx
    index_i = 0
    index_j = 0
  [../]
  [./plastic_xy]
    type = RankTwoAux
    rank_two_tensor = plastic_strain
    variable = plastic_xy
    index_i = 0
    index_j = 1
  [../]
  [./plastic_xz]
    type = RankTwoAux
    rank_two_tensor = plastic_strain
    variable = plastic_xz
    index_i = 0
    index_j = 2
  [../]
  [./plastic_yy]
    type = RankTwoAux
    rank_two_tensor = plastic_strain
    variable = plastic_yy
    index_i = 1
    index_j = 1
  [../]
  [./plastic_yz]
    type = RankTwoAux
    rank_two_tensor = plastic_strain
    variable = plastic_yz
    index_i = 1
    index_j = 2
  [../]
  [./plastic_zz]
    type = RankTwoAux
    rank_two_tensor = plastic_strain
    variable = plastic_zz
    index_i = 2
    index_j = 2
  [../]
  [./f]
    type = MaterialStdVectorAux
    index = 0
    property = plastic_yield_function
    variable = f
  [../]
  [./iter]
    type = MaterialRealAux
    property = plastic_NR_iterations
    variable = iter
  [../]
  [./intnl]
    type = MaterialStdVectorAux
    index = 0
    property = plastic_internal_parameter
    variable = intnl
  [../]
  [./sdev]
    type = RankTwoScalarAux
    variable = sdev
    rank_two_tensor = stress
    scalar_type = VonMisesStress
  [../]
[]

[Postprocessors]
  [./sdev]
    type = PointValue
    point = '0 0 0'
    variable = sdev
  [../]
  [./s_xx]
    type = PointValue
    point = '0 0 0'
    variable = stress_xx
  [../]
  [./p_xx]
    type = PointValue
    point = '0 0 0'
    variable = plastic_xx
  [../]
  [./s_xy]
    type = PointValue
    point = '0 0 0'
    variable = stress_xy
  [../]
  [./p_xy]
    type = PointValue
    point = '0 0 0'
    variable = plastic_xy
  [../]
  [./p_xz]
    type = PointValue
    point = '0 0 0'
    variable = plastic_xz
  [../]
  [./p_yz]
    type = PointValue
    point = '0 0 0'
    variable = plastic_yz
  [../]
  [./s_xz]
    type = PointValue
    point = '0 0 0'
    variable = stress_xz
  [../]
  [./s_yy]
    type = PointValue
    point = '0 0 0'
    variable = stress_yy
  [../]
  [./p_yy]
    type = PointValue
    point = '0 0 0'
    variable = plastic_yy
  [../]
  [./s_yz]
    type = PointValue
    point = '0 0 0'
    variable = stress_yz
  [../]
  [./s_zz]
    type = PointValue
    point = '0 0 0'
    variable = stress_zz
  [../]
  [./p_zz]
    type = PointValue
    point = '0 0 0'
    variable = plastic_zz
  [../]
  [./intnl]
    type = PointValue
    point = '0 0 0'
    variable = intnl
  [../]
[]

[UserObjects]
  [./str]
    type = SolidMechanicsHardeningConstant
    value = 300
  [../]
  [./IsotropicSD]
    type = SolidMechanicsPlasticIsotropicSD
    b = -0.2
    c = -0.779422863
    associative = true
    yield_strength = str
    yield_function_tolerance = 1e-5
    internal_constraint_tolerance = 1e-9
    use_custom_returnMap = false
    use_custom_cto = false
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeElasticityTensor
    block = 0
    fill_method = symmetric_isotropic
    C_ijkl = '121e3 80e3'
  [../]
  [./strain]
    type = ComputeFiniteStrain
    block = 0
    displacements = 'disp_x disp_y disp_z'
  [../]
  [./mc]
    type = ComputeMultiPlasticityStress
    block = 0
    ep_plastic_tolerance = 1e-9
    plastic_models = IsotropicSD
    debug_fspb = crash
    tangent_operator = elastic
  [../]
[]


[Executioner]
  num_steps = 3
  dt = .5
  type = Transient

  nl_rel_tol = 1e-6
  nl_max_its = 10
  l_tol = 1e-4
  l_max_its = 50

  solve_type = PJFNK
  petsc_options_iname = '-pc_type'
  petsc_options_value = 'lu'
[]


[Outputs]
  perf_graph = false
  csv = true
[]

[Preconditioning]
 [./smp]
   type = SMP
   full = true
 [../]
[]

(modules/solid_mechanics/test/tests/crystal_plasticity/user_object_based/user_object.i)

[Mesh]
  type = GeneratedMesh
  dim = 2
  elem_type = QUAD4
  displacements = 'disp_x disp_y'
  nx = 2
  ny = 2
[]

[GlobalParams]
  volumetric_locking_correction = true
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
[]

[Kernels]
  [SolidMechanics]
    displacements = 'disp_x disp_y'
    use_displaced_mesh = true
  [../]
[]

[AuxVariables]
  [./stress_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./e_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./fp_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./rotout]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./gss]
    order = CONSTANT
    family = MONOMIAL
  [../]
[]

[Functions]
  [./tdisp]
    type = ParsedFunction
    expression = 0.01*t
  [../]
[]

[UserObjects]
  [./prop_read]
    type = PropertyReadFile
    prop_file_name = 'euler_ang_file.txt'
    # Enter file data as prop#1, prop#2, .., prop#nprop
    nprop = 3
    read_type = element
  [../]
[]

[AuxKernels]
  [./stress_yy]
    type = RankTwoAux
    variable = stress_yy
    rank_two_tensor = stress
    index_j = 1
    index_i = 1
    execute_on = timestep_end
  [../]
  [./e_yy]
    type = RankTwoAux
    variable = e_yy
    rank_two_tensor = lage
    index_j = 1
    index_i = 1
    execute_on = timestep_end
  [../]
  [./fp_yy]
    type = RankTwoAux
    variable = fp_yy
    rank_two_tensor = fp
    index_j = 1
    index_i = 1
    execute_on = timestep_end
  [../]
  [./gss]
    type = MaterialStdVectorAux
    variable = gss
    property = state_var_gss
    index = 0
    execute_on = timestep_end
  [../]
[]

[BCs]
  [./fix_x]
    type = DirichletBC
    variable = disp_x
    boundary = 'left'
    value = 0
  [../]
  [./fix_y]
    type = DirichletBC
    variable = disp_y
    boundary = 'bottom'
    value = 0
  [../]
  [./tdisp]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = top
    function = tdisp
  [../]
[]

[UserObjects]
  [./slip_rate_gss]
    type = CrystalPlasticitySlipRateGSS
    variable_size = 12
    slip_sys_file_name = input_slip_sys.txt
    num_slip_sys_flowrate_props = 2
    flowprops = '1 4 0.001 0.1 5 8 0.001 0.1 9 12 0.001 0.1'
    uo_state_var_name = state_var_gss
  [../]
  [./slip_resistance_gss]
    type = CrystalPlasticitySlipResistanceGSS
    variable_size = 12
    uo_state_var_name = state_var_gss
  [../]
  [./state_var_gss]
    type = CrystalPlasticityStateVariable
    variable_size = 12
    groups = '0 4 8 12'
    group_values = '60.8 60.8 60.8'
    uo_state_var_evol_rate_comp_name = state_var_evol_rate_comp_gss
    scale_factor = 1.0
  [../]
  [./state_var_evol_rate_comp_gss]
    type = CrystalPlasticityStateVarRateComponentGSS
    variable_size = 12
    hprops = '1.0 541.5 109.8 2.5'
    uo_slip_rate_name = slip_rate_gss
    uo_state_var_name = state_var_gss
  [../]
[]

[Materials]
  [./crysp]
    type = FiniteStrainUObasedCP
    stol = 1e-2
    tan_mod_type = exact
    uo_slip_rates = 'slip_rate_gss'
    uo_slip_resistances = 'slip_resistance_gss'
    uo_state_vars = 'state_var_gss'
    uo_state_var_evol_rate_comps = 'state_var_evol_rate_comp_gss'
  [../]
  [./strain]
    type = ComputeFiniteStrain
    displacements = 'disp_x disp_y'
  [../]
  [./elasticity_tensor]
    type = ComputeElasticityTensorCP
    C_ijkl = '1.684e5 1.214e5 1.214e5 1.684e5 1.214e5 1.684e5 0.754e5 0.754e5 0.754e5'
    fill_method = symmetric9
    read_prop_user_object = prop_read
  [../]
[]

[Postprocessors]
  [./stress_yy]
    type = ElementAverageValue
    variable = stress_yy
  [../]
  [./e_yy]
    type = ElementAverageValue
    variable = e_yy
  [../]
  [./fp_yy]
    type = ElementAverageValue
    variable = fp_yy
  [../]
  [./gss]
    type = ElementAverageValue
    variable = gss
  [../]
[]

[Preconditioning]
  [./smp]
    type = SMP
    full = true
  [../]
[]

[Executioner]
  type = Transient
  dt = 0.01
  solve_type = 'PJFNK'

  petsc_options_iname = -pc_hypre_type
  petsc_options_value = boomerang
  nl_abs_tol = 1e-10
  nl_rel_step_tol = 1e-10
  dtmax = 10.0
  nl_rel_tol = 1e-10
  end_time = 1
  dtmin = 0.01
  num_steps = 10
  nl_abs_step_tol = 1e-10
[]

[Outputs]
  exodus = true
[]

(modules/solid_mechanics/test/tests/multi/three_surface10.i)

# Plasticit models:
# SimpleTester0 with a = 0 and b = 1 and strength = 1
# SimpleTester1 with a = 1 and b = 0 and strength = 1
# SimpleTester2 with a = 1 and b = 1 and strength = 1.5
#
# Lame lambda = 0 (Poisson=0).  Lame mu = 0.5E6
#
# A single element is stretched by 1.5E-6m in y direction and 0.0E-6 in z direction.
# trial stress_yy = 1.5 and stress_zz = 0.0
#
# Then SimpleTester1 should activate and the algorithm will return to
# stress_yy=1
# internal1 should be 0.5

[Mesh]
  type = GeneratedMesh
  dim = 3
  nx = 1
  ny = 1
  nz = 1
  xmin = -0.5
  xmax = 0.5
  ymin = -0.5
  ymax = 0.5
  zmin = -0.5
  zmax = 0.5
[]


[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./disp_z]
  [../]
[]

[Kernels]
  [SolidMechanics]
    displacements = 'disp_x disp_y disp_z'
  [../]
[]


[BCs]
  [./x]
    type = FunctionDirichletBC
    variable = disp_x
    boundary = 'front back'
    function = '0E-6*x'
  [../]
  [./y]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = 'front back'
    function = '1.5E-6*y'
  [../]
  [./z]
    type = FunctionDirichletBC
    variable = disp_z
    boundary = 'front back'
    function = '0.0E-6*z'
  [../]
[]

[AuxVariables]
  [./stress_xx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_zz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./f0]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./f1]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./f2]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./int0]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./int1]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./int2]
    order = CONSTANT
    family = MONOMIAL
  [../]
[]

[AuxKernels]
  [./stress_xx]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xx
    index_i = 0
    index_j = 0
  [../]
  [./stress_xy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xy
    index_i = 0
    index_j = 1
  [../]
  [./stress_xz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xz
    index_i = 0
    index_j = 2
  [../]
  [./stress_yy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yy
    index_i = 1
    index_j = 1
  [../]
  [./stress_yz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yz
    index_i = 1
    index_j = 2
  [../]
  [./stress_zz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_zz
    index_i = 2
    index_j = 2
  [../]
  [./f0]
    type = MaterialStdVectorAux
    property = plastic_yield_function
    index = 0
    variable = f0
  [../]
  [./f1]
    type = MaterialStdVectorAux
    property = plastic_yield_function
    index = 1
    variable = f1
  [../]
  [./f2]
    type = MaterialStdVectorAux
    property = plastic_yield_function
    index = 2
    variable = f2
  [../]
  [./int0]
    type = MaterialStdVectorAux
    property = plastic_internal_parameter
    factor = 1E6
    index = 0
    variable = int0
  [../]
  [./int1]
    type = MaterialStdVectorAux
    property = plastic_internal_parameter
    factor = 1E6
    index = 1
    variable = int1
  [../]
  [./int2]
    type = MaterialStdVectorAux
    property = plastic_internal_parameter
    factor = 1E6
    index = 2
    variable = int2
  [../]
[]

[Postprocessors]
  [./s_xx]
    type = PointValue
    point = '0 0 0'
    variable = stress_xx
  [../]
  [./s_xy]
    type = PointValue
    point = '0 0 0'
    variable = stress_xy
  [../]
  [./s_xz]
    type = PointValue
    point = '0 0 0'
    variable = stress_xz
  [../]
  [./s_yy]
    type = PointValue
    point = '0 0 0'
    variable = stress_yy
  [../]
  [./s_yz]
    type = PointValue
    point = '0 0 0'
    variable = stress_yz
  [../]
  [./s_zz]
    type = PointValue
    point = '0 0 0'
    variable = stress_zz
  [../]
  [./f0]
    type = PointValue
    point = '0 0 0'
    variable = f0
  [../]
  [./f1]
    type = PointValue
    point = '0 0 0'
    variable = f1
  [../]
  [./f2]
    type = PointValue
    point = '0 0 0'
    variable = f2
  [../]
  [./int0]
    type = PointValue
    point = '0 0 0'
    variable = int0
  [../]
  [./int1]
    type = PointValue
    point = '0 0 0'
    variable = int1
  [../]
  [./int2]
    type = PointValue
    point = '0 0 0'
    variable = int2
  [../]
[]

[UserObjects]
  [./simple0]
    type = SolidMechanicsPlasticSimpleTester
    a = 0
    b = 1
    strength = 1
    yield_function_tolerance = 1.0E-9
    internal_constraint_tolerance = 1.0E-9
  [../]
  [./simple1]
    type = SolidMechanicsPlasticSimpleTester
    a = 1
    b = 0
    strength = 1
    yield_function_tolerance = 1.0E-9
    internal_constraint_tolerance = 1.0E-9
  [../]
  [./simple2]
    type = SolidMechanicsPlasticSimpleTester
    a = 1
    b = 1
    strength = 1.5
    yield_function_tolerance = 1.0E-9
    internal_constraint_tolerance = 1.0E-9
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeElasticityTensor
    block = 0
    fill_method = symmetric_isotropic
    C_ijkl = '0 0.5E6'
  [../]
  [./strain]
    type = ComputeFiniteStrain
    block = 0
    displacements = 'disp_x disp_y disp_z'
  [../]
  [./multi]
    type = ComputeMultiPlasticityStress
    block = 0
    ep_plastic_tolerance = 1E-9
    plastic_models = 'simple0 simple1 simple2'
    max_NR_iterations = 2
    min_stepsize = 1
    debug_fspb = crash
    debug_jac_at_stress = '10 0 0 0 10 0 0 0 10'
    debug_jac_at_pm = '1 1'
    debug_jac_at_intnl = '1 1'
    debug_stress_change = 1E-5
    debug_pm_change = '1E-6 1E-6'
    debug_intnl_change = '1E-6 1E-6'
  [../]
[]


[Executioner]
  end_time = 1
  dt = 1
  type = Transient
[]


[Outputs]
  file_base = three_surface10
  exodus = false
  [./csv]
    type = CSV
    [../]
[]

(modules/fsi/test/tests/fsi_acoustics/1D_struc_acoustic/1D_struc_acoustic.i)

# Test for `StructureAcousticInterface` interface kernel. The domain is 1D with 20m
# length. The fluid domain is on the right and the structural domain is on the left.
# Fluid end is subjected to a 250Hz sine wave with a single peak of amplitude unity.
# Structural domain is 4 times as dense as the fluid domain with all other material
# properties being the same. Fluid pressure is recorded at the midpoint in the fluid
# domain (i.e., at 15m). Structural stress is recorded at the midpoint in the structural
# domain (i.e., at 5m). The recorded pressure and stress amplitudes should match
# with theoretical values.
#
# Input parameters:
# Dimensions = 1
# Length = 20 meters
# Fluid speed of sound = 1500 m/s
# Fluid density = 1e-6 Giga kg/m^3
# Structural bulk modulus = 2.25 GPa
# Structural shear modulus = 0 GPa
# Structural density = 4e-6 Giga kg/m^3
# Fluid domain = true
# Fluid BC = single peak sine wave applied as a pressure on the fluid end
# Structural domain = true
# Structural BC = Neumann BC with value zero applied on the structural end.

[Mesh]
  [gen]
    type = GeneratedMeshGenerator
    dim = 1
    nx = 50
    xmax = 20
  []
  [./subdomain1]
    input = gen
    type = SubdomainBoundingBoxGenerator
    bottom_left = '10.0 0 0'
    block_id = 1
    top_right = '20.0 0.0 0'
  [../]
  [./interface1]
    type = SideSetsBetweenSubdomainsGenerator
    input = subdomain1
    primary_block = '1'
    paired_block = 0
    new_boundary = 'interface1'
  [../]
[]

[GlobalParams]
[]

[Variables]
  [./p]
    block = 1
  [../]
  [./disp_x]
    block = 0
  [../]
[]

[AuxVariables]
  [./vel_x]
    order = FIRST
    family = LAGRANGE
    block = 0
  [../]
  [./accel_x]
    order = FIRST
    family = LAGRANGE
    block = 0
  [../]
  [./stress_xx]
    order = CONSTANT
    family = MONOMIAL
    block = 0
  [../]
[]

[Kernels]
  [./diffusion]
    type = Diffusion
    variable = 'p'
    block = 1
  [../]
  [./inertia]
    type = AcousticInertia
    variable = p
    block = 1
  [../]
  [./DynamicTensorMechanics]
    displacements = 'disp_x'
    block = 0
  [../]
  [./inertia_x1]
    type = InertialForce
    variable = disp_x
    block = 0
  [../]
[]

[AuxKernels]
  [./accel_x]
    type = TestNewmarkTI
    displacement = disp_x
    variable = accel_x
    first = false
    block = 0
  [../]
  [./vel_x]
    type = TestNewmarkTI
    displacement = disp_x
    variable = vel_x
    block = 0
  [../]
  [./stress_xx]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xx
    index_i = 0
    index_j = 0
    block = 0
  [../]
[]

[InterfaceKernels]
  [./interface1]
    type =  StructureAcousticInterface
    variable = p
    neighbor_var = disp_x
    boundary = 'interface1'
    D = 1e-6
    component = 0
  [../]
[]

[BCs]
  [./bottom_accel]
    type = FunctionDirichletBC
    variable = p
    boundary = 'right'
    function = accel_bottom
  [../]
  [./disp_x1]
    type = NeumannBC
    boundary = 'left'
    variable = disp_x
    value = 0.0
  [../]
[]

[Functions]
  [./accel_bottom]
    type = PiecewiseLinear
    data_file = Input_1Peak_highF.csv
    scale_factor = 1e-2
    format = 'columns'
  [../]
[]

[Materials]
  [./co_sq]
    type = GenericConstantMaterial
    prop_names = inv_co_sq
    prop_values = 4.44e-7
    block = '1'
  [../]
  [./density0]
    type = GenericConstantMaterial
    block = 0
    prop_names = density
    prop_values = 4e-6
  [../]
  [./elasticity_base]
    type = ComputeIsotropicElasticityTensor
    bulk_modulus = 2.25
    shear_modulus = 0.0
    block = 0
  [../]
  [./strain]
    type = ComputeFiniteStrain
    block = 0
    displacements = 'disp_x'
  [../]
  [./stress]
    type =  ComputeFiniteStrainElasticStress
    block = 0
  [../]
[]

[Preconditioning]
  [./andy]
    type = SMP
    full = true
  [../]
[]

[Executioner]
  type = Transient
  solve_type = 'NEWTON'
  petsc_options_iname = '-pc_type -pc_factor_mat_solver_package'
  petsc_options_value = 'lu       superlu_dist'
  start_time = 0.0
  end_time = 0.01
  dt = 0.0001
  dtmin = 0.00001
  nl_abs_tol = 1e-12
  nl_rel_tol = 1e-12
  l_tol = 1e-12
  l_max_its = 25
  timestep_tolerance = 1e-8
  automatic_scaling = true
  [TimeIntegrator]
    type = NewmarkBeta
  []
[]

[Postprocessors]
  [./p1]
    type = PointValue
    point = '10.0 0.0 0.0'
    variable = p
  [../]
  [./stress1]
    type = PointValue
    point = '10.0 0.0 0.0'
    variable = stress_xx
  [../]
[]

[Outputs]
  csv = true
  perf_graph = true
  print_linear_residuals = true
[]

(modules/solid_mechanics/test/tests/crystal_plasticity/user_object_based/exception.i)

[Mesh]
  type = GeneratedMesh
  dim = 3
  elem_type = HEX8
  displacements = 'ux uy uz'
[]

[Variables]
  [./ux]
  [../]
  [./uy]
  [../]
  [./uz]
  [../]
[]

[AuxVariables]
  [./stress_zz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./pk2]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./fp_zz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./rotout]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./e_zz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./gss]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./slip_increment]
   order = CONSTANT
   family = MONOMIAL
  [../]
[]

[Functions]
  [./tdisp]
    type = ParsedFunction
    expression = 0.1*t
  [../]
[]

[Kernels]
  [SolidMechanics]
    displacements = 'ux uy uz'
    use_displaced_mesh = true
  [../]
[]

[AuxKernels]
  [./stress_zz]
    type = RankTwoAux
    variable = stress_zz
    rank_two_tensor = stress
    index_j = 2
    index_i = 2
    execute_on = timestep_end
  [../]
  [./pk2]
   type = RankTwoAux
   variable = pk2
   rank_two_tensor = pk2
   index_j = 2
   index_i = 2
   execute_on = timestep_end
  [../]
  [./fp_zz]
    type = RankTwoAux
    variable = fp_zz
    rank_two_tensor = fp
    index_j = 2
    index_i = 2
    execute_on = timestep_end
  [../]
  [./e_zz]
    type = RankTwoAux
    variable = e_zz
    rank_two_tensor = lage
    index_j = 2
    index_i = 2
    execute_on = timestep_end
  [../]
  [./gss]
    type = MaterialStdVectorAux
    variable = gss
    property = state_var_gss
    index = 0
    execute_on = timestep_end
  [../]
  [./slip_inc]
   type = MaterialStdVectorAux
   variable = slip_increment
   property = slip_rate_gss
   index = 0
   execute_on = timestep_end
  [../]
[]

[BCs]
  [./symmy]
    type = DirichletBC
    variable = uy
    boundary = bottom
    value = 0
  [../]
  [./symmx]
    type = DirichletBC
    variable = ux
    boundary = left
    value = 0
  [../]
  [./symmz]
    type = DirichletBC
    variable = uz
    boundary = back
    value = 0
  [../]
  [./tdisp]
    type = FunctionDirichletBC
    variable = uz
    boundary = front
    function = tdisp
  [../]
[]

[UserObjects]
  [./slip_rate_gss]
    type = CrystalPlasticitySlipRateGSS
    variable_size = 12
    slip_sys_file_name = input_slip_sys.txt
    num_slip_sys_flowrate_props = 2
    flowprops = '1 4 0.001 0.1 5 8 0.001 0.1 9 12 0.001 0.1'
    uo_state_var_name = state_var_gss
  [../]
  [./slip_resistance_gss]
    type = CrystalPlasticitySlipResistanceGSS
    variable_size = 12
    uo_state_var_name = state_var_gss
  [../]
  [./state_var_gss]
    type = CrystalPlasticityStateVariable
    variable_size = 12
    groups = '0 4 8 12'
    group_values = '60.8 60.8 60.8'
    uo_state_var_evol_rate_comp_name = state_var_evol_rate_comp_gss
    scale_factor = 1.0
  [../]
  [./state_var_evol_rate_comp_gss]
    type = CrystalPlasticityStateVarRateComponentGSS
    variable_size = 12
    hprops = '1.0 541.5 109.8 2.5'
    uo_slip_rate_name = slip_rate_gss
    uo_state_var_name = state_var_gss
  [../]
[]

[Materials]
  [./crysp]
    type = FiniteStrainUObasedCP
    block = 0
    stol = 1e-2
    tan_mod_type = exact
    uo_slip_rates = 'slip_rate_gss'
    uo_slip_resistances = 'slip_resistance_gss'
    uo_state_vars = 'state_var_gss'
    uo_state_var_evol_rate_comps = 'state_var_evol_rate_comp_gss'
  [../]
  [./strain]
    type = ComputeFiniteStrain
    block = 0
    displacements = 'ux uy uz'
  [../]
  [./elasticity_tensor]
    type = ComputeElasticityTensorCP
    block = 0
    C_ijkl = '1.684e5 1.214e5 1.214e5 1.684e5 1.214e5 1.684e5 0.754e5 0.754e5 0.754e5'
    fill_method = symmetric9
  [../]
[]

[Postprocessors]
  [./stress_zz]
    type = ElementAverageValue
    variable = stress_zz
  [../]
  [./pk2]
   type = ElementAverageValue
   variable = pk2
  [../]
  [./fp_zz]
    type = ElementAverageValue
    variable = fp_zz
  [../]
  [./e_zz]
    type = ElementAverageValue
    variable = e_zz
  [../]
  [./gss]
    type = ElementAverageValue
    variable = gss
  [../]
  [./slip_increment]
   type = ElementAverageValue
   variable = slip_increment
  [../]
[]

[Preconditioning]
  [./smp]
    type = SMP
    full = true
  [../]
[]

[Executioner]
  type = Transient
  dt = 0.05
  solve_type = 'PJFNK'

  petsc_options_iname = -pc_hypre_type
  petsc_options_value = boomerang
  nl_abs_tol = 1e-10
  nl_rel_step_tol = 1e-10
  dtmax = 10.0
  nl_rel_tol = 1e-10
  end_time = 1
  dtmin = 0.01
  num_steps = 10
  nl_abs_step_tol = 1e-10
[]

[Outputs]
  exodus = true
[]

(modules/combined/test/tests/poro_mechanics/borehole_highres.i)

# Poroelastic response of a borehole.
#
# HIGHRES VERSION: this version gives good agreement with the analytical solution, but it takes a while so is a "heavy" test
#
# A fully-saturated medium contains a fluid with a homogeneous porepressure,
# but an anisitropic insitu stress.  A infinitely-long borehole aligned with
# the $$z$$ axis is instanteously excavated.  The borehole boundary is
# stress-free and allowed to freely drain.  This problem is analysed using
# plane-strain conditions (no $$z$$ displacement).
#
# The solution in Laplace space is found in E Detournay and AHD Cheng "Poroelastic response of a borehole in a non-hydrostatic stress field".  International Journal of Rock Mechanics and Mining Sciences and Geomechanics Abstracts 25 (1988) 171-182.  In the small-time limit, the Laplace transforms may be performed.  There is one typo in the paper.  Equation (A4)'s final term should be -(a/r)\sqrt(4ct/(a^2\pi)), and not +(a/r)\sqrt(4ct/(a^2\pi)).
#
# Because realistic parameters are chosen (below),
# the residual for porepressure is much smaller than
# the residuals for the displacements.  Therefore the
# scaling parameter is chosen.  Also note that the
# insitu stresses are effective stresses, not total
# stresses, but the solution in the above paper is
# expressed in terms of total stresses.
#
# Here are the problem's parameters, and their values:
# Borehole radius.  a = 1
# Rock's Lame lambda.  la = 0.5E9
# Rock's Lame mu, which is also the Rock's shear modulus.  mu = G = 1.5E9
# Rock bulk modulus.  K = la + 2*mu/3 = 1.5E9
# Drained Poisson ratio.  nu = (3K - 2G)/(6K + 2G) = 0.125
# Rock bulk compliance.  1/K = 0.66666666E-9
# Fluid bulk modulus.  Kf = 0.7171315E9
# Fluid bulk compliance.  1/Kf = 1.39444444E-9
# Rock initial porosity.  phi0 = 0.3
# Biot coefficient.  alpha = 0.65
# Biot modulus.  M = 1/(phi0/Kf + (alpha - phi0)(1 - alpha)/K) = 2E9
# Undrained bulk modulus. Ku = K + alpha^2*M = 2.345E9
# Undrained Poisson ratio.  nuu = (3Ku - 2G)/(6Ku + 2G) = 0.2364
# Skempton coefficient.  B = alpha*M/Ku = 0.554
# Fluid mobility (rock permeability/fluid viscosity).  k = 1E-12

[Mesh]
  type = FileMesh
  file = borehole_highres_input.e
[]

[GlobalParams]
  displacements = 'disp_x disp_y disp_z'
  porepressure = porepressure
  block = 1
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./disp_z]
  [../]
  [./porepressure]
    scaling = 1E9  # Notice the scaling, to make porepressure's kernels roughly of same magnitude as disp's kernels
  [../]
[]

[GlobalParams]
  volumetric_locking_correction=true
[]

[ICs]
  [./initial_p]
    type = ConstantIC
    variable = porepressure
    value = 1E6
  [../]
[]

[BCs]
  [./fixed_outer_x]
    type = DirichletBC
    variable = disp_x
    value = 0
    boundary = outer
  [../]
  [./fixed_outer_y]
    type = DirichletBC
    variable = disp_y
    value = 0
    boundary = outer
  [../]
  [./plane_strain]
    type = DirichletBC
    variable = disp_z
    value = 0
    boundary = 'zmin zmax'
  [../]
  [./borehole_wall]
    type = DirichletBC
    variable = porepressure
    value = 0
    boundary = bh_wall
  [../]
[]



[AuxVariables]
  [./stress_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./tot_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
[]

[AuxKernels]
  [./stress_yy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yy
    index_i = 1
    index_j = 1
  [../]
  [./tot_yy]
    type = ParsedAux
    coupled_variables = 'stress_yy porepressure'
    execute_on = timestep_end
    variable = tot_yy
    expression = 'stress_yy-0.65*porepressure'
  [../]
[]



[Kernels]
  [./grad_stress_x]
    type = StressDivergenceTensors
    variable = disp_x
    component = 0
  [../]
  [./grad_stress_y]
    type = StressDivergenceTensors
    variable = disp_y
    component = 1
  [../]
  [./grad_stress_z]
    type = StressDivergenceTensors
    variable = disp_z
    component = 2
  [../]
  [./poro_x]
    type = PoroMechanicsCoupling
    variable = disp_x
    component = 0
  [../]
  [./poro_y]
    type = PoroMechanicsCoupling
    variable = disp_y
    component = 1
  [../]
  [./poro_z]
    type = PoroMechanicsCoupling
    variable = disp_z
    component = 2
  [../]
  [./poro_timederiv]
    type = PoroFullSatTimeDerivative
    variable = porepressure
  [../]
  [./darcy_flow]
    type = CoefDiffusion
    variable = porepressure
    coef = 1E-12
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeElasticityTensor
    C_ijkl = '0.5E9 1.5E9'
    # bulk modulus is lambda + 2*mu/3 = 0.5 + 2*1.5/3 = 1.5E9
    fill_method = symmetric_isotropic
  [../]
  [./strain]
    type = ComputeFiniteStrain
    displacements = 'disp_x disp_y disp_z'
    eigenstrain_names = ini_stress
  [../]
  [./ini_stress]
    type = ComputeEigenstrainFromInitialStress
    initial_stress = '-1.35E6 0 0  0 -3.35E6 0  0 0 0' # remember this is the effective stress
    eigenstrain_name = ini_stress
  [../]
  [./no_plasticity]
    type = ComputeFiniteStrainElasticStress
  [../]
  [./poro_material]
    type = PoroFullSatMaterial
    porosity0 = 0.3
    biot_coefficient = 0.65
    solid_bulk_compliance = 0.6666666666667E-9
    fluid_bulk_compliance = 1.3944444444444E-9
    constant_porosity = false
  [../]
[]

[Postprocessors]
  [./p00]
    type = PointValue
    variable = porepressure
    point = '1.00 0 0'
    outputs = csv_p
  [../]
  [./p01]
    type = PointValue
    variable = porepressure
    point = '1.01 0 0'
    outputs = csv_p
  [../]
  [./p02]
    type = PointValue
    variable = porepressure
    point = '1.02 0 0'
    outputs = csv_p
  [../]
  [./p03]
    type = PointValue
    variable = porepressure
    point = '1.03 0 0'
    outputs = csv_p
  [../]
  [./p04]
    type = PointValue
    variable = porepressure
    point = '1.04 0 0'
    outputs = csv_p
  [../]
  [./p05]
    type = PointValue
    variable = porepressure
    point = '1.05 0 0'
    outputs = csv_p
  [../]
  [./p06]
    type = PointValue
    variable = porepressure
    point = '1.06 0 0'
    outputs = csv_p
  [../]
  [./p07]
    type = PointValue
    variable = porepressure
    point = '1.07 0 0'
    outputs = csv_p
  [../]
  [./p08]
    type = PointValue
    variable = porepressure
    point = '1.08 0 0'
    outputs = csv_p
  [../]
  [./p09]
    type = PointValue
    variable = porepressure
    point = '1.09 0 0'
    outputs = csv_p
  [../]
  [./p10]
    type = PointValue
    variable = porepressure
    point = '1.10 0 0'
    outputs = csv_p
  [../]
  [./p11]
    type = PointValue
    variable = porepressure
    point = '1.11 0 0'
    outputs = csv_p
  [../]
  [./p12]
    type = PointValue
    variable = porepressure
    point = '1.12 0 0'
    outputs = csv_p
  [../]
  [./p13]
    type = PointValue
    variable = porepressure
    point = '1.13 0 0'
    outputs = csv_p
  [../]
  [./p14]
    type = PointValue
    variable = porepressure
    point = '1.14 0 0'
    outputs = csv_p
  [../]
  [./p15]
    type = PointValue
    variable = porepressure
    point = '1.15 0 0'
    outputs = csv_p
  [../]
  [./p16]
    type = PointValue
    variable = porepressure
    point = '1.16 0 0'
    outputs = csv_p
  [../]
  [./p17]
    type = PointValue
    variable = porepressure
    point = '1.17 0 0'
    outputs = csv_p
  [../]
  [./p18]
    type = PointValue
    variable = porepressure
    point = '1.18 0 0'
    outputs = csv_p
  [../]
  [./p19]
    type = PointValue
    variable = porepressure
    point = '1.19 0 0'
    outputs = csv_p
  [../]
  [./p20]
    type = PointValue
    variable = porepressure
    point = '1.20 0 0'
    outputs = csv_p
  [../]
  [./p21]
    type = PointValue
    variable = porepressure
    point = '1.21 0 0'
    outputs = csv_p
  [../]
  [./p22]
    type = PointValue
    variable = porepressure
    point = '1.22 0 0'
    outputs = csv_p
  [../]
  [./p23]
    type = PointValue
    variable = porepressure
    point = '1.23 0 0'
    outputs = csv_p
  [../]
  [./p24]
    type = PointValue
    variable = porepressure
    point = '1.24 0 0'
    outputs = csv_p
  [../]
  [./p25]
    type = PointValue
    variable = porepressure
    point = '1.25 0 0'
    outputs = csv_p
  [../]

  [./s00]
    type = PointValue
    variable = disp_x
    point = '1.00 0 0'
    outputs = csv_s
  [../]
  [./s01]
    type = PointValue
    variable = disp_x
    point = '1.01 0 0'
    outputs = csv_s
  [../]
  [./s02]
    type = PointValue
    variable = disp_x
    point = '1.02 0 0'
    outputs = csv_s
  [../]
  [./s03]
    type = PointValue
    variable = disp_x
    point = '1.03 0 0'
    outputs = csv_s
  [../]
  [./s04]
    type = PointValue
    variable = disp_x
    point = '1.04 0 0'
    outputs = csv_s
  [../]
  [./s05]
    type = PointValue
    variable = disp_x
    point = '1.05 0 0'
    outputs = csv_s
  [../]
  [./s06]
    type = PointValue
    variable = disp_x
    point = '1.06 0 0'
    outputs = csv_s
  [../]
  [./s07]
    type = PointValue
    variable = disp_x
    point = '1.07 0 0'
    outputs = csv_s
  [../]
  [./s08]
    type = PointValue
    variable = disp_x
    point = '1.08 0 0'
    outputs = csv_s
  [../]
  [./s09]
    type = PointValue
    variable = disp_x
    point = '1.09 0 0'
    outputs = csv_s
  [../]
  [./s10]
    type = PointValue
    variable = disp_x
    point = '1.10 0 0'
    outputs = csv_s
  [../]
  [./s11]
    type = PointValue
    variable = disp_x
    point = '1.11 0 0'
    outputs = csv_s
  [../]
  [./s12]
    type = PointValue
    variable = disp_x
    point = '1.12 0 0'
    outputs = csv_s
  [../]
  [./s13]
    type = PointValue
    variable = disp_x
    point = '1.13 0 0'
    outputs = csv_s
  [../]
  [./s14]
    type = PointValue
    variable = disp_x
    point = '1.14 0 0'
    outputs = csv_s
  [../]
  [./s15]
    type = PointValue
    variable = disp_x
    point = '1.15 0 0'
    outputs = csv_s
  [../]
  [./s16]
    type = PointValue
    variable = disp_x
    point = '1.16 0 0'
    outputs = csv_s
  [../]
  [./s17]
    type = PointValue
    variable = disp_x
    point = '1.17 0 0'
    outputs = csv_s
  [../]
  [./s18]
    type = PointValue
    variable = disp_x
    point = '1.18 0 0'
    outputs = csv_s
  [../]
  [./s19]
    type = PointValue
    variable = disp_x
    point = '1.19 0 0'
    outputs = csv_s
  [../]
  [./s20]
    type = PointValue
    variable = disp_x
    point = '1.20 0 0'
    outputs = csv_s
  [../]
  [./s21]
    type = PointValue
    variable = disp_x
    point = '1.21 0 0'
    outputs = csv_s
  [../]
  [./s22]
    type = PointValue
    variable = disp_x
    point = '1.22 0 0'
    outputs = csv_s
  [../]
  [./s23]
    type = PointValue
    variable = disp_x
    point = '1.23 0 0'
    outputs = csv_s
  [../]
  [./s24]
    type = PointValue
    variable = disp_x
    point = '1.24 0 0'
    outputs = csv_s
  [../]
  [./s25]
    type = PointValue
    variable = disp_x
    point = '1.25 0 0'
    outputs = csv_s
  [../]

  [./t00]
    type = PointValue
    variable = tot_yy
    point = '1.00 0 0'
    outputs = csv_t
  [../]
  [./t01]
    type = PointValue
    variable = tot_yy
    point = '1.01 0 0'
    outputs = csv_t
  [../]
  [./t02]
    type = PointValue
    variable = tot_yy
    point = '1.02 0 0'
    outputs = csv_t
  [../]
  [./t03]
    type = PointValue
    variable = tot_yy
    point = '1.03 0 0'
    outputs = csv_t
  [../]
  [./t04]
    type = PointValue
    variable = tot_yy
    point = '1.04 0 0'
    outputs = csv_t
  [../]
  [./t05]
    type = PointValue
    variable = tot_yy
    point = '1.05 0 0'
    outputs = csv_t
  [../]
  [./t06]
    type = PointValue
    variable = tot_yy
    point = '1.06 0 0'
    outputs = csv_t
  [../]
  [./t07]
    type = PointValue
    variable = tot_yy
    point = '1.07 0 0'
    outputs = csv_t
  [../]
  [./t08]
    type = PointValue
    variable = tot_yy
    point = '1.08 0 0'
    outputs = csv_t
  [../]
  [./t09]
    type = PointValue
    variable = tot_yy
    point = '1.09 0 0'
    outputs = csv_t
  [../]
  [./t10]
    type = PointValue
    variable = tot_yy
    point = '1.10 0 0'
    outputs = csv_t
  [../]
  [./t11]
    type = PointValue
    variable = tot_yy
    point = '1.11 0 0'
    outputs = csv_t
  [../]
  [./t12]
    type = PointValue
    variable = tot_yy
    point = '1.12 0 0'
    outputs = csv_t
  [../]
  [./t13]
    type = PointValue
    variable = tot_yy
    point = '1.13 0 0'
    outputs = csv_t
  [../]
  [./t14]
    type = PointValue
    variable = tot_yy
    point = '1.14 0 0'
    outputs = csv_t
  [../]
  [./t15]
    type = PointValue
    variable = tot_yy
    point = '1.15 0 0'
    outputs = csv_t
  [../]
  [./t16]
    type = PointValue
    variable = tot_yy
    point = '1.16 0 0'
    outputs = csv_t
  [../]
  [./t17]
    type = PointValue
    variable = tot_yy
    point = '1.17 0 0'
    outputs = csv_t
  [../]
  [./t18]
    type = PointValue
    variable = tot_yy
    point = '1.18 0 0'
    outputs = csv_t
  [../]
  [./t19]
    type = PointValue
    variable = tot_yy
    point = '1.19 0 0'
    outputs = csv_t
  [../]
  [./t20]
    type = PointValue
    variable = tot_yy
    point = '1.20 0 0'
    outputs = csv_t
  [../]
  [./t21]
    type = PointValue
    variable = tot_yy
    point = '1.21 0 0'
    outputs = csv_t
  [../]
  [./t22]
    type = PointValue
    variable = tot_yy
    point = '1.22 0 0'
    outputs = csv_t
  [../]
  [./t23]
    type = PointValue
    variable = tot_yy
    point = '1.23 0 0'
    outputs = csv_t
  [../]
  [./t24]
    type = PointValue
    variable = tot_yy
    point = '1.24 0 0'
    outputs = csv_t
  [../]
  [./t25]
    type = PointValue
    variable = tot_yy
    point = '1.25 0 0'
    outputs = csv_t
  [../]

  [./dt]
    type = FunctionValuePostprocessor
    outputs = console
    function = 2*t
  [../]
[]


[Preconditioning]
  [./andy]
    type = SMP
    full = true
    petsc_options = '-snes_monitor -snes_linesearch_monitor'
    petsc_options_iname = '-ksp_type -pc_type -snes_atol -snes_rtol -snes_max_it -ksp_max_it -sub_pc_type -sub_pc_factor_shift_type'
    petsc_options_value = 'gmres asm 1E0 1E-10 200 500 lu NONZERO'
  [../]
[]

[Executioner]
  type = Transient
  solve_type = Newton
  start_time = 0
  end_time = 0.3
  dt = 0.1
  #[./TimeStepper]
  #  type = PostprocessorDT
  #  postprocessor = dt
  #  dt = 0.003
  #[../]
[]

[Outputs]
  execute_on = 'timestep_end'
  file_base = borehole_highres
  exodus = true
  sync_times = '0.003 0.3'
  [./csv_p]
    file_base = borehole_highres_p
    type = CSV
  [../]
  [./csv_s]
    file_base = borehole_highres_s
    type = CSV
  [../]
  [./csv_t]
    file_base = borehole_highres_t
    type = CSV
  [../]
[]

(modules/contact/test/tests/mortar_dynamics/block-dynamics-friction.i)

starting_point = 2e-1
offset = -0.19

[GlobalParams]
  displacements = 'disp_x disp_y'
[]

[Mesh]
  file = long-bottom-block-1elem-blocks.e
  allow_renumbering = false
[]

[Variables]
  [disp_x]
    block = '1 2'
  []
  [disp_y]
    block = '1 2'
  []
  [mechanical_normal_lm]
    block = 3
    use_dual = true
  []
  [mechanical_tangential_lm]
    block = 3
    use_dual = true
  []
[]

[ICs]
  [disp_y]
    block = 2
    variable = disp_y
    value = '${fparse starting_point + offset}'
    type = ConstantIC
  []
[]

[Kernels]
  [DynamicTensorMechanics]
    displacements = 'disp_x disp_y'
    generate_output = 'stress_xx stress_yy'
    strain = FINITE
    block = '1 2'
    stiffness_damping_coefficient = 0.05
    hht_alpha = 0.0
  []
  [inertia_x]
    type = InertialForce
    variable = disp_x
    velocity = vel_x
    acceleration = accel_x
    beta = 0.25
    gamma = 0.5
    alpha = 0
    eta = 0.0
    block = '1 2'
  []
  [inertia_y]
    type = InertialForce
    variable = disp_y
    velocity = vel_y
    acceleration = accel_y
    beta = 0.25
    gamma = 0.5
    alpha = 0
    eta = 0.0
    block = '1 2'
  []
[]

[Materials]
  [elasticity_2]
    type = ComputeIsotropicElasticityTensor
    block = '2'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  []
  [elasticity_1]
    type = ComputeIsotropicElasticityTensor
    block = '1'
    youngs_modulus = 1e8
    poissons_ratio = 0.3
  []
  [stress]
    type = ComputeFiniteStrainElasticStress
    block = '1 2'
  []
  [strain]
    type = ComputeFiniteStrain
    block = '1 2'
  []
  [density]
    type = GenericConstantMaterial
    block = '1 2'
    prop_names = 'density'
    prop_values = '7750'
  []
[]

[AuxVariables]
  [vel_x]
    block = '1 2'
  []
  [accel_x]
    block = '1 2'
  []
  [vel_y]
    block = '1 2'
  []
  [accel_y]
    block = '1 2'
  []
  [vel_z]
    block = '1 2'
  []
  [accel_z]
    block = '1 2'
  []
  [gap]
    block = 3
  []
[]

[AuxKernels]
  [gap]
    type = WeightedGapAux
    variable = gap
    primary_boundary = 20
    secondary_boundary = 10
    primary_subdomain = 4
    secondary_subdomain = 3
    use_displaced_mesh = true
  []
  [accel_x]
    type = NewmarkAccelAux
    variable = accel_x
    displacement = disp_x
    velocity = vel_x
    beta = 0.25
    execute_on = 'LINEAR timestep_end'
  []
  [vel_x]
    type = NewmarkVelAux
    variable = vel_x
    acceleration = accel_x
    gamma = 0.5
    execute_on = 'LINEAR timestep_end'
  []
  [accel_y]
    type = NewmarkAccelAux
    variable = accel_y
    displacement = disp_y
    velocity = vel_y
    beta = 0.25
    execute_on = 'LINEAR timestep_end'
  []
  [vel_y]
    type = NewmarkVelAux
    variable = vel_y
    acceleration = accel_y
    gamma = 0.5
    execute_on = 'LINEAR timestep_end'
  []
[]



# User object provides the contact force (e.g. LM)
# for the application of the generalized force
[UserObjects]
  [weighted_vel_uo]
    type = LMWeightedVelocitiesUserObject
    primary_boundary = 20
    secondary_boundary = 10
    primary_subdomain = 4
    secondary_subdomain = 3
    lm_variable_normal = mechanical_normal_lm
    lm_variable_tangential_one = mechanical_tangential_lm
    secondary_variable = disp_x
    disp_x = disp_x
    disp_y = disp_y
  []
[]

[Constraints]
  [weighted_gap_lm]
    type = ComputeDynamicFrictionalForceLMMechanicalContact
    primary_boundary = 20
    secondary_boundary = 10
    primary_subdomain = 4
    secondary_subdomain = 3
    variable = mechanical_normal_lm
    friction_lm = mechanical_tangential_lm
    disp_x = disp_x
    disp_y = disp_y
    use_displaced_mesh = true
    c = 1e4
    c_t = 1e4
    mu = 0.5
    newmark_beta = 0.25
    newmark_gamma = 0.5
    capture_tolerance = 1.0e-5
  []
  [normal_x]
    type = NormalMortarMechanicalContact
    primary_boundary = 20
    secondary_boundary = 10
    primary_subdomain = 4
    secondary_subdomain = 3
    variable = mechanical_normal_lm
    secondary_variable = disp_x
    component = x
    use_displaced_mesh = true
    compute_lm_residuals = false
    weighted_gap_uo = weighted_vel_uo
  []
  [normal_y]
    type = NormalMortarMechanicalContact
    primary_boundary = 20
    secondary_boundary = 10
    primary_subdomain = 4
    secondary_subdomain = 3
    variable = mechanical_normal_lm
    secondary_variable = disp_y
    component = y
    use_displaced_mesh = true
    compute_lm_residuals = false
    weighted_gap_uo = weighted_vel_uo
  []
  [tangential_x]
    type = TangentialMortarMechanicalContact
    primary_boundary = 20
    secondary_boundary = 10
    primary_subdomain = 4
    secondary_subdomain = 3
    variable = mechanical_tangential_lm
    secondary_variable = disp_x
    component = x
    use_displaced_mesh = true
    compute_lm_residuals = false
    weighted_velocities_uo = weighted_vel_uo
  []
  [tangential_y]
    type = TangentialMortarMechanicalContact
    primary_boundary = 20
    secondary_boundary = 10
    primary_subdomain = 4
    secondary_subdomain = 3
    variable = mechanical_tangential_lm
    secondary_variable = disp_y
    component = y
    use_displaced_mesh = true
    compute_lm_residuals = false
    weighted_velocities_uo = weighted_vel_uo
  []
[]

[BCs]
  [botx]
    type = DirichletBC
    variable = disp_x
    boundary = 40
    value = 0.0
  []
  [boty]
    type = DirichletBC
    variable = disp_y
    boundary = 40
    value = 0.0
  []
  [topy]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = 30
    function = '${starting_point} * cos(2 * pi / 4 * t) + ${offset}'
  []
  [leftx]
    type = FunctionDirichletBC
    variable = disp_x
    boundary = 30 # 50
    function = '0' # '1e-2*t'
  []
[]

[Executioner]
  type = Transient
  end_time = 75
  dt = 0.05
  dtmin = .005
  solve_type = 'PJFNK'
  petsc_options = '-snes_converged_reason -ksp_converged_reason -pc_svd_monitor '
                  '-snes_linesearch_monitor -snes_ksp_ew'
  petsc_options_iname = '-pc_type -pc_factor_shift_type -pc_factor_shift_amount -mat_mffd_err '
  petsc_options_value = 'lu       NONZERO               1e-15                   1e-5'
  nl_max_its = 50
  line_search = 'none'
  snesmf_reuse_base = false

  [TimeIntegrator]
    type = NewmarkBeta
    beta = 0.25
    gamma = 0.5
  []
[]

[Debug]
  show_var_residual_norms = true
[]

[Outputs]
  exodus = true
  csv = true
  checkpoint = true
[]

[Preconditioning]
  [smp]
    type = SMP
    full = true
  []
[]

[VectorPostprocessors]
  [mechanical_tangential_lm]
    type = NodalValueSampler
    block = '3'
    variable = mechanical_tangential_lm
    sort_by = 'x'
    execute_on = TIMESTEP_END
  []
[]

(modules/solid_mechanics/test/tests/multi/two_surface05.i)

# Plasticit models:
# SimpleTester with a = 0 and b = 1 and strength = 1
# SimpleTester with a = 1 and b = 1 and strength = 2
#
# Lame lambda = 0 (Poisson=0).  Lame mu = 0.5E6
#
# A single element is stretched by 3E-6m in y directions and 1.0E-6 in z direction.
# trial stress_zz = 1 and stress_yy = 3
#
# Then SimpleTester2 should activate and the algorithm will return to
# stress_zz = 0, stress_yy = 2
# internal0 should be zero, and internal1 should be 1

[Mesh]
  type = GeneratedMesh
  dim = 3
  nx = 1
  ny = 1
  nz = 1
  xmin = -0.5
  xmax = 0.5
  ymin = -0.5
  ymax = 0.5
  zmin = -0.5
  zmax = 0.5
[]


[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./disp_z]
  [../]
[]

[Kernels]
  [SolidMechanics]
    displacements = 'disp_x disp_y disp_z'
  [../]
[]


[BCs]
  [./x]
    type = FunctionDirichletBC
    variable = disp_x
    boundary = 'front back'
    function = '0E-6*x'
  [../]
  [./y]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = 'front back'
    function = '3E-6*y'
  [../]
  [./z]
    type = FunctionDirichletBC
    variable = disp_z
    boundary = 'front back'
    function = '1E-6*z'
  [../]
[]

[AuxVariables]
  [./stress_xx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_zz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./f0]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./f1]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./int0]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./int1]
    order = CONSTANT
    family = MONOMIAL
  [../]
[]

[AuxKernels]
  [./stress_xx]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xx
    index_i = 0
    index_j = 0
  [../]
  [./stress_xy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xy
    index_i = 0
    index_j = 1
  [../]
  [./stress_xz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xz
    index_i = 0
    index_j = 2
  [../]
  [./stress_yy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yy
    index_i = 1
    index_j = 1
  [../]
  [./stress_yz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yz
    index_i = 1
    index_j = 2
  [../]
  [./stress_zz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_zz
    index_i = 2
    index_j = 2
  [../]
  [./f0]
    type = MaterialStdVectorAux
    property = plastic_yield_function
    index = 0
    variable = f0
  [../]
  [./f1]
    type = MaterialStdVectorAux
    property = plastic_yield_function
    index = 1
    variable = f1
  [../]
  [./int0]
    type = MaterialStdVectorAux
    property = plastic_internal_parameter
    factor = 1E6
    index = 0
    variable = int0
  [../]
  [./int1]
    type = MaterialStdVectorAux
    property = plastic_internal_parameter
    factor = 1E6
    index = 1
    variable = int1
  [../]
[]

[Postprocessors]
  [./s_xx]
    type = PointValue
    point = '0 0 0'
    variable = stress_xx
  [../]
  [./s_xy]
    type = PointValue
    point = '0 0 0'
    variable = stress_xy
  [../]
  [./s_xz]
    type = PointValue
    point = '0 0 0'
    variable = stress_xz
  [../]
  [./s_yy]
    type = PointValue
    point = '0 0 0'
    variable = stress_yy
  [../]
  [./s_yz]
    type = PointValue
    point = '0 0 0'
    variable = stress_yz
  [../]
  [./s_zz]
    type = PointValue
    point = '0 0 0'
    variable = stress_zz
  [../]
  [./f0]
    type = PointValue
    point = '0 0 0'
    variable = f0
  [../]
  [./f1]
    type = PointValue
    point = '0 0 0'
    variable = f1
  [../]
  [./int0]
    type = PointValue
    point = '0 0 0'
    variable = int0
  [../]
  [./int1]
    type = PointValue
    point = '0 0 0'
    variable = int1
  [../]
[]

[UserObjects]
  [./simple1]
    type = SolidMechanicsPlasticSimpleTester
    a = 0
    b = 1
    strength = 1
    yield_function_tolerance = 1.0E-9
    internal_constraint_tolerance = 1.0E-9
  [../]
  [./simple2]
    type = SolidMechanicsPlasticSimpleTester
    a = 1
    b = 1
    strength = 2
    yield_function_tolerance = 1.0E-9
    internal_constraint_tolerance = 1.0E-9
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeElasticityTensor
    block = 0
    fill_method = symmetric_isotropic
    C_ijkl = '0 0.5E6'
  [../]
  [./strain]
    type = ComputeFiniteStrain
    block = 0
    displacements = 'disp_x disp_y disp_z'
  [../]
  [./multi]
    type = ComputeMultiPlasticityStress
    block = 0
    ep_plastic_tolerance = 1E-9
    plastic_models = 'simple1 simple2'
    max_NR_iterations = 2
    min_stepsize = 1
    debug_fspb = crash
    debug_jac_at_stress = '10 0 0 0 10 0 0 0 10'
    debug_jac_at_pm = '1 1'
    debug_jac_at_intnl = '1 1'
    debug_stress_change = 1E-5
    debug_pm_change = '1E-6 1E-6'
    debug_intnl_change = '1E-6 1E-6'
  [../]
[]


[Executioner]
  end_time = 1
  dt = 1
  type = Transient
[]


[Outputs]
  file_base = two_surface05
  exodus = false
  [./csv]
    type = CSV
    [../]
[]

(modules/contact/test/tests/verification/patch_tests/mindlin/cylinder_friction_node_face.i)

[GlobalParams]
  volumetric_locking_correction = true
  displacements = 'disp_x disp_y'
[]

[Mesh]
  [input_file]
    type = FileMeshGenerator
    file = hertz_cyl_coarser.e
  []
[]

[Problem]
  type = ReferenceResidualProblem
  extra_tag_vectors = 'ref'
  reference_vector = 'ref'
[]

[Variables]
  [disp_x]
  []
  [disp_y]
  []
[]

[AuxVariables]
  [stress_xx]
    order = CONSTANT
    family = MONOMIAL
  []
  [stress_yy]
    order = CONSTANT
    family = MONOMIAL
  []
  [stress_xy]
    order = CONSTANT
    family = MONOMIAL
  []
  [react_x]
  []
  [react_y]
  []
  [penetration]
  []
  [inc_slip_x]
  []
  [inc_slip_y]
  []
  [accum_slip_x]
  []
  [accum_slip_y]
  []
[]

[Functions]
  [disp_ramp_vert]
    type = PiecewiseLinear
    x = '0. 1. 3.5'
    y = '0. -0.020 -0.020'
  []
  [disp_ramp_horz]
    type = PiecewiseLinear
    x = '0. 1. 3.5'
    y = '0. 0.0 0.015'
  []
[]

[Kernels]
  [TensorMechanics]
    use_displaced_mesh = true
    extra_vector_tags = 'ref'
    block = '1 2 3 4 5 6 7'
  []
[]

[AuxKernels]
  [stress_xx]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xx
    index_i = 0
    index_j = 0
    execute_on = timestep_end
    block = '1 2 3 4 5 6 7'
  []
  [stress_yy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yy
    index_i = 1
    index_j = 1
    execute_on = timestep_end
    block = '1 2 3 4 5 6 7'
  []
  [stress_xy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xy
    index_i = 0
    index_j = 1
    execute_on = timestep_end
    block = '1 2 3 4 5 6 7'
  []
  [incslip_x]
    type = PenetrationAux
    variable = inc_slip_x
    quantity = incremental_slip_x
    boundary = 3
    paired_boundary = 2
  []
  [incslip_y]
    type = PenetrationAux
    variable = inc_slip_y
    quantity = incremental_slip_y
    boundary = 3
    paired_boundary = 2
  []
  [accum_slip_x]
    type = AccumulateAux
    variable = accum_slip_x
    accumulate_from_variable = inc_slip_x
    execute_on = timestep_end
  []
  [accum_slip_y]
    type = AccumulateAux
    variable = accum_slip_y
    accumulate_from_variable = inc_slip_y
    execute_on = timestep_end
  []
  [penetration]
    type = PenetrationAux
    variable = penetration
    boundary = 3
    paired_boundary = 2
  []
  [react_x]
    type = TagVectorAux
    vector_tag = 'ref'
    v = 'disp_x'
    variable = 'react_x'
  []
  [react_y]
    type = TagVectorAux
    vector_tag = 'ref'
    v = 'disp_y'
    variable = 'react_y'
  []
[]

[Postprocessors]
  [bot_react_x]
    type = NodalSum
    variable = react_x
    boundary = 1
  []
  [bot_react_y]
    type = NodalSum
    variable = react_y
    boundary = 1
  []
  [top_react_x]
    type = NodalSum
    variable = react_x
    boundary = 4
  []
  [top_react_y]
    type = NodalSum
    variable = react_y
    boundary = 4
  []
  [penetration]
    type = NodalExtremeValue
    variable = penetration
    value_type = max
    boundary = 3
  []
  [inc_slip_x_max]
    type = NodalExtremeValue
    variable = inc_slip_x
    value_type = max
    boundary = 3
  []
  [inc_slip_x_min]
    type = NodalExtremeValue
    variable = inc_slip_x
    value_type = min
    boundary = 3
  []
  [inc_slip_y_max]
    type = NodalExtremeValue
    variable = inc_slip_y
    value_type = max
    boundary = 3
  []
  [inc_slip_y_min]
    type = NodalExtremeValue
    variable = inc_slip_y
    value_type = min
    boundary = 3
  []
  [accum_slip_x]
    type = NodalExtremeValue
    variable = accum_slip_x
    value_type = max
    boundary = 3
  []
  [accum_slip_y]
    type = NodalExtremeValue
    variable = accum_slip_y
    value_type = max
    boundary = 3
  []
  [_dt]
    type = TimestepSize
  []
[]

[BCs]
  [side_x]
    type = DirichletBC
    variable = disp_y
    boundary = '1 2'
    value = 0.0
  []
  [bot_y]
    type = DirichletBC
    variable = disp_x
    boundary = '1 2'
    value = 0.0
  []
  [top_y_disp]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = 4
    function = disp_ramp_vert
  []
  [top_x_disp]
    type = FunctionDirichletBC
    variable = disp_x
    boundary = 4
    function = disp_ramp_horz
  []
[]

[Materials]
  [stuff1_elas_tens]
    type = ComputeIsotropicElasticityTensor
    block = '1'
    youngs_modulus = 1e10
    poissons_ratio = 0.0
  []
  [stuff1_strain]
    type = ComputeFiniteStrain
    block = '1'
  []
  [stuff1_stress]
    type = ComputeFiniteStrainElasticStress
    block = '1'
  []
  [stuff2_elas_tens]
    type = ComputeIsotropicElasticityTensor
    block = '2 3 4 5 6 7'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  []
  [stuff2_strain]
    type = ComputeFiniteStrain
    block = '2 3 4 5 6 7'
  []
  [stuff2_stress]
    type = ComputeFiniteStrainElasticStress
    block = '2 3 4 5 6 7'
  []
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'

  petsc_options = '-snes_ksp_ew'
  petsc_options_iname = '-pc_type -pc_factor_mat_solver_type -pc_factor_shift_type '
                        '-pc_factor_shift_amount -mat_mffd_err'
  petsc_options_value = 'lu       superlu_dist                  NONZERO               1e-15          '
                        '         1e-5'

  line_search = 'none'

  nl_abs_tol = 1e-8
  start_time = 0.0
  end_time = 0.3
  l_tol = 1e-4
  dt = 0.1
  dtmin = 0.1
[]

[Preconditioning]
  [SMP]
    type = SMP
    full = true
  []
[]

[VectorPostprocessors]
  [x_disp]
    type = NodalValueSampler
    variable = disp_x
    boundary = '3 4'
    sort_by = id
  []
  [y_disp]
    type = NodalValueSampler
    variable = disp_y
    boundary = '3 4'
    sort_by = id
  []
[]

[Outputs]
  print_linear_residuals = true
  perf_graph = true
  exodus = true
  csv = true
  [console]
    type = Console
    max_rows = 5
  []
  [chkfile]
    type = CSV
    show = 'x_disp y_disp'
    file_base = cylinder_friction_check
    create_final_symlink = true
    execute_on = 'FINAL'
  []
[]

[Contact]
  [leftright]
    primary = 2
    secondary = 3
    model = coulomb
    formulation = penalty
    penalty = 5e9
    normalize_penalty = true
    friction_coefficient = '0.2'
  []
[]

(modules/solid_mechanics/test/tests/volumetric_deform_grad/volumetric_strain_interface.i)

#This test has volumetric deformation gradient as identity
#Test the interface
#Results should match with elasticity
[Mesh]
  type = GeneratedMesh
  dim = 3
  elem_type = HEX8
  displacements = 'disp_x disp_y disp_z'
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./disp_z]
  [../]
[]

[Kernels]
  [SolidMechanics]
    displacements = 'disp_x disp_y disp_z'
    use_displaced_mesh = true
  [../]
[]

[AuxVariables]
  [./stress_zz]
    order = CONSTANT
    family = MONOMIAL
    block = 0
  [../]
[]

[AuxKernels]
  [./stress_zz]
    type = RankTwoAux
    variable = stress_zz
    rank_two_tensor = stress
    index_j = 2
    index_i = 2
    execute_on = timestep_end
    block = 0
  [../]
[]

[BCs]
  [./symmy]
    type = DirichletBC
    variable = disp_y
    boundary = bottom
    value = 0
  [../]
  [./symmx]
    type = DirichletBC
    variable = disp_x
    boundary = left
    value = 0
  [../]
  [./symmz]
    type = DirichletBC
    variable = disp_z
    boundary = back
    value = 0
  [../]
  [./tdisp]
    type = FunctionDirichletBC
    variable = disp_z
    boundary = front
    function = '0.01*t'
  [../]
[]

[Materials]
  [./strain]
    type = ComputeFiniteStrain
    block = 0
    displacements = 'disp_x disp_y disp_z'
  [../]
  [./volumetric_strain]
    type = ComputeVolumetricDeformGrad
    pre_deform_grad_name = deformation_gradient
    volumetric_deform_grad_name = volumetric_deformation_gradient
    post_deform_grad_name = elastic_deformation_gradient
    block = 0
  [../]
  [./elastic_stress]
    type = ComputeDeformGradBasedStress
    deform_grad_name = elastic_deformation_gradient
    elasticity_tensor_name = elasticity_tensor
    stress_name = elastic_stress
    jacobian_name = elastic_jacobian
    block = 0
  [../]
  [./corrected_stress]
    type = VolumeDeformGradCorrectedStress
    pre_stress_name = elastic_stress
    deform_grad_name = volumetric_deformation_gradient
    pre_jacobian_name = elastic_jacobian
    stress_name = stress
    jacobian_name = Jacobian_mult
    block = 0
  [../]
  [./elasticity_tensor]
    type = ComputeElasticityTensor
    block = 0
    C_ijkl = '2.8e5 1.2e5 1.2e5 2.8e5 1.2e5 2.8e5 0.8e5 0.8e5 0.8e5'
    fill_method = symmetric9
  [../]
[]

[Postprocessors]
  [./stress_zz]
    type = ElementAverageValue
    variable = stress_zz
    block = 'ANY_BLOCK_ID 0'
  [../]
[]

[Preconditioning]
  [./smp]
    type = SMP
    full = true
  [../]
[]

[Executioner]
  type = Transient
  dt = 0.02
  #Preconditioned JFNK (default)
  solve_type = 'PJFNK'
  petsc_options_iname = '-pc_type -pc_hypre_type -ksp_gmres_restart'
  petsc_options_value = 'hypre boomeramg 101'
  dtmax = 10.0
  nl_rel_tol = 1e-10
  dtmin = 0.02
  num_steps = 10
[]

[Outputs]
  csv = true
[]

(modules/solid_mechanics/test/tests/mohr_coulomb/small_deform5.i)

# apply repeated stretches in x z directions, and smaller stretches along the y direction,
# so that sigma_I = sigma_II,
# which means that lode angle = 30deg.
# The allows yield surface in meridional plane to be mapped out
# Use 'cap' smoothing


[Mesh]
  type = GeneratedMesh
  dim = 3
  nx = 1
  ny = 1
  nz = 1
  xmin = -0.5
  xmax = 0.5
  ymin = -0.5
  ymax = 0.5
  zmin = -0.5
  zmax = 0.5
[]


[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./disp_z]
  [../]
[]

[Kernels]
  [SolidMechanics]
    displacements = 'disp_x disp_y disp_z'
  [../]
[]


[BCs]
  [./x]
    type = FunctionDirichletBC
    variable = disp_x
    boundary = 'front back'
    function = '1E-6*x*t'
  [../]
  [./y]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = 'front back'
    function = '0.9E-6*y*sin(t)'
  [../]
  [./z]
    type = FunctionDirichletBC
    variable = disp_z
    boundary = 'front back'
    function = '1E-6*z*t'
  [../]
[]

[AuxVariables]
  [./stress_xx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_zz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./mc_int]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./yield_fcn]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./iter]
    order = CONSTANT
    family = MONOMIAL
  [../]
[]

[AuxKernels]
  [./stress_xx]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xx
    index_i = 0
    index_j = 0
  [../]
  [./stress_xy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xy
    index_i = 0
    index_j = 1
  [../]
  [./stress_xz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xz
    index_i = 0
    index_j = 2
  [../]
  [./stress_yy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yy
    index_i = 1
    index_j = 1
  [../]
  [./stress_yz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yz
    index_i = 1
    index_j = 2
  [../]
  [./stress_zz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_zz
    index_i = 2
    index_j = 2
  [../]
  [./mc_int_auxk]
    type = MaterialStdVectorAux
    index = 0
    property = plastic_internal_parameter
    variable = mc_int
  [../]
  [./yield_fcn_auxk]
    type = MaterialStdVectorAux
    index = 0
    property = plastic_yield_function
    variable = yield_fcn
  [../]
  [./iter_auxk]
    type = MaterialRealAux
    property = plastic_NR_iterations
    variable = iter
  [../]
[]

[Postprocessors]
  [./s_xx]
    type = PointValue
    point = '0 0 0'
    variable = stress_xx
  [../]
  [./s_xy]
    type = PointValue
    point = '0 0 0'
    variable = stress_xy
  [../]
  [./s_xz]
    type = PointValue
    point = '0 0 0'
    variable = stress_xz
  [../]
  [./s_yy]
    type = PointValue
    point = '0 0 0'
    variable = stress_yy
  [../]
  [./s_yz]
    type = PointValue
    point = '0 0 0'
    variable = stress_yz
  [../]
  [./s_zz]
    type = PointValue
    point = '0 0 0'
    variable = stress_zz
  [../]
  [./internal]
    type = PointValue
    point = '0 0 0'
    variable = mc_int
  [../]
  [./f]
    type = PointValue
    point = '0 0 0'
    variable = yield_fcn
  [../]
  [./iter]
    type = PointValue
    point = '0 0 0'
    variable = iter
  [../]
[]

[UserObjects]
  [./mc_coh]
    type = SolidMechanicsHardeningConstant
    value = 10
  [../]
  [./mc_phi]
    type = SolidMechanicsHardeningConstant
    value = 50
    convert_to_radians = true
  [../]
  [./mc_psi]
    type = SolidMechanicsHardeningExponential
    value_0 = 0
    value_residual = 0.8726646 # 50deg
    rate = 3000.0
  [../]
  [./mc]
    type = SolidMechanicsPlasticMohrCoulomb
    cohesion = mc_coh
    friction_angle = mc_phi
    dilation_angle = mc_psi
    tip_scheme = cap
    mc_tip_smoother = 0
    cap_start = 3
    cap_rate = 0.8
    mc_edge_smoother = 20
    yield_function_tolerance = 1E-8
    internal_constraint_tolerance = 1E-9
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeElasticityTensor
    block = 0
    fill_method = symmetric_isotropic
    C_ijkl = '0 1E7'
  [../]
  [./strain]
    type = ComputeFiniteStrain
    block = 0
    displacements = 'disp_x disp_y disp_z'
  [../]
  [./mc]
    type = ComputeMultiPlasticityStress
    block = 0
    ep_plastic_tolerance = 1E-9
    plastic_models = mc
    debug_fspb = crash
  [../]
[]


[Executioner]
  end_time = 150
  dt = 5
  type = Transient
[]


[Outputs]
  file_base = small_deform5
  exodus = false
  [./csv]
    type = CSV
    [../]
[]

(modules/contact/test/tests/verification/patch_tests/brick_2/brick2_aug.i)

[GlobalParams]
  volumetric_locking_correction = true
  displacements = 'disp_x disp_y disp_z'
[]

[Mesh]
  file = brick2_mesh.e
[]

[Problem]
  type = AugmentedLagrangianContactProblem
  extra_tag_vectors = 'ref'
  reference_vector = 'ref'
  maximum_lagrangian_update_iterations = 100
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./disp_z]
  [../]
[]

[AuxVariables]
  [./stress_xx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_zz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./penetration]
  [../]
  [./saved_x]
  [../]
  [./saved_y]
  [../]
  [./saved_z]
  [../]
  [./diag_saved_x]
  [../]
  [./diag_saved_y]
  [../]
  [./diag_saved_z]
  [../]
  [./inc_slip_x]
  [../]
  [./inc_slip_y]
  [../]
  [./inc_slip_z]
  [../]
  [./accum_slip_x]
  [../]
  [./accum_slip_y]
  [../]
  [./accum_slip_z]
  [../]
[]

[Kernels]
  [./TensorMechanics]
    use_displaced_mesh = true
    save_in = 'saved_x saved_y saved_z'
    extra_vector_tags = 'ref'
  [../]
[]

[AuxKernels]
  [./stress_xx]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xx
    index_i = 0
    index_j = 0
    execute_on = timestep_end
  [../]
  [./stress_yy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yy
    index_i = 1
    index_j = 1
    execute_on = timestep_end
  [../]
  [./stress_xy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xy
    index_i = 0
    index_j = 1
    execute_on = timestep_end
  [../]
  [./stress_zz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_zz
    index_i = 2
    index_j = 2
    execute_on = timestep_end
  [../]
  [./inc_slip_x]
    type = PenetrationAux
    variable = inc_slip_x
    execute_on = timestep_begin
    boundary = 4
    paired_boundary = 3
  [../]
  [./inc_slip_y]
    type = PenetrationAux
    variable = inc_slip_y
    execute_on = timestep_begin
    boundary = 4
    paired_boundary = 3
  [../]
  [./accum_slip_x]
    type = PenetrationAux
    variable = accum_slip_x
    execute_on = timestep_end
    boundary = 4
    paired_boundary = 3
  [../]
  [./accum_slip_y]
    type = PenetrationAux
    variable = accum_slip_y
    execute_on = timestep_end
    boundary = 4
    paired_boundary = 3
  [../]
  [./penetration]
    type = PenetrationAux
    variable = penetration
    boundary = 4
    paired_boundary = 3
  [../]
[]

[Postprocessors]
  [./bot_react_x]
    type = NodalSum
    variable = saved_x
    boundary = 1
  [../]
  [./bot_react_y]
    type = NodalSum
    variable = saved_y
    boundary = 1
  [../]
  [./top_react_x]
    type = NodalSum
    variable = saved_x
    boundary = 5
  [../]
  [./top_react_y]
    type = NodalSum
    variable = saved_y
    boundary = 5
  [../]
  [./ref_resid_x]
    type = NodalL2Norm
    execute_on = timestep_end
    variable = saved_x
  [../]
  [./ref_resid_y]
    type = NodalL2Norm
    execute_on = timestep_end
    variable = saved_y
  [../]
  [./sigma_yy]
    type = ElementAverageValue
    variable = stress_yy
  [../]
  [./sigma_zz]
    type = ElementAverageValue
    variable = stress_zz
  [../]
  [./disp_x7]
    type = NodalVariableValue
    nodeid = 6
    variable = disp_x
  [../]
  [./disp_x26]
    type = NodalVariableValue
    nodeid = 25
    variable = disp_x
  [../]
  [./disp_y7]
    type = NodalVariableValue
    nodeid = 6
    variable = disp_y
  [../]
  [./disp_y26]
    type = NodalVariableValue
    nodeid = 25
    variable = disp_y
  [../]
  [./_dt]
    type = TimestepSize
  [../]
  [./num_lin_it]
    type = NumLinearIterations
  [../]
  [./num_nonlin_it]
    type = NumNonlinearIterations
  [../]
[]

[BCs]
  [./bot_y]
    type = DirichletBC
    variable = disp_y
    boundary = 1
    value = 0.0
  [../]
  [./side_x]
    type = DirichletBC
    variable = disp_x
    boundary = 2
    value = 0.0
  [../]
  [./back_z]
    type = DirichletBC
    variable = disp_z
    boundary = 6
    value = 0.0
  [../]
  [./top_press]
    type = Pressure
    variable = disp_y
    boundary = 5
    factor = 109.89
  [../]
[]

[Materials]
  [./bot_elas_tens]
    type = ComputeIsotropicElasticityTensor
    block = '1'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./bot_strain]
    type = ComputeFiniteStrain
    block = '1'
  [../]
  [./bot_stress]
    type = ComputeFiniteStrainElasticStress
    block = '1'
  [../]
  [./top_elas_tens]
    type = ComputeIsotropicElasticityTensor
    block = '2'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./top_strain]
    type = ComputeFiniteStrain
    block = '2'
  [../]
  [./top_stress]
    type = ComputeFiniteStrainElasticStress
    block = '2'
  [../]
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'

  petsc_options_iname = '-pc_type -pc_factor_mat_solver_type'
  petsc_options_value = 'lu     superlu_dist'

  line_search = 'none'

  nl_abs_tol = 1e-9
  nl_rel_tol = 1e-8
  l_max_its = 50
  nl_max_its = 100
  dt = 1.0
  end_time = 1.0
  num_steps = 10
  dtmin = 1.0
  l_tol = 1e-5

[]

[VectorPostprocessors]
  [./x_disp]
    type = NodalValueSampler
    variable = disp_x
    boundary = '1 3 4 5'
    sort_by = id
  [../]
  [./y_disp]
    type = NodalValueSampler
    variable = disp_y
    boundary = '1 3 4 5'
    sort_by = id
  [../]
  [./cont_press]
    type = NodalValueSampler
    variable = contact_pressure
    boundary = '3'
    sort_by = id
  [../]
[]

[Outputs]
  print_linear_residuals = true
  perf_graph = true
  [./exodus]
    type = Exodus
    elemental_as_nodal = true
  [../]
  [./console]
    type = Console
    max_rows = 5
  [../]
  [./chkfile]
    type = CSV
    show = 'bot_react_x bot_react_y disp_x7 disp_y7 disp_x26 disp_y26 stress_yy stress_zz top_react_x top_react_y x_disp y_disp cont_press'
    execute_vector_postprocessors_on = timestep_end
  [../]
  [./outfile]
    type = CSV
    delimiter = ' '
    execute_vector_postprocessors_on = none
  [../]
[]

[Contact]
  [./leftright]
    secondary = 3
    primary = 4
    tangential_tolerance = 1e-3
    formulation = augmented_lagrange
    normalize_penalty = true
    penalty = 1e8
    model = frictionless
    al_penetration_tolerance = 1e-8
  [../]
[]

(modules/solid_mechanics/test/tests/crystal_plasticity/user_object_based/substep.i)

[Mesh]
  type = GeneratedMesh
  dim = 3
  elem_type = HEX8
  displacements = 'ux uy uz'
[]

[Variables]
  [./ux]
    block = 0
  [../]
  [./uy]
    block = 0
  [../]
  [./uz]
    block = 0
  [../]
[]

[AuxVariables]
  [./stress_zz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./fp_zz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./e_zz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./gss]
    order = CONSTANT
    family = MONOMIAL
  [../]
[]

[Functions]
  [./tdisp]
    type = ParsedFunction
    expression = 0.01*t
  [../]
[]

[Kernels]
  [SolidMechanics]
    displacements = 'ux uy uz'
    use_displaced_mesh = true
  [../]
[]

[AuxKernels]
  [./stress_zz]
    type = RankTwoAux
    variable = stress_zz
    rank_two_tensor = stress
    index_j = 2
    index_i = 2
    execute_on = timestep_end
  [../]
  [./fp_zz]
    type = RankTwoAux
    variable = fp_zz
    rank_two_tensor = fp
    index_j = 2
    index_i = 2
    execute_on = timestep_end
  [../]
  [./e_zz]
    type = RankTwoAux
    variable = e_zz
    rank_two_tensor = lage
    index_j = 2
    index_i = 2
    execute_on = timestep_end
  [../]
  [./gss]
    type = MaterialStdVectorAux
    variable = gss
    property = state_var_gss
    index = 0
    execute_on = timestep_end
  [../]
[]

[BCs]
  [./symmy]
    type = DirichletBC
    variable = uy
    boundary = bottom
    value = 0
  [../]
  [./symmx]
    type = DirichletBC
    variable = ux
    boundary = left
    value = 0
  [../]
  [./symmz]
    type = DirichletBC
    variable = uz
    boundary = back
    value = 0
  [../]
  [./tdisp]
    type = FunctionDirichletBC
    variable = uz
    boundary = front
    function = tdisp
  [../]
[]

[UserObjects]
  [./slip_rate_gss]
    type = CrystalPlasticitySlipRateGSS
    variable_size = 12
    slip_sys_file_name = input_slip_sys.txt
    num_slip_sys_flowrate_props = 2
    flowprops = '1 4 0.001 0.1 5 8 0.001 0.1 9 12 0.001 0.1'
    uo_state_var_name = state_var_gss
  [../]
  [./slip_resistance_gss]
    type = CrystalPlasticitySlipResistanceGSS
    variable_size = 12
    uo_state_var_name = state_var_gss
  [../]
  [./state_var_gss]
    type = CrystalPlasticityStateVariable
    variable_size = 12
    groups = '0 4 8 12'
    group_values = '60.8 60.8 60.8'
    uo_state_var_evol_rate_comp_name = state_var_evol_rate_comp_gss
    scale_factor = 1.0
  [../]
  [./state_var_evol_rate_comp_gss]
    type = CrystalPlasticityStateVarRateComponentGSS
    variable_size = 12
    hprops = '1.0 541.5 109.8 2.5'
    uo_slip_rate_name = slip_rate_gss
    uo_state_var_name = state_var_gss
  [../]
[]

[Materials]
  [./crysp]
    type = FiniteStrainUObasedCP
    block = 0
    stol = 1e-2
    tan_mod_type = exact
    maximum_substep_iteration = 10
    uo_slip_rates = 'slip_rate_gss'
    uo_slip_resistances = 'slip_resistance_gss'
    uo_state_vars = 'state_var_gss'
    uo_state_var_evol_rate_comps = 'state_var_evol_rate_comp_gss'
  [../]
  [./strain]
    type = ComputeFiniteStrain
    block = 0
    displacements = 'ux uy uz'
  [../]
  [./elasticity_tensor]
    type = ComputeElasticityTensorCP
    block = 0
    C_ijkl = '1.684e5 1.214e5 1.214e5 1.684e5 1.214e5 1.684e5 0.754e5 0.754e5 0.754e5'
    fill_method = symmetric9
  [../]

[]

[Postprocessors]
  [./stress_zz]
    type = ElementAverageValue
    variable = stress_zz
    block = 'ANY_BLOCK_ID 0'
  [../]
  [./fp_zz]
    type = ElementAverageValue
    variable = fp_zz
    block = 'ANY_BLOCK_ID 0'
  [../]
  [./e_zz]
    type = ElementAverageValue
    variable = e_zz
    block = 'ANY_BLOCK_ID 0'
  [../]
  [./gss]
    type = ElementAverageValue
    variable = gss
    block = 'ANY_BLOCK_ID 0'
  [../]
[]

[Preconditioning]
  [./smp]
    type = SMP
    full = true
  [../]
[]

[Executioner]
  type = Transient
  dt = 2.0
  solve_type = 'PJFNK'

  petsc_options_iname = -pc_hypre_type
  petsc_options_value = boomerang
  nl_abs_tol = 1e-10
  nl_rel_step_tol = 1e-10
  dtmax = 10.0
  nl_rel_tol = 1e-10
  end_time = 30.0
  dtmin = 0.5
  num_steps = 10
  nl_abs_step_tol = 1e-10
[]

[Outputs]
  exodus = true
  csv = true
  gnuplot = true
[]

(modules/solid_mechanics/test/tests/multi/three_surface13.i)

# Plasticit models:
# SimpleTester0 with a = 0 and b = 1 and strength = 1
# SimpleTester1 with a = 1 and b = 0 and strength = 1
# SimpleTester2 with a = 1 and b = 1 and strength = 3
#
# Lame lambda = 0 (Poisson=0).  Lame mu = 0.5E6
#
# A single element is stretched by 2.0E-6m in y direction and 0E-6 in z direction.
# trial stress_yy = 2 and stress_zz = 0
#
# Then SimpleTester1 should activate and the algorithm will return to
# stress_yy=1
# internal1 should be 1

[Mesh]
  type = GeneratedMesh
  dim = 3
  nx = 1
  ny = 1
  nz = 1
  xmin = -0.5
  xmax = 0.5
  ymin = -0.5
  ymax = 0.5
  zmin = -0.5
  zmax = 0.5
[]


[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./disp_z]
  [../]
[]

[Kernels]
  [SolidMechanics]
    displacements = 'disp_x disp_y disp_z'
  [../]
[]


[BCs]
  [./x]
    type = FunctionDirichletBC
    variable = disp_x
    boundary = 'front back'
    function = '0E-6*x'
  [../]
  [./y]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = 'front back'
    function = '2.0E-6*y'
  [../]
  [./z]
    type = FunctionDirichletBC
    variable = disp_z
    boundary = 'front back'
    function = '0.0E-6*z'
  [../]
[]

[AuxVariables]
  [./stress_xx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_zz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./f0]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./f1]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./f2]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./int0]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./int1]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./int2]
    order = CONSTANT
    family = MONOMIAL
  [../]
[]

[AuxKernels]
  [./stress_xx]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xx
    index_i = 0
    index_j = 0
  [../]
  [./stress_xy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xy
    index_i = 0
    index_j = 1
  [../]
  [./stress_xz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xz
    index_i = 0
    index_j = 2
  [../]
  [./stress_yy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yy
    index_i = 1
    index_j = 1
  [../]
  [./stress_yz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yz
    index_i = 1
    index_j = 2
  [../]
  [./stress_zz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_zz
    index_i = 2
    index_j = 2
  [../]
  [./f0]
    type = MaterialStdVectorAux
    property = plastic_yield_function
    index = 0
    variable = f0
  [../]
  [./f1]
    type = MaterialStdVectorAux
    property = plastic_yield_function
    index = 1
    variable = f1
  [../]
  [./f2]
    type = MaterialStdVectorAux
    property = plastic_yield_function
    index = 2
    variable = f2
  [../]
  [./int0]
    type = MaterialStdVectorAux
    property = plastic_internal_parameter
    factor = 1E6
    index = 0
    variable = int0
  [../]
  [./int1]
    type = MaterialStdVectorAux
    property = plastic_internal_parameter
    factor = 1E6
    index = 1
    variable = int1
  [../]
  [./int2]
    type = MaterialStdVectorAux
    property = plastic_internal_parameter
    factor = 1E6
    index = 2
    variable = int2
  [../]
[]

[Postprocessors]
  [./s_xx]
    type = PointValue
    point = '0 0 0'
    variable = stress_xx
  [../]
  [./s_xy]
    type = PointValue
    point = '0 0 0'
    variable = stress_xy
  [../]
  [./s_xz]
    type = PointValue
    point = '0 0 0'
    variable = stress_xz
  [../]
  [./s_yy]
    type = PointValue
    point = '0 0 0'
    variable = stress_yy
  [../]
  [./s_yz]
    type = PointValue
    point = '0 0 0'
    variable = stress_yz
  [../]
  [./s_zz]
    type = PointValue
    point = '0 0 0'
    variable = stress_zz
  [../]
  [./f0]
    type = PointValue
    point = '0 0 0'
    variable = f0
  [../]
  [./f1]
    type = PointValue
    point = '0 0 0'
    variable = f1
  [../]
  [./f2]
    type = PointValue
    point = '0 0 0'
    variable = f2
  [../]
  [./int0]
    type = PointValue
    point = '0 0 0'
    variable = int0
  [../]
  [./int1]
    type = PointValue
    point = '0 0 0'
    variable = int1
  [../]
  [./int2]
    type = PointValue
    point = '0 0 0'
    variable = int2
  [../]
[]

[UserObjects]
  [./simple0]
    type = SolidMechanicsPlasticSimpleTester
    a = 0
    b = 1
    strength = 1
    yield_function_tolerance = 1.0E-9
    internal_constraint_tolerance = 1.0E-9
  [../]
  [./simple1]
    type = SolidMechanicsPlasticSimpleTester
    a = 1
    b = 0
    strength = 1
    yield_function_tolerance = 1.0E-9
    internal_constraint_tolerance = 1.0E-9
  [../]
  [./simple2]
    type = SolidMechanicsPlasticSimpleTester
    a = 1
    b = 1
    strength = 3
    yield_function_tolerance = 1.0E-9
    internal_constraint_tolerance = 1.0E-9
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeElasticityTensor
    block = 0
    fill_method = symmetric_isotropic
    C_ijkl = '0 0.5E6'
  [../]
  [./strain]
    type = ComputeFiniteStrain
    block = 0
    displacements = 'disp_x disp_y disp_z'
  [../]
  [./multi]
    type = ComputeMultiPlasticityStress
    block = 0
    ep_plastic_tolerance = 1E-9
    plastic_models = 'simple0 simple1 simple2'
    max_NR_iterations = 2
    min_stepsize = 1
    debug_fspb = crash
    debug_jac_at_stress = '10 0 0 0 10 0 0 0 10'
    debug_jac_at_pm = '1 1'
    debug_jac_at_intnl = '1 1'
    debug_stress_change = 1E-5
    debug_pm_change = '1E-6 1E-6'
    debug_intnl_change = '1E-6 1E-6'
  [../]
[]


[Executioner]
  end_time = 1
  dt = 1
  type = Transient
[]


[Outputs]
  file_base = three_surface13
  exodus = false
  [./csv]
    type = CSV
    [../]
[]

(modules/contact/test/tests/mortar_aux_kernels/block-dynamics-aux-wear-vel.i)

starting_point = 0.5e-1
offset = -0.05

[GlobalParams]
  displacements = 'disp_x disp_y'
[]

[Mesh]
  file = long-bottom-block-1elem-blocks.e
[]

[Variables]
  [disp_x]
    block = '1 2'
  []
  [disp_y]
    block = '1 2'
  []
  [normal_lm]
    block = 3
    use_dual = true
    scaling = 1.0e3
  []
  [frictional_lm]
    block = 3
    use_dual = true
  []
[]

[ICs]
  [disp_y]
    block = 2
    variable = disp_y
    value = '${fparse starting_point + offset}'
    type = ConstantIC
  []
[]

[Kernels]
  [DynamicTensorMechanics]
    displacements = 'disp_x disp_y'
    generate_output = 'stress_xx stress_yy'
    strain = FINITE
    block = '1 2'
    zeta = 1.0
    hht_alpha = 0.0
  []
  [inertia_x]
    type = InertialForce
    variable = disp_x
    velocity = vel_x
    acceleration = accel_x
    beta = 0.25
    gamma = 0.5
    alpha = 0
    eta = 0.0
    block = '1 2'
  []
  [inertia_y]
    type = InertialForce
    variable = disp_y
    velocity = vel_y
    acceleration = accel_y
    beta = 0.25
    gamma = 0.5
    alpha = 0
    eta = 0.0
    block = '1 2'
  []
[]

[Materials]
  [elasticity_2]
    type = ComputeIsotropicElasticityTensor
    block = '2'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  []
  [elasticity_1]
    type = ComputeIsotropicElasticityTensor
    block = '1'
    youngs_modulus = 1e8
    poissons_ratio = 0.3
  []
  [stress]
    type = ComputeFiniteStrainElasticStress
    block = '1 2'
  []
  [strain]
    type = ComputeFiniteStrain
    block = '1 2'
  []
  [density]
    type = GenericConstantMaterial
    block = '1 2'
    prop_names = 'density'
    prop_values = '7750'
  []
[]

[AuxVariables]
  [worn_depth]
    block = '3'
  []
  [gap_vel]
    block = '3'
  []
  [vel_x]
    block = '1 2'
  []
  [accel_x]
    block = '1 2'
  []
  [vel_y]
    block = '1 2'
  []
  [accel_y]
    block = '1 2'
  []
  [vel_z]
    block = '1 2'
  []
  [accel_z]
    block = '1 2'
  []
[]

[AuxKernels]
  [gap_vel]
    type = WeightedGapVelAux
    variable = gap_vel
    primary_boundary = 20
    secondary_boundary = 10
    primary_subdomain = 4
    secondary_subdomain = 3
    disp_x = disp_x
    disp_y = disp_y
  []
  [worn_depth]
    type = MortarArchardsLawAux
    variable = worn_depth
    primary_boundary = 20
    secondary_boundary = 10
    primary_subdomain = 4
    secondary_subdomain = 3
    displacements = 'disp_x disp_y'
    friction_coefficient = 0.5
    energy_wear_coefficient = 1.0
    normal_pressure = normal_lm
  []
  [accel_x]
    type = NewmarkAccelAux
    variable = accel_x
    displacement = disp_x
    velocity = vel_x
    beta = 0.25
    execute_on = 'linear timestep_end'
  []
  [vel_x]
    type = NewmarkVelAux
    variable = vel_x
    acceleration = accel_x
    gamma = 0.5
    execute_on = 'linear timestep_end'
  []
  [accel_y]
    type = NewmarkAccelAux
    variable = accel_y
    displacement = disp_y
    velocity = vel_y
    beta = 0.25
    execute_on = 'linear timestep_end'
  []
  [vel_y]
    type = NewmarkVelAux
    variable = vel_y
    acceleration = accel_y
    gamma = 0.5
    execute_on = 'linear timestep_end'
  []
[]

[UserObjects]
  [weighted_vel_uo]
    type = LMWeightedVelocitiesUserObject
    primary_boundary = 20
    secondary_boundary = 10
    primary_subdomain = 4
    secondary_subdomain = 3
    secondary_variable = disp_x
    lm_variable_normal = normal_lm
    lm_variable_tangential_one = frictional_lm
    disp_x = disp_x
    disp_y = disp_y
  []
[]

[Constraints]
  [weighted_gap_lm]
    type = ComputeDynamicFrictionalForceLMMechanicalContact
    primary_boundary = 20
    secondary_boundary = 10
    primary_subdomain = 4
    secondary_subdomain = 3
    variable = normal_lm
    disp_x = disp_x
    disp_y = disp_y
    use_displaced_mesh = true
    c = 1e4
    c_t = 1e6
    mu = 0.15
    friction_lm = frictional_lm
    capture_tolerance = 1.0e-5
    newmark_beta = 0.25
    newmark_gamma = 0.5
  []
  [normal_x]
    type = NormalMortarMechanicalContact
    primary_boundary = 20
    secondary_boundary = 10
    primary_subdomain = 4
    secondary_subdomain = 3
    variable = normal_lm
    secondary_variable = disp_x
    component = x
    use_displaced_mesh = true
    compute_lm_residuals = false
    weighted_gap_uo = weighted_vel_uo
  []
  [normal_y]
    type = NormalMortarMechanicalContact
    primary_boundary = 20
    secondary_boundary = 10
    primary_subdomain = 4
    secondary_subdomain = 3
    variable = normal_lm
    secondary_variable = disp_y
    component = y
    use_displaced_mesh = true
    compute_lm_residuals = false
    weighted_gap_uo = weighted_vel_uo
  []
  [tangential_x]
    type = TangentialMortarMechanicalContact
    primary_boundary = 20
    secondary_boundary = 10
    primary_subdomain = 4
    secondary_subdomain = 3
    variable = frictional_lm
    secondary_variable = disp_x
    component = x
    use_displaced_mesh = true
    compute_lm_residuals = false
    weighted_velocities_uo = weighted_vel_uo
  []
  [tangential_y]
    type = TangentialMortarMechanicalContact
    primary_boundary = 20
    secondary_boundary = 10
    primary_subdomain = 4
    secondary_subdomain = 3
    variable = frictional_lm
    secondary_variable = disp_y
    component = y
    use_displaced_mesh = true
    compute_lm_residuals = false
    weighted_velocities_uo = weighted_vel_uo
  []
[]

[BCs]
  [botx]
    type = DirichletBC
    variable = disp_x
    boundary = 40
    value = 0.0
  []
  [boty]
    type = DirichletBC
    variable = disp_y
    boundary = 40
    value = 0.0
  []
  [topy]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = 30
    function = '${starting_point} * cos(16.0 * pi / 4 * t) + ${offset}'
  []
  [leftx]
    type = FunctionDirichletBC
    variable = disp_x
    boundary = 50
    function = '1e-2 * t'
  []
[]

[Executioner]
  type = Transient
  end_time = 0.3
  dt = 0.03
  dtmin = .002
  solve_type = 'NEWTON'
  petsc_options = '-snes_converged_reason -ksp_converged_reason -pc_svd_monitor '
                  '-snes_linesearch_monitor -snes_ksp_ew'
  petsc_options_iname = '-pc_type -pc_factor_mat_solver_type -pc_factor_shift_type -pc_factor_shift_amount'
  petsc_options_value = 'lu       superlu_dist                  NONZERO               1e-15'
  nl_max_its = 40
  nl_abs_tol = 1.0e-11
  nl_rel_tol = 1.0e-11
  line_search = 'none'
  snesmf_reuse_base = true

  [TimeIntegrator]
    type = NewmarkBeta
    beta = 0.25
    gamma = 0.5
  []
[]

[Debug]
  show_var_residual_norms = true
[]

[Outputs]
  exodus = true
  checkpoint = true
[]

[Preconditioning]
  [smp]
    type = SMP
    full = true
  []
[]

[Postprocessors]
  active = 'contact'
  [num_nl]
    type = NumNonlinearIterations
  []
  [cumulative]
    type = CumulativeValuePostprocessor
    postprocessor = num_nl
  []
  [contact]
    type = ContactDOFSetSize
    variable = normal_lm
    subdomain = '3'
    execute_on = 'nonlinear timestep_end'
  []
[]

(modules/solid_mechanics/test/tests/multi/three_surface15.i)

# Plasticit models:
# SimpleTester0 with a = 0 and b = 1 and strength = 1
# SimpleTester1 with a = 1 and b = 0 and strength = 1
# SimpleTester2 with a = 1 and b = 1 and strength = 3
#
# Lame lambda = 0 (Poisson=0).  Lame mu = 0.5E6
#
# A single element is stretched by 3.0E-6m in y direction and 3E-6 in z direction.
# trial stress_yy = 3.0 and stress_zz = 3
#
# A complicated return will follow, with various contraints being
# deactivated, kuhn-tucker failing, line-searching, etc, but
# the result should be
# stress_yy=1=stress_zz, and internal0=2 internal1=2

[Mesh]
  type = GeneratedMesh
  dim = 3
  nx = 1
  ny = 1
  nz = 1
  xmin = -0.5
  xmax = 0.5
  ymin = -0.5
  ymax = 0.5
  zmin = -0.5
  zmax = 0.5
[]


[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./disp_z]
  [../]
[]

[Kernels]
  [SolidMechanics]
    displacements = 'disp_x disp_y disp_z'
  [../]
[]


[BCs]
  [./x]
    type = FunctionDirichletBC
    variable = disp_x
    boundary = 'front back'
    function = '0E-6*x'
  [../]
  [./y]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = 'front back'
    function = '3.0E-6*y'
  [../]
  [./z]
    type = FunctionDirichletBC
    variable = disp_z
    boundary = 'front back'
    function = '3.0E-6*z'
  [../]
[]

[AuxVariables]
  [./stress_xx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_zz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./f0]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./f1]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./f2]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./int0]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./int1]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./int2]
    order = CONSTANT
    family = MONOMIAL
  [../]
[]

[AuxKernels]
  [./stress_xx]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xx
    index_i = 0
    index_j = 0
  [../]
  [./stress_xy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xy
    index_i = 0
    index_j = 1
  [../]
  [./stress_xz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xz
    index_i = 0
    index_j = 2
  [../]
  [./stress_yy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yy
    index_i = 1
    index_j = 1
  [../]
  [./stress_yz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yz
    index_i = 1
    index_j = 2
  [../]
  [./stress_zz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_zz
    index_i = 2
    index_j = 2
  [../]
  [./f0]
    type = MaterialStdVectorAux
    property = plastic_yield_function
    index = 0
    variable = f0
  [../]
  [./f1]
    type = MaterialStdVectorAux
    property = plastic_yield_function
    index = 1
    variable = f1
  [../]
  [./f2]
    type = MaterialStdVectorAux
    property = plastic_yield_function
    index = 2
    variable = f2
  [../]
  [./int0]
    type = MaterialStdVectorAux
    property = plastic_internal_parameter
    factor = 1E6
    index = 0
    variable = int0
  [../]
  [./int1]
    type = MaterialStdVectorAux
    property = plastic_internal_parameter
    factor = 1E6
    index = 1
    variable = int1
  [../]
  [./int2]
    type = MaterialStdVectorAux
    property = plastic_internal_parameter
    factor = 1E6
    index = 2
    variable = int2
  [../]
[]

[Postprocessors]
  [./s_xx]
    type = PointValue
    point = '0 0 0'
    variable = stress_xx
  [../]
  [./s_xy]
    type = PointValue
    point = '0 0 0'
    variable = stress_xy
  [../]
  [./s_xz]
    type = PointValue
    point = '0 0 0'
    variable = stress_xz
  [../]
  [./s_yy]
    type = PointValue
    point = '0 0 0'
    variable = stress_yy
  [../]
  [./s_yz]
    type = PointValue
    point = '0 0 0'
    variable = stress_yz
  [../]
  [./s_zz]
    type = PointValue
    point = '0 0 0'
    variable = stress_zz
  [../]
  [./f0]
    type = PointValue
    point = '0 0 0'
    variable = f0
  [../]
  [./f1]
    type = PointValue
    point = '0 0 0'
    variable = f1
  [../]
  [./f2]
    type = PointValue
    point = '0 0 0'
    variable = f2
  [../]
  [./int0]
    type = PointValue
    point = '0 0 0'
    variable = int0
  [../]
  [./int1]
    type = PointValue
    point = '0 0 0'
    variable = int1
  [../]
  [./int2]
    type = PointValue
    point = '0 0 0'
    variable = int2
  [../]
[]

[UserObjects]
  [./simple0]
    type = SolidMechanicsPlasticSimpleTester
    a = 0
    b = 1
    strength = 1
    yield_function_tolerance = 1.0E-6
    internal_constraint_tolerance = 1.0E-6
  [../]
  [./simple1]
    type = SolidMechanicsPlasticSimpleTester
    a = 1
    b = 0
    strength = 1
    yield_function_tolerance = 1.0E-6
    internal_constraint_tolerance = 1.0E-6
  [../]
  [./simple2]
    type = SolidMechanicsPlasticSimpleTester
    a = 1
    b = 1
    strength = 3
    yield_function_tolerance = 1.0E-6
    internal_constraint_tolerance = 1.0E-6
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeElasticityTensor
    block = 0
    fill_method = symmetric_isotropic
    C_ijkl = '0 0.5E6'
  [../]
  [./strain]
    type = ComputeFiniteStrain
    block = 0
    displacements = 'disp_x disp_y disp_z'
  [../]
  [./multi]
    type = ComputeMultiPlasticityStress
    block = 0
    ep_plastic_tolerance = 1E-9
    plastic_models = 'simple0 simple1 simple2'
    max_NR_iterations = 4
    min_stepsize = 1
    debug_fspb = crash
    debug_jac_at_stress = '10 0 0 0 10 0 0 0 10'
    debug_jac_at_pm = '1 1 1'
    debug_jac_at_intnl = '1 1 1'
    debug_stress_change = 1E-5
    debug_pm_change = '1E-6 1E-6 1E-6'
    debug_intnl_change = '1E-6 1E-6 1E-6'
  [../]
[]


[Executioner]
  end_time = 1
  dt = 1
  type = Transient
[]


[Outputs]
  file_base = three_surface15
  exodus = false
  [./csv]
    type = CSV
    [../]
[]

(modules/solid_mechanics/test/tests/initial_stress/mc_tensile.i)

# In this example, an initial stress is applied that
# is inadmissible, and the return-map algorithm must be
# used to return to the yield surface before any other
# computations can be carried out.
# In this case, the return-map algorithm must subdivide
# the initial stress, otherwise it does not converge.
# This test is testing that subdivision process.

[Mesh]
  type = GeneratedMesh
  dim = 3
  nx = 1
  ny = 1
  nz = 1
  xmin = -0.5
  xmax = 0.5
  ymin = -0.5
  ymax = 0.5
  zmin = -0.5
  zmax = 0.5
[]


[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./disp_z]
  [../]
[]

[Kernels]
  [SolidMechanics]
    displacements = 'disp_x disp_y disp_z'
  [../]
[]


[BCs]
  [./bottomx]
    type = DirichletBC
    variable = disp_x
    boundary = 'back'
    value = 0.0
  [../]
  [./bottomy]
    type = DirichletBC
    variable = disp_y
    boundary = 'back'
    value = 0.0
  [../]
  [./bottomz]
    type = DirichletBC
    variable = disp_z
    boundary = 'back'
    value = 0.0
  [../]
  [./topx]
    type = FunctionDirichletBC
    variable = disp_x
    boundary = 'front'
    function = '2*t-1'
  [../]
  [./topy]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = 'front'
    function = 't-1'
  [../]
  [./topz]
    type = FunctionDirichletBC
    variable = disp_z
    boundary = 'front'
    function = 't-1'
  [../]
[]

[AuxVariables]
  [./stress_xx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_zz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./iter]
    order = CONSTANT
    family = MONOMIAL
  [../]
[]

[AuxKernels]
  [./stress_xx]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xx
    index_i = 0
    index_j = 0
  [../]
  [./stress_xy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xy
    index_i = 0
    index_j = 1
  [../]
  [./stress_xz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xz
    index_i = 0
    index_j = 2
  [../]
  [./stress_yy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yy
    index_i = 1
    index_j = 1
  [../]
  [./stress_yz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yz
    index_i = 1
    index_j = 2
  [../]
  [./stress_zz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_zz
    index_i = 2
    index_j = 2
  [../]
  [./iter]
    type = MaterialRealAux
    property = plastic_NR_iterations
    variable = iter
  [../]
[]

[Postprocessors]
  [./s_xx]
    type = PointValue
    point = '0 0 0'
    variable = stress_xx
  [../]
  [./s_xy]
    type = PointValue
    point = '0 0 0'
    variable = stress_xy
  [../]
  [./s_xz]
    type = PointValue
    point = '0 0 0'
    variable = stress_xz
  [../]
  [./s_yy]
    type = PointValue
    point = '0 0 0'
    variable = stress_yy
  [../]
  [./s_yz]
    type = PointValue
    point = '0 0 0'
    variable = stress_yz
  [../]
  [./s_zz]
    type = PointValue
    point = '0 0 0'
    variable = stress_zz
  [../]
  [./iter]
    type = PointValue
    point = '0 0 0'
    variable = iter
    outputs = console
  [../]
[]

[UserObjects]
  [./mc_coh]
    type = SolidMechanicsHardeningConstant
    value = 1E5
  [../]
  [./mc_phi]
    type = SolidMechanicsHardeningConstant
    value = 60
    convert_to_radians = true
  [../]
  [./mc_psi]
    type = SolidMechanicsHardeningConstant
    value = 5
    convert_to_radians = true
  [../]
  [./mc]
    type = SolidMechanicsPlasticMohrCoulomb
    cohesion = mc_coh
    friction_angle = mc_phi
    dilation_angle = mc_psi
    mc_tip_smoother = 4.0
    mc_edge_smoother = 25
    yield_function_tolerance = 1E-3
    internal_constraint_tolerance = 1E-9
  [../]

  [./str]
    type = SolidMechanicsHardeningConstant
    value = 1
  [../]
  [./pt]
    type = SolidMechanicsPlasticTensile
    tensile_strength = str
    yield_function_tolerance = 1E-3
    tensile_tip_smoother = 0.05
    internal_constraint_tolerance = 1E-9
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeElasticityTensor
    fill_method = symmetric_isotropic
    C_ijkl = '0 1E7'
  [../]
  [./strain]
    type = ComputeFiniteStrain
    displacements = 'disp_x disp_y disp_z'
    eigenstrain_names = ini_stress
  [../]
  [./ini_stress]
    type = ComputeEigenstrainFromInitialStress
    initial_stress = '8E6 4E6 -18E6 4E6 -40E6 -2E6 -18E6 -2E6 -34E6'
    eigenstrain_name = ini_stress
  [../]
  [./mc]
    type = ComputeMultiPlasticityStress
    ep_plastic_tolerance = 1E-9
    plastic_models = 'pt mc'
    deactivation_scheme = safe
    max_NR_iterations = 100
    min_stepsize = 0.1
  [../]
[]


[Executioner]
  end_time = 2
  dt = 1
  type = Transient
[]


[Outputs]
  file_base = mc_tensile
  exodus = false
  [./csv]
    type = CSV
    [../]
[]

(modules/xfem/test/tests/moving_interface/moving_bimaterial_finite_strain_esm_using_cut_mesh.i)

# This test is for two layer materials with different youngs modulus with AD
# The global stress is determined by switching the stress based on level set values
# The material interface is marked by a level set function
# The two layer materials are glued together

[GlobalParams]
  displacements = 'disp_x disp_y'
[]

[XFEM]
  output_cut_plane = true
[]

[UserObjects]
  [cut]
    type = InterfaceMeshCut2DUserObject
    mesh_file = line.e
    interface_velocity_function = 1
    heal_always = true
  []
  [esm]
    type = CutElementSubdomainModifier
    geometric_cut_userobject = cut
    apply_initial_conditions = false
  []
[]

[Mesh]
  use_displaced_mesh = true
  [generated_mesh]
    type = GeneratedMeshGenerator
    dim = 2
    nx = 10
    ny = 10
    xmin = 0
    xmax = 5
    ymin = 0
    ymax = 5
    elem_type = QUAD4
  []
  [bottom]
    type = SubdomainBoundingBoxGenerator
    input = generated_mesh
    block_id = 0
    bottom_left = '0 0 0'
    top_right = '5 2.5 0'
  []
  [top]
    type = SubdomainBoundingBoxGenerator
    input = bottom
    block_id = 1
    bottom_left = '0 2.5 0'
    top_right = '5 5 0'
  []
[]

[Functions]
  [ls_func]
    type = ParsedFunction
    expression = 'y-2.73+t'
  []
[]

[Variables]
  [disp_x]
  []
  [disp_y]
  []
[]

[AuxVariables]
  [ls]
  []
  [strain_xx]
    order = CONSTANT
    family = MONOMIAL
  []
  [strain_yy]
    order = CONSTANT
    family = MONOMIAL
  []
  [strain_xy]
    order = CONSTANT
    family = MONOMIAL
  []
  [stress_xx]
    order = CONSTANT
    family = MONOMIAL
  []
  [stress_yy]
    order = CONSTANT
    family = MONOMIAL
  []
  [stress_xy]
    order = CONSTANT
    family = MONOMIAL
  []
[]

[AuxKernels]
  [ls_function]
    type = FunctionAux
    variable = ls
    function = ls_func
  []
  [strain_xx]
    type = RankTwoAux
    variable = strain_xx
    rank_two_tensor = total_strain
    index_i = 0
    index_j = 0
  []
  [strain_yy]
    type = RankTwoAux
    variable = strain_yy
    rank_two_tensor = total_strain
    index_i = 1
    index_j = 1
  []
  [strain_xy]
    type = RankTwoAux
    variable = strain_xy
    rank_two_tensor = total_strain
    index_i = 0
    index_j = 1
  []
  [stress_xx]
    type = RankTwoAux
    variable = stress_xx
    rank_two_tensor = stress
    index_i = 0
    index_j = 0
  []
  [stress_xy]
    type = RankTwoAux
    variable = stress_xy
    rank_two_tensor = stress
    index_i = 0
    index_j = 1
  []
  [stress_yy]
    type = RankTwoAux
    variable = stress_yy
    rank_two_tensor = stress
    index_i = 1
    index_j = 1
  []
[]

[Kernels]
  [solid_x]
    type = StressDivergenceTensors
    variable = disp_x
    component = 0
    use_displaced_mesh = true
  []
  [solid_y]
    type = StressDivergenceTensors
    variable = disp_y
    component = 1
    use_displaced_mesh = true
  []
[]

[Constraints]
  [dispx_constraint]
    type = XFEMSingleVariableConstraint
    use_displaced_mesh = false
    variable = disp_x
    alpha = 1e8
    geometric_cut_userobject = 'cut'
  []
  [dispy_constraint]
    type = XFEMSingleVariableConstraint
    use_displaced_mesh = false
    variable = disp_y
    alpha = 1e8
    geometric_cut_userobject = 'cut'
  []
[]

[BCs]
  [bottomx]
    type = DirichletBC
    boundary = bottom
    variable = disp_x
    value = 0.0
  []
  [bottomy]
    type = DirichletBC
    boundary = bottom
    variable = disp_y
    value = 0.0
  []
  [topx]
    type = FunctionDirichletBC
    boundary = top
    variable = disp_x
    function = 0.03*t
  []
  [topy]
    type = FunctionDirichletBC
    boundary = top
    variable = disp_y
    function = '0.03*t'
  []
[]

[Materials]
  [elasticity_tensor_A]
    type = ComputeIsotropicElasticityTensor
    block = 1
    youngs_modulus = 1e9
    poissons_ratio = 0.3
  []
  [strain_A]
    type = ComputeFiniteStrain
    block = 1
  []
  [stress_A]
    type = ComputeFiniteStrainElasticStress
    block = 1
  []
  [elasticity_tensor_B]
    type = ComputeIsotropicElasticityTensor
    block = 0
    youngs_modulus = 1e7
    poissons_ratio = 0.3
  []
  [strain_B]
    type = ComputeFiniteStrain
    block = 0
  []
  [stress_B]
    type = ComputeFiniteStrainElasticStress
    block = 0
  []
[]

[Postprocessors]
  [disp_x_norm]
    type = ElementL2Norm
    variable = disp_x
  []
  [disp_y_norm]
    type = ElementL2Norm
    variable = disp_y
  []
[]

[Executioner]
  type = Transient

  solve_type = NEWTON
  petsc_options_iname = '-pc_type'
  petsc_options_value = 'lu'
  automatic_scaling = true

  # controls for nonlinear iterations
  nl_max_its = 15
  nl_rel_tol = 1e-13
  nl_abs_tol = 1e-50

  # time control
  start_time = 0.0
  dt = 0.1
  num_steps = 4

  max_xfem_update = 1
[]

[Outputs]
  print_linear_residuals = false
  exodus = true
[]

(modules/contact/test/tests/mortar_aux_kernels/block-dynamics-aux-wear.i)

starting_point = 0.5e-1
offset = -0.05

[GlobalParams]
  displacements = 'disp_x disp_y'
[]

[Mesh]
  file = long-bottom-block-1elem-blocks.e
[]

[Variables]
  [disp_x]
    block = '1 2'
  []
  [disp_y]
    block = '1 2'
  []
  [normal_lm]
    block = 3
    use_dual = true
  []
[]

[ICs]
  [disp_y]
    block = 2
    variable = disp_y
    value = '${fparse starting_point + offset}'
    type = ConstantIC
  []
[]

[Kernels]
  [DynamicTensorMechanics]
    displacements = 'disp_x disp_y'
    generate_output = 'stress_xx stress_yy'
    strain = FINITE
    block = '1 2'
    zeta = 1.0
    hht_alpha = 0.0
  []
  [inertia_x]
    type = InertialForce
    variable = disp_x
    velocity = vel_x
    acceleration = accel_x
    beta = 0.25
    gamma = 0.5
    alpha = 0
    eta = 0.0
    block = '1 2'
  []
  [inertia_y]
    type = InertialForce
    variable = disp_y
    velocity = vel_y
    acceleration = accel_y
    beta = 0.25
    gamma = 0.5
    alpha = 0
    eta = 0.0
    block = '1 2'
  []
[]

[Materials]
  [elasticity_2]
    type = ComputeIsotropicElasticityTensor
    block = '2'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  []
  [elasticity_1]
    type = ComputeIsotropicElasticityTensor
    block = '1'
    youngs_modulus = 1e8
    poissons_ratio = 0.3
  []
  [stress]
    type = ComputeFiniteStrainElasticStress
    block = '1 2'
  []
  [strain]
    type = ComputeFiniteStrain
    block = '1 2'
  []
  [density]
    type = GenericConstantMaterial
    block = '1 2'
    prop_names = 'density'
    prop_values = '7750'
  []
[]

[AuxVariables]
  [worn_depth]
    block = '3'
  []
  [vel_x]
    block = '1 2'
  []
  [accel_x]
    block = '1 2'
  []
  [vel_y]
    block = '1 2'
  []
  [accel_y]
    block = '1 2'
  []
  [vel_z]
    block = '1 2'
  []
  [accel_z]
    block = '1 2'
  []
[]

[AuxKernels]
  [worn_depth]
    type = MortarArchardsLawAux
    variable = worn_depth
    primary_boundary = 20
    secondary_boundary = 10
    primary_subdomain = 4
    secondary_subdomain = 3
    displacements = 'disp_x disp_y'
    friction_coefficient = 0.5
    energy_wear_coefficient = 1.0
    normal_pressure = normal_lm
  []
  [accel_x]
    type = NewmarkAccelAux
    variable = accel_x
    displacement = disp_x
    velocity = vel_x
    beta = 0.25
    execute_on = 'linear timestep_end'
  []
  [vel_x]
    type = NewmarkVelAux
    variable = vel_x
    acceleration = accel_x
    gamma = 0.5
    execute_on = 'linear timestep_end'
  []
  [accel_y]
    type = NewmarkAccelAux
    variable = accel_y
    displacement = disp_y
    velocity = vel_y
    beta = 0.25
    execute_on = 'linear timestep_end'
  []
  [vel_y]
    type = NewmarkVelAux
    variable = vel_y
    acceleration = accel_y
    gamma = 0.5
    execute_on = 'linear timestep_end'
  []
[]

[UserObjects]
  [weighted_gap_uo]
    type = LMWeightedGapUserObject
    primary_boundary = 20
    secondary_boundary = 10
    primary_subdomain = 4
    secondary_subdomain = 3
    lm_variable = normal_lm
    disp_x = disp_x
    disp_y = disp_y
  []
[]

[Constraints]
  [weighted_gap_lm]
    type = ComputeDynamicWeightedGapLMMechanicalContact
    primary_boundary = 20
    secondary_boundary = 10
    primary_subdomain = 4
    secondary_subdomain = 3
    variable = normal_lm
    disp_x = disp_x
    disp_y = disp_y
    use_displaced_mesh = true
    c = 1e4
    capture_tolerance = 1.0e-5
    newmark_beta = 0.25
    newmark_gamma = 0.5
  []
  [normal_x]
    type = NormalMortarMechanicalContact
    primary_boundary = 20
    secondary_boundary = 10
    primary_subdomain = 4
    secondary_subdomain = 3
    variable = normal_lm
    secondary_variable = disp_x
    component = x
    use_displaced_mesh = true
    compute_lm_residuals = false
    weighted_gap_uo = weighted_gap_uo
  []
  [normal_y]
    type = NormalMortarMechanicalContact
    primary_boundary = 20
    secondary_boundary = 10
    primary_subdomain = 4
    secondary_subdomain = 3
    variable = normal_lm
    secondary_variable = disp_y
    component = y
    use_displaced_mesh = true
    compute_lm_residuals = false
    weighted_gap_uo = weighted_gap_uo
  []
[]

[BCs]
  [botx]
    type = DirichletBC
    variable = disp_x
    boundary = 40
    value = 0.0
  []
  [boty]
    type = DirichletBC
    variable = disp_y
    boundary = 40
    value = 0.0
  []
  [topy]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = 30
    function = '${starting_point} * cos(8.0 * pi / 4 * t) + ${offset}'
  []
  [leftx]
    type = FunctionDirichletBC
    variable = disp_x
    boundary = 50
    function = '1e-2 * t'
  []
[]

[Executioner]
  type = Transient
  end_time = 0.675
  dt = 0.075
  dtmin = .075
  solve_type = 'NEWTON'
  petsc_options = '-snes_converged_reason -ksp_converged_reason -pc_svd_monitor '
                  '-snes_linesearch_monitor -snes_ksp_ew'
  petsc_options_iname = '-pc_type -pc_factor_mat_solver_type -pc_factor_shift_type -pc_factor_shift_amount '
  petsc_options_value = 'lu       superlu_dist                  NONZERO               1e-15'
  nl_max_its = 30
  line_search = 'l2'
  snesmf_reuse_base = false

  [TimeIntegrator]
    type = NewmarkBeta
    beta = 0.25
    gamma = 0.5
  []
[]

[Debug]
  show_var_residual_norms = true
[]

[Outputs]
  exodus = true
  checkpoint = true
[]

[Preconditioning]
  [smp]
    type = SMP
    full = true
  []
[]

[Postprocessors]
  active = 'num_nl cumulative contact'
  [num_nl]
    type = NumNonlinearIterations
  []
  [cumulative]
    type = CumulativeValuePostprocessor
    postprocessor = num_nl
  []
  [contact]
    type = ContactDOFSetSize
    variable = normal_lm
    subdomain = '3'
    execute_on = 'nonlinear timestep_end'
  []
[]

(modules/solid_mechanics/test/tests/finite_strain_tensor_mechanics_tests/elastic_rotation.i)

#
# Rotation Test
#
# This test is designed to compute a uniaxial stress and then follow that
# stress as the mesh is rotated 90 degrees.
#
# The mesh is composed of one block with a single element.  The nodal
# displacements in the x and y directions are prescribed.  Poisson's
# ratio is zero.
#

[Mesh]
  file = rotation_test.e
[]

[GlobalParams]
  displacements = 'disp_x disp_y disp_z'
[]

[Functions]
  # Functions
  [./x_200]
    type = ParsedFunction
    symbol_names = 'delta t0'
    symbol_values = '-1e-6 1.0'
    expression = 'if(t<=1.0, delta*t, (1.0+delta)*cos(pi/2*(t-t0)) - 1.0)'
  [../]
  [./y_200]
    type = ParsedFunction
    symbol_names = 'delta t0'
    symbol_values = '-1e-6 1.0'
    expression = 'if(t<=1.0, 0.0, (1.0+delta)*sin(pi/2*(t-t0)))'
  [../]
  [./x_300]
    type = ParsedFunction
    symbol_names = 'delta t0'
    symbol_values = '-1e-6 1.0'
    expression = 'if(t<=1.0, delta*t, (1.0+delta)*cos(pi/2.0*(t-t0)) - sin(pi/2.0*(t-t0)) - 1.0)'
  [../]
  [./y_300]
    type = ParsedFunction
    symbol_names = 'delta t0'
    symbol_values = '-1e-6 1.0'
    expression = 'if(t<=1.0, 0.0, cos(pi/2.0*(t-t0)) + (1+delta)*sin(pi/2.0*(t-t0)) - 1.0)'
  [../]
  [./x_400]
    type = ParsedFunction
    symbol_names = 'delta t0'
    symbol_values = '-1e-6 1.0'
    expression = 'if(t<=1.0, 0.0, -sin(pi/2.0*(t-t0)))'
  [../]
  [./y_400]
    type = ParsedFunction
    symbol_names = 'delta t0'
    symbol_values = '-1e-6 1.0'
    expression = 'if(t<=1.0, 0.0, cos(pi/2.0*(t-t0)) - 1.0)'
  [../]
[]

[Variables]
  # Variables
  [./disp_x]
    order = FIRST
    family = LAGRANGE
  [../]
  [./disp_y]
    order = FIRST
    family = LAGRANGE
  [../]
  [./disp_z]
    order = FIRST
    family = LAGRANGE
  [../]
[]

[AuxVariables]
  # AuxVariables
  [./stress_xx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xy]
    order = CONSTANT
    family = MONOMIAL
  [../]
[]

[Kernels]
  [SolidMechanics]
    use_displaced_mesh = true
  [../]
[]

[AuxKernels]
  # AuxKernels
  [./stress_xx]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xx
    index_i = 0
    index_j = 0
  [../]
  [./stress_yy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yy
    index_i = 1
    index_j = 1
  [../]
  [./stress_xy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xy
    index_i = 0
    index_j = 1
  [../]
[]

[BCs]
  # BCs
  [./no_x]
    type = DirichletBC
    variable = disp_x
    boundary = 100
    value = 0.0
  [../]
  [./no_y]
    type = DirichletBC
    variable = disp_y
    boundary = 100
    value = 0.0
  [../]
  [./x_200]
    type = FunctionDirichletBC
    variable = disp_x
    boundary = 200
    function = x_200
  [../]
  [./y_200]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = 200
    function = y_200
  [../]
  [./x_300]
    type = FunctionDirichletBC
    variable = disp_x
    boundary = 300
    function = x_300
  [../]
  [./y_300]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = 300
    function = y_300
  [../]
  [./x_400]
    type = FunctionDirichletBC
    variable = disp_x
    boundary = 400
    function = x_400
  [../]
  [./y_400]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = 400
    function = y_400
  [../]
  [./no_z]
    type = DirichletBC
    variable = disp_z
    boundary = '100 200 300 400'
    value = 0.0
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeElasticityTensor
    block = 1
    C_ijkl = '1.0e6  0.0   0.0 1.0e6  0.0  1.0e6 0.5e6 0.5e6 0.5e6'
    fill_method = symmetric9
  [../]
  [./strain]
    type = ComputeFiniteStrain
    block = 1
    displacements = 'disp_x disp_y disp_z'
  [../]
  [./stress]
    type = ComputeFiniteStrainElasticStress
    block = 1
  [../]
[]

[Postprocessors]
  [./stress_xx]
    type = ElementAverageValue
    variable = stress_xx
  [../]
  [./stress_yy]
    type = ElementAverageValue
    variable = stress_yy
  [../]
  [./stress_xy]
    type = ElementAverageValue
    variable = stress_xy
  [../]
[]

[Preconditioning]
  [./SMP]
    type = SMP
    full = true
  [../]
[]

[Executioner]
  # Executioner
  type = Transient

  solve_type = 'NEWTON'

  petsc_options_iname = '-pc_type '
  petsc_options_value = 'lu'
  nl_rel_tol = 1e-30
  nl_abs_tol = 1e-20
  l_max_its = 20
  start_time = 0.0
  dt = 0.01
  end_time = 2.0
[]

[Outputs]
  exodus = true
[] # Outputs

(modules/solid_mechanics/test/tests/multi/four_surface14.i)

# Plasticit models:
# SimpleTester0 with a = 0 and b = 1 and strength = 1
# SimpleTester1 with a = 1 and b = 0 and strength = 1
# SimpleTester2 with a = 1 and b = 1 and strength = 3
# SimpleTester3 with a = 0 and b = 1 and strength = 1.1
#
# Lame lambda = 0 (Poisson=0).  Lame mu = 0.5E6
#
# A single element is stretched by 2.1E-6m in y direction and 3E-6 in z direction.
# trial stress_yy = 2.1 and stress_zz = 3.0
#
# This is similar to three_surface14.i, and a description is found there.
# The result should be stress_zz=1=stress_yy, with internal0=2
# and internal1=1.1

[Mesh]
  type = GeneratedMesh
  dim = 3
  nx = 1
  ny = 1
  nz = 1
  xmin = -0.5
  xmax = 0.5
  ymin = -0.5
  ymax = 0.5
  zmin = -0.5
  zmax = 0.5
[]


[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./disp_z]
  [../]
[]

[Kernels]
  [SolidMechanics]
    displacements = 'disp_x disp_y disp_z'
  [../]
[]


[BCs]
  [./x]
    type = FunctionDirichletBC
    variable = disp_x
    boundary = 'front back'
    function = '0E-6*x'
  [../]
  [./y]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = 'front back'
    function = '2.1E-6*y'
  [../]
  [./z]
    type = FunctionDirichletBC
    variable = disp_z
    boundary = 'front back'
    function = '3.0E-6*z'
  [../]
[]

[AuxVariables]
  [./stress_xx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_zz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./f0]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./f1]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./f2]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./f3]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./int0]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./int1]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./int2]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./int3]
    order = CONSTANT
    family = MONOMIAL
  [../]
[]

[AuxKernels]
  [./stress_xx]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xx
    index_i = 0
    index_j = 0
  [../]
  [./stress_xy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xy
    index_i = 0
    index_j = 1
  [../]
  [./stress_xz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xz
    index_i = 0
    index_j = 2
  [../]
  [./stress_yy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yy
    index_i = 1
    index_j = 1
  [../]
  [./stress_yz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yz
    index_i = 1
    index_j = 2
  [../]
  [./stress_zz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_zz
    index_i = 2
    index_j = 2
  [../]
  [./f0]
    type = MaterialStdVectorAux
    property = plastic_yield_function
    index = 0
    variable = f0
  [../]
  [./f1]
    type = MaterialStdVectorAux
    property = plastic_yield_function
    index = 1
    variable = f1
  [../]
  [./f2]
    type = MaterialStdVectorAux
    property = plastic_yield_function
    index = 2
    variable = f2
  [../]
  [./f3]
    type = MaterialStdVectorAux
    property = plastic_yield_function
    index = 3
    variable = f3
  [../]
  [./int0]
    type = MaterialStdVectorAux
    property = plastic_internal_parameter
    factor = 1E6
    index = 0
    variable = int0
  [../]
  [./int1]
    type = MaterialStdVectorAux
    property = plastic_internal_parameter
    factor = 1E6
    index = 1
    variable = int1
  [../]
  [./int2]
    type = MaterialStdVectorAux
    property = plastic_internal_parameter
    factor = 1E6
    index = 2
    variable = int2
  [../]
  [./int3]
    type = MaterialStdVectorAux
    property = plastic_internal_parameter
    factor = 1E6
    index = 3
    variable = int3
  [../]
[]

[Postprocessors]
  [./s_xx]
    type = PointValue
    point = '0 0 0'
    variable = stress_xx
  [../]
  [./s_xy]
    type = PointValue
    point = '0 0 0'
    variable = stress_xy
  [../]
  [./s_xz]
    type = PointValue
    point = '0 0 0'
    variable = stress_xz
  [../]
  [./s_yy]
    type = PointValue
    point = '0 0 0'
    variable = stress_yy
  [../]
  [./s_yz]
    type = PointValue
    point = '0 0 0'
    variable = stress_yz
  [../]
  [./s_zz]
    type = PointValue
    point = '0 0 0'
    variable = stress_zz
  [../]
  [./f0]
    type = PointValue
    point = '0 0 0'
    variable = f0
  [../]
  [./f1]
    type = PointValue
    point = '0 0 0'
    variable = f1
  [../]
  [./f2]
    type = PointValue
    point = '0 0 0'
    variable = f2
  [../]
  [./f3]
    type = PointValue
    point = '0 0 0'
    variable = f3
  [../]
  [./int0]
    type = PointValue
    point = '0 0 0'
    variable = int0
  [../]
  [./int1]
    type = PointValue
    point = '0 0 0'
    variable = int1
  [../]
  [./int2]
    type = PointValue
    point = '0 0 0'
    variable = int2
  [../]
  [./int3]
    type = PointValue
    point = '0 0 0'
    variable = int3
  [../]
[]

[UserObjects]
  [./simple0]
    type = SolidMechanicsPlasticSimpleTester
    a = 0
    b = 1
    strength = 1
    yield_function_tolerance = 1.0E-6
    internal_constraint_tolerance = 1.0E-6
  [../]
  [./simple1]
    type = SolidMechanicsPlasticSimpleTester
    a = 1
    b = 0
    strength = 1
    yield_function_tolerance = 1.0E-6
    internal_constraint_tolerance = 1.0E-6
  [../]
  [./simple2]
    type = SolidMechanicsPlasticSimpleTester
    a = 1
    b = 1
    strength = 3
    yield_function_tolerance = 1.0E-6
    internal_constraint_tolerance = 1.0E-6
  [../]
  [./simple3]
    type = SolidMechanicsPlasticSimpleTester
    a = 0
    b = 1
    strength = 1.1
    yield_function_tolerance = 1.0E-6
    internal_constraint_tolerance = 1.0E-6
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeElasticityTensor
    block = 0
    fill_method = symmetric_isotropic
    C_ijkl = '0 0.5E6'
  [../]
  [./strain]
    type = ComputeFiniteStrain
    block = 0
    displacements = 'disp_x disp_y disp_z'
  [../]
  [./multi]
    type = ComputeMultiPlasticityStress
    block = 0
    ep_plastic_tolerance = 1E-9
    plastic_models = 'simple0 simple1 simple2 simple3'
    max_NR_iterations = 4
    min_stepsize = 1
    debug_fspb = crash
    debug_jac_at_stress = '10 0 0 0 10 0 0 0 10'
    debug_jac_at_pm = '1 1 1'
    debug_jac_at_intnl = '1 1 1'
    debug_stress_change = 1E-5
    debug_pm_change = '1E-6 1E-6 1E-6'
    debug_intnl_change = '1E-6 1E-6 1E-6'
  [../]
[]


[Executioner]
  end_time = 1
  dt = 1
  type = Transient
[]


[Outputs]
  file_base = four_surface14
  exodus = false
  [./csv]
    type = CSV
    [../]
[]

(modules/solid_mechanics/test/tests/ad_elastic/finite_elastic-noad.i)

[Mesh]
  type = GeneratedMesh
  dim = 3
  nx = 3
  ny = 3
  nz = 3
[]

[GlobalParams]
  displacements = 'disp_x disp_y disp_z'
[]

[Variables]
  # scale with one over Young's modulus
  [./disp_x]
    scaling = 1e-10
  [../]
  [./disp_y]
    scaling = 1e-10
  [../]
  [./disp_z]
    scaling = 1e-10
  [../]
[]

[Kernels]
  [./stress_x]
    type = StressDivergenceTensors
    component = 0
    variable = disp_x
    use_displaced_mesh = true
  [../]
  [./stress_y]
    type = StressDivergenceTensors
    component = 1
    variable = disp_y
    use_displaced_mesh = true
  [../]
  [./stress_z]
    type = StressDivergenceTensors
    component = 2
    variable = disp_z
    use_displaced_mesh = true
  [../]
[]

[BCs]
  [./symmy]
    type = DirichletBC
    variable = disp_y
    boundary = bottom
    value = 0
  [../]
  [./symmx]
    type = DirichletBC
    variable = disp_x
    boundary = left
    value = 0
  [../]
  [./symmz]
    type = DirichletBC
    variable = disp_z
    boundary = back
    value = 0
  [../]
  [./tdisp]
    type = DirichletBC
    variable = disp_z
    boundary = front
    value = 0.1
  [../]
[]

[Materials]
  [./elasticity]
    type = ComputeIsotropicElasticityTensor
    poissons_ratio = 0.3
    youngs_modulus = 1e10
  [../]
  [./strain]
    type = ComputeFiniteStrain
  [../]
  [./stress]
    type = ComputeFiniteStrainElasticStress
  [../]
[]

[Preconditioning]
  [./smp]
    type = SMP
    full = true
  [../]
[]

[Executioner]
  type = Transient
  dt = 0.05
  solve_type = 'NEWTON'

  petsc_options_iname = -pc_hypre_type
  petsc_options_value = boomeramg

  dtmin = 0.05
  num_steps = 1
[]

[Outputs]
  exodus = true
  file_base = finite_elastic_out
[]

(modules/solid_mechanics/test/tests/multi/paper1.i)

# This runs the models mentioned in the first example of the Multi-Surface paper
#
# Plasticity models:
# SimpleTester with a = 1 and b = 0 and strength = 1E9  (only does elasticity)
# SimpleTester with a = 1 and b = 0 and strength = 0
# SimpleTester with a = 1 and b = 0 and strength = 1E-3
#
# Lame lambda = 0 (Poisson=0).  Lame mu = 0.5E6
#
# A line of elements is perturbed randomly, and return to the yield surface at each quadpoint is checked

[Mesh]
  type = GeneratedMesh
  dim = 3
  nx = 1
  ny = 125
  nz = 1
  xmin = 0
  xmax = 1
  ymin = 0
  ymax = 125
  zmin = 0
  zmax = 1
[]


[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./disp_z]
  [../]
[]

[Kernels]
  [SolidMechanics]
    displacements = 'disp_x disp_y disp_z'
  [../]
[]


[ICs]
  [./x]
    type = RandomIC
    min = -0.1
    max = 0.1
    variable = disp_x
  [../]
  [./y]
    type = RandomIC
    min = -0.1
    max = 0.1
    variable = disp_y
  [../]
  [./z]
    type = RandomIC
    min = -0.1
    max = 0.1
    variable = disp_z
  [../]
[]

[BCs]
  [./x]
    type = FunctionDirichletBC
    variable = disp_x
    boundary = 'front back'
    function = '0'
  [../]
  [./y]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = 'front back'
    function = '0'
  [../]
  [./z]
    type = FunctionDirichletBC
    variable = disp_z
    boundary = 'front back'
    function = '0'
  [../]
[]

[AuxVariables]
  [./stress_xx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_zz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./linesearch]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./ld]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./constr_added]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./iter]
    order = CONSTANT
    family = MONOMIAL
  [../]
[]

[AuxKernels]
  [./stress_xx]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xx
    index_i = 0
    index_j = 0
  [../]
  [./stress_xy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xy
    index_i = 0
    index_j = 1
  [../]
  [./stress_xz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xz
    index_i = 0
    index_j = 2
  [../]
  [./stress_yy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yy
    index_i = 1
    index_j = 1
  [../]
  [./stress_yz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yz
    index_i = 1
    index_j = 2
  [../]
  [./stress_zz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_zz
    index_i = 2
    index_j = 2
  [../]
  [./linesearch]
    type = MaterialRealAux
    property = plastic_linesearch_needed
    variable = linesearch
  [../]
  [./ld]
    type = MaterialRealAux
    property = plastic_linear_dependence_encountered
    variable = ld
  [../]
  [./constr_added]
    type = MaterialRealAux
    property = plastic_constraints_added
    variable = constr_added
  [../]
  [./iter]
    type = MaterialRealAux
    property = plastic_NR_iterations
    variable = iter
  [../]
[]

[Postprocessors]
  [./max_iter]
    type = ElementExtremeValue
    variable = iter
    outputs = console
  [../]
  [./av_linesearch]
    type = ElementAverageValue
    variable = linesearch
    outputs = console
  [../]
  [./av_ld]
    type = ElementAverageValue
    variable = ld
    outputs = console
  [../]
  [./av_constr_added]
    type = ElementAverageValue
    variable = constr_added
    outputs = console
  [../]
  [./av_iter]
    type = ElementAverageValue
    variable = iter
    outputs = console
  [../]
[]


[UserObjects]
  [./simple0]
    type = SolidMechanicsPlasticSimpleTester
    a = 1
    b = 0
    strength = 1E9
    yield_function_tolerance = 1.0E-6
    internal_constraint_tolerance = 1.0E-6
  [../]
  [./simple1]
    type = SolidMechanicsPlasticSimpleTester
    a = 1
    b = 0
    strength = 0
    yield_function_tolerance = 1.0E-6
    internal_constraint_tolerance = 1.0E-6
  [../]
  [./simple2]
    type = SolidMechanicsPlasticSimpleTester
    a = 1
    b = 0
    strength = 1E-3
    yield_function_tolerance = 1.0E-6
    internal_constraint_tolerance = 1.0E-6
  [../]
[]

[Materials]
  active = 'elasticity_tensor strain single'
  [./elasticity_tensor]
    type = ComputeElasticityTensor
    block = 0
    fill_method = symmetric_isotropic
    C_ijkl = '0 0.5E6'
  [../]
  [./strain]
    type = ComputeFiniteStrain
    block = 0
    displacements = 'disp_x disp_y disp_z'
  [../]
  [./elastic_model]
    type = ComputeMultiPlasticityStress
    block = 0
    ep_plastic_tolerance = 1E-7
    plastic_models = 'simple0'
  [../]
  [./single]
    type = ComputeMultiPlasticityStress
    block = 0
    ep_plastic_tolerance = 1E-7
    plastic_models = 'simple1'
  [../]
  [./double]
    type = ComputeMultiPlasticityStress
    block = 0
    ep_plastic_tolerance = 1E-7
    plastic_models = 'simple1 simple2'
  [../]
[]


[Executioner]
  end_time = 1
  dt = 1
  type = Transient
[]


[Outputs]
  file_base = paper1
  exodus = false
  csv = true
[]

(modules/solid_mechanics/test/tests/auxkernels/principalstress.i)

[Mesh]
  type = GeneratedMesh
  elem_type = HEX8
  dim = 3
  nx = 1
  ny = 1
  nz = 1
  xmin=0.0
  xmax=1.0
  ymin=0.0
  ymax=1.0
  zmin=0.0
  zmax=1.0
  displacements = 'disp_x disp_y disp_z'
[]

[Variables]
  [./disp_x]
    order = FIRST
    family = LAGRANGE
  [../]
  [./disp_y]
    order = FIRST
    family = LAGRANGE
  [../]
  [./disp_z]
    order = FIRST
    family = LAGRANGE
  [../]
[]

[Kernels]
  [SolidMechanics]
    displacements = 'disp_x disp_y disp_z'
  [../]
[]

[Materials]
  [./fplastic]
    type = FiniteStrainPlasticMaterial
    block = 0
    yield_stress='0. 445. 0.05 610. 0.1 680. 0.38 810. 0.95 920. 2. 950.'
  [../]
  [./elasticity_tensor]
    type = ComputeElasticityTensor
    block = 0
    C_ijkl = '2.827e5 1.21e5 1.21e5 2.827e5 1.21e5 2.827e5 0.808e5 0.808e5 0.808e5'
    fill_method = symmetric9
  [../]
  [./strain]
    type = ComputeFiniteStrain
    block = 0
    displacements = 'disp_x disp_y disp_z'
  [../]
[]

[BCs]
  [./left]
    type = DirichletBC
    variable = disp_x
    boundary = left
    value = 0.0
  [../]
  [./bottom]
    type = DirichletBC
    variable = disp_y
    boundary = bottom
    value = 0.0
  [../]
  [./back]
    type = DirichletBC
    variable = disp_z
    boundary = back
    value = 0.0
  [../]
  [./front]
    type = FunctionDirichletBC
    variable = disp_z
    boundary = front
    function = 't'
  [../]
  [./right]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = right
    function = '-0.5*t'
  [../]
[]

[AuxVariables]
  [./stress_zz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_max]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_mid]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_min]
    order = CONSTANT
    family = MONOMIAL
  [../]
[]

[AuxKernels]
  [./stress_zz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_zz
    index_i = 2
    index_j = 2
  [../]
  [./stress_max]
    type = RankTwoScalarAux
    rank_two_tensor = stress
    variable = stress_max
    scalar_type = MaxPrincipal
  [../]
  [./stress_mid]
    type = RankTwoScalarAux
    rank_two_tensor = stress
    variable = stress_mid
    scalar_type = MidPrincipal
  [../]
  [./stress_min]
    type = RankTwoScalarAux
    rank_two_tensor = stress
    variable = stress_min
    scalar_type = MinPrincipal
  [../]
[]

[Postprocessors]
  [./stress_zz]
    type = ElementAverageValue
    variable = stress_zz
  [../]
  [./stress_max]
    type = ElementAverageValue
    variable = stress_max
  [../]
  [./stress_mid]
    type = ElementAverageValue
    variable = stress_mid
  [../]
  [./stress_min]
    type = ElementAverageValue
    variable = stress_min
  [../]
[]

[Executioner]

  type = Transient

  dt=0.1
  dtmin=0.1
  dtmax=1
  end_time=1.0

  #Preconditioned JFNK (default)
  solve_type = 'PJFNK'

  nl_rel_tol = 1e-10
  nl_abs_tol = 1e-10
[]


[Outputs]
  exodus = true
[]

(modules/solid_mechanics/test/tests/mohr_coulomb/small_deform3.i)

# apply repeated stretches in x z directions, and smaller stretches along the y direction,
# so that sigma_I = sigma_II,
# which means that lode angle = 30deg.
# The allows yield surface in meridional plane to be mapped out


[Mesh]
  type = GeneratedMesh
  dim = 3
  nx = 1
  ny = 1
  nz = 1
  xmin = -0.5
  xmax = 0.5
  ymin = -0.5
  ymax = 0.5
  zmin = -0.5
  zmax = 0.5
[]


[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./disp_z]
  [../]
[]

[Kernels]
  [SolidMechanics]
    displacements = 'disp_x disp_y disp_z'
  [../]
[]


[BCs]
  [./x]
    type = FunctionDirichletBC
    variable = disp_x
    boundary = 'front back'
    function = '1E-6*x*t'
  [../]
  [./y]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = 'front back'
    function = '0.25E-6*y*sin(t)'
  [../]
  [./z]
    type = FunctionDirichletBC
    variable = disp_z
    boundary = 'front back'
    function = '1E-6*z*t'
  [../]
[]

[AuxVariables]
  [./stress_xx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_zz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./mc_int]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./yield_fcn]
    order = CONSTANT
    family = MONOMIAL
  [../]
[]

[AuxKernels]
  [./stress_xx]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xx
    index_i = 0
    index_j = 0
  [../]
  [./stress_xy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xy
    index_i = 0
    index_j = 1
  [../]
  [./stress_xz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xz
    index_i = 0
    index_j = 2
  [../]
  [./stress_yy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yy
    index_i = 1
    index_j = 1
  [../]
  [./stress_yz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yz
    index_i = 1
    index_j = 2
  [../]
  [./stress_zz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_zz
    index_i = 2
    index_j = 2
  [../]
  [./mc_int_auxk]
    type = MaterialStdVectorAux
    index = 0
    property = plastic_internal_parameter
    variable = mc_int
  [../]
  [./yield_fcn_auxk]
    type = MaterialStdVectorAux
    index = 0
    property = plastic_yield_function
    variable = yield_fcn
  [../]
[]

[Postprocessors]
  [./s_xx]
    type = PointValue
    point = '0 0 0'
    variable = stress_xx
  [../]
  [./s_xy]
    type = PointValue
    point = '0 0 0'
    variable = stress_xy
  [../]
  [./s_xz]
    type = PointValue
    point = '0 0 0'
    variable = stress_xz
  [../]
  [./s_yy]
    type = PointValue
    point = '0 0 0'
    variable = stress_yy
  [../]
  [./s_yz]
    type = PointValue
    point = '0 0 0'
    variable = stress_yz
  [../]
  [./s_zz]
    type = PointValue
    point = '0 0 0'
    variable = stress_zz
  [../]
  [./internal]
    type = PointValue
    point = '0 0 0'
    variable = mc_int
  [../]
  [./f]
    type = PointValue
    point = '0 0 0'
    variable = yield_fcn
  [../]
[]

[UserObjects]
  [./mc_coh]
    type = SolidMechanicsHardeningConstant
    value = 10
  [../]
  [./mc_phi]
    type = SolidMechanicsHardeningConstant
    value = 50
    convert_to_radians = true
  [../]
  [./mc_psi]
    type = SolidMechanicsHardeningExponential
    value_0 = 0
    value_residual = 0.8726646 # 50deg
    rate = 3000.0
  [../]
  [./mc]
    type = SolidMechanicsPlasticMohrCoulomb
    cohesion = mc_coh
    friction_angle = mc_phi
    dilation_angle = mc_psi
    mc_tip_smoother = 4
    mc_edge_smoother = 20
    yield_function_tolerance = 1E-8
    internal_constraint_tolerance = 1E-9
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeElasticityTensor
    block = 0
    fill_method = symmetric_isotropic
    C_ijkl = '0 1E7'
  [../]
  [./strain]
    type = ComputeFiniteStrain
    block = 0
    displacements = 'disp_x disp_y disp_z'
  [../]
  [./mc]
    type = ComputeMultiPlasticityStress
    block = 0
    ep_plastic_tolerance = 1E-9
    plastic_models = mc
    debug_fspb = crash
  [../]
[]


[Executioner]
  end_time = 30
  dt = 1
  type = Transient
[]


[Outputs]
  file_base = small_deform3
  exodus = false
  [./csv]
    type = CSV
    [../]
[]

(modules/solid_mechanics/test/tests/multi/three_surface07.i)

# Plasticit models:
# SimpleTester0 with a = 0 and b = 1 and strength = 1
# SimpleTester1 with a = 1 and b = 0 and strength = 1
# SimpleTester2 with a = 1 and b = 1 and strength = 1.5
#
# Lame lambda = 0 (Poisson=0).  Lame mu = 0.5E6
#
# A single element is stretched by 1.5E-6m in y direction and 0.8E-6 in z direction.
# trial stress_yy = 1.5 and stress_zz = 0.8
#
# Then SimpleTester1 and SimpleTester2 should activate and the algorithm will return to
# the corner stress_yy=1.0, stress_zz=0.5
# internal1 should be 0.2, and internal2 should be 0.3

[Mesh]
  type = GeneratedMesh
  dim = 3
  nx = 1
  ny = 1
  nz = 1
  xmin = -0.5
  xmax = 0.5
  ymin = -0.5
  ymax = 0.5
  zmin = -0.5
  zmax = 0.5
[]


[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./disp_z]
  [../]
[]

[Kernels]
  [SolidMechanics]
    displacements = 'disp_x disp_y disp_z'
  [../]
[]


[BCs]
  [./x]
    type = FunctionDirichletBC
    variable = disp_x
    boundary = 'front back'
    function = '0E-6*x'
  [../]
  [./y]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = 'front back'
    function = '1.5E-6*y'
  [../]
  [./z]
    type = FunctionDirichletBC
    variable = disp_z
    boundary = 'front back'
    function = '0.8E-6*z'
  [../]
[]

[AuxVariables]
  [./stress_xx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_zz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./f0]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./f1]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./f2]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./int0]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./int1]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./int2]
    order = CONSTANT
    family = MONOMIAL
  [../]
[]

[AuxKernels]
  [./stress_xx]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xx
    index_i = 0
    index_j = 0
  [../]
  [./stress_xy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xy
    index_i = 0
    index_j = 1
  [../]
  [./stress_xz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xz
    index_i = 0
    index_j = 2
  [../]
  [./stress_yy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yy
    index_i = 1
    index_j = 1
  [../]
  [./stress_yz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yz
    index_i = 1
    index_j = 2
  [../]
  [./stress_zz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_zz
    index_i = 2
    index_j = 2
  [../]
  [./f0]
    type = MaterialStdVectorAux
    property = plastic_yield_function
    index = 0
    variable = f0
  [../]
  [./f1]
    type = MaterialStdVectorAux
    property = plastic_yield_function
    index = 1
    variable = f1
  [../]
  [./f2]
    type = MaterialStdVectorAux
    property = plastic_yield_function
    index = 2
    variable = f2
  [../]
  [./int0]
    type = MaterialStdVectorAux
    property = plastic_internal_parameter
    factor = 1E6
    index = 0
    variable = int0
  [../]
  [./int1]
    type = MaterialStdVectorAux
    property = plastic_internal_parameter
    factor = 1E6
    index = 1
    variable = int1
  [../]
  [./int2]
    type = MaterialStdVectorAux
    property = plastic_internal_parameter
    factor = 1E6
    index = 2
    variable = int2
  [../]
[]

[Postprocessors]
  [./s_xx]
    type = PointValue
    point = '0 0 0'
    variable = stress_xx
  [../]
  [./s_xy]
    type = PointValue
    point = '0 0 0'
    variable = stress_xy
  [../]
  [./s_xz]
    type = PointValue
    point = '0 0 0'
    variable = stress_xz
  [../]
  [./s_yy]
    type = PointValue
    point = '0 0 0'
    variable = stress_yy
  [../]
  [./s_yz]
    type = PointValue
    point = '0 0 0'
    variable = stress_yz
  [../]
  [./s_zz]
    type = PointValue
    point = '0 0 0'
    variable = stress_zz
  [../]
  [./f0]
    type = PointValue
    point = '0 0 0'
    variable = f0
  [../]
  [./f1]
    type = PointValue
    point = '0 0 0'
    variable = f1
  [../]
  [./f2]
    type = PointValue
    point = '0 0 0'
    variable = f2
  [../]
  [./int0]
    type = PointValue
    point = '0 0 0'
    variable = int0
  [../]
  [./int1]
    type = PointValue
    point = '0 0 0'
    variable = int1
  [../]
  [./int2]
    type = PointValue
    point = '0 0 0'
    variable = int2
  [../]
[]

[UserObjects]
  [./simple0]
    type = SolidMechanicsPlasticSimpleTester
    a = 0
    b = 1
    strength = 1
    yield_function_tolerance = 1.0E-9
    internal_constraint_tolerance = 1.0E-9
  [../]
  [./simple1]
    type = SolidMechanicsPlasticSimpleTester
    a = 1
    b = 0
    strength = 1
    yield_function_tolerance = 1.0E-9
    internal_constraint_tolerance = 1.0E-9
  [../]
  [./simple2]
    type = SolidMechanicsPlasticSimpleTester
    a = 1
    b = 1
    strength = 1.5
    yield_function_tolerance = 1.0E-9
    internal_constraint_tolerance = 1.0E-9
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeElasticityTensor
    block = 0
    fill_method = symmetric_isotropic
    C_ijkl = '0 0.5E6'
  [../]
  [./strain]
    type = ComputeFiniteStrain
    block = 0
    displacements = 'disp_x disp_y disp_z'
  [../]
  [./multi]
    type = ComputeMultiPlasticityStress
    block = 0
    ep_plastic_tolerance = 1E-9
    plastic_models = 'simple0 simple1 simple2'
    max_NR_iterations = 2
    min_stepsize = 1
    debug_fspb = crash
    debug_jac_at_stress = '10 0 0 0 10 0 0 0 10'
    debug_jac_at_pm = '1 1'
    debug_jac_at_intnl = '1 1'
    debug_stress_change = 1E-5
    debug_pm_change = '1E-6 1E-6'
    debug_intnl_change = '1E-6 1E-6'
  [../]
[]


[Executioner]
  end_time = 1
  dt = 1
  type = Transient
[]


[Outputs]
  file_base = three_surface07
  exodus = false
  [./csv]
    type = CSV
    [../]
[]

(modules/contact/test/tests/verification/hertz_cyl/half_symm_q4/hertz_cyl_half_1deg_template1.i)

[GlobalParams]
  volumetric_locking_correction = true
  displacements = 'disp_x disp_y'
[]

[Mesh]
  file = hertz_cyl_half_1deg.e
[]

[Problem]
  type = ReferenceResidualProblem
  extra_tag_vectors = 'ref'
  reference_vector = 'ref'
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
[]

[AuxVariables]
  [./stress_xx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./saved_x]
  [../]
  [./saved_y]
  [../]
  [./diag_saved_x]
  [../]
  [./diag_saved_y]
  [../]
  [./inc_slip_x]
  [../]
  [./inc_slip_y]
  [../]
  [./accum_slip_x]
  [../]
  [./accum_slip_y]
  [../]
  [./tang_force_x]
  [../]
  [./tang_force_y]
  [../]
[]

[Functions]
  [./disp_ramp_vert]
    type = PiecewiseLinear
    x = '0. 1. 3.5'
    y = '0. -0.0020 -0.0020'
  [../]
  [./disp_ramp_horz]
    type = PiecewiseLinear
    x = '0. 1. 3.5'
    y = '0. 0.0 0.0014'
  [../]
[]

[Kernels]
  [./TensorMechanics]
    use_displaced_mesh = true
    save_in = 'saved_x saved_y'
    extra_vector_tags = 'ref'
  [../]
[]

[AuxKernels]
  [./stress_xx]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xx
    index_i = 0
    index_j = 0
    execute_on = timestep_end
  [../]
  [./stress_yy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yy
    index_i = 1
    index_j = 1
    execute_on = timestep_end
  [../]
  [./stress_xy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xy
    index_i = 0
    index_j = 1
    execute_on = timestep_end
  [../]
  [./inc_slip_x]
    type = PenetrationAux
    variable = inc_slip_x
    execute_on = timestep_end
    boundary = 3
    paired_boundary = 2
  [../]
  [./inc_slip_y]
    type = PenetrationAux
    variable = inc_slip_y
    execute_on = timestep_end
    boundary = 3
    paired_boundary = 2
  [../]
  [./accum_slip_x]
    type = PenetrationAux
    variable = accum_slip_x
    execute_on = timestep_end
    boundary = 3
    paired_boundary = 2
  [../]
  [./accum_slip_y]
    type = PenetrationAux
    variable = accum_slip_y
    execute_on = timestep_end
    boundary = 3
    paired_boundary = 2
  [../]
  [./tang_force_x]
    type = PenetrationAux
    variable = tang_force_x
    quantity = tangential_force_x
    boundary = 3
    paired_boundary = 2
  [../]
  [./tang_force_y]
    type = PenetrationAux
    variable = tang_force_y
    quantity = tangential_force_y
    boundary = 3
    paired_boundary = 2
  [../]
  [./penetration]
    type = PenetrationAux
    variable = penetration
    boundary = 3
    paired_boundary = 2
  [../]
[]

[Postprocessors]
  [./bot_react_x]
    type = NodalSum
    variable = saved_x
    boundary = 1
  [../]
  [./bot_react_y]
    type = NodalSum
    variable = saved_y
    boundary = 1
  [../]
  [./top_react_x]
    type = NodalSum
    variable = saved_x
    boundary = 4
  [../]
  [./top_react_y]
    type = NodalSum
    variable = saved_y
    boundary = 4
  [../]
  [./disp_x226]
    type = NodalVariableValue
    nodeid = 225
    variable = disp_x
  [../]
  [./disp_y226]
    type = NodalVariableValue
    nodeid = 225
    variable = disp_y
  [../]
  [./_dt]
    type = TimestepSize
  [../]
  [./num_lin_it]
    type = NumLinearIterations
  [../]
  [./num_nonlin_it]
    type = NumNonlinearIterations
  [../]
[]

[BCs]
  [./side_x]
    type = DirichletBC
    variable = disp_y
    boundary = '1 2'
    value = 0.0
  [../]
  [./bot_y]
    type = DirichletBC
    variable = disp_x
    boundary = '1 2'
    value = 0.0
  [../]
  [./top_y_disp]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = 4
    function = disp_ramp_vert
  [../]
  [./top_x_disp]
    type = FunctionDirichletBC
    variable = disp_x
    boundary = 4
    function = disp_ramp_horz
  [../]
[]

[Materials]
  [./stuff1_elas_tens]
    type = ComputeIsotropicElasticityTensor
    block = '1'
    youngs_modulus = 1e10
    poissons_ratio = 0.0
  [../]
  [./stuff1_strain]
    type = ComputeFiniteStrain
    block = '1'
  [../]
  [./stuff1_stress]
    type = ComputeFiniteStrainElasticStress
    block = '1'
  [../]
  [./stuff2_elas_tens]
    type = ComputeIsotropicElasticityTensor
    block = '2'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./stuff2_strain]
    type = ComputeFiniteStrain
    block = '2'
  [../]
  [./stuff2_stress]
    type = ComputeFiniteStrainElasticStress
    block = '2'
  [../]
  [./stuff3_elas_tens]
    type = ComputeIsotropicElasticityTensor
    block = '3'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./stuff3_strain]
    type = ComputeFiniteStrain
    block = '3'
  [../]
  [./stuff3_stress]
    type = ComputeFiniteStrainElasticStress
    block = '3'
  [../]
  [./stuff4_elas_tens]
    type = ComputeIsotropicElasticityTensor
    block = '4'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./stuff4_strain]
    type = ComputeFiniteStrain
    block = '4'
  [../]
  [./stuff4_stress]
    type = ComputeFiniteStrainElasticStress
    block = '4'
  [../]
  [./stuff5_elas_tens]
    type = ComputeIsotropicElasticityTensor
    block = '5'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./stuff5_strain]
    type = ComputeFiniteStrain
    block = '5'
  [../]
  [./stuff5_stress]
    type = ComputeFiniteStrainElasticStress
    block = '5'
  [../]
  [./stuff6_elas_tens]
    type = ComputeIsotropicElasticityTensor
    block = '6'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./stuff6_strain]
    type = ComputeFiniteStrain
    block = '6'
  [../]
  [./stuff6_stress]
    type = ComputeFiniteStrainElasticStress
    block = '6'
  [../]
  [./stuff7_elas_tens]
    type = ComputeIsotropicElasticityTensor
    block = '7'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./stuff7_strain]
    type = ComputeFiniteStrain
    block = '7'
  [../]
  [./stuff7_stress]
    type = ComputeFiniteStrainElasticStress
    block = '7'
  [../]
[]

[Executioner]
  type = Transient

  #Preconditioned JFNK (default)
  solve_type = 'PJFNK'

  petsc_options_iname = '-pc_type -pc_factor_mat_solver_type'
  petsc_options_value = 'lu     superlu_dist'

  line_search = 'none'

  nl_abs_tol = 1e-6
  nl_rel_tol = 1e-5
  l_max_its = 100
  nl_max_its = 200

  start_time = 0.0
  end_time = 3.5
  l_tol = 1e-3
  dt = 0.1
  dtmin = 0.1
[]

[Preconditioning]
  [./SMP]
    type = SMP
    full = true
  [../]
[]

[VectorPostprocessors]
  [./x_disp]
    type = NodalValueSampler
    variable = disp_x
    boundary = '3 4'
    sort_by = id
  [../]
  [./y_disp]
    type = NodalValueSampler
    variable = disp_y
    boundary = '3 4'
    sort_by = id
  [../]
  [./cont_press]
    type = NodalValueSampler
    variable = contact_pressure
    boundary = '3'
    sort_by = id
  [../]
[]

[Outputs]
  print_linear_residuals = true
  perf_graph = true
  [./exodus]
    type = Exodus
    elemental_as_nodal = true
  [../]
  [./console]
    type = Console
    max_rows = 5
  [../]
  [./chkfile]
    type = CSV
    show = 'x_disp y_disp cont_press'
    start_time = 0.9
    execute_vector_postprocessors_on = timestep_end
  [../]
  [./chkfile2]
    type = CSV
    show = 'bot_react_x bot_react_y disp_x226 disp_y226 top_react_x top_react_y'
    start_time = 0.9
    execute_vector_postprocessors_on = timestep_end
  [../]
  [./outfile]
    type = CSV
    delimiter = ' '
    execute_vector_postprocessors_on = none
  [../]
[]

[Contact]
  [./interface]
    primary = 2
    secondary = 3
    normalize_penalty = true
    tangential_tolerance = 1e-3
    penalty = 1e+10
  [../]
[]

(modules/solid_mechanics/test/tests/crystal_plasticity/user_object_based/patch_recovery.i)

[Mesh]
  type = GeneratedMesh
  dim = 2
  nx = 2
  ny = 2
  displacements = 'ux uy'
[]

[Variables]
  [ux]
  []
  [uy]
  []
[]

[AuxVariables]
  [stress_xx_recovered]
    order = FIRST
    family = LAGRANGE
  []
  [stress_yy_recovered]
    order = FIRST
    family = LAGRANGE
  []
[]

[Functions]
  [tdisp]
    type = ParsedFunction
    expression = 0.01*t
  []
[]

[Kernels]
  [SolidMechanics]
    displacements = 'ux uy'
    use_displaced_mesh = true
  []
[]

[AuxKernels]
  [stress_xx_recovered]
    type = NodalPatchRecoveryAux
    variable = stress_xx_recovered
    nodal_patch_recovery_uo = stress_xx_patch
    execute_on = 'TIMESTEP_END'
  []
  [stress_yy_recovered]
    type = NodalPatchRecoveryAux
    variable = stress_yy_recovered
    nodal_patch_recovery_uo = stress_yy_patch
    execute_on = 'TIMESTEP_END'
  []
[]

[BCs]
  [symmy]
    type = DirichletBC
    variable = uy
    boundary = bottom
    value = 0
  []
  [symmx]
    type = DirichletBC
    variable = ux
    boundary = left
    value = 0
  []
  [tdisp]
    type = FunctionDirichletBC
    variable = uy
    boundary = top
    function = tdisp
  []
[]

[UserObjects]
  [slip_rate_gss]
    type = CrystalPlasticitySlipRateGSS
    variable_size = 12
    slip_sys_file_name = input_slip_sys.txt
    num_slip_sys_flowrate_props = 2
    flowprops = '1 4 0.001 0.1 5 8 0.001 0.1 9 12 0.001 0.1'
    uo_state_var_name = state_var_gss
  []
  [slip_resistance_gss]
    type = CrystalPlasticitySlipResistanceGSS
    variable_size = 12
    uo_state_var_name = state_var_gss
  []
  [state_var_gss]
    type = CrystalPlasticityStateVariable
    variable_size = 12
    groups = '0 4 8 12'
    group_values = '60.8 60.8 60.8'
    uo_state_var_evol_rate_comp_name = state_var_evol_rate_comp_gss
    scale_factor = 1.0
  []
  [state_var_evol_rate_comp_gss]
    type = CrystalPlasticityStateVarRateComponentGSS
    variable_size = 12
    hprops = '1.0 541.5 109.8 2.5'
    uo_slip_rate_name = slip_rate_gss
    uo_state_var_name = state_var_gss
  []
  [stress_xx_patch]
    type = NodalPatchRecoveryMaterialProperty
    patch_polynomial_order = FIRST
    property = 'stress'
    component = '0 0'
    execute_on = 'TIMESTEP_END'
  []
  [stress_yy_patch]
    type = NodalPatchRecoveryMaterialProperty
    patch_polynomial_order = FIRST
    property = 'stress'
    component = '1 1'
    execute_on = 'TIMESTEP_END'
  []
[]

[Materials]
  [crysp]
    type = FiniteStrainUObasedCP
    stol = 1e-2
    tan_mod_type = exact
    uo_slip_rates = 'slip_rate_gss'
    uo_slip_resistances = 'slip_resistance_gss'
    uo_state_vars = 'state_var_gss'
    uo_state_var_evol_rate_comps = 'state_var_evol_rate_comp_gss'
  []
  [strain]
    type = ComputeFiniteStrain
    displacements = 'ux uy'
  []
  [elasticity_tensor]
    type = ComputeElasticityTensorCP
    C_ijkl = '1.684e5 1.214e5 1.214e5 1.684e5 1.214e5 1.684e5 0.754e5 0.754e5 0.754e5'
    fill_method = symmetric9
  []
[]

[Preconditioning]
  [smp]
    type = SMP
    full = true
  []
[]

[Executioner]
  type = Transient
  dt = 0.05
  solve_type = 'PJFNK'

  petsc_options_iname = -pc_hypre_type
  petsc_options_value = boomerang
  nl_abs_tol = 1e-10
  nl_rel_step_tol = 1e-10
  dtmax = 10.0
  nl_rel_tol = 1e-10
  end_time = 1
  dtmin = 0.05
  num_steps = 10
  nl_abs_step_tol = 1e-10
[]

[Outputs]
  exodus = true
[]

(modules/solid_mechanics/test/tests/volumetric_deform_grad/elastic_stress.i)

[Mesh]
  type = GeneratedMesh
  dim = 3
  elem_type = HEX8
  displacements = 'disp_x disp_y disp_z'
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./disp_z]
  [../]
[]

[Kernels]
  [SolidMechanics]
    displacements = 'disp_x disp_y disp_z'
    use_displaced_mesh = true
  [../]
[]

[AuxVariables]
  [./stress_zz]
    order = CONSTANT
    family = MONOMIAL
    block = 0
  [../]
[]

[AuxKernels]
  [./stress_zz]
    type = RankTwoAux
    variable = stress_zz
    rank_two_tensor = stress
    index_j = 2
    index_i = 2
    execute_on = timestep_end
    block = 0
  [../]
[]

[BCs]
  [./symmy]
    type = DirichletBC
    variable = disp_y
    boundary = bottom
    value = 0
  [../]
  [./symmx]
    type = DirichletBC
    variable = disp_x
    boundary = left
    value = 0
  [../]
  [./symmz]
    type = DirichletBC
    variable = disp_z
    boundary = back
    value = 0
  [../]
  [./tdisp]
    type = FunctionDirichletBC
    variable = disp_z
    boundary = front
    function = '0.01*t'
  [../]
[]

[Materials]
  [./strain]
    type = ComputeFiniteStrain
    block = 0
    displacements = 'disp_x disp_y disp_z'
  [../]
  [./elastic_stress]
    type = ComputeDeformGradBasedStress
    deform_grad_name = deformation_gradient
    elasticity_tensor_name = elasticity_tensor
    stress_name = stress
    jacobian_name = Jacobian_mult
    block = 0
  [../]
  [./elasticity_tensor]
    type = ComputeElasticityTensor
    block = 0
    C_ijkl = '2.8e5 1.2e5 1.2e5 2.8e5 1.2e5 2.8e5 0.8e5 0.8e5 0.8e5'
    fill_method = symmetric9
  [../]
[]

[Postprocessors]
  [./stress_zz]
    type = ElementAverageValue
    variable = stress_zz
    block = 'ANY_BLOCK_ID 0'
  [../]
[]

[Preconditioning]
  [./smp]
    type = SMP
    full = true
  [../]
[]

[Executioner]
  type = Transient
  dt = 0.02
  #Preconditioned JFNK (default)
  solve_type = 'PJFNK'
  petsc_options_iname = '-pc_type -pc_hypre_type -ksp_gmres_restart'
  petsc_options_value = 'hypre boomeramg 101'
  dtmax = 10.0
  nl_rel_tol = 1e-10
  dtmin = 0.02
  num_steps = 10
[]

[Outputs]
  csv = true
[]

(modules/solid_mechanics/test/tests/crystal_plasticity/user_object_based/save_euler.i)

[Mesh]
  type = GeneratedMesh
  dim = 2
  elem_type = QUAD4
  displacements = 'disp_x disp_y'
  nx = 2
  ny = 2
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
[]

[GlobalParams]
  volumetric_locking_correction = true
[]

[AuxVariables]
  [./stress_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./e_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./fp_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./gss]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./euler1]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./euler2]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./euler3]
    order = CONSTANT
    family = MONOMIAL
  [../]
[]

[Functions]
  [./tdisp]
    type = ParsedFunction
    expression = 0.01*t
  [../]
[]

[UserObjects]
  [./prop_read]
    type = PropertyReadFile
    prop_file_name = 'euler_ang_file.txt'
    # Enter file data as prop#1, prop#2, .., prop#nprop
    nprop = 3
    read_type = element
  [../]
[]

[AuxKernels]
  [./stress_yy]
    type = RankTwoAux
    variable = stress_yy
    rank_two_tensor = stress
    index_j = 1
    index_i = 1
    execute_on = timestep_end
  [../]
  [./e_yy]
    type = RankTwoAux
    variable = e_yy
    rank_two_tensor = lage
    index_j = 1
    index_i = 1
    execute_on = timestep_end
  [../]
  [./fp_yy]
    type = RankTwoAux
    variable = fp_yy
    rank_two_tensor = fp
    index_j = 1
    index_i = 1
    execute_on = timestep_end
  [../]
  [./gss]
    type = MaterialStdVectorAux
    variable = gss
    property = state_var_gss
    index = 0
    execute_on = timestep_end
  [../]
  [./euler1]
    type = MaterialRealVectorValueAux
    variable = euler1
    property = Euler_angles
    component = 0
    execute_on = timestep_end
  [../]
  [./euler2]
    type = MaterialRealVectorValueAux
    variable = euler2
    property = Euler_angles
    component = 1
    execute_on = timestep_end
  [../]
  [./euler3]
    type = MaterialRealVectorValueAux
    variable = euler3
    property = Euler_angles
    component = 2
    execute_on = timestep_end
  [../]
[]

[BCs]
  [./fix_x]
    type = DirichletBC
    variable = disp_x
    boundary = 'left'
    value = 0
  [../]
  [./fix_y]
    type = DirichletBC
    variable = disp_y
    boundary = 'bottom'
    value = 0
  [../]
  [./tdisp]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = top
    function = tdisp
  [../]
[]

[UserObjects]
  [./slip_rate_gss]
    type = CrystalPlasticitySlipRateGSS
    variable_size = 12
    slip_sys_file_name = input_slip_sys.txt
    num_slip_sys_flowrate_props = 2
    flowprops = '1 4 0.001 0.1 5 8 0.001 0.1 9 12 0.001 0.1'
    uo_state_var_name = state_var_gss
  [../]
  [./slip_resistance_gss]
    type = CrystalPlasticitySlipResistanceGSS
    variable_size = 12
    uo_state_var_name = state_var_gss
  [../]
  [./state_var_gss]
    type = CrystalPlasticityStateVariable
    variable_size = 12
    groups = '0 4 8 12'
    group_values = '60.8 60.8 60.8'
    uo_state_var_evol_rate_comp_name = state_var_evol_rate_comp_gss
    scale_factor = 1.0
  [../]
  [./state_var_evol_rate_comp_gss]
    type = CrystalPlasticityStateVarRateComponentGSS
    variable_size = 12
    hprops = '1.0 541.5 109.8 2.5'
    uo_slip_rate_name = slip_rate_gss
    uo_state_var_name = state_var_gss
  [../]
[]

[Materials]
  [./crysp]
    type = FiniteStrainUObasedCP
    stol = 1e-2
    tan_mod_type = exact
    uo_slip_rates = 'slip_rate_gss'
    uo_slip_resistances = 'slip_resistance_gss'
    uo_state_vars = 'state_var_gss'
    uo_state_var_evol_rate_comps = 'state_var_evol_rate_comp_gss'
  [../]
  [./strain]
    type = ComputeFiniteStrain
    displacements = 'disp_x disp_y'
  [../]
  [./elasticity_tensor]
    type = ComputeElasticityTensorCP
    C_ijkl = '1.684e5 1.214e5 1.214e5 1.684e5 1.214e5 1.684e5 0.754e5 0.754e5 0.754e5'
    fill_method = symmetric9
    read_prop_user_object = prop_read
  [../]
[]

[Postprocessors]
  [./stress_yy]
    type = ElementAverageValue
    variable = stress_yy
  [../]
  [./e_yy]
    type = ElementAverageValue
    variable = e_yy
  [../]
  [./fp_yy]
    type = ElementAverageValue
    variable = fp_yy
  [../]
  [./gss]
    type = ElementAverageValue
    variable = gss
  [../]
[]

[Preconditioning]
  [./smp]
    type = SMP
    full = true
  [../]
[]

[Executioner]
  type = Transient
  dt = 0.01
  solve_type = 'PJFNK'

  petsc_options_iname = -pc_hypre_type
  petsc_options_value = boomerang
  nl_abs_tol = 1e-10
  nl_rel_step_tol = 1e-10
  dtmax = 10.0
  nl_rel_tol = 1e-10
  end_time = 1
  dtmin = 0.01
  num_steps = 10
  nl_abs_step_tol = 1e-10
[]

[Outputs]
  exodus = true
[]

[Kernels]
  [SolidMechanics]
    displacements = 'disp_x disp_y'
    use_displaced_mesh = true
  [../]
[]

(modules/solid_mechanics/test/tests/action/custom_output.i)

[GlobalParams]
  displacements = 'disp_x disp_y disp_z'
[]

[Mesh]
  [ring]
    type = GeneratedMeshGenerator
    dim = 3
  []
[]

[BCs]
  [fix_x1]
    type = DirichletBC
    boundary = left
    variable = disp_x
    value = 0
  []
  [fix_x2]
    type = FunctionDirichletBC
    boundary = right
    variable = disp_x
    function = 0.1*sin(t)
  []
  [fix_y]
    type = DirichletBC
    boundary = 'left right'
    variable = disp_y
    value = 0
  []
  [fix_z]
    type = DirichletBC
    boundary = 'left right'
    variable = disp_z
    value = 0
  []
[]

[Physics/SolidMechanics/QuasiStatic]
  [all]
    add_variables = true
    strain = FINITE
    generate_output = 'vonmises_stress effective_alt_total_strain'
  []
[]

[Materials]
  [stress]
    type = ComputeFiniteStrainElasticStress
  []
  [elastic]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 0.3
    shear_modulus = 100
  []
  [alt_strain]
    type = ComputeFiniteStrain
    base_name = alt
  []
[]

[Executioner]
  type = Transient
  num_steps = 12
  solve_type = PJFNK
[]

[Outputs]
  exodus = true
  print_linear_residuals = false
  perf_graph = true
[]

(modules/solid_mechanics/test/tests/multi/three_surface08.i)

# Plasticit models:
# SimpleTester0 with a = 0 and b = 1 and strength = 1
# SimpleTester1 with a = 1 and b = 0 and strength = 1
# SimpleTester2 with a = 1 and b = 1 and strength = 1.5
#
# Lame lambda = 0 (Poisson=0).  Lame mu = 0.5E6
#
# A single element is stretched by 2.0E-6m in y direction and 0.5E-6 in z direction.
# trial stress_yy = 2.0 and stress_zz = 0.5
#
# Then SimpleTester1 and SimpleTester2 should activate and the algorithm will return to
# the corner stress_yy=1.0, stress_zz=0.5
# internal1 should be 1.0, and internal2 should be 0

[Mesh]
  type = GeneratedMesh
  dim = 3
  nx = 1
  ny = 1
  nz = 1
  xmin = -0.5
  xmax = 0.5
  ymin = -0.5
  ymax = 0.5
  zmin = -0.5
  zmax = 0.5
[]


[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./disp_z]
  [../]
[]

[Kernels]
  [SolidMechanics]
    displacements = 'disp_x disp_y disp_z'
  [../]
[]


[BCs]
  [./x]
    type = FunctionDirichletBC
    variable = disp_x
    boundary = 'front back'
    function = '0E-6*x'
  [../]
  [./y]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = 'front back'
    function = '2.0E-6*y'
  [../]
  [./z]
    type = FunctionDirichletBC
    variable = disp_z
    boundary = 'front back'
    function = '0.5E-6*z'
  [../]
[]

[AuxVariables]
  [./stress_xx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_zz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./f0]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./f1]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./f2]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./int0]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./int1]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./int2]
    order = CONSTANT
    family = MONOMIAL
  [../]
[]

[AuxKernels]
  [./stress_xx]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xx
    index_i = 0
    index_j = 0
  [../]
  [./stress_xy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xy
    index_i = 0
    index_j = 1
  [../]
  [./stress_xz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xz
    index_i = 0
    index_j = 2
  [../]
  [./stress_yy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yy
    index_i = 1
    index_j = 1
  [../]
  [./stress_yz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yz
    index_i = 1
    index_j = 2
  [../]
  [./stress_zz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_zz
    index_i = 2
    index_j = 2
  [../]
  [./f0]
    type = MaterialStdVectorAux
    property = plastic_yield_function
    index = 0
    variable = f0
  [../]
  [./f1]
    type = MaterialStdVectorAux
    property = plastic_yield_function
    index = 1
    variable = f1
  [../]
  [./f2]
    type = MaterialStdVectorAux
    property = plastic_yield_function
    index = 2
    variable = f2
  [../]
  [./int0]
    type = MaterialStdVectorAux
    property = plastic_internal_parameter
    factor = 1E6
    index = 0
    variable = int0
  [../]
  [./int1]
    type = MaterialStdVectorAux
    property = plastic_internal_parameter
    factor = 1E6
    index = 1
    variable = int1
  [../]
  [./int2]
    type = MaterialStdVectorAux
    property = plastic_internal_parameter
    factor = 1E6
    index = 2
    variable = int2
  [../]
[]

[Postprocessors]
  [./s_xx]
    type = PointValue
    point = '0 0 0'
    variable = stress_xx
  [../]
  [./s_xy]
    type = PointValue
    point = '0 0 0'
    variable = stress_xy
  [../]
  [./s_xz]
    type = PointValue
    point = '0 0 0'
    variable = stress_xz
  [../]
  [./s_yy]
    type = PointValue
    point = '0 0 0'
    variable = stress_yy
  [../]
  [./s_yz]
    type = PointValue
    point = '0 0 0'
    variable = stress_yz
  [../]
  [./s_zz]
    type = PointValue
    point = '0 0 0'
    variable = stress_zz
  [../]
  [./f0]
    type = PointValue
    point = '0 0 0'
    variable = f0
  [../]
  [./f1]
    type = PointValue
    point = '0 0 0'
    variable = f1
  [../]
  [./f2]
    type = PointValue
    point = '0 0 0'
    variable = f2
  [../]
  [./int0]
    type = PointValue
    point = '0 0 0'
    variable = int0
  [../]
  [./int1]
    type = PointValue
    point = '0 0 0'
    variable = int1
  [../]
  [./int2]
    type = PointValue
    point = '0 0 0'
    variable = int2
  [../]
[]

[UserObjects]
  [./simple0]
    type = SolidMechanicsPlasticSimpleTester
    a = 0
    b = 1
    strength = 1
    yield_function_tolerance = 1.0E-9
    internal_constraint_tolerance = 1.0E-9
  [../]
  [./simple1]
    type = SolidMechanicsPlasticSimpleTester
    a = 1
    b = 0
    strength = 1
    yield_function_tolerance = 1.0E-9
    internal_constraint_tolerance = 1.0E-9
  [../]
  [./simple2]
    type = SolidMechanicsPlasticSimpleTester
    a = 1
    b = 1
    strength = 1.5
    yield_function_tolerance = 1.0E-9
    internal_constraint_tolerance = 1.0E-9
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeElasticityTensor
    block = 0
    fill_method = symmetric_isotropic
    C_ijkl = '0 0.5E6'
  [../]
  [./strain]
    type = ComputeFiniteStrain
    block = 0
    displacements = 'disp_x disp_y disp_z'
  [../]
  [./multi]
    type = ComputeMultiPlasticityStress
    block = 0
    ep_plastic_tolerance = 1E-9
    plastic_models = 'simple0 simple1 simple2'
    max_NR_iterations = 2
    min_stepsize = 1
    debug_fspb = crash
    debug_jac_at_stress = '10 0 0 0 10 0 0 0 10'
    debug_jac_at_pm = '1 1'
    debug_jac_at_intnl = '1 1'
    debug_stress_change = 1E-5
    debug_pm_change = '1E-6 1E-6'
    debug_intnl_change = '1E-6 1E-6'
  [../]
[]


[Executioner]
  end_time = 1
  dt = 1
  type = Transient
[]


[Outputs]
  file_base = three_surface08
  exodus = false
  [./csv]
    type = CSV
    [../]
[]

(modules/contact/test/tests/mortar_dynamics/block-dynamics-reference.i)

starting_point = 2e-1
offset = -0.19

[GlobalParams]
  displacements = 'disp_x disp_y'
[]

[Mesh]
  file = long-bottom-block-1elem-blocks.e
[]

[Variables]
  [disp_x]
    block = '1 2'
  []
  [disp_y]
    block = '1 2'
  []
  [normal_lm]
    block = 3
    use_dual = true
  []
[]

[ICs]
  [disp_y]
    block = 2
    variable = disp_y
    value = '${fparse starting_point + offset}'
    type = ConstantIC
  []
[]

[Kernels]
  [DynamicTensorMechanics]
    displacements = 'disp_x disp_y'
    generate_output = 'stress_xx stress_yy'
    strain = FINITE
    block = '1 2'
    zeta = 1.0
    alpha = 0.0
  []
  [inertia_x]
    type = InertialForce
    variable = disp_x
    velocity = vel_x
    acceleration = accel_x
    beta = 0.25
    gamma = 0.5
    alpha = 0
    eta = 0.0
    block = '1 2'
  []
  [inertia_y]
    type = InertialForce
    variable = disp_y
    velocity = vel_y
    acceleration = accel_y
    beta = 0.25
    gamma = 0.5
    alpha = 0
    eta = 0.0
    block = '1 2'
  []
[]

[Materials]
  [elasticity_2]
    type = ComputeIsotropicElasticityTensor
    block = '2'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  []
  [elasticity_1]
    type = ComputeIsotropicElasticityTensor
    block = '1'
    youngs_modulus = 1e8
    poissons_ratio = 0.3
  []
  [stress]
    type = ComputeFiniteStrainElasticStress
    block = '1 2'
  []
  [strain]
    type = ComputeFiniteStrain
    block = '1 2'
  []
  [density]
    type = GenericConstantMaterial
    block = '1 2'
    prop_names = 'density'
    prop_values = '7750'
  []
[]

[AuxVariables]
  [vel_x]
    block = '1 2'
  []
  [accel_x]
    block = '1 2'
  []
  [vel_y]
    block = '1 2'
  []
  [accel_y]
    block = '1 2'
  []
  [vel_z]
    block = '1 2'
  []
  [accel_z]
    block = '1 2'
  []
  [kinetic_energy]
    order = CONSTANT
    family = MONOMIAL
  []
  [elastic_energy]
    order = CONSTANT
    family = MONOMIAL
  []
[]

[AuxKernels]
  [accel_x]
    type = NewmarkAccelAux
    variable = accel_x
    displacement = disp_x
    velocity = vel_x
    beta = 0.25
    execute_on = 'timestep_end'
  []
  [vel_x]
    type = NewmarkVelAux
    variable = vel_x
    acceleration = accel_x
    gamma = 0.5
    execute_on = 'timestep_end'
  []
  [accel_y]
    type = NewmarkAccelAux
    variable = accel_y
    displacement = disp_y
    velocity = vel_y
    beta = 0.25
    execute_on = 'timestep_end'
  []
  [vel_y]
    type = NewmarkVelAux
    variable = vel_y
    acceleration = accel_y
    gamma = 0.5
    execute_on = 'timestep_end'
  []
  [kinetic_energy]
    type = KineticEnergyAux
    block = '1 2'
    variable = kinetic_energy
    newmark_velocity_x = vel_x
    newmark_velocity_y = vel_y
    newmark_velocity_z = 0.0
    density = density
  []
  [elastic_energy]
    type = ElasticEnergyAux
    variable = elastic_energy
    block = '1 2'
  []
[]


# User object provides the contact force (e.g. LM)
# for the application of the generalized force
[UserObjects]
  [weighted_gap_uo]
    type = LMWeightedGapUserObject
    primary_boundary = 20
    secondary_boundary = 10
    primary_subdomain = 4
    secondary_subdomain = 3
    lm_variable = normal_lm
    disp_x = disp_x
    disp_y = disp_y
  []
[]


[Constraints]
  # Not using 'dynamic' constraints results in poor enforcement of contact
  # constraints and lack of kinetic and elastic energy conservation.
  [weighted_gap_lm]
    type = ComputeDynamicWeightedGapLMMechanicalContact
    primary_boundary = 20
    secondary_boundary = 10
    primary_subdomain = 4
    secondary_subdomain = 3
    variable = normal_lm
    disp_x = disp_x
    disp_y = disp_y
    newmark_beta = 0.25
    newmark_gamma = 0.5
    use_displaced_mesh = true
    # Capture tolerance is important. If too small, stabilization takes longer
    capture_tolerance = 1.0e-5
    c = 1.0e6
  []

  [normal_x]
    type = NormalMortarMechanicalContact
    primary_boundary = 20
    secondary_boundary = 10
    primary_subdomain = 4
    secondary_subdomain = 3
    variable = normal_lm
    secondary_variable = disp_x
    component = x
    use_displaced_mesh = true
    compute_lm_residuals = false
    weighted_gap_uo = weighted_gap_uo
  []
  [normal_y]
    type = NormalMortarMechanicalContact
    primary_boundary = 20
    secondary_boundary = 10
    primary_subdomain = 4
    secondary_subdomain = 3
    variable = normal_lm
    secondary_variable = disp_y
    component = y
    use_displaced_mesh = true
    compute_lm_residuals = false
    weighted_gap_uo = weighted_gap_uo
  []
[]

[BCs]
  [botx]
    type = DirichletBC
    variable = disp_x
    boundary = 40
    value = 0.0
  []
  [boty]
    type = DirichletBC
    variable = disp_y
    boundary = 40
    value = 0.0
  []
  [topy]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = 30
    function = '${starting_point} * cos(2 * pi / 4 * t) + ${offset}'
  []
  [leftx]
    type = FunctionDirichletBC
    variable = disp_x
    boundary = 30 # 50
    function = '0' # '1e-2*t'
  []
[]

[Executioner]
  type = Transient
  end_time = 0.275 # 8.0
  dt = 0.025
  dtmin = .025
  solve_type = 'NEWTON'
  petsc_options = '-snes_converged_reason -ksp_converged_reason -snes_linesearch_monitor'
  petsc_options_iname = '-pc_type -pc_factor_shift_type -pc_factor_shift_amount'
  petsc_options_value = 'lu       NONZERO               1e-15'
  nl_max_its = 50
  line_search = 'none'
  [TimeIntegrator]
    type = NewmarkBeta
    beta = 0.25
    gamma = 0.5
  []
[]

[Debug]
  show_var_residual_norms = true
[]

[Outputs]
  exodus = true
  checkpoint = true
  csv = true
[]

[Postprocessors]
  active = 'contact total_kinetic_energy total_elastic_energy'
  [num_nl]
    type = NumNonlinearIterations
  []
  [cumulative]
    type = CumulativeValuePostprocessor
    postprocessor = num_nl
  []
  [contact]
    type = ContactDOFSetSize
    variable = normal_lm
    subdomain = '3'
    execute_on = 'nonlinear timestep_end'
  []
  [total_kinetic_energy]
    type = ElementIntegralVariablePostprocessor
    variable = kinetic_energy
    block = '1 2'
  []
  [total_elastic_energy]
    type = ElementIntegralVariablePostprocessor
    variable = elastic_energy
    block = '1 2'
  []
[]

(modules/solid_mechanics/test/tests/crystal_plasticity/user_object_based/fileread.i)

[Mesh]
  type = GeneratedMesh
  dim = 3
  elem_type = HEX8
  displacements = 'ux uy uz'
[]

[Variables]
  [./ux]
  [../]
  [./uy]
  [../]
  [./uz]
  [../]
[]

[AuxVariables]
  [./stress_zz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./fp_zz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./rotout]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./e_zz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./gss]
    order = CONSTANT
    family = MONOMIAL
  [../]
[]

[Functions]
  [./tdisp]
    type = ParsedFunction
    expression = 0.01*t
  [../]
[]

[Kernels]
  [SolidMechanics]
    displacements = 'ux uy uz'
    use_displaced_mesh = true
  [../]
[]

[AuxKernels]
  [./stress_zz]
    type = RankTwoAux
    variable = stress_zz
    rank_two_tensor = stress
    index_j = 2
    index_i = 2
    execute_on = timestep_end
  [../]
  [./fp_zz]
    type = RankTwoAux
    variable = fp_zz
    rank_two_tensor = fp
    index_j = 2
    index_i = 2
    execute_on = timestep_end
  [../]
  [./e_zz]
    type = RankTwoAux
    variable = e_zz
    rank_two_tensor = lage
    index_j = 2
    index_i = 2
    execute_on = timestep_end
  [../]
  [./gss]
    type = MaterialStdVectorAux
    variable = gss
    property = state_var_gss
    index = 0
    execute_on = timestep_end
  [../]
[]

[BCs]
  [./symmy]
    type = DirichletBC
    variable = uy
    boundary = bottom
    value = 0
  [../]
  [./symmx]
    type = DirichletBC
    variable = ux
    boundary = left
    value = 0
  [../]
  [./symmz]
    type = DirichletBC
    variable = uz
    boundary = back
    value = 0
  [../]
  [./tdisp]
    type = FunctionDirichletBC
    variable = uz
    boundary = front
    function = tdisp
  [../]
[]

[UserObjects]
  [./slip_rate_gss]
    type = CrystalPlasticitySlipRateGSS
    variable_size = 12
    slip_sys_file_name = input_slip_sys.txt
    num_slip_sys_flowrate_props = 2
    flowprops = '1 4 0.001 0.1 5 8 0.001 0.1 9 12 0.001 0.1'
    uo_state_var_name = state_var_gss
  [../]
  [./slip_resistance_gss]
    type = CrystalPlasticitySlipResistanceGSS
    variable_size = 12
    uo_state_var_name = state_var_gss
  [../]
  [./state_var_gss]
    type = CrystalPlasticityStateVariable
    variable_size = 12
    intvar_read_type = file_input
    state_variable_file_name = input_state_variable.txt
    uo_state_var_evol_rate_comp_name = state_var_evol_rate_comp_gss
    scale_factor = 1.0
  [../]
  [./state_var_evol_rate_comp_gss]
    type = CrystalPlasticityStateVarRateComponentGSS
    variable_size = 12
    hprops = '1.0 541.5 109.8 2.5'
    uo_slip_rate_name = slip_rate_gss
    uo_state_var_name = state_var_gss
  [../]
[]

[Materials]
  [./crysp]
    type = FiniteStrainUObasedCP
    stol = 1e-2
    tan_mod_type = exact
    uo_slip_rates = 'slip_rate_gss'
    uo_slip_resistances = 'slip_resistance_gss'
    uo_state_vars = 'state_var_gss'
    uo_state_var_evol_rate_comps = 'state_var_evol_rate_comp_gss'
  [../]
  [./strain]
    type = ComputeFiniteStrain
    displacements = 'ux uy uz'
  [../]
  [./elasticity_tensor]
    type = ComputeElasticityTensorCP
    C_ijkl = '1.684e5 1.214e5 1.214e5 1.684e5 1.214e5 1.684e5 0.754e5 0.754e5 0.754e5'
    fill_method = symmetric9
  [../]
[]

[Postprocessors]
  [./stress_zz]
    type = ElementAverageValue
    variable = stress_zz
  [../]
  [./fp_zz]
    type = ElementAverageValue
    variable = fp_zz
  [../]
  [./e_zz]
    type = ElementAverageValue
    variable = e_zz
  [../]
  [./gss]
    type = ElementAverageValue
    variable = gss
  [../]
[]

[Preconditioning]
  [./smp]
    type = SMP
    full = true
  [../]
[]

[Executioner]
  type = Transient
  dt = 0.05
  solve_type = 'PJFNK'

  petsc_options_iname = -pc_hypre_type
  petsc_options_value = boomerang
  nl_abs_tol = 1e-10
  nl_rel_step_tol = 1e-10
  dtmax = 10.0
  nl_rel_tol = 1e-10
  end_time = 1
  dtmin = 0.05
  num_steps = 10
  nl_abs_step_tol = 1e-10
[]

[Outputs]
  exodus = true
[]

(modules/solid_mechanics/test/tests/multi/three_surface03.i)

# Plasticit models:
# SimpleTester0 with a = 0 and b = 1 and strength = 1
# SimpleTester1 with a = 1 and b = 0 and strength = 1
# SimpleTester2 with a = 1 and b = 1 and strength = 1.5
#
# Lame lambda = 0 (Poisson=0).  Lame mu = 0.5E6
#
# A single element is stretched by 0.5E-6m in y direction and 2.0E-6 in z direction.
# trial stress_yy = 0.5 and stress_zz = 2.0
#
# Then SimpleTester0 and SimpleTester2 should activate and the algorithm will return to
# the corner stress_yy=0.5, stress_zz=1
# internal0 should be 1.0, and others zero

[Mesh]
  type = GeneratedMesh
  dim = 3
  nx = 1
  ny = 1
  nz = 1
  xmin = -0.5
  xmax = 0.5
  ymin = -0.5
  ymax = 0.5
  zmin = -0.5
  zmax = 0.5
[]


[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./disp_z]
  [../]
[]

[Kernels]
  [SolidMechanics]
    displacements = 'disp_x disp_y disp_z'
  [../]
[]


[BCs]
  [./x]
    type = FunctionDirichletBC
    variable = disp_x
    boundary = 'front back'
    function = '0E-6*x'
  [../]
  [./y]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = 'front back'
    function = '0.5E-6*y'
  [../]
  [./z]
    type = FunctionDirichletBC
    variable = disp_z
    boundary = 'front back'
    function = '2.0E-6*z'
  [../]
[]

[AuxVariables]
  [./stress_xx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_zz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./f0]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./f1]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./f2]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./int0]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./int1]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./int2]
    order = CONSTANT
    family = MONOMIAL
  [../]
[]

[AuxKernels]
  [./stress_xx]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xx
    index_i = 0
    index_j = 0
  [../]
  [./stress_xy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xy
    index_i = 0
    index_j = 1
  [../]
  [./stress_xz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xz
    index_i = 0
    index_j = 2
  [../]
  [./stress_yy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yy
    index_i = 1
    index_j = 1
  [../]
  [./stress_yz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yz
    index_i = 1
    index_j = 2
  [../]
  [./stress_zz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_zz
    index_i = 2
    index_j = 2
  [../]
  [./f0]
    type = MaterialStdVectorAux
    property = plastic_yield_function
    index = 0
    variable = f0
  [../]
  [./f1]
    type = MaterialStdVectorAux
    property = plastic_yield_function
    index = 1
    variable = f1
  [../]
  [./f2]
    type = MaterialStdVectorAux
    property = plastic_yield_function
    index = 2
    variable = f2
  [../]
  [./int0]
    type = MaterialStdVectorAux
    property = plastic_internal_parameter
    factor = 1E6
    index = 0
    variable = int0
  [../]
  [./int1]
    type = MaterialStdVectorAux
    property = plastic_internal_parameter
    factor = 1E6
    index = 1
    variable = int1
  [../]
  [./int2]
    type = MaterialStdVectorAux
    property = plastic_internal_parameter
    factor = 1E6
    index = 2
    variable = int2
  [../]
[]

[Postprocessors]
  [./s_xx]
    type = PointValue
    point = '0 0 0'
    variable = stress_xx
  [../]
  [./s_xy]
    type = PointValue
    point = '0 0 0'
    variable = stress_xy
  [../]
  [./s_xz]
    type = PointValue
    point = '0 0 0'
    variable = stress_xz
  [../]
  [./s_yy]
    type = PointValue
    point = '0 0 0'
    variable = stress_yy
  [../]
  [./s_yz]
    type = PointValue
    point = '0 0 0'
    variable = stress_yz
  [../]
  [./s_zz]
    type = PointValue
    point = '0 0 0'
    variable = stress_zz
  [../]
  [./f0]
    type = PointValue
    point = '0 0 0'
    variable = f0
  [../]
  [./f1]
    type = PointValue
    point = '0 0 0'
    variable = f1
  [../]
  [./f2]
    type = PointValue
    point = '0 0 0'
    variable = f2
  [../]
  [./int0]
    type = PointValue
    point = '0 0 0'
    variable = int0
  [../]
  [./int1]
    type = PointValue
    point = '0 0 0'
    variable = int1
  [../]
  [./int2]
    type = PointValue
    point = '0 0 0'
    variable = int2
  [../]
[]

[UserObjects]
  [./simple0]
    type = SolidMechanicsPlasticSimpleTester
    a = 0
    b = 1
    strength = 1
    yield_function_tolerance = 1.0E-9
    internal_constraint_tolerance = 1.0E-9
  [../]
  [./simple1]
    type = SolidMechanicsPlasticSimpleTester
    a = 1
    b = 0
    strength = 1
    yield_function_tolerance = 1.0E-9
    internal_constraint_tolerance = 1.0E-9
  [../]
  [./simple2]
    type = SolidMechanicsPlasticSimpleTester
    a = 1
    b = 1
    strength = 1.5
    yield_function_tolerance = 1.0E-9
    internal_constraint_tolerance = 1.0E-9
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeElasticityTensor
    block = 0
    fill_method = symmetric_isotropic
    C_ijkl = '0 0.5E6'
  [../]
  [./strain]
    type = ComputeFiniteStrain
    block = 0
    displacements = 'disp_x disp_y disp_z'
  [../]
  [./multi]
    type = ComputeMultiPlasticityStress
    block = 0
    ep_plastic_tolerance = 1E-9
    plastic_models = 'simple0 simple1 simple2'
    max_NR_iterations = 2
    min_stepsize = 1
    debug_fspb = crash
    debug_jac_at_stress = '10 0 0 0 10 0 0 0 10'
    debug_jac_at_pm = '1 1'
    debug_jac_at_intnl = '1 1'
    debug_stress_change = 1E-5
    debug_pm_change = '1E-6 1E-6'
    debug_intnl_change = '1E-6 1E-6'
  [../]
[]


[Executioner]
  end_time = 1
  dt = 1
  type = Transient
[]


[Outputs]
  file_base = three_surface03
  exodus = false
  [./csv]
    type = CSV
    [../]
[]

(modules/solid_mechanics/test/tests/j2_plasticity/small_deform1.i)

# UserObject J2 test
# apply uniform stretch in x, y and z directions.
# no plasticity should be observed

[Mesh]
  type = GeneratedMesh
  dim = 3
  nx = 1
  ny = 1
  nz = 1
  xmin = -0.5
  xmax = 0.5
  ymin = -0.5
  ymax = 0.5
  zmin = -0.5
  zmax = 0.5
[]


[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./disp_z]
  [../]
[]

[Kernels]
  [SolidMechanics]
    displacements = 'disp_x disp_y disp_z'
  [../]
[]


[BCs]
  [./x]
    type = FunctionDirichletBC
    variable = disp_x
    boundary = 'front back'
    function = '1E-6*x'
  [../]
  [./y]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = 'front back'
    function = '1E-6*y'
  [../]
  [./z]
    type = FunctionDirichletBC
    variable = disp_z
    boundary = 'front back'
    function = '1E-6*z'
  [../]
[]

[AuxVariables]
  [./stress_xx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_zz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./f]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./iter]
    order = CONSTANT
    family = MONOMIAL
  [../]
[]

[AuxKernels]
  [./stress_xx]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xx
    index_i = 0
    index_j = 0
  [../]
  [./stress_xy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xy
    index_i = 0
    index_j = 1
  [../]
  [./stress_xz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xz
    index_i = 0
    index_j = 2
  [../]
  [./stress_yy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yy
    index_i = 1
    index_j = 1
  [../]
  [./stress_yz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yz
    index_i = 1
    index_j = 2
  [../]
  [./stress_zz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_zz
    index_i = 2
    index_j = 2
  [../]
  [./f]
    type = MaterialStdVectorAux
    index = 0
    property = plastic_yield_function
    variable = f
  [../]
  [./iter]
    type = MaterialRealAux
    property = plastic_NR_iterations
    variable = iter
  [../]
[]

[Postprocessors]
  [./s_xx]
    type = PointValue
    point = '0 0 0'
    variable = stress_xx
  [../]
  [./s_xy]
    type = PointValue
    point = '0 0 0'
    variable = stress_xy
  [../]
  [./s_xz]
    type = PointValue
    point = '0 0 0'
    variable = stress_xz
  [../]
  [./s_yy]
    type = PointValue
    point = '0 0 0'
    variable = stress_yy
  [../]
  [./s_yz]
    type = PointValue
    point = '0 0 0'
    variable = stress_yz
  [../]
  [./s_zz]
    type = PointValue
    point = '0 0 0'
    variable = stress_zz
  [../]
  [./f]
    type = PointValue
    point = '0 0 0'
    variable = f
  [../]
  [./iter]
    type = PointValue
    point = '0 0 0'
    variable = iter
  [../]
[]

[UserObjects]
  [./str]
    type = SolidMechanicsHardeningConstant
    value = 1
  [../]
  [./j2]
    type = SolidMechanicsPlasticJ2
    yield_strength = str
    yield_function_tolerance = 1E-3
    internal_constraint_tolerance = 1E-9
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeElasticityTensor
    block = 0
    fill_method = symmetric_isotropic
    C_ijkl = '0 1E6'
  [../]
  [./strain]
    type = ComputeFiniteStrain
    block = 0
    displacements = 'disp_x disp_y disp_z'
  [../]
  [./mc]
    type = ComputeMultiPlasticityStress
    block = 0
    ep_plastic_tolerance = 1E-9
    plastic_models = j2
    debug_fspb = crash
  [../]
[]


[Executioner]
  end_time = 1
  dt = 1
  type = Transient
[]


[Outputs]
  file_base = small_deform1
  exodus = false
  [./csv]
    type = CSV
    [../]
[]

(modules/solid_mechanics/test/tests/multi/six_surface14.i)

# Plasticit models:
# SimpleTester0 with a = 0 and b = 1 and strength = 1
# SimpleTester1 with a = 1 and b = 0 and strength = 1
# SimpleTester2 with a = 1 and b = 1 and strength = 3
# SimpleTester3 with a = 0 and b = 1 and strength = 1.1
# SimpleTester4 with a = 1 and b = 0 and strength = 1.1
# SimpleTester5 with a = 1 and b = 1 and strength = 3.1
#
# Lame lambda = 0 (Poisson=0).  Lame mu = 0.5E6
#
# A single element is stretched by 2.1E-6m in y direction and 3E-6 in z direction.
# trial stress_yy = 2.1 and stress_zz = 3.0
#
# This is similar to three_surface14.i, and a description is found there.
# The result should be stress_zz=1=stress_yy, with internal0=2
# and internal1=1.1

[Mesh]
  type = GeneratedMesh
  dim = 3
  nx = 1
  ny = 1
  nz = 1
  xmin = -0.5
  xmax = 0.5
  ymin = -0.5
  ymax = 0.5
  zmin = -0.5
  zmax = 0.5
[]


[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./disp_z]
  [../]
[]

[Kernels]
  [SolidMechanics]
    displacements = 'disp_x disp_y disp_z'
  [../]
[]


[BCs]
  [./x]
    type = FunctionDirichletBC
    variable = disp_x
    boundary = 'front back'
    function = '0E-6*x'
  [../]
  [./y]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = 'front back'
    function = '2.1E-6*y'
  [../]
  [./z]
    type = FunctionDirichletBC
    variable = disp_z
    boundary = 'front back'
    function = '3.0E-6*z'
  [../]
[]

[AuxVariables]
  [./stress_xx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_zz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./f0]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./f1]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./f2]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./f3]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./f4]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./f5]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./int0]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./int1]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./int2]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./int3]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./int4]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./int5]
    order = CONSTANT
    family = MONOMIAL
  [../]
[]

[AuxKernels]
  [./stress_xx]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xx
    index_i = 0
    index_j = 0
  [../]
  [./stress_xy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xy
    index_i = 0
    index_j = 1
  [../]
  [./stress_xz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xz
    index_i = 0
    index_j = 2
  [../]
  [./stress_yy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yy
    index_i = 1
    index_j = 1
  [../]
  [./stress_yz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yz
    index_i = 1
    index_j = 2
  [../]
  [./stress_zz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_zz
    index_i = 2
    index_j = 2
  [../]
  [./f0]
    type = MaterialStdVectorAux
    property = plastic_yield_function
    index = 0
    variable = f0
  [../]
  [./f1]
    type = MaterialStdVectorAux
    property = plastic_yield_function
    index = 1
    variable = f1
  [../]
  [./f2]
    type = MaterialStdVectorAux
    property = plastic_yield_function
    index = 2
    variable = f2
  [../]
  [./f3]
    type = MaterialStdVectorAux
    property = plastic_yield_function
    index = 3
    variable = f3
  [../]
  [./f4]
    type = MaterialStdVectorAux
    property = plastic_yield_function
    index = 4
    variable = f4
  [../]
  [./f5]
    type = MaterialStdVectorAux
    property = plastic_yield_function
    index = 5
    variable = f5
  [../]
  [./int0]
    type = MaterialStdVectorAux
    property = plastic_internal_parameter
    factor = 1E6
    index = 0
    variable = int0
  [../]
  [./int1]
    type = MaterialStdVectorAux
    property = plastic_internal_parameter
    factor = 1E6
    index = 1
    variable = int1
  [../]
  [./int2]
    type = MaterialStdVectorAux
    property = plastic_internal_parameter
    factor = 1E6
    index = 2
    variable = int2
  [../]
  [./int3]
    type = MaterialStdVectorAux
    property = plastic_internal_parameter
    factor = 1E6
    index = 3
    variable = int3
  [../]
  [./int4]
    type = MaterialStdVectorAux
    property = plastic_internal_parameter
    factor = 1E6
    index = 4
    variable = int4
  [../]
  [./int5]
    type = MaterialStdVectorAux
    property = plastic_internal_parameter
    factor = 1E6
    index = 5
    variable = int5
  [../]
[]

[Postprocessors]
  [./s_xx]
    type = PointValue
    point = '0 0 0'
    variable = stress_xx
  [../]
  [./s_xy]
    type = PointValue
    point = '0 0 0'
    variable = stress_xy
  [../]
  [./s_xz]
    type = PointValue
    point = '0 0 0'
    variable = stress_xz
  [../]
  [./s_yy]
    type = PointValue
    point = '0 0 0'
    variable = stress_yy
  [../]
  [./s_yz]
    type = PointValue
    point = '0 0 0'
    variable = stress_yz
  [../]
  [./s_zz]
    type = PointValue
    point = '0 0 0'
    variable = stress_zz
  [../]
  [./f0]
    type = PointValue
    point = '0 0 0'
    variable = f0
  [../]
  [./f1]
    type = PointValue
    point = '0 0 0'
    variable = f1
  [../]
  [./f2]
    type = PointValue
    point = '0 0 0'
    variable = f2
  [../]
  [./f3]
    type = PointValue
    point = '0 0 0'
    variable = f3
  [../]
  [./f4]
    type = PointValue
    point = '0 0 0'
    variable = f4
  [../]
  [./f5]
    type = PointValue
    point = '0 0 0'
    variable = f5
  [../]
  [./int0]
    type = PointValue
    point = '0 0 0'
    variable = int0
  [../]
  [./int1]
    type = PointValue
    point = '0 0 0'
    variable = int1
  [../]
  [./int2]
    type = PointValue
    point = '0 0 0'
    variable = int2
  [../]
  [./int3]
    type = PointValue
    point = '0 0 0'
    variable = int3
  [../]
  [./int4]
    type = PointValue
    point = '0 0 0'
    variable = int4
  [../]
  [./int5]
    type = PointValue
    point = '0 0 0'
    variable = int5
  [../]
[]

[UserObjects]
  [./simple0]
    type = SolidMechanicsPlasticSimpleTester
    a = 0
    b = 1
    strength = 1
    yield_function_tolerance = 1.0E-6
    internal_constraint_tolerance = 1.0E-6
  [../]
  [./simple1]
    type = SolidMechanicsPlasticSimpleTester
    a = 1
    b = 0
    strength = 1
    yield_function_tolerance = 1.0E-6
    internal_constraint_tolerance = 1.0E-6
  [../]
  [./simple2]
    type = SolidMechanicsPlasticSimpleTester
    a = 1
    b = 1
    strength = 3
    yield_function_tolerance = 1.0E-6
    internal_constraint_tolerance = 1.0E-6
  [../]
  [./simple3]
    type = SolidMechanicsPlasticSimpleTester
    a = 0
    b = 1
    strength = 1.1
    yield_function_tolerance = 1.0E-6
    internal_constraint_tolerance = 1.0E-6
  [../]
  [./simple4]
    type = SolidMechanicsPlasticSimpleTester
    a = 1
    b = 0
    strength = 1.1
    yield_function_tolerance = 1.0E-6
    internal_constraint_tolerance = 1.0E-6
  [../]
  [./simple5]
    type = SolidMechanicsPlasticSimpleTester
    a = 1
    b = 1
    strength = 3.1
    yield_function_tolerance = 1.0E-6
    internal_constraint_tolerance = 1.0E-6
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeElasticityTensor
    block = 0
    fill_method = symmetric_isotropic
    C_ijkl = '0 0.5E6'
  [../]
  [./strain]
    type = ComputeFiniteStrain
    block = 0
    displacements = 'disp_x disp_y disp_z'
  [../]
  [./multi]
    type = ComputeMultiPlasticityStress
    block = 0
    ep_plastic_tolerance = 1E-9
    plastic_models = 'simple0 simple1 simple2 simple3 simple4 simple5'
    max_NR_iterations = 4
    min_stepsize = 1
    debug_fspb = crash
    debug_jac_at_stress = '10 0 0 0 10 0 0 0 10'
    debug_jac_at_pm = '1 1 1'
    debug_jac_at_intnl = '1 1 1'
    debug_stress_change = 1E-5
    debug_pm_change = '1E-6 1E-6 1E-6'
    debug_intnl_change = '1E-6 1E-6 1E-6'
  [../]
[]


[Executioner]
  end_time = 1
  dt = 1
  type = Transient
[]


[Outputs]
  file_base = six_surface14
  exodus = false
  [./csv]
    type = CSV
    [../]
[]

(modules/solid_mechanics/test/tests/mohr_coulomb/small_deform_hard3.i)

# apply repeated stretches in x z directions, and smaller stretches along the y direction,
# so that sigma_I = sigma_II,
# which means that lode angle = 30deg.
# The allows yield surface in meridional plane to be mapped out
#
# friction_angle = 50deg, friction_angle_residual=51deg, friction_angle_rate = 1E7 (huge)
# cohesion = 10, cohesion_residual = 9.9, cohesion_rate = 1E7 (huge)

[Mesh]
  type = GeneratedMesh
  dim = 3
  nx = 1
  ny = 1
  nz = 1
  xmin = -0.5
  xmax = 0.5
  ymin = -0.5
  ymax = 0.5
  zmin = -0.5
  zmax = 0.5
[]


[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./disp_z]
  [../]
[]

[Kernels]
  [SolidMechanics]
    displacements = 'disp_x disp_y disp_z'
  [../]
[]


[BCs]
  [./x]
    type = FunctionDirichletBC
    variable = disp_x
    boundary = 'front back'
    function = '1E-6*x*t'
  [../]
  [./y]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = 'front back'
    function = '0.25E-6*y*sin(t)'
  [../]
  [./z]
    type = FunctionDirichletBC
    variable = disp_z
    boundary = 'front back'
    function = '1E-6*z*t'
  [../]
[]

[AuxVariables]
  [./stress_xx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_zz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./mc_int]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./yield_fcn]
    order = CONSTANT
    family = MONOMIAL
  [../]
[]

[AuxKernels]
  [./stress_xx]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xx
    index_i = 0
    index_j = 0
  [../]
  [./stress_xy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xy
    index_i = 0
    index_j = 1
  [../]
  [./stress_xz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xz
    index_i = 0
    index_j = 2
  [../]
  [./stress_yy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yy
    index_i = 1
    index_j = 1
  [../]
  [./stress_yz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yz
    index_i = 1
    index_j = 2
  [../]
  [./stress_zz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_zz
    index_i = 2
    index_j = 2
  [../]
  [./mc_int_auxk]
    type = MaterialStdVectorAux
    index = 0
    property = plastic_internal_parameter
    variable = mc_int
  [../]
  [./yield_fcn_auxk]
    type = MaterialStdVectorAux
    index = 0
    property = plastic_yield_function
    variable = yield_fcn
  [../]
[]

[Postprocessors]
  [./s_xx]
    type = PointValue
    point = '0 0 0'
    variable = stress_xx
  [../]
  [./s_xy]
    type = PointValue
    point = '0 0 0'
    variable = stress_xy
  [../]
  [./s_xz]
    type = PointValue
    point = '0 0 0'
    variable = stress_xz
  [../]
  [./s_yy]
    type = PointValue
    point = '0 0 0'
    variable = stress_yy
  [../]
  [./s_yz]
    type = PointValue
    point = '0 0 0'
    variable = stress_yz
  [../]
  [./s_zz]
    type = PointValue
    point = '0 0 0'
    variable = stress_zz
  [../]
  [./internal]
    type = PointValue
    point = '0 0 0'
    variable = mc_int
  [../]
  [./f]
    type = PointValue
    point = '0 0 0'
    variable = yield_fcn
  [../]
[]

[UserObjects]
  [./mc_coh]
    type = SolidMechanicsHardeningExponential
    value_0 = 10
    value_residual = 9.9
    rate = 1E7
  [../]
  [./mc_phi]
    type = SolidMechanicsHardeningExponential
    value_0 = 0.8726646 # 50deg
    value_residual = 0.8901179 # 51deg
    rate = 1E7
  [../]
  [./mc_psi]
    type = SolidMechanicsHardeningExponential
    value_0 = 0
    value_residual = 0.8726646 # 50deg
    rate = 3000
  [../]
  [./mc]
    type = SolidMechanicsPlasticMohrCoulomb
    cohesion = mc_coh
    friction_angle = mc_phi
    dilation_angle = mc_psi
    mc_tip_smoother = 4
    mc_edge_smoother = 20
    yield_function_tolerance = 1E-6
    internal_constraint_tolerance = 1E-9
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeElasticityTensor
    block = 0
    fill_method = symmetric_isotropic
    C_ijkl = '0 1E7'
  [../]
  [./strain]
    type = ComputeFiniteStrain
    block = 0
    displacements = 'disp_x disp_y disp_z'
  [../]
  [./mc]
    type = ComputeMultiPlasticityStress
    block = 0
    ep_plastic_tolerance = 1E-9
    plastic_models = mc
    debug_fspb = crash
    debug_jac_at_stress = '10 1 2 1 11 -3 2 -3 8'
    debug_jac_at_pm = 1
    debug_jac_at_intnl = 1
    debug_stress_change = 1E-5
    debug_pm_change = 1E-6
    debug_intnl_change = 1E-6
  [../]
[]


[Executioner]
  end_time = 30
  dt = 1
  type = Transient
[]


[Outputs]
  file_base = small_deform_hard3
  exodus = false
  [./csv]
    type = CSV
    [../]
[]

(modules/contact/test/tests/mortar_aux_kernels/block-dynamics-aux-fretting-wear-test.i)

starting_point = 0.5e-1
offset = -0.045

[GlobalParams]
  displacements = 'disp_x disp_y'
[]

[Mesh]
  file = long-bottom-block-1elem-blocks.e
[]

[Variables]
  [disp_x]
    block = '1 2'
  []
  [disp_y]
    block = '1 2'
  []
  [normal_lm]
    block = 3
    use_dual = true
  #  scaling = 1.0e-5
  []
  [frictional_lm]
    block = 3
    use_dual = true
    scaling = 1.0e-5
  []
[]

[ICs]
  [disp_y]
    block = 2
    variable = disp_y
    value = '${fparse starting_point + offset}'
    type = ConstantIC
  []
[]

[Kernels]
  [DynamicTensorMechanics]
    displacements = 'disp_x disp_y'
    generate_output = 'stress_xx stress_yy'
    strain = FINITE
    block = '1 2'
    zeta = 0.04
    hht_alpha = 0.0
  []
  [inertia_x]
    type = InertialForce
    variable = disp_x
    velocity = vel_x
    acceleration = accel_x
    beta = 0.25
    gamma = 0.5
    alpha = 0
    eta = 0.0
    block = '1 2'
  []
  [inertia_y]
    type = InertialForce
    variable = disp_y
    velocity = vel_y
    acceleration = accel_y
    beta = 0.25
    gamma = 0.5
    alpha = 0
    eta = 0.0
    block = '1 2'
  []
[]

[Materials]
  [elasticity_2]
    type = ComputeIsotropicElasticityTensor
    block = '2'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  []
  [elasticity_1]
    type = ComputeIsotropicElasticityTensor
    block = '1'
    youngs_modulus = 1e8
    poissons_ratio = 0.3
  []
  [stress]
    type = ComputeFiniteStrainElasticStress
    block = '1 2'
  []
  [strain]
    type = ComputeFiniteStrain
    block = '1 2'
  []
  [density]
    type = GenericConstantMaterial
    block = '1 2'
    prop_names = 'density'
    prop_values = '7750'
  []
[]

[AuxVariables]
  [worn_depth]
    block = '3'
  []
  [gap_vel]
    block = '3'
  []
  [vel_x]
    block = '1 2'
  []
  [accel_x]
    block = '1 2'
  []
  [vel_y]
    block = '1 2'
  []
  [accel_y]
    block = '1 2'
  []
  [vel_z]
    block = '1 2'
  []
  [accel_z]
    block = '1 2'
  []
[]

[AuxKernels]
  [gap_vel]
    type = WeightedGapVelAux
    variable = gap_vel
    primary_boundary = 20
    secondary_boundary = 10
    primary_subdomain = 4
    secondary_subdomain = 3
    disp_x = disp_x
    disp_y = disp_y
  []
  [worn_depth]
    type = MortarArchardsLawAux
    variable = worn_depth
    primary_boundary = 20
    secondary_boundary = 10
    primary_subdomain = 4
    secondary_subdomain = 3
    displacements = 'disp_x disp_y'
    friction_coefficient = 0.5
    energy_wear_coefficient = 1.0e-6
    normal_pressure = normal_lm
    execute_on = 'TIMESTEP_END'
  []
  [accel_x]
    type = NewmarkAccelAux
    variable = accel_x
    displacement = disp_x
    velocity = vel_x
    beta = 0.25
    execute_on = 'linear timestep_end'
  []
  [vel_x]
    type = NewmarkVelAux
    variable = vel_x
    acceleration = accel_x
    gamma = 0.5
    execute_on = 'linear timestep_end'
  []
  [accel_y]
    type = NewmarkAccelAux
    variable = accel_y
    displacement = disp_y
    velocity = vel_y
    beta = 0.25
    execute_on = 'linear timestep_end'
  []
  [vel_y]
    type = NewmarkVelAux
    variable = vel_y
    acceleration = accel_y
    gamma = 0.5
    execute_on = 'linear timestep_end'
  []
[]

[UserObjects]
  [weighted_vel_uo]
    type = LMWeightedVelocitiesUserObject
    primary_boundary = 20
    secondary_boundary = 10
    primary_subdomain = 4
    secondary_subdomain = 3
    secondary_variable = disp_x
    lm_variable_normal = normal_lm
    lm_variable_tangential_one = frictional_lm
    disp_x = disp_x
    disp_y = disp_y
  []
[]

[Constraints]
  [weighted_gap_lm]
    type = ComputeDynamicFrictionalForceLMMechanicalContact
    primary_boundary = 20
    secondary_boundary = 10
    primary_subdomain = 4
    secondary_subdomain = 3
    variable = normal_lm
    disp_x = disp_x
    disp_y = disp_y
    use_displaced_mesh = true
    wear_depth = worn_depth
    c = 1e6
    c_t = 1e6
    normalize_c = true
    mu = 0.5
    friction_lm = frictional_lm
    capture_tolerance = 1.0e-5
    newmark_beta = 0.25
    newmark_gamma = 0.5
  []
  [normal_x]
    type = NormalMortarMechanicalContact
    primary_boundary = 20
    secondary_boundary = 10
    primary_subdomain = 4
    secondary_subdomain = 3
    variable = normal_lm
    secondary_variable = disp_x
    component = x
    use_displaced_mesh = true
    compute_lm_residuals = false
    weighted_gap_uo = weighted_vel_uo
  []
  [normal_y]
    type = NormalMortarMechanicalContact
    primary_boundary = 20
    secondary_boundary = 10
    primary_subdomain = 4
    secondary_subdomain = 3
    variable = normal_lm
    secondary_variable = disp_y
    component = y
    use_displaced_mesh = true
    weighted_gap_uo = weighted_vel_uo
  []
  [tangential_x]
    type = TangentialMortarMechanicalContact
    primary_boundary = 20
    secondary_boundary = 10
    primary_subdomain = 4
    secondary_subdomain = 3
    variable = frictional_lm
    secondary_variable = disp_x
    component = x
    use_displaced_mesh = true
    compute_lm_residuals = false
    weighted_velocities_uo = weighted_vel_uo
  []
  [tangential_y]
    type = TangentialMortarMechanicalContact
    primary_boundary = 20
    secondary_boundary = 10
    primary_subdomain = 4
    secondary_subdomain = 3
    variable = frictional_lm
    secondary_variable = disp_y
    component = y
    use_displaced_mesh = true
    compute_lm_residuals = false
    weighted_velocities_uo = weighted_vel_uo
  []
[]

[BCs]
  [botx]
    type = DirichletBC
    variable = disp_x
    boundary = 40
    value = 0.0
  []
  [boty]
    type = DirichletBC
    variable = disp_y
    boundary = 40
    value = 0.0
  []
  [topy]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = 30
    function = '${starting_point} * cos(4.0 * pi / 4 * t) + ${offset}'
  []
  [leftx]
    type = FunctionDirichletBC
    variable = disp_x
    boundary = 50
    function = '1e-5 * (cos(32.0 * pi / 4 * t) - 1.0)'
  []
[]

[Executioner]
  type = Transient
  end_time = 0.5
  dt = 0.05
  dtmin = .002
  solve_type = 'NEWTON'
  petsc_options = '-snes_converged_reason -ksp_converged_reason -pc_svd_monitor '
                  '-snes_linesearch_monitor -snes_ksp_ew'
  petsc_options_iname = '-pc_type -pc_factor_mat_solver_type -pc_factor_shift_type -pc_factor_shift_amount'
  petsc_options_value = 'lu       superlu_dist                  NONZERO               1e-15'
  nl_max_its = 40
  l_max_its = 15
  line_search = none
  snesmf_reuse_base = true

  [TimeIntegrator]
    type = NewmarkBeta
    beta = 0.25
    gamma = 0.5
  []
[]

[Debug]
  show_var_residual_norms = true
[]

[Outputs]
  exodus = true
[]

[Preconditioning]
  [smp]
    type = SMP
    full = true
  []
[]

[Postprocessors]
  active = 'contact'
  [contact]
    type = ContactDOFSetSize
    variable = normal_lm
    subdomain = '3'
    execute_on = 'nonlinear timestep_end'
  []
[]

(modules/solid_mechanics/test/tests/mohr_coulomb/planar3.i)

# apply repeated stretches in x z directions, and smaller stretches along the y direction,
# so that sigma_I = sigma_II,
# which means that lode angle = 30deg.

[Mesh]
  type = GeneratedMesh
  dim = 3
  nx = 1
  ny = 1
  nz = 1
  xmin = -0.5
  xmax = 0.5
  ymin = -0.5
  ymax = 0.5
  zmin = -0.5
  zmax = 0.5
[]


[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./disp_z]
  [../]
[]

[Kernels]
  [SolidMechanics]
    displacements = 'disp_x disp_y disp_z'
  [../]
[]


[BCs]
  [./x]
    type = FunctionDirichletBC
    variable = disp_x
    boundary = 'front back'
    function = '1E-6*x*t'
  [../]
  [./y]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = 'front back'
    function = '0.25E-6*y*sin(t)'
  [../]
  [./z]
    type = FunctionDirichletBC
    variable = disp_z
    boundary = 'front back'
    function = '1.1E-6*z*t'
  [../]
[]

[AuxVariables]
  [./stress_xx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_zz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./f]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./iter]
    order = CONSTANT
    family = MONOMIAL
  [../]
[]

[AuxKernels]
  [./stress_xx]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xx
    index_i = 0
    index_j = 0
  [../]
  [./stress_xy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xy
    index_i = 0
    index_j = 1
  [../]
  [./stress_xz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xz
    index_i = 0
    index_j = 2
  [../]
  [./stress_yy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yy
    index_i = 1
    index_j = 1
  [../]
  [./stress_yz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yz
    index_i = 1
    index_j = 2
  [../]
  [./stress_zz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_zz
    index_i = 2
    index_j = 2
  [../]
  [./f]
    type = MaterialStdVectorAux
    index = 0
    property = plastic_yield_function
    variable = f
  [../]
  [./iter]
    type = MaterialRealAux
    property = plastic_NR_iterations
    variable = iter
  [../]
[]

[Postprocessors]
  [./s_xx]
    type = PointValue
    point = '0 0 0'
    variable = stress_xx
  [../]
  [./s_xy]
    type = PointValue
    point = '0 0 0'
    variable = stress_xy
  [../]
  [./s_xz]
    type = PointValue
    point = '0 0 0'
    variable = stress_xz
  [../]
  [./s_yy]
    type = PointValue
    point = '0 0 0'
    variable = stress_yy
  [../]
  [./s_yz]
    type = PointValue
    point = '0 0 0'
    variable = stress_yz
  [../]
  [./s_zz]
    type = PointValue
    point = '0 0 0'
    variable = stress_zz
  [../]
  [./f]
    type = PointValue
    point = '0 0 0'
    variable = f
  [../]
  [./iter]
    type = PointValue
    point = '0 0 0'
    variable = iter
  [../]
[]

[UserObjects]
  [./coh]
    type = SolidMechanicsHardeningConstant
    value = 10
  [../]
  [./phi]
    type = SolidMechanicsHardeningConstant
    value = 0.9
  [../]
  [./psi]
    type = SolidMechanicsHardeningConstant
    value = 0.1
  [../]
  [./mc]
    type = SolidMechanicsPlasticMohrCoulombMulti
    cohesion = coh
    friction_angle = phi
    dilation_angle = psi
    yield_function_tolerance = 1E-8
    shift = 1E-8
    internal_constraint_tolerance = 1E-9
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeElasticityTensor
    block = 0
    fill_method = symmetric_isotropic
    C_ijkl = '0 1E7'
  [../]
  [./strain]
    type = ComputeFiniteStrain
    block = 0
    displacements = 'disp_x disp_y disp_z'
  [../]
  [./mc]
    type = ComputeMultiPlasticityStress
    block = 0
    ep_plastic_tolerance = 1E-9
    plastic_models = mc
    deactivation_scheme = safe
    max_NR_iterations = 3
    min_stepsize = 1
    max_stepsize_for_dumb = 1
    debug_fspb = crash
    debug_jac_at_stress = '10 5 2 5 11 -1 2 -1 12'
    debug_jac_at_pm = '1 1 1 1 1 1'
    debug_jac_at_intnl = 1
    debug_stress_change = 1E-5
    debug_pm_change = '1E-6 1E-6 1E-6 1E-6 1E-6 1E-6'
    debug_intnl_change = 1E-6
  [../]
[]


[Executioner]
  end_time = 10
  dt = 1
  type = Transient
[]


[Outputs]
  file_base = planar3
  exodus = false
  [./csv]
    type = CSV
    [../]
[]

(modules/contact/test/tests/verification/patch_tests/brick_2/brick2_mu_0_2_pen.i)

[GlobalParams]
  volumetric_locking_correction = true
  displacements = 'disp_x disp_y disp_z'
[]

[Mesh]
  file = brick2_mesh.e
[]

[Problem]
  type = ReferenceResidualProblem
  extra_tag_vectors = 'ref'
  reference_vector = 'ref'
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./disp_z]
  [../]
[]

[AuxVariables]
  [./stress_xx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_zz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./penetration]
  [../]
  [./saved_x]
  [../]
  [./saved_y]
  [../]
  [./saved_z]
  [../]
  [./diag_saved_x]
  [../]
  [./diag_saved_y]
  [../]
  [./diag_saved_z]
  [../]
  [./inc_slip_x]
  [../]
  [./inc_slip_y]
  [../]
  [./inc_slip_z]
  [../]
  [./accum_slip_x]
  [../]
  [./accum_slip_y]
  [../]
  [./accum_slip_z]
  [../]
  [./tang_force_x]
  [../]
  [./tang_force_y]
  [../]
  [./tang_force_z]
  [../]
[]

[Kernels]
  [./TensorMechanics]
    use_displaced_mesh = true
    save_in = 'saved_x saved_y saved_z'
    extra_vector_tags = 'ref'
  [../]
[]

[AuxKernels]
  [./stress_xx]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xx
    index_i = 0
    index_j = 0
    execute_on = timestep_end
  [../]
  [./stress_yy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yy
    index_i = 1
    index_j = 1
    execute_on = timestep_end
  [../]
  [./stress_xy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xy
    index_i = 0
    index_j = 1
    execute_on = timestep_end
  [../]
  [./stress_zz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_zz
    index_i = 2
    index_j = 2
    execute_on = timestep_end
  [../]
  [./inc_slip_x]
    type = PenetrationAux
    variable = inc_slip_x
    execute_on = timestep_end
    boundary = 3
    paired_boundary = 4
  [../]
  [./inc_slip_y]
    type = PenetrationAux
    variable = inc_slip_y
    execute_on = timestep_end
    boundary = 3
    paired_boundary = 4
  [../]
  [./accum_slip_x]
    type = PenetrationAux
    variable = accum_slip_x
    execute_on = timestep_end
    boundary = 3
    paired_boundary = 4
  [../]
  [./accum_slip_y]
    type = PenetrationAux
    variable = accum_slip_y
    execute_on = timestep_end
    boundary = 3
    paired_boundary = 4
  [../]
  [./penetration]
    type = PenetrationAux
    variable = penetration
    boundary = 3
    paired_boundary = 4
  [../]
  [./tang_force_x]
    type = PenetrationAux
    variable = tang_force_x
    quantity = tangential_force_x
    boundary = 3
    paired_boundary = 4
  [../]
  [./tang_force_y]
    type = PenetrationAux
    variable = tang_force_y
    quantity = tangential_force_y
    boundary = 3
    paired_boundary = 4
  [../]
[]

[Postprocessors]
  [./bot_react_x]
    type = NodalSum
    variable = saved_x
    boundary = 1
  [../]
  [./bot_react_y]
    type = NodalSum
    variable = saved_y
    boundary = 1
  [../]
  [./top_react_x]
    type = NodalSum
    variable = saved_x
    boundary = 5
  [../]
  [./top_react_y]
    type = NodalSum
    variable = saved_y
    boundary = 5
  [../]
  [./ref_resid_x]
    type = NodalL2Norm
    execute_on = timestep_end
    variable = saved_x
  [../]
  [./ref_resid_y]
    type = NodalL2Norm
    execute_on = timestep_end
    variable = saved_y
  [../]
  [./sigma_yy]
    type = ElementAverageValue
    variable = stress_yy
  [../]
  [./sigma_zz]
    type = ElementAverageValue
    variable = stress_zz
  [../]
  [./disp_x7]
    type = NodalVariableValue
    nodeid = 6
    variable = disp_x
  [../]
  [./disp_x26]
    type = NodalVariableValue
    nodeid = 25
    variable = disp_x
  [../]
  [./disp_y7]
    type = NodalVariableValue
    nodeid = 6
    variable = disp_y
  [../]
  [./disp_y26]
    type = NodalVariableValue
    nodeid = 25
    variable = disp_y
  [../]
  [./_dt]
    type = TimestepSize
  [../]
  [./num_lin_it]
    type = NumLinearIterations
  [../]
  [./num_nonlin_it]
    type = NumNonlinearIterations
  [../]
[]

[BCs]
  [./bot_y]
    type = DirichletBC
    variable = disp_y
    boundary = 1
    value = 0.0
  [../]
  [./side_x]
    type = DirichletBC
    variable = disp_x
    boundary = 2
    value = 0.0
  [../]
  [./back_z]
    type = DirichletBC
    variable = disp_z
    boundary = 6
    value = 0.0
  [../]
  [./top_press]
    type = Pressure
    variable = disp_y
    boundary = 5
    factor = 109.89
  [../]
[]

[Materials]
  [./bot_elas_tens]
    type = ComputeIsotropicElasticityTensor
    block = '1'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./bot_strain]
    type = ComputeFiniteStrain
    block = '1'
  [../]
  [./bot_stress]
    type = ComputeFiniteStrainElasticStress
    block = '1'
  [../]
  [./top_elas_tens]
    type = ComputeIsotropicElasticityTensor
    block = '2'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./top_strain]
    type = ComputeFiniteStrain
    block = '2'
  [../]
  [./top_stress]
    type = ComputeFiniteStrainElasticStress
    block = '2'
  [../]
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'

  petsc_options_iname = '-pc_type -pc_factor_mat_solver_type'
  petsc_options_value = 'lu     superlu_dist'

  line_search = 'none'

  nl_abs_tol = 1e-9
  nl_rel_tol = 1e-8
  l_max_its = 50
  nl_max_its = 100
  dt = 1.0
  end_time = 1.0
  num_steps = 10
  dtmin = 1.0
  l_tol = 1e-5

[]

[VectorPostprocessors]
  [./x_disp]
    type = NodalValueSampler
    variable = disp_x
    boundary = '1 3 4 5'
    sort_by = id
  [../]
  [./y_disp]
    type = NodalValueSampler
    variable = disp_y
    boundary = '1 3 4 5'
    sort_by = id
  [../]
  [./cont_press]
    type = NodalValueSampler
    variable = contact_pressure
    boundary = '3'
    sort_by = id
  [../]
[]

[Outputs]
  file_base = brick2_mu_0_2_pen_out
  print_linear_residuals = true
  perf_graph = true
  [./exodus]
    type = Exodus
    elemental_as_nodal = true
  [../]
  [./console]
    type = Console
    max_rows = 5
  [../]
  [./chkfile]
    type = CSV
    file_base = brick2_mu_0_2_pen_check
    show = 'bot_react_x bot_react_y disp_x7 disp_y7 disp_x26 disp_y26 stress_yy stress_zz top_react_x top_react_y x_disp y_disp cont_press'
    execute_vector_postprocessors_on = timestep_end
  [../]
  [./outfile]
    type = CSV
    delimiter = ' '
    execute_vector_postprocessors_on = none
  [../]
[]

[Contact]
  [./leftright]
    secondary = 3
    primary = 4
    model = coulomb
    formulation = penalty
    normalize_penalty = true
    friction_coefficient = 0.2
    penalty = 1e+7
  [../]
[]

(modules/solid_mechanics/test/tests/j2_plasticity/small_deform3.i)

# UserObject J2 test
# apply uniform compression in x direction to give
# trial stress_xx = -7, so sqrt(3*J2) = 7
# with zero Poisson's ratio, this should return to
# stress_xx = -3, stress_yy = -2 = stress_zz
# (note that stress_xx - stress_yy = stress_xx - stress_zz = -1, so sqrt(3*j2) = 1,
#  and that the mean stress remains = -7/3)

[Mesh]
  type = GeneratedMesh
  dim = 3
  nx = 1
  ny = 1
  nz = 1
  xmin = -0.5
  xmax = 0.5
  ymin = -0.5
  ymax = 0.5
  zmin = -0.5
  zmax = 0.5
[]


[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./disp_z]
  [../]
[]

[Kernels]
  [SolidMechanics]
    displacements = 'disp_x disp_y disp_z'
  [../]
[]


[BCs]
  [./x]
    type = FunctionDirichletBC
    variable = disp_x
    boundary = 'front back'
    function = '-3.5E-6*x'
  [../]
  [./y]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = 'front back'
    function = '0E-6*y'
  [../]
  [./z]
    type = FunctionDirichletBC
    variable = disp_z
    boundary = 'front back'
    function = '0E-6*z'
  [../]
[]

[AuxVariables]
  [./stress_xx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_zz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./f]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./iter]
    order = CONSTANT
    family = MONOMIAL
  [../]
[]

[AuxKernels]
  [./stress_xx]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xx
    index_i = 0
    index_j = 0
  [../]
  [./stress_xy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xy
    index_i = 0
    index_j = 1
  [../]
  [./stress_xz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xz
    index_i = 0
    index_j = 2
  [../]
  [./stress_yy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yy
    index_i = 1
    index_j = 1
  [../]
  [./stress_yz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yz
    index_i = 1
    index_j = 2
  [../]
  [./stress_zz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_zz
    index_i = 2
    index_j = 2
  [../]
  [./f]
    type = MaterialStdVectorAux
    index = 0
    property = plastic_yield_function
    variable = f
  [../]
  [./iter]
    type = MaterialRealAux
    property = plastic_NR_iterations
    variable = iter
  [../]
[]

[Postprocessors]
  [./s_xx]
    type = PointValue
    point = '0 0 0'
    variable = stress_xx
  [../]
  [./s_xy]
    type = PointValue
    point = '0 0 0'
    variable = stress_xy
  [../]
  [./s_xz]
    type = PointValue
    point = '0 0 0'
    variable = stress_xz
  [../]
  [./s_yy]
    type = PointValue
    point = '0 0 0'
    variable = stress_yy
  [../]
  [./s_yz]
    type = PointValue
    point = '0 0 0'
    variable = stress_yz
  [../]
  [./s_zz]
    type = PointValue
    point = '0 0 0'
    variable = stress_zz
  [../]
  [./f]
    type = PointValue
    point = '0 0 0'
    variable = f
  [../]
  [./iter]
    type = PointValue
    point = '0 0 0'
    variable = iter
  [../]
[]

[UserObjects]
  [./str]
    type = SolidMechanicsHardeningConstant
    value = 1
  [../]
  [./j2]
    type = SolidMechanicsPlasticJ2
    yield_strength = str
    yield_function_tolerance = 1E-3
    internal_constraint_tolerance = 1E-9
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeElasticityTensor
    block = 0
    fill_method = symmetric_isotropic
    C_ijkl = '0 1E6'
  [../]
  [./strain]
    type = ComputeFiniteStrain
    block = 0
    displacements = 'disp_x disp_y disp_z'
  [../]
  [./mc]
    type = ComputeMultiPlasticityStress
    block = 0
    ep_plastic_tolerance = 1E-9
    plastic_models = j2
    debug_fspb = crash
  [../]
[]


[Executioner]
  end_time = 1
  dt = 1
  type = Transient
[]


[Outputs]
  file_base = small_deform3
  exodus = false
  [./csv]
    type = CSV
    [../]
[]

(modules/solid_mechanics/test/tests/isotropicSD_plasticity/powerRuleHardening.i)

# UserObject IsotropicSD test, with power rule hardening with rate 1e2.
# Linear strain is applied in the x and y direction.

[Mesh]
  type = GeneratedMesh
  dim = 3
  nx = 1
  ny = 1
  nz = 1
  xmin =  -.5
  xmax = .5
  ymin = -.5
  ymax = .5
  zmin = -.5
  zmax = .5
[]


[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./disp_z]
  [../]
[]

[Kernels]
  [SolidMechanics]
    displacements = 'disp_x disp_y disp_z'
  [../]
[]


[BCs]
  [./xdisp]
    type = FunctionDirichletBC
    variable = disp_x
    boundary = 'right'
    function = '0.005*t'
  [../]
  [./ydisp]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = 'top'
    function = '0.005*t'
  [../]
  [./yfix]
    type = DirichletBC
    variable = disp_y
    #boundary = 'bottom top'
    boundary = 'bottom'
    value = 0
  [../]
  [./xfix]
    type = DirichletBC
    variable = disp_x
    boundary = 'left'
    value = 0
  [../]
  [./zfix]
    type = DirichletBC
    variable = disp_z
    #boundary = 'front back'
    boundary = 'back'
    value = 0
  [../]
[]

[AuxVariables]
  [./stress_xx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_zz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./plastic_xx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./plastic_xy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./plastic_xz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./plastic_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./plastic_yz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./plastic_zz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./f]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./iter]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./intnl]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./sdev]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./sdet]
    order = CONSTANT
    family = MONOMIAL
  [../]
[]

[AuxKernels]
  [./stress_xx]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xx
    index_i = 0
    index_j = 0
  [../]
  [./stress_xy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xy
    index_i = 0
    index_j = 1
  [../]
  [./stress_xz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xz
    index_i = 0
    index_j = 2
  [../]
  [./stress_yy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yy
    index_i = 1
    index_j = 1
  [../]
  [./stress_yz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yz
    index_i = 1
    index_j = 2
  [../]
  [./stress_zz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_zz
    index_i = 2
    index_j = 2
  [../]
  [./plastic_xx]
    type = RankTwoAux
    rank_two_tensor = plastic_strain
    variable = plastic_xx
    index_i = 0
    index_j = 0
  [../]
  [./plastic_xy]
    type = RankTwoAux
    rank_two_tensor = plastic_strain
    variable = plastic_xy
    index_i = 0
    index_j = 1
  [../]
  [./plastic_xz]
    type = RankTwoAux
    rank_two_tensor = plastic_strain
    variable = plastic_xz
    index_i = 0
    index_j = 2
  [../]
  [./plastic_yy]
    type = RankTwoAux
    rank_two_tensor = plastic_strain
    variable = plastic_yy
    index_i = 1
    index_j = 1
  [../]
  [./plastic_yz]
    type = RankTwoAux
    rank_two_tensor = plastic_strain
    variable = plastic_yz
    index_i = 1
    index_j = 2
  [../]
  [./plastic_zz]
    type = RankTwoAux
    rank_two_tensor = plastic_strain
    variable = plastic_zz
    index_i = 2
    index_j = 2
  [../]
  [./f]
    type = MaterialStdVectorAux
    index = 0
    property = plastic_yield_function
    variable = f
  [../]
  [./iter]
    type = MaterialRealAux
    property = plastic_NR_iterations
    variable = iter
  [../]
  [./intnl]
    type = MaterialStdVectorAux
    index = 0
    property = plastic_internal_parameter
    variable = intnl
  [../]
  [./sdev]
    type = RankTwoScalarAux
    variable = sdev
    rank_two_tensor = stress
    scalar_type = VonMisesStress
  [../]
[]

[Postprocessors]
  [./sdev]
    type = PointValue
    point = '0 0 0'
    variable = sdev
  [../]
  [./s_xx]
    type = PointValue
    point = '0 0 0'
    variable = stress_xx
  [../]
  [./p_xx]
    type = PointValue
    point = '0 0 0'
    variable = plastic_xx
  [../]
  [./s_xy]
    type = PointValue
    point = '0 0 0'
    variable = stress_xy
  [../]
  [./p_xy]
    type = PointValue
    point = '0 0 0'
    variable = plastic_xy
  [../]
  [./p_xz]
    type = PointValue
    point = '0 0 0'
    variable = plastic_xz
  [../]
  [./p_yz]
    type = PointValue
    point = '0 0 0'
    variable = plastic_yz
  [../]
  [./s_xz]
    type = PointValue
    point = '0 0 0'
    variable = stress_xz
  [../]
  [./s_yy]
    type = PointValue
    point = '0 0 0'
    variable = stress_yy
  [../]
  [./p_yy]
    type = PointValue
    point = '0 0 0'
    variable = plastic_yy
  [../]
  [./s_yz]
    type = PointValue
    point = '0 0 0'
    variable = stress_yz
  [../]
  [./s_zz]
    type = PointValue
    point = '0 0 0'
    variable = stress_zz
  [../]
  [./p_zz]
    type = PointValue
    point = '0 0 0'
    variable = plastic_zz
  [../]
  [./intnl]
    type = PointValue
    point = '0 0 0'
    variable = intnl
  [../]
[]

[UserObjects]
  [./str]
    type = SolidMechanicsHardeningPowerRule
    value_0 = 300
    epsilon0 = 1
    exponent = 1e2

  [../]
  [./IsotropicSD]
    type = SolidMechanicsPlasticIsotropicSD
    b = -0.2
    c = -0.779422863
    associative = true
    yield_strength = str
    yield_function_tolerance = 1e-5
    internal_constraint_tolerance = 1e-9
    use_custom_returnMap = false
    use_custom_cto = false
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeElasticityTensor
    block = 0
    fill_method = symmetric_isotropic
    C_ijkl = '121e3 80e3'
  [../]
  [./strain]
    type = ComputeFiniteStrain
    block = 0
    displacements = 'disp_x disp_y disp_z'
  [../]
  [./mc]
    type = ComputeMultiPlasticityStress
    block = 0
    ep_plastic_tolerance = 1e-9
    plastic_models = IsotropicSD
    debug_fspb = crash
    tangent_operator = elastic
  [../]
[]


[Executioner]
  num_steps = 3
  dt = .5
  type = Transient

  nl_rel_tol = 1e-6
  nl_max_its = 10
  l_tol = 1e-4
  l_max_its = 50

  solve_type = PJFNK
  petsc_options_iname = '-pc_type'
  petsc_options_value = 'lu'
[]


[Outputs]
  perf_graph = false
  csv = true
[]

[Preconditioning]
 [./smp]
   type = SMP
   full = true
 [../]
[]

(modules/solid_mechanics/test/tests/mohr_coulomb/except4.i)

# checking for exception error messages on the edge smoothing
# here edge_smoother=5deg, which means the friction_angle must be <= 35.747
[Mesh]
  type = GeneratedMesh
  dim = 3
  nx = 1
  ny = 1
  nz = 1
  xmin = -0.5
  xmax = 0.5
  ymin = -0.5
  ymax = 0.5
  zmin = -0.5
  zmax = 0.5
[]


[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./disp_z]
  [../]
[]

[Kernels]
  [SolidMechanics]
    displacements = 'disp_x disp_y disp_z'
  [../]
[]


[BCs]
  [./x]
    type = FunctionDirichletBC
    variable = disp_x
    boundary = 'front back'
    function = '1E-6*x'
  [../]
  [./y]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = 'front back'
    function = '1E-6*y'
  [../]
  [./z]
    type = FunctionDirichletBC
    variable = disp_z
    boundary = 'front back'
    function = '1E-6*z'
  [../]
[]

[AuxVariables]
  [./stress_xx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_zz]
    order = CONSTANT
    family = MONOMIAL
  [../]
[]

[AuxKernels]
  [./stress_xx]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xx
    index_i = 0
    index_j = 0
  [../]
  [./stress_xy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xy
    index_i = 0
    index_j = 1
  [../]
  [./stress_xz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xz
    index_i = 0
    index_j = 2
  [../]
  [./stress_yy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yy
    index_i = 1
    index_j = 1
  [../]
  [./stress_yz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yz
    index_i = 1
    index_j = 2
  [../]
  [./stress_zz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_zz
    index_i = 2
    index_j = 2
  [../]
[]

[Postprocessors]
  [./s_xx]
    type = PointValue
    point = '0 0 0'
    variable = stress_xx
  [../]
  [./s_xy]
    type = PointValue
    point = '0 0 0'
    variable = stress_xy
  [../]
  [./s_xz]
    type = PointValue
    point = '0 0 0'
    variable = stress_xz
  [../]
  [./s_yy]
    type = PointValue
    point = '0 0 0'
    variable = stress_yy
  [../]
  [./s_yz]
    type = PointValue
    point = '0 0 0'
    variable = stress_yz
  [../]
  [./s_zz]
    type = PointValue
    point = '0 0 0'
    variable = stress_zz
  [../]
[]

[UserObjects]
  [./mc_coh]
    type = SolidMechanicsHardeningConstant
    value = 10
  [../]
  [./mc_phi]
    type = SolidMechanicsHardeningExponential
    value_0 = 0.52359878 # 30deg
    value_residual = 0.62831853 # 36deg
    rate = 3000.0
  [../]
  [./mc_psi]
    type = SolidMechanicsHardeningConstant
    value = 5
    convert_to_radians = true
  [../]
  [./mc]
    type = SolidMechanicsPlasticMohrCoulomb
    cohesion = mc_coh
    friction_angle = mc_phi
    dilation_angle = mc_psi
    mc_tip_smoother = 1
    mc_edge_smoother = 5
    yield_function_tolerance = 1E-3
    internal_constraint_tolerance = 1E-9
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeElasticityTensor
    block = 0
    fill_method = symmetric_isotropic
    C_ijkl = '0 1E7'
  [../]
  [./strain]
    type = ComputeFiniteStrain
    block = 0
    displacements = 'disp_x disp_y disp_z'
  [../]
  [./mc]
    type = ComputeMultiPlasticityStress
    block = 0
    ep_plastic_tolerance = 1E-9
    plastic_models = mc
    debug_fspb = crash
    debug_jac_at_stress = '10 0 0 0 10 0 0 0 10'
    debug_jac_at_pm = 1
    debug_jac_at_intnl = 1
    debug_stress_change = 1E-5
    debug_pm_change = 1E-6
    debug_intnl_change = 1E-6
  [../]
[]


[Executioner]
  end_time = 1
  dt = 1
  type = Transient
[]


[Outputs]
  file_base = except4
  exodus = false
  [./csv]
    type = CSV
    [../]
[]

(modules/solid_mechanics/test/tests/mohr_coulomb/except1.i)

# checking for exception error messages
[Mesh]
  type = GeneratedMesh
  dim = 3
  nx = 1
  ny = 1
  nz = 1
  xmin = -0.5
  xmax = 0.5
  ymin = -0.5
  ymax = 0.5
  zmin = -0.5
  zmax = 0.5
[]


[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./disp_z]
  [../]
[]

[Kernels]
  [SolidMechanics]
    displacements = 'disp_x disp_y disp_z'
  [../]
[]


[BCs]
  [./x]
    type = FunctionDirichletBC
    variable = disp_x
    boundary = 'front back'
    function = '1E-6*x'
  [../]
  [./y]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = 'front back'
    function = '1E-6*y'
  [../]
  [./z]
    type = FunctionDirichletBC
    variable = disp_z
    boundary = 'front back'
    function = '1E-6*z'
  [../]
[]

[AuxVariables]
  [./stress_xx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_zz]
    order = CONSTANT
    family = MONOMIAL
  [../]
[]

[AuxKernels]
  [./stress_xx]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xx
    index_i = 0
    index_j = 0
  [../]
  [./stress_xy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xy
    index_i = 0
    index_j = 1
  [../]
  [./stress_xz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xz
    index_i = 0
    index_j = 2
  [../]
  [./stress_yy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yy
    index_i = 1
    index_j = 1
  [../]
  [./stress_yz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yz
    index_i = 1
    index_j = 2
  [../]
  [./stress_zz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_zz
    index_i = 2
    index_j = 2
  [../]
[]

[Postprocessors]
  [./s_xx]
    type = PointValue
    point = '0 0 0'
    variable = stress_xx
  [../]
  [./s_xy]
    type = PointValue
    point = '0 0 0'
    variable = stress_xy
  [../]
  [./s_xz]
    type = PointValue
    point = '0 0 0'
    variable = stress_xz
  [../]
  [./s_yy]
    type = PointValue
    point = '0 0 0'
    variable = stress_yy
  [../]
  [./s_yz]
    type = PointValue
    point = '0 0 0'
    variable = stress_yz
  [../]
  [./s_zz]
    type = PointValue
    point = '0 0 0'
    variable = stress_zz
  [../]
[]

[UserObjects]
  [./mc_coh]
    type = SolidMechanicsHardeningConstant
    value = 10
  [../]
  [./mc_phi]
    type = SolidMechanicsHardeningConstant
    value = 30
    convert_to_radians = true
  [../]
  [./mc_psi]
    type = SolidMechanicsHardeningConstant
    value = 45
    convert_to_radians = true
  [../]
  [./mc]
    type = SolidMechanicsPlasticMohrCoulomb
    cohesion = mc_coh
    friction_angle = mc_phi
    dilation_angle = mc_psi
    mc_tip_smoother = 1
    mc_edge_smoother = 25
    yield_function_tolerance = 1E-3
    internal_constraint_tolerance = 1E-9
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeElasticityTensor
    block = 0
    fill_method = symmetric_isotropic
    C_ijkl = '0 1E7'
  [../]
  [./strain]
    type = ComputeFiniteStrain
    block = 0
    displacements = 'disp_x disp_y disp_z'
  [../]
  [./mc]
    type = ComputeMultiPlasticityStress
    block = 0
    ep_plastic_tolerance = 1E-9
    plastic_models = mc
    debug_fspb = crash
    debug_jac_at_stress = '10 0 0 0 10 0 0 0 10'
    debug_jac_at_pm = 1
    debug_jac_at_intnl = 1
    debug_stress_change = 1E-5
    debug_pm_change = 1E-6
    debug_intnl_change = 1E-6
  [../]
[]


[Executioner]
  end_time = 1
  dt = 1
  type = Transient
[]


[Outputs]
  file_base = except1
  exodus = false
  [./csv]
    type = CSV
    [../]
[]

(modules/solid_mechanics/test/tests/mohr_coulomb/small_deform_hard_cubic.i)

# apply uniform stretches in x, y and z directions.
# let cohesion = 10, cohesion_residual = 2, cohesion_limit = 0.0003
# With cohesion = C, friction_angle = 60deg, tip_smoother = 4, the
# algorithm should return to
# sigma_m = (C*Cos(60) - 4)/Sin(60)
# This allows checking of the relationship for C

[Mesh]
  type = GeneratedMesh
  dim = 3
  nx = 1
  ny = 1
  nz = 1
  xmin = -0.5
  xmax = 0.5
  ymin = -0.5
  ymax = 0.5
  zmin = -0.5
  zmax = 0.5
[]


[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./disp_z]
  [../]
[]

[Kernels]
  [SolidMechanics]
    displacements = 'disp_x disp_y disp_z'
  [../]
[]


[BCs]
  [./x]
    type = FunctionDirichletBC
    variable = disp_x
    boundary = 'front back'
    function = '1E-6*x*t'
  [../]
  [./y]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = 'front back'
    function = '1E-6*y*t'
  [../]
  [./z]
    type = FunctionDirichletBC
    variable = disp_z
    boundary = 'front back'
    function = '1E-6*z*t'
  [../]
[]

[AuxVariables]
  [./stress_xx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_zz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./mc_int]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./yield_fcn]
    order = CONSTANT
    family = MONOMIAL
  [../]
[]

[AuxKernels]
  [./stress_xx]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xx
    index_i = 0
    index_j = 0
  [../]
  [./stress_xy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xy
    index_i = 0
    index_j = 1
  [../]
  [./stress_xz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xz
    index_i = 0
    index_j = 2
  [../]
  [./stress_yy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yy
    index_i = 1
    index_j = 1
  [../]
  [./stress_yz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yz
    index_i = 1
    index_j = 2
  [../]
  [./stress_zz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_zz
    index_i = 2
    index_j = 2
  [../]
  [./mc_int_auxk]
    type = MaterialStdVectorAux
    index = 0
    property = plastic_internal_parameter
    variable = mc_int
  [../]
  [./yield_fcn_auxk]
    type = MaterialStdVectorAux
    index = 0
    property = plastic_yield_function
    variable = yield_fcn
  [../]
[]

[Postprocessors]
  [./s_xx]
    type = PointValue
    point = '0 0 0'
    variable = stress_xx
  [../]
  [./s_xy]
    type = PointValue
    point = '0 0 0'
    variable = stress_xy
  [../]
  [./s_xz]
    type = PointValue
    point = '0 0 0'
    variable = stress_xz
  [../]
  [./s_yy]
    type = PointValue
    point = '0 0 0'
    variable = stress_yy
  [../]
  [./s_yz]
    type = PointValue
    point = '0 0 0'
    variable = stress_yz
  [../]
  [./s_zz]
    type = PointValue
    point = '0 0 0'
    variable = stress_zz
  [../]
  [./internal]
    type = PointValue
    point = '0 0 0'
    variable = mc_int
  [../]
  [./f]
    type = PointValue
    point = '0 0 0'
    variable = yield_fcn
  [../]
[]

[UserObjects]
  [./mc_coh]
    type = SolidMechanicsHardeningCubic
    value_0 = 10
    value_residual = 2
    internal_limit = 0.0003
  [../]
  [./mc_phi]
    type = SolidMechanicsHardeningConstant
    value = 60
    convert_to_radians = true
  [../]
  [./mc_psi]
    type = SolidMechanicsHardeningConstant
    value = 5
    convert_to_radians = true
  [../]
  [./mc]
    type = SolidMechanicsPlasticMohrCoulomb
    cohesion = mc_coh
    friction_angle = mc_phi
    dilation_angle = mc_psi
    mc_tip_smoother = 4
    mc_edge_smoother = 25
    yield_function_tolerance = 1E-3
    internal_constraint_tolerance = 1E-9
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeElasticityTensor
    block = 0
    fill_method = symmetric_isotropic
    C_ijkl = '0 1E7'
  [../]
  [./strain]
    type = ComputeFiniteStrain
    block = 0
    displacements = 'disp_x disp_y disp_z'
  [../]
  [./mc]
    type = ComputeMultiPlasticityStress
    block = 0
    ep_plastic_tolerance = 1E-9
    plastic_models = mc
    debug_fspb = crash
    debug_jac_at_stress = '10 1 2 1 10 3 2 3 10'
    debug_jac_at_pm = 1
    debug_jac_at_intnl = 1E-4
    debug_stress_change = 1E-5
    debug_pm_change = 1E-6
    debug_intnl_change = 1E-8
  [../]
[]


[Executioner]
  end_time = 10
  dt = 0.25
  type = Transient
[]


[Outputs]
  file_base = small_deform_hard_cubic
  exodus = false
  [./csv]
    type = CSV
    [../]
[]

(modules/solid_mechanics/test/tests/crystal_plasticity/monolithic_material_based/crysp_linesearch.i)

[Mesh]
  type = GeneratedMesh
  dim = 3
  elem_type = HEX8
  displacements = 'ux uy uz'
[]

[Variables]
  [./ux]
    block = 0
  [../]
  [./uy]
    block = 0
  [../]
  [./uz]
    block = 0
  [../]
[]

[AuxVariables]
  [./stress_zz]
    order = CONSTANT
    family = MONOMIAL
    block = 0
  [../]
  [./fp_zz]
    order = CONSTANT
    family = MONOMIAL
    block = 0
  [../]
  [./e_zz]
    order = CONSTANT
    family = MONOMIAL
    block = 0
  [../]
  [./gss1]
    order = CONSTANT
    family = MONOMIAL
    block = 0
  [../]
[]

[Functions]
  [./tdisp]
    type = ParsedFunction
    expression = 0.01*t
  [../]
[]

[Kernels]
  [SolidMechanics]
    displacements = 'ux uy uz'
    use_displaced_mesh = true
  [../]
[]

[AuxKernels]
  [./stress_zz]
    type = RankTwoAux
    variable = stress_zz
    rank_two_tensor = stress
    index_j = 2
    index_i = 2
    execute_on = timestep_end
    block = 0
  [../]
  [./fp_zz]
    type = RankTwoAux
    variable = fp_zz
    rank_two_tensor = fp
    index_j = 2
    index_i = 2
    execute_on = timestep_end
    block = 0
  [../]
  [./e_zz]
    type = RankTwoAux
    variable = e_zz
    rank_two_tensor = lage
    index_j = 2
    index_i = 2
    execute_on = timestep_end
    block = 0
  [../]
  [./gss1]
    type = MaterialStdVectorAux
    variable = gss1
    property = gss
    index = 0
    execute_on = timestep_end
    block = 0
  [../]
[]

[BCs]
  [./symmy]
    type = DirichletBC
    variable = uy
    boundary = bottom
    value = 0
  [../]
  [./symmx]
    type = DirichletBC
    variable = ux
    boundary = left
    value = 0
  [../]
  [./symmz]
    type = DirichletBC
    variable = uz
    boundary = back
    value = 0
  [../]
  [./tdisp]
    type = FunctionDirichletBC
    variable = uz
    boundary = front
    function = tdisp
  [../]
[]

[Materials]
  [./crysp]
    type = FiniteStrainCrystalPlasticity
    block = 0
    rtol = 1e-6
    abs_tol = 1e-8
    gtol = 1e-2
    slip_sys_file_name = input_slip_sys.txt
    nss = 12
    num_slip_sys_flowrate_props = 2 #Number of properties in a slip system
    flowprops = '1 4 0.001 0.1 5 8 0.001 0.1 9 12 0.001 0.1'
    hprops = '1.0 541.5 60.8 109.8 2.5'
    gprops = '1 4 60.8 5 8 60.8 9 12 60.8'
    tan_mod_type = exact
    use_line_search = true
    min_line_search_step_size = 0.01
  [../]
  [./elasticity_tensor]
    type = ComputeElasticityTensorCP
    block = 0
    C_ijkl = '1.684e5 1.214e5 1.214e5 1.684e5 1.214e5 1.684e5 0.754e5 0.754e5 0.754e5'
    fill_method = symmetric9
  [../]
  [./strain]
    type = ComputeFiniteStrain
    block = 0
    displacements = 'ux uy uz'
  [../]
[]

[Postprocessors]
  [./stress_zz]
    type = ElementAverageValue
    variable = stress_zz
    block = 'ANY_BLOCK_ID 0'
  [../]
  [./fp_zz]
    type = ElementAverageValue
    variable = fp_zz
    block = 'ANY_BLOCK_ID 0'
  [../]
  [./e_zz]
    type = ElementAverageValue
    variable = e_zz
    block = 'ANY_BLOCK_ID 0'
  [../]
  [./gss1]
    type = ElementAverageValue
    variable = gss1
    block = 'ANY_BLOCK_ID 0'
  [../]
[]

[Preconditioning]
  [./smp]
    type = SMP
    full = true
  [../]
[]

[Executioner]
  type = Transient

  #Preconditioned JFNK (default)
  solve_type = 'PJFNK'

  petsc_options_iname = '-pc_type'
  petsc_options_value = 'lu'

  nl_rel_tol = 1e-10
  nl_abs_tol = 1e-10

  dt = 0.025
  dtmax = 10.0
  dtmin = 0.02

  num_steps = 10
[]

[Outputs]
  file_base = crysp_lsearch_out
  exodus = true
[]

(modules/solid_mechanics/test/tests/multi/three_surface21.i)

# Plasticit models:
# SimpleTester0 with a = 0 and b = 1 and strength = 1
# SimpleTester1 with a = 1 and b = 0 and strength = 1
# SimpleTester2 with a = 1 and b = 1 and strength = 1.5
#
# Lame lambda = 0 (Poisson=0).  Lame mu = 0.5E6
#
# A single element is stretched by 2.0E-6m in y direction and 2.0E-6 in z direction.
# trial stress_yy = 2.0 and stress_zz = 2.0
#
# Then all yield functions will activate
# However, there is linear dependence.  SimpleTester1 or SimpleTester0 will be rutned off (they are equi-distant).
# The algorithm will return to one corner point, but there will be negative plastic multipliers
# so the other SimpleTester0 or SimpleTester1 will turn off, and the algorithm will return to
# stress_yy=0.75 and stress_zz=0.75
# internal2=1.25


[Mesh]
  type = GeneratedMesh
  dim = 3
  nx = 1
  ny = 1
  nz = 1
  xmin = -0.5
  xmax = 0.5
  ymin = -0.5
  ymax = 0.5
  zmin = -0.5
  zmax = 0.5
[]


[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./disp_z]
  [../]
[]

[Kernels]
  [SolidMechanics]
    displacements = 'disp_x disp_y disp_z'
  [../]
[]


[BCs]
  [./x]
    type = FunctionDirichletBC
    variable = disp_x
    boundary = 'front back'
    function = '0E-6*x'
  [../]
  [./y]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = 'front back'
    function = '2.0E-6*y'
  [../]
  [./z]
    type = FunctionDirichletBC
    variable = disp_z
    boundary = 'front back'
    function = '2.0E-6*z'
  [../]
[]

[AuxVariables]
  [./stress_xx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_zz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./f0]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./f1]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./f2]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./int0]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./int1]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./int2]
    order = CONSTANT
    family = MONOMIAL
  [../]
[]

[AuxKernels]
  [./stress_xx]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xx
    index_i = 0
    index_j = 0
  [../]
  [./stress_xy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xy
    index_i = 0
    index_j = 1
  [../]
  [./stress_xz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xz
    index_i = 0
    index_j = 2
  [../]
  [./stress_yy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yy
    index_i = 1
    index_j = 1
  [../]
  [./stress_yz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yz
    index_i = 1
    index_j = 2
  [../]
  [./stress_zz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_zz
    index_i = 2
    index_j = 2
  [../]
  [./f0]
    type = MaterialStdVectorAux
    property = plastic_yield_function
    index = 0
    variable = f0
  [../]
  [./f1]
    type = MaterialStdVectorAux
    property = plastic_yield_function
    index = 1
    variable = f1
  [../]
  [./f2]
    type = MaterialStdVectorAux
    property = plastic_yield_function
    index = 2
    variable = f2
  [../]
  [./int0]
    type = MaterialStdVectorAux
    property = plastic_internal_parameter
    factor = 1E6
    index = 0
    variable = int0
  [../]
  [./int1]
    type = MaterialStdVectorAux
    property = plastic_internal_parameter
    factor = 1E6
    index = 1
    variable = int1
  [../]
  [./int2]
    type = MaterialStdVectorAux
    property = plastic_internal_parameter
    factor = 1E6
    index = 2
    variable = int2
  [../]
[]

[Postprocessors]
  [./s_xx]
    type = PointValue
    point = '0 0 0'
    variable = stress_xx
  [../]
  [./s_xy]
    type = PointValue
    point = '0 0 0'
    variable = stress_xy
  [../]
  [./s_xz]
    type = PointValue
    point = '0 0 0'
    variable = stress_xz
  [../]
  [./s_yy]
    type = PointValue
    point = '0 0 0'
    variable = stress_yy
  [../]
  [./s_yz]
    type = PointValue
    point = '0 0 0'
    variable = stress_yz
  [../]
  [./s_zz]
    type = PointValue
    point = '0 0 0'
    variable = stress_zz
  [../]
  [./f0]
    type = PointValue
    point = '0 0 0'
    variable = f0
  [../]
  [./f1]
    type = PointValue
    point = '0 0 0'
    variable = f1
  [../]
  [./f2]
    type = PointValue
    point = '0 0 0'
    variable = f2
  [../]
  [./int0]
    type = PointValue
    point = '0 0 0'
    variable = int0
  [../]
  [./int1]
    type = PointValue
    point = '0 0 0'
    variable = int1
  [../]
  [./int2]
    type = PointValue
    point = '0 0 0'
    variable = int2
  [../]
[]

[UserObjects]
  [./simple0]
    type = SolidMechanicsPlasticSimpleTester
    a = 0
    b = 1
    strength = 1
    yield_function_tolerance = 1.0E-9
    internal_constraint_tolerance = 1.0E-9
  [../]
  [./simple1]
    type = SolidMechanicsPlasticSimpleTester
    a = 1
    b = 0
    strength = 1
    yield_function_tolerance = 1.0E-9
    internal_constraint_tolerance = 1.0E-9
  [../]
  [./simple2]
    type = SolidMechanicsPlasticSimpleTester
    a = 1
    b = 1
    strength = 1.5
    yield_function_tolerance = 1.0E-9
    internal_constraint_tolerance = 1.0E-9
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeElasticityTensor
    block = 0
    fill_method = symmetric_isotropic
    C_ijkl = '0 0.5E6'
  [../]
  [./strain]
    type = ComputeFiniteStrain
    block = 0
    displacements = 'disp_x disp_y disp_z'
  [../]
  [./multi]
    type = ComputeMultiPlasticityStress
    block = 0
    ep_plastic_tolerance = 1E-9
    plastic_models = 'simple0 simple1 simple2'
    max_NR_iterations = 2
    min_stepsize = 1
    debug_fspb = crash
    debug_jac_at_stress = '10 0 0 0 10 0 0 0 10'
    debug_jac_at_pm = '1 1'
    debug_jac_at_intnl = '1 1'
    debug_stress_change = 1E-5
    debug_pm_change = '1E-6 1E-6'
    debug_intnl_change = '1E-6 1E-6'
  [../]
[]


[Executioner]
  end_time = 1
  dt = 1
  type = Transient
[]


[Outputs]
  file_base = three_surface21
  exodus = false
  [./csv]
    type = CSV
    [../]
[]

(modules/contact/test/tests/pdass_problems/cylinder_friction.i)

[GlobalParams]
  volumetric_locking_correction = true
  displacements = 'disp_x disp_y'
[]

[Mesh]
  [input_file]
    type = FileMeshGenerator
    file = hertz_cyl_coarser.e
  []
  [secondary]
    type = LowerDBlockFromSidesetGenerator
    new_block_id = 10001
    new_block_name = 'secondary_lower'
    sidesets = '3'
    input = input_file
  []
  [primary]
    type = LowerDBlockFromSidesetGenerator
    new_block_id = 10000
    sidesets = '2'
    new_block_name = 'primary_lower'
    input = secondary
  []
[]

[Problem]
  type = ReferenceResidualProblem
  extra_tag_vectors = 'ref'
  reference_vector = 'ref'
[]

[Variables]
  [disp_x]
  []
  [disp_y]
  []
  [frictionless_normal_lm]
    order = FIRST
    family = LAGRANGE
    block = 'secondary_lower'
    use_dual = true
  []
  [tangential_lm]
    block = 'secondary_lower'
    use_dual = true
  []
[]

[AuxVariables]
  [stress_xx]
    order = CONSTANT
    family = MONOMIAL
  []
  [stress_yy]
    order = CONSTANT
    family = MONOMIAL
  []
  [stress_xy]
    order = CONSTANT
    family = MONOMIAL
  []
  [saved_x]
  []
  [saved_y]
  []
  [diag_saved_x]
  []
  [diag_saved_y]
  []
[]

[Functions]
  [disp_ramp_vert]
    type = PiecewiseLinear
    x = '0. 1. 3.5'
    y = '0. -0.020 -0.020'
  []
  [disp_ramp_horz]
    type = PiecewiseLinear
    x = '0. 1. 3.5'
    y = '0. 0.0 0.015'
  []
[]

[Kernels]
  [TensorMechanics]
    use_displaced_mesh = true
    save_in = 'saved_x saved_y'
    extra_vector_tags = 'ref'
    block = '1 2 3 4 5 6 7'
  []
[]

[AuxKernels]
  [stress_xx]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xx
    index_i = 0
    index_j = 0
    execute_on = timestep_end
    block = '1 2 3 4 5 6 7'
  []
  [stress_yy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yy
    index_i = 1
    index_j = 1
    execute_on = timestep_end
    block = '1 2 3 4 5 6 7'
  []
  [stress_xy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xy
    index_i = 0
    index_j = 1
    execute_on = timestep_end
    block = '1 2 3 4 5 6 7'
  []
[]

[Postprocessors]
  [bot_react_x]
    type = NodalSum
    variable = saved_x
    boundary = 1
  []
  [bot_react_y]
    type = NodalSum
    variable = saved_y
    boundary = 1
  []
  [top_react_x]
    type = NodalSum
    variable = saved_x
    boundary = 4
  []
  [top_react_y]
    type = NodalSum
    variable = saved_y
    boundary = 4
  []
  [_dt]
    type = TimestepSize
  []
  [num_lin_it]
    type = NumLinearIterations
  []
  [num_nonlin_it]
    type = NumNonlinearIterations
  []
[]

[BCs]
  [side_x]
    type = DirichletBC
    variable = disp_y
    boundary = '1 2'
    value = 0.0
  []
  [bot_y]
    type = DirichletBC
    variable = disp_x
    boundary = '1 2'
    value = 0.0
  []
  [top_y_disp]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = 4
    function = disp_ramp_vert
  []
  [top_x_disp]
    type = FunctionDirichletBC
    variable = disp_x
    boundary = 4
    function = disp_ramp_horz
  []
[]

[Materials]
  [stuff1_elas_tens]
    type = ComputeIsotropicElasticityTensor
    block = '1'
    youngs_modulus = 1e10
    poissons_ratio = 0.0
  []
  [stuff1_strain]
    type = ComputeFiniteStrain
    block = '1'
  []
  [stuff1_stress]
    type = ComputeFiniteStrainElasticStress
    block = '1'
  []
  [stuff2_elas_tens]
    type = ComputeIsotropicElasticityTensor
    block = '2 3 4 5 6 7'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  []
  [stuff2_strain]
    type = ComputeFiniteStrain
    block = '2 3 4 5 6 7'
  []
  [stuff2_stress]
    type = ComputeFiniteStrainElasticStress
    block = '2 3 4 5 6 7'
  []
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'

  petsc_options = '-snes_ksp_ew'
  petsc_options_iname = '-pc_type -pc_factor_mat_solver_type -pc_factor_shift_type -pc_factor_shift_amount -mat_mffd_err'
  petsc_options_value = 'lu       superlu_dist                  NONZERO               1e-15                   1e-5'

  line_search = 'none'

  nl_abs_tol = 1e-7

  start_time = 0.0
  end_time = 0.3 # 3.5
  l_tol = 1e-4
  dt = 0.1
  dtmin = 0.001
[]

[Preconditioning]
  [SMP]
    type = SMP
    full = true
  []
[]

[VectorPostprocessors]
  [x_disp]
    type = NodalValueSampler
    variable = disp_x
    boundary = '3 4'
    sort_by = id
  []
  [y_disp]
    type = NodalValueSampler
    variable = disp_y
    boundary = '3 4'
    sort_by = id
  []
  [cont_press]
    type = NodalValueSampler
    variable = frictionless_normal_lm
    boundary = '3'
    sort_by = id
  []
  [friction]
    type = NodalValueSampler
    variable = frictionless_normal_lm
    boundary = '3'
    sort_by = id
  []
[]

[Outputs]
  print_linear_residuals = true
  perf_graph = true
  exodus = false
  csv = false
  [console]
    type = Console
    max_rows = 5
  []
  [chkfile]
    type = CSV
    show = 'x_disp y_disp cont_press friction'
    file_base = cylinder_friction_check
    create_final_symlink = true
    execute_on = 'FINAL'
  []
[]

[UserObjects]
  [weighted_vel_uo]
    type = LMWeightedVelocitiesUserObject
    primary_boundary = 2
    secondary_boundary = 3
    primary_subdomain = 10000
    secondary_subdomain = 10001
    lm_variable_normal = frictionless_normal_lm
    lm_variable_tangential_one = tangential_lm
    secondary_variable = disp_x
    disp_x = disp_x
    disp_y = disp_y
  []
[]

[Constraints]
  [weighted_gap_lm]
    type = ComputeFrictionalForceLMMechanicalContact
    primary_boundary = 2
    secondary_boundary = 3
    primary_subdomain = 10000
    secondary_subdomain = 10001
    variable = frictionless_normal_lm
    disp_x = disp_x
    disp_y = disp_y
    use_displaced_mesh = true
    friction_lm = tangential_lm
    mu = 0.4
    c_t = 1.0e5
    c = 1.0e6
    weighted_gap_uo = weighted_vel_uo
    weighted_velocities_uo = weighted_vel_uo
  []
  [x]
    type = NormalMortarMechanicalContact
    primary_boundary = '2'
    secondary_boundary = '3'
    primary_subdomain = '10000'
    secondary_subdomain = '10001'
    variable = frictionless_normal_lm
    secondary_variable = disp_x
    component = x
    use_displaced_mesh = true
    compute_lm_residuals = false
    weighted_gap_uo = weighted_vel_uo
  []
  [y]
    type = NormalMortarMechanicalContact
    primary_boundary = '2'
    secondary_boundary = '3'
    primary_subdomain = '10000'
    secondary_subdomain = '10001'
    variable = frictionless_normal_lm
    secondary_variable = disp_y
    component = y
    use_displaced_mesh = true
    compute_lm_residuals = false
    weighted_gap_uo = weighted_vel_uo
  []
  [tangential_x]
    type = TangentialMortarMechanicalContact
    primary_boundary = 2
    secondary_boundary = 3
    primary_subdomain = 10000
    secondary_subdomain = 10001
    variable = tangential_lm
    secondary_variable = disp_x
    component = x
    use_displaced_mesh = true
    compute_lm_residuals = false
    weighted_velocities_uo = weighted_vel_uo
  []
  [tangential_y]
    type = TangentialMortarMechanicalContact
    primary_boundary = 2
    secondary_boundary = 3
    primary_subdomain = 10000
    secondary_subdomain = 10001
    variable = tangential_lm
    secondary_variable = disp_y
    component = y
    use_displaced_mesh = true
    compute_lm_residuals = false
    weighted_velocities_uo = weighted_vel_uo
  []
[]

(modules/solid_mechanics/test/tests/crystal_plasticity/monolithic_material_based/cp_slip_rate_integ/crysp.i)

[Mesh]
  type = GeneratedMesh
  dim = 3
  elem_type = HEX8
  displacements = 'disp_x disp_y disp_z'
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./disp_z]
  [../]
[]

[AuxVariables]
  [./stress_zz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./fp_zz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./e_zz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./gss1]
    order = CONSTANT
    family = MONOMIAL
  [../]
[]

[Functions]
  [./tdisp]
    type = ParsedFunction
    expression = 0.01*t
  [../]
[]

[Kernels]
  [SolidMechanics]
    displacements = 'disp_x disp_y disp_z'
    use_displaced_mesh = true
  [../]
[]

[AuxKernels]
  [./stress_zz]
    type = RankTwoAux
    variable = stress_zz
    rank_two_tensor = stress
    index_j = 2
    index_i = 2
    execute_on = timestep_end
  [../]
  [./fp_zz]
    type = RankTwoAux
    variable = fp_zz
    rank_two_tensor = fp
    index_j = 2
    index_i = 2
    execute_on = timestep_end
  [../]
  [./e_zz]
    type = RankTwoAux
    variable = e_zz
    rank_two_tensor = lage
    index_j = 2
    index_i = 2
    execute_on = timestep_end
  [../]
  [./gss1]
    type = MaterialStdVectorAux
    variable = gss1
    property = gss
    index = 0
    execute_on = timestep_end
  [../]
[]

[BCs]
  [./symmy]
    type = DirichletBC
    variable = disp_y
    boundary = bottom
    value = 0
  [../]
  [./symmx]
    type = DirichletBC
    variable = disp_x
    boundary = left
    value = 0
  [../]
  [./symmz]
    type = DirichletBC
    variable = disp_z
    boundary = back
    value = 0
  [../]
  [./tdisp]
    type = FunctionDirichletBC
    variable = disp_z
    boundary = front
    function = tdisp
  [../]
[]

[Materials]
  [./crysp]
    type = FiniteStrainCPSlipRateRes
    gtol = 1e-2
    rtol = 1e-8
    abs_tol = 1e-15
    slip_sys_file_name = input_slip_sys.txt
    nss = 12
    num_slip_sys_flowrate_props = 2 #Number of properties in a slip system
    flowprops = '1 4 0.001 0.1 5 8 0.001 0.1 9 12 0.001 0.1'
    hprops = '1.0 541.5 60.8 109.8 2.5'
    gprops = '1 4 60.8 5 8 60.8 9 12 60.8'
    tan_mod_type = exact
    slip_incr_tol = 1
  [../]
  [./elasticity_tensor]
    type = ComputeElasticityTensorCP
    C_ijkl = '1.684e5 1.214e5 1.214e5 1.684e5 1.214e5 1.684e5 0.754e5 0.754e5 0.754e5'
    fill_method = symmetric9
  [../]
  [./strain]
    type = ComputeFiniteStrain
    displacements = 'disp_x disp_y disp_z'
  [../]
[]

[Postprocessors]
  [./stress_zz]
    type = ElementAverageValue
    variable = stress_zz
  [../]
  [./fp_zz]
    type = ElementAverageValue
    variable = fp_zz
  [../]
  [./e_zz]
    type = ElementAverageValue
    variable = e_zz
  [../]
  [./gss1]
    type = ElementAverageValue
    variable = gss1
  [../]
[]

[Preconditioning]
  [./smp]
    type = SMP
    full = true
  [../]
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'

  petsc_options_iname = '-pc_type'
  petsc_options_value = 'lu'

  dt = 0.2
  dtmin = 0.05
  dtmax = 10.0

  nl_rel_tol = 1e-10
  nl_abs_tol = 1e-10

  end_time = 1
[]

[Outputs]
  file_base = out
  exodus = true
  print_linear_residuals = true
  perf_graph = true
[]

(modules/contact/test/tests/verification/patch_tests/brick_4/brick4_mu_0_2_pen.i)

[GlobalParams]
  order = SECOND
  displacements = 'disp_x disp_y disp_z'
[]

[Mesh]
  file = brick4_mesh.e
[]

[Problem]
  type = ReferenceResidualProblem
  extra_tag_vectors = 'ref'
  reference_vector = 'ref'
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./disp_z]
  [../]
[]

[AuxVariables]
  [./stress_xx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_zz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./penetration]
  [../]
  [./saved_x]
  [../]
  [./saved_y]
  [../]
  [./saved_z]
  [../]
  [./diag_saved_x]
  [../]
  [./diag_saved_y]
  [../]
  [./diag_saved_z]
  [../]
  [./inc_slip_x]
  [../]
  [./inc_slip_y]
  [../]
  [./inc_slip_z]
  [../]
  [./accum_slip_x]
  [../]
  [./accum_slip_y]
  [../]
  [./accum_slip_z]
  [../]
  [./tang_force_x]
  [../]
  [./tang_force_y]
  [../]
  [./tang_force_z]
  [../]
[]

[Kernels]
  [./TensorMechanics]
    use_displaced_mesh = true
    save_in = 'saved_x saved_y saved_z'
    extra_vector_tags = 'ref'
  [../]
[]

[AuxKernels]
  [./stress_xx]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xx
    index_i = 0
    index_j = 0
    execute_on = timestep_end
  [../]
  [./stress_yy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yy
    index_i = 1
    index_j = 1
    execute_on = timestep_end
  [../]
  [./stress_xy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xy
    index_i = 0
    index_j = 1
    execute_on = timestep_end
  [../]
  [./stress_zz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_zz
    index_i = 2
    index_j = 2
    execute_on = timestep_end
  [../]
  [./inc_slip_x]
    type = PenetrationAux
    variable = inc_slip_x
    execute_on = timestep_end
    boundary = 3
    paired_boundary = 4
  [../]
  [./inc_slip_y]
    type = PenetrationAux
    variable = inc_slip_y
    execute_on = timestep_end
    boundary = 3
    paired_boundary = 4
  [../]
  [./accum_slip_x]
    type = PenetrationAux
    variable = accum_slip_x
    execute_on = timestep_end
    boundary = 3
    paired_boundary = 4
  [../]
  [./accum_slip_y]
    type = PenetrationAux
    variable = accum_slip_y
    execute_on = timestep_end
    boundary = 3
    paired_boundary = 4
  [../]
  [./penetration]
    type = PenetrationAux
    variable = penetration
    boundary = 3
    paired_boundary = 4
  [../]
  [./tang_force_x]
    type = PenetrationAux
    variable = tang_force_x
    quantity = tangential_force_x
    boundary = 3
    paired_boundary = 4
  [../]
  [./tang_force_y]
    type = PenetrationAux
    variable = tang_force_y
    quantity = tangential_force_y
    boundary = 3
    paired_boundary = 4
  [../]
[]

[Postprocessors]
  [./bot_react_x]
    type = NodalSum
    variable = saved_x
    boundary = 1
  [../]
  [./bot_react_y]
    type = NodalSum
    variable = saved_y
    boundary = 1
  [../]
  [./top_react_x]
    type = NodalSum
    variable = saved_x
    boundary = 5
  [../]
  [./top_react_y]
    type = NodalSum
    variable = saved_y
    boundary = 5
  [../]
  [./ref_resid_x]
    type = NodalL2Norm
    execute_on = timestep_end
    variable = saved_x
  [../]
  [./ref_resid_y]
    type = NodalL2Norm
    execute_on = timestep_end
    variable = saved_y
  [../]
  [./sigma_yy]
    type = ElementAverageValue
    variable = stress_yy
  [../]
  [./sigma_zz]
    type = ElementAverageValue
    variable = stress_zz
  [../]
  [./disp_x59]
    type = NodalVariableValue
    nodeid = 58
    variable = disp_x
  [../]
  [./disp_x64]
    type = NodalVariableValue
    nodeid = 63
    variable = disp_x
  [../]
  [./disp_y59]
    type = NodalVariableValue
    nodeid = 58
    variable = disp_y
  [../]
  [./disp_y64]
    type = NodalVariableValue
    nodeid = 63
    variable = disp_y
  [../]
  [./_dt]
    type = TimestepSize
  [../]
  [./num_lin_it]
    type = NumLinearIterations
  [../]
  [./num_nonlin_it]
    type = NumNonlinearIterations
  [../]
[]

[BCs]
  [./bot_y]
    type = DirichletBC
    variable = disp_y
    boundary = 1
    value = 0.0
  [../]
  [./side_x]
    type = DirichletBC
    variable = disp_x
    boundary = 2
    value = 0.0
  [../]
  [./back_z]
    type = DirichletBC
    variable = disp_z
    boundary = 6
    value = 0.0
  [../]
  [./top_press]
    type = Pressure
    variable = disp_y
    boundary = 5
    factor = 109.89
  [../]
[]

[Materials]
  [./bot_elas_tens]
    type = ComputeIsotropicElasticityTensor
    block = '1'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./bot_strain]
    type = ComputeFiniteStrain
    block = '1'
  [../]
  [./bot_stress]
    type = ComputeFiniteStrainElasticStress
    block = '1'
  [../]
  [./top_elas_tens]
    type = ComputeIsotropicElasticityTensor
    block = '2'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./top_strain]
    type = ComputeFiniteStrain
    block = '2'
  [../]
  [./top_stress]
    type = ComputeFiniteStrainElasticStress
    block = '2'
  [../]
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'

  petsc_options_iname = '-pc_type -pc_factor_mat_solver_type'
  petsc_options_value = 'lu     superlu_dist'

  line_search = 'none'

  nl_abs_tol = 1e-7
  nl_rel_tol = 1e-6
  l_max_its = 50
  nl_max_its = 100
  dt = 1.0
  end_time = 1.0
  num_steps = 10
  dtmin = 1.0
  l_tol = 1e-4
[]

[VectorPostprocessors]
  [./x_disp]
    type = NodalValueSampler
    variable = disp_x
    boundary = '1 3 4 5'
    sort_by = id
  [../]
  [./y_disp]
    type = NodalValueSampler
    variable = disp_y
    boundary = '1 3 4 5'
    sort_by = id
  [../]
  [./cont_press]
    type = NodalValueSampler
    variable = contact_pressure
    boundary = '3'
    sort_by = id
  [../]
[]

[Outputs]
  file_base = brick4_mu_0_2_pen_out
  print_linear_residuals = true
  perf_graph = true
  [./exodus]
    type = Exodus
    elemental_as_nodal = true
  [../]
  [./console]
    type = Console
    max_rows = 5
  [../]
  [./chkfile]
    type = CSV
    file_base = brick4_mu_0_2_pen_check
    show = 'bot_react_x bot_react_y disp_x59 disp_y59 disp_x64 disp_y64 stress_yy stress_zz top_react_x top_react_y x_disp y_disp cont_press'
    execute_vector_postprocessors_on = timestep_end
  [../]
  [./outfile]
    type = CSV
    delimiter = ' '
    execute_vector_postprocessors_on = none
  [../]
[]

[Contact]
  [./leftright]
    secondary = 3
    primary = 4
    model = coulomb
    formulation = penalty
    normalize_penalty = true
    friction_coefficient = 0.2
    penalty = 1e+6
  [../]
[]

(modules/solid_mechanics/test/tests/j2_plasticity/solid_mechanics_j2plasticity.i)

[Mesh]
  displacements = 'x_disp y_disp z_disp'
  [generated_mesh]
    type = GeneratedMeshGenerator
    elem_type = HEX8
    dim = 3
    nx = 1
    ny = 1
    nz = 1
    xmin = 0.0
    xmax = 1.0
    ymin = 0.0
    ymax = 1.0
    zmin = 0.0
    zmax = 1.0
  []
  [cnode]
    type = ExtraNodesetGenerator
    coord = '0.0 0.0 0.0'
    new_boundary = 6
    input = generated_mesh
  []
  [snode]
    type = ExtraNodesetGenerator
    coord = '1.0 0.0 0.0'
    new_boundary = 7
    input = cnode
  []
[]

[Variables]
  [./x_disp]
    order = FIRST
    family = LAGRANGE
  [../]
  [./y_disp]
    order = FIRST
    family = LAGRANGE
  [../]
  [./z_disp]
    order = FIRST
    family = LAGRANGE
  [../]
[]

[Kernels]
  [SolidMechanics]
    displacements = 'x_disp y_disp z_disp'
    use_displaced_mesh = true
  [../]
[]

[Materials]
  [./fplastic]
    type = FiniteStrainPlasticMaterial
    block=0
    yield_stress='0. 445. 0.05 610. 0.1 680. 0.38 810. 0.95 920. 2. 950.'
  [../]
  [./elasticity_tensor]
    type = ComputeElasticityTensor
    block = 0
    C_ijkl = '2.827e5 1.21e5 1.21e5 2.827e5 1.21e5 2.827e5 0.808e5 0.808e5 0.808e5'
    fill_method = symmetric9
  [../]
  [./strain]
    type = ComputeFiniteStrain
    block = 0
    displacements = 'x_disp y_disp z_disp'
  [../]
[]

[Functions]
  [./topfunc]
    type = ParsedFunction
    expression = 't'
  [../]
[]

[BCs]
  [./bottom3]
    type = DirichletBC
    variable = z_disp
    boundary = 0
    value = 0.0
  [../]
  [./top]
    type = FunctionDirichletBC
    variable = z_disp
    boundary = 5
    function = topfunc
  [../]
  [./corner1]
    type = DirichletBC
    variable = x_disp
    boundary = 6
    value = 0.0
  [../]
  [./corner2]
    type = DirichletBC
    variable = y_disp
    boundary = 6
    value = 0.0
  [../]
  [./corner3]
    type = DirichletBC
    variable = z_disp
    boundary = 6
    value = 0.0
  [../]
  [./side1]
    type = DirichletBC
    variable = y_disp
    boundary = 7
    value = 0.0
  [../]
  [./side2]
    type = DirichletBC
    variable = z_disp
    boundary = 7
    value = 0.0
  [../]
[]

[AuxVariables]
  [./stress_zz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./peeq]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./pe11]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./pe22]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./pe33]
    order = CONSTANT
    family = MONOMIAL
  [../]
[]

[AuxKernels]
  [./stress_zz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_zz
    index_i = 2
    index_j = 2
  [../]
  [./pe11]
    type = RankTwoAux
    rank_two_tensor = plastic_strain
    variable = pe11
    index_i = 0
    index_j = 0
  [../]
    [./pe22]
    type = RankTwoAux
    rank_two_tensor = plastic_strain
    variable = pe22
    index_i = 1
    index_j = 1
  [../]
  [./pe33]
    type = RankTwoAux
    rank_two_tensor = plastic_strain
    variable = pe33
    index_i = 2
    index_j = 2
  [../]
  [./eqv_plastic_strain]
    type = MaterialRealAux
    property = eqv_plastic_strain
    variable = peeq
  [../]
[]

[Preconditioning]
  [./SMP]
   type = SMP
   full=true
  [../]
[]

[Executioner]
  type = Transient

  dt=0.1
  dtmax=1
  dtmin=0.1
  end_time=1.0

  nl_abs_tol = 1e-10
[]


[Outputs]
  file_base = out
  exodus = true
[]

(modules/contact/test/tests/pdass_problems/cylinder_friction_penalty.i)

[GlobalParams]
  volumetric_locking_correction = true
  displacements = 'disp_x disp_y'
[]

[Mesh]
  [input_file]
    type = FileMeshGenerator
    file = hertz_cyl_coarser.e
  []
  [secondary]
    type = LowerDBlockFromSidesetGenerator
    new_block_id = 10001
    new_block_name = 'secondary_lower'
    sidesets = '3'
    input = input_file
  []
  [primary]
    type = LowerDBlockFromSidesetGenerator
    new_block_id = 10000
    sidesets = '2'
    new_block_name = 'primary_lower'
    input = secondary
  []
  allow_renumbering = false
[]

[Problem]
  type = ReferenceResidualProblem
  extra_tag_vectors = 'ref'
  reference_vector = 'ref'
[]

[Variables]
  [disp_x]
  []
  [disp_y]
  []
[]

[AuxVariables]
  [penalty_normal_pressure]
    order = FIRST
    family = LAGRANGE
  []
  [penalty_frictional_pressure]
    order = FIRST
    family = LAGRANGE
  []
  [accumulated_slip_one]
    order = FIRST
    family = LAGRANGE
  []
  [tangential_vel_one]
    order = FIRST
    family = LAGRANGE
  []
  [weighted_gap]
    order = FIRST
    family = LAGRANGE
  []
  [stress_xx]
    order = CONSTANT
    family = MONOMIAL
  []
  [stress_yy]
    order = CONSTANT
    family = MONOMIAL
  []
  [stress_xy]
    order = CONSTANT
    family = MONOMIAL
  []
  [react_x]
  []
  [react_y]
  []
[]

[Functions]
  [disp_ramp_vert]
    type = PiecewiseLinear
    x = '0. 1. 3.5'
    y = '0. -0.020 -0.020'
  []
  [disp_ramp_horz]
    type = PiecewiseLinear
    x = '0. 1. 3.5'
    y = '0. 0.0 0.015'
  []
[]

[Kernels]
  [TensorMechanics]
    use_displaced_mesh = true
    extra_vector_tags = 'ref'
    block = '1 2 3 4 5 6 7'
  []
[]

[AuxKernels]
  [penalty_normal_pressure_auxk]
    type = PenaltyMortarUserObjectAux
    variable = penalty_normal_pressure
    user_object = friction_uo
    contact_quantity = normal_pressure
  []
  [penalty_frictional_pressure_auxk]
    type = PenaltyMortarUserObjectAux
    variable = penalty_frictional_pressure
    user_object = friction_uo
    contact_quantity = tangential_pressure_one
  []
  [penalty_accumulated_slip_auxk]
    type = PenaltyMortarUserObjectAux
    variable = accumulated_slip_one
    user_object = friction_uo
    contact_quantity = accumulated_slip_one
  []
  [penalty_tangential_vel_auxk]
    type = PenaltyMortarUserObjectAux
    variable = tangential_vel_one
    user_object = friction_uo
    contact_quantity = tangential_velocity_one
  []
  [penalty_weighted_gap_auxk]
    type = PenaltyMortarUserObjectAux
    variable = weighted_gap
    user_object = friction_uo
    contact_quantity = normal_gap
  []
  [stress_xx]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xx
    index_i = 0
    index_j = 0
    execute_on = timestep_end
    block = '1 2 3 4 5 6 7'
  []
  [stress_yy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yy
    index_i = 1
    index_j = 1
    execute_on = timestep_end
    block = '1 2 3 4 5 6 7'
  []
  [stress_xy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xy
    index_i = 0
    index_j = 1
    execute_on = timestep_end
    block = '1 2 3 4 5 6 7'
  []
  [react_x]
    type = TagVectorAux
    vector_tag = 'ref'
    v = 'disp_x'
    variable = 'react_x'
  []
  [react_y]
    type = TagVectorAux
    vector_tag = 'ref'
    v = 'disp_y'
    variable = 'react_y'
  []
[]

[Postprocessors]
  [bot_react_x]
    type = NodalSum
    variable = react_x
    boundary = 1
  []
  [bot_react_y]
    type = NodalSum
    variable = react_y
    boundary = 1
  []
  [top_react_x]
    type = NodalSum
    variable = react_x
    boundary = 4
  []
  [top_react_y]
    type = NodalSum
    variable = react_y
    boundary = 4
  []
[]

[BCs]
  [side_x]
    type = DirichletBC
    variable = disp_y
    boundary = '1 2'
    value = 0.0
  []
  [bot_y]
    type = DirichletBC
    variable = disp_x
    boundary = '1 2'
    value = 0.0
  []
  [top_y_disp]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = 4
    function = disp_ramp_vert
  []
  [top_x_disp]
    type = FunctionDirichletBC
    variable = disp_x
    boundary = 4
    function = disp_ramp_horz
  []
[]

[Materials]
  [stuff1_elas_tens]
    type = ComputeIsotropicElasticityTensor
    block = '1'
    youngs_modulus = 1e10
    poissons_ratio = 0.0
  []
  [stuff1_strain]
    type = ComputeFiniteStrain
    block = '1'
  []
  [stuff1_stress]
    type = ComputeFiniteStrainElasticStress
    block = '1'
  []
  [stuff2_elas_tens]
    type = ComputeIsotropicElasticityTensor
    block = '2 3 4 5 6 7'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  []
  [stuff2_strain]
    type = ComputeFiniteStrain
    block = '2 3 4 5 6 7'
  []
  [stuff2_stress]
    type = ComputeFiniteStrainElasticStress
    block = '2 3 4 5 6 7'
  []
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'

  petsc_options = '-snes_ksp_ew'
  petsc_options_iname = '-pc_type -pc_factor_mat_solver_type -pc_factor_shift_type '
                        '-pc_factor_shift_amount -mat_mffd_err'
  petsc_options_value = 'lu       superlu_dist                  NONZERO               1e-15          '
                        '         1e-5'

  line_search = 'none'

  nl_abs_tol = 1e-14
  nl_rel_tol = 1e-10
  start_time = 0.0
  end_time = 0.3 # 3.5
  l_tol = 1e-4
  dt = 0.1
  dtmin = 0.001
  [Predictor]
    type = SimplePredictor
    scale = 1.0
  []
[]

[Preconditioning]
  [SMP]
    type = SMP
    full = true
  []
[]

[VectorPostprocessors]
  [x_disp]
    type = NodalValueSampler
    variable = disp_x
    boundary = '3'
    sort_by = id
  []
  [y_disp]
    type = NodalValueSampler
    variable = disp_y
    boundary = '3'
    sort_by = id
  []
  [cont_press]
    type = NodalValueSampler
    variable = penalty_normal_pressure
    boundary = '3'
    sort_by = id
  []
  [friction]
    type = NodalValueSampler
    variable = penalty_frictional_pressure
    boundary = '3'
    sort_by = id
  []
[]

[Outputs]
  print_linear_residuals = true
  perf_graph = true
  exodus = true
  csv = false
  [console]
    type = Console
    max_rows = 5
  []
  [chkfile]
    type = CSV
    show = 'x_disp y_disp cont_press friction'
    file_base = cylinder_friction_penalty_check
    create_final_symlink = true
    execute_on = 'FINAL'
  []
[]

[UserObjects]
  [friction_uo]
    type = PenaltyFrictionUserObject
    primary_boundary = '2'
    secondary_boundary = '3'
    primary_subdomain = '10000'
    secondary_subdomain = '10001'
    disp_x = disp_x
    disp_y = disp_y
    friction_coefficient = 0.4 # with 2.0 works
    secondary_variable = disp_x
    penalty = 5e9
    penalty_friction = 1e7
  []
[]

[Constraints]
  [x]
    type = NormalMortarMechanicalContact
    primary_boundary = '2'
    secondary_boundary = '3'
    primary_subdomain = '10000'
    secondary_subdomain = '10001'
    secondary_variable = disp_x
    component = x
    use_displaced_mesh = true
    compute_lm_residuals = false
    weighted_gap_uo = friction_uo
  []
  [y]
    type = NormalMortarMechanicalContact
    primary_boundary = '2'
    secondary_boundary = '3'
    primary_subdomain = '10000'
    secondary_subdomain = '10001'
    secondary_variable = disp_y
    component = y
    use_displaced_mesh = true
    compute_lm_residuals = false
    weighted_gap_uo = friction_uo
  []
  [tangential_x]
    type = TangentialMortarMechanicalContact
    primary_boundary = 2
    secondary_boundary = 3
    primary_subdomain = 10000
    secondary_subdomain = 10001
    secondary_variable = disp_x
    component = x
    use_displaced_mesh = true
    compute_lm_residuals = false
    weighted_velocities_uo = friction_uo
  []
  [tangential_y]
    type = TangentialMortarMechanicalContact
    primary_boundary = 2
    secondary_boundary = 3
    primary_subdomain = 10000
    secondary_subdomain = 10001
    secondary_variable = disp_y
    component = y
    use_displaced_mesh = true
    compute_lm_residuals = false
    weighted_velocities_uo = friction_uo
  []
[]

(modules/contact/test/tests/verification/patch_tests/brick_1/brick1_aug.i)

[GlobalParams]
  volumetric_locking_correction = true
  displacements = 'disp_x disp_y disp_z'
[]

[Mesh]
  file = brick1_mesh.e
[]

[Problem]
  type = AugmentedLagrangianContactProblem
  extra_tag_vectors = 'ref'
  reference_vector = 'ref'
  maximum_lagrangian_update_iterations = 100
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./disp_z]
  [../]
[]

[AuxVariables]
  [./stress_xx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_zz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./penetration]
  [../]
  [./saved_x]
  [../]
  [./saved_y]
  [../]
  [./saved_z]
  [../]
  [./diag_saved_x]
  [../]
  [./diag_saved_y]
  [../]
  [./diag_saved_z]
  [../]
  [./inc_slip_x]
  [../]
  [./inc_slip_y]
  [../]
  [./inc_slip_z]
  [../]
  [./accum_slip_x]
  [../]
  [./accum_slip_y]
  [../]
  [./accum_slip_z]
  [../]
[]

[Kernels]
  [./TensorMechanics]
    use_displaced_mesh = true
    save_in = 'saved_x saved_y saved_z'
    extra_vector_tags = 'ref'
  [../]
[]

[AuxKernels]
  [./stress_xx]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xx
    index_i = 0
    index_j = 0
    execute_on = timestep_end
  [../]
  [./stress_yy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yy
    index_i = 1
    index_j = 1
    execute_on = timestep_end
  [../]
  [./stress_xy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xy
    index_i = 0
    index_j = 1
    execute_on = timestep_end
  [../]
  [./stress_zz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_zz
    index_i = 2
    index_j = 2
    execute_on = timestep_end
  [../]
  [./inc_slip_x]
    type = PenetrationAux
    variable = inc_slip_x
    execute_on = timestep_begin
    boundary = 4
    paired_boundary = 3
  [../]
  [./inc_slip_y]
    type = PenetrationAux
    variable = inc_slip_y
    execute_on = timestep_begin
    boundary = 4
    paired_boundary = 3
  [../]
  [./accum_slip_x]
    type = PenetrationAux
    variable = accum_slip_x
    execute_on = timestep_end
    boundary = 4
    paired_boundary = 3
  [../]
  [./accum_slip_y]
    type = PenetrationAux
    variable = accum_slip_y
    execute_on = timestep_end
    boundary = 4
    paired_boundary = 3
  [../]
  [./penetration]
    type = PenetrationAux
    variable = penetration
    boundary = 4
    paired_boundary = 3
  [../]
[]

[Postprocessors]
  [./bot_react_x]
    type = NodalSum
    variable = saved_x
    boundary = 1
  [../]
  [./bot_react_y]
    type = NodalSum
    variable = saved_y
    boundary = 1
  [../]
  [./top_react_x]
    type = NodalSum
    variable = saved_x
    boundary = 5
  [../]
  [./top_react_y]
    type = NodalSum
    variable = saved_y
    boundary = 5
  [../]
  [./ref_resid_x]
    type = NodalL2Norm
    execute_on = timestep_end
    variable = saved_x
  [../]
  [./ref_resid_y]
    type = NodalL2Norm
    execute_on = timestep_end
    variable = saved_y
  [../]
  [./sigma_yy]
    type = ElementAverageValue
    variable = stress_yy
  [../]
  [./sigma_zz]
    type = ElementAverageValue
    variable = stress_zz
  [../]
  [./disp_x5]
    type = NodalVariableValue
    nodeid = 4
    variable = disp_x
  [../]
  [./disp_x8]
    type = NodalVariableValue
    nodeid = 7
    variable = disp_x
  [../]
  [./disp_x13]
    type = NodalVariableValue
    nodeid = 12
    variable = disp_x
  [../]
  [./disp_x16]
    type = NodalVariableValue
    nodeid = 15
    variable = disp_x
  [../]
  [./disp_y5]
    type = NodalVariableValue
    nodeid = 4
    variable = disp_y
  [../]
  [./disp_y8]
    type = NodalVariableValue
    nodeid = 7
    variable = disp_y
  [../]
  [./disp_y13]
    type = NodalVariableValue
    nodeid = 12
    variable = disp_y
  [../]
  [./disp_y16]
    type = NodalVariableValue
    nodeid = 15
    variable = disp_y
  [../]
  [./_dt]
    type = TimestepSize
  [../]
  [./num_lin_it]
    type = NumLinearIterations
  [../]
  [./num_nonlin_it]
    type = NumNonlinearIterations
  [../]
[]

[BCs]
  [./bot_y]
    type = DirichletBC
    variable = disp_y
    boundary = 1
    value = 0.0
  [../]
  [./side_x]
    type = DirichletBC
    variable = disp_x
    boundary = 2
    value = 0.0
  [../]
  [./back_z]
    type = DirichletBC
    variable = disp_z
    boundary = 6
    value = 0.0
  [../]
  [./top_press]
    type = Pressure
    variable = disp_y
    boundary = 5
    factor = 109.89
  [../]
[]

[Materials]
  [./bot_elas_tens]
    type = ComputeIsotropicElasticityTensor
    block = '1'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./bot_strain]
    type = ComputeFiniteStrain
    block = '1'
  [../]
  [./bot_stress]
    type = ComputeFiniteStrainElasticStress
    block = '1'
  [../]
  [./top_elas_tens]
    type = ComputeIsotropicElasticityTensor
    block = '2'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./top_strain]
    type = ComputeFiniteStrain
    block = '2'
  [../]
  [./top_stress]
    type = ComputeFiniteStrainElasticStress
    block = '2'
  [../]
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'

  petsc_options_iname = '-pc_type -pc_factor_mat_solver_type'
  petsc_options_value = 'lu     superlu_dist'

  line_search = 'none'

  nl_abs_tol = 1e-9
  nl_rel_tol = 1e-8
  l_max_its = 50
  nl_max_its = 100
  dt = 1.0
  end_time = 1.0
  num_steps = 10
  dtmin = 1.0
  l_tol = 1e-5
[]

[VectorPostprocessors]
  [./x_disp]
    type = NodalValueSampler
    variable = disp_x
    boundary = '1 3 4 5'
    sort_by = id
  [../]
  [./y_disp]
    type = NodalValueSampler
    variable = disp_y
    boundary = '1 3 4 5'
    sort_by = id
  [../]
  [./cont_press]
    type = NodalValueSampler
    variable = contact_pressure
    boundary = '3'
    sort_by = id
  [../]
[]

[Outputs]
  print_linear_residuals = true
  perf_graph = true
  [./exodus]
    type = Exodus
    elemental_as_nodal = true
  [../]
  [./console]
    type = Console
    max_rows = 5
  [../]
  [./chkfile]
    type = CSV
    show = 'bot_react_x bot_react_y disp_x5 disp_x8 disp_x13 disp_x16 disp_y5 disp_y8 disp_y13 disp_y16 stress_yy stress_zz top_react_x top_react_y x_disp y_disp cont_press'
    execute_vector_postprocessors_on = timestep_end
  [../]
  [./outfile]
    type = CSV
    delimiter = ' '
    execute_vector_postprocessors_on = none
  [../]
[]

[Contact]
  [./leftright]
    secondary = 3
    primary = 4
    tangential_tolerance = 1e-3
    formulation = augmented_lagrange
    normalize_penalty = true
    penalty = 1e8
    model = frictionless
    al_penetration_tolerance = 1e-8
  [../]
[]

(modules/solid_mechanics/test/tests/multi/two_surface04.i)

# Plasticit models:
# SimpleTester with a = 0 and b = 1 and strength = 1
# SimpleTester with a = 1 and b = 1 and strength = 2
#
# Lame lambda = 0 (Poisson=0).  Lame mu = 0.5E6
#
# A single element is stretched by 4.0E-6m in y directions and 2.0E-6 in z direction.
# trial stress_zz = 2 and stress_yy = 4
#
# Then both  SimpleTesters should activate initially and return to the "corner" point
# (stress_zz = 1 = stress_yy), but then the plastic multiplier for SimpleTester1 will
# be negative, and so it will be deactivated, and the algorithm will return to
# stress_zz = 0, stress_yy = 2
# internal1 should be zero, internal2 should be 2

[Mesh]
  type = GeneratedMesh
  dim = 3
  nx = 1
  ny = 1
  nz = 1
  xmin = -0.5
  xmax = 0.5
  ymin = -0.5
  ymax = 0.5
  zmin = -0.5
  zmax = 0.5
[]


[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./disp_z]
  [../]
[]

[Kernels]
  [SolidMechanics]
    displacements = 'disp_x disp_y disp_z'
  [../]
[]


[BCs]
  [./x]
    type = FunctionDirichletBC
    variable = disp_x
    boundary = 'front back'
    function = '0E-6*x'
  [../]
  [./y]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = 'front back'
    function = '4E-6*y'
  [../]
  [./z]
    type = FunctionDirichletBC
    variable = disp_z
    boundary = 'front back'
    function = '2E-6*z'
  [../]
[]

[AuxVariables]
  [./stress_xx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_zz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./f0]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./f1]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./int0]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./int1]
    order = CONSTANT
    family = MONOMIAL
  [../]
[]

[AuxKernels]
  [./stress_xx]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xx
    index_i = 0
    index_j = 0
  [../]
  [./stress_xy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xy
    index_i = 0
    index_j = 1
  [../]
  [./stress_xz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xz
    index_i = 0
    index_j = 2
  [../]
  [./stress_yy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yy
    index_i = 1
    index_j = 1
  [../]
  [./stress_yz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yz
    index_i = 1
    index_j = 2
  [../]
  [./stress_zz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_zz
    index_i = 2
    index_j = 2
  [../]
  [./f0]
    type = MaterialStdVectorAux
    property = plastic_yield_function
    index = 0
    variable = f0
  [../]
  [./f1]
    type = MaterialStdVectorAux
    property = plastic_yield_function
    index = 1
    variable = f1
  [../]
  [./int0]
    type = MaterialStdVectorAux
    property = plastic_internal_parameter
    factor = 1E6
    index = 0
    variable = int0
  [../]
  [./int1]
    type = MaterialStdVectorAux
    property = plastic_internal_parameter
    factor = 1E6
    index = 1
    variable = int1
  [../]
[]

[Postprocessors]
  [./s_xx]
    type = PointValue
    point = '0 0 0'
    variable = stress_xx
  [../]
  [./s_xy]
    type = PointValue
    point = '0 0 0'
    variable = stress_xy
  [../]
  [./s_xz]
    type = PointValue
    point = '0 0 0'
    variable = stress_xz
  [../]
  [./s_yy]
    type = PointValue
    point = '0 0 0'
    variable = stress_yy
  [../]
  [./s_yz]
    type = PointValue
    point = '0 0 0'
    variable = stress_yz
  [../]
  [./s_zz]
    type = PointValue
    point = '0 0 0'
    variable = stress_zz
  [../]
  [./f0]
    type = PointValue
    point = '0 0 0'
    variable = f0
  [../]
  [./f1]
    type = PointValue
    point = '0 0 0'
    variable = f1
  [../]
  [./int0]
    type = PointValue
    point = '0 0 0'
    variable = int0
  [../]
  [./int1]
    type = PointValue
    point = '0 0 0'
    variable = int1
  [../]
[]

[UserObjects]
  [./simple1]
    type = SolidMechanicsPlasticSimpleTester
    a = 0
    b = 1
    strength = 1
    yield_function_tolerance = 1.0E-9
    internal_constraint_tolerance = 1.0E-9
  [../]
  [./simple2]
    type = SolidMechanicsPlasticSimpleTester
    a = 1
    b = 1
    strength = 2
    yield_function_tolerance = 1.0E-9
    internal_constraint_tolerance = 1.0E-9
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeElasticityTensor
    block = 0
    fill_method = symmetric_isotropic
    C_ijkl = '0 0.5E6'
  [../]
  [./strain]
    type = ComputeFiniteStrain
    block = 0
    displacements = 'disp_x disp_y disp_z'
  [../]
  [./multi]
    type = ComputeMultiPlasticityStress
    block = 0
    ep_plastic_tolerance = 1E-9
    plastic_models = 'simple1 simple2'
    max_NR_iterations = 2
    min_stepsize = 1
    debug_fspb = crash
    debug_jac_at_stress = '10 0 0 0 10 0 0 0 10'
    debug_jac_at_pm = '1 1'
    debug_jac_at_intnl = '1 1'
    debug_stress_change = 1E-5
    debug_pm_change = '1E-6 1E-6'
    debug_intnl_change = '1E-6 1E-6'
  [../]
[]


[Executioner]
  end_time = 1
  dt = 1
  type = Transient
[]


[Outputs]
  file_base = two_surface04
  exodus = false
  [./csv]
    type = CSV
    [../]
[]

(modules/solid_mechanics/test/tests/crystal_plasticity/user_object_based/linesearch.i)

[Mesh]
  type = GeneratedMesh
  dim = 3
  elem_type = HEX8
  displacements = 'ux uy uz'
[]

[Variables]
  [./ux]
  [../]
  [./uy]
  [../]
  [./uz]
  [../]
[]

[AuxVariables]
  [./stress_zz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./fp_zz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./e_zz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./gss]
    order = CONSTANT
    family = MONOMIAL
  [../]
[]

[Functions]
  [./tdisp]
    type = ParsedFunction
    expression = 0.01*t
  [../]
[]

[Kernels]
  [SolidMechanics]
    displacements = 'ux uy uz'
    use_displaced_mesh = true
  [../]
[]

[AuxKernels]
  [./stress_zz]
    type = RankTwoAux
    variable = stress_zz
    rank_two_tensor = stress
    index_j = 2
    index_i = 2
    execute_on = timestep_end
  [../]
  [./fp_zz]
    type = RankTwoAux
    variable = fp_zz
    rank_two_tensor = fp
    index_j = 2
    index_i = 2
    execute_on = timestep_end
  [../]
  [./e_zz]
    type = RankTwoAux
    variable = e_zz
    rank_two_tensor = lage
    index_j = 2
    index_i = 2
    execute_on = timestep_end
  [../]
  [./gss1]
    type = MaterialStdVectorAux
    variable = gss
    property = state_var_gss
    index = 0
    execute_on = timestep_end
  [../]
[]

[BCs]
  [./symmy]
    type = DirichletBC
    variable = uy
    boundary = bottom
    value = 0
  [../]
  [./symmx]
    type = DirichletBC
    variable = ux
    boundary = left
    value = 0
  [../]
  [./symmz]
    type = DirichletBC
    variable = uz
    boundary = back
    value = 0
  [../]
  [./tdisp]
    type = FunctionDirichletBC
    variable = uz
    boundary = front
    function = tdisp
  [../]
[]

[UserObjects]
  [./slip_rate_gss]
    type = CrystalPlasticitySlipRateGSS
    variable_size = 12
    slip_sys_file_name = input_slip_sys.txt
    num_slip_sys_flowrate_props = 2
    flowprops = '1 4 0.001 0.1 5 8 0.001 0.1 9 12 0.001 0.1'
    uo_state_var_name = state_var_gss
  [../]
  [./slip_resistance_gss]
    type = CrystalPlasticitySlipResistanceGSS
    variable_size = 12
    uo_state_var_name = state_var_gss
  [../]
  [./state_var_gss]
    type = CrystalPlasticityStateVariable
    variable_size = 12
    groups = '0 4 8 12'
    group_values = '60.8 60.8 60.8'
    uo_state_var_evol_rate_comp_name = state_var_evol_rate_comp_gss
    scale_factor = 1.0
  [../]
  [./state_var_evol_rate_comp_gss]
    type = CrystalPlasticityStateVarRateComponentGSS
    variable_size = 12
    hprops = '1.0 541.5 109.8 2.5'
    uo_slip_rate_name = slip_rate_gss
    uo_state_var_name = state_var_gss
  [../]
[]

[Materials]
  [./crysp]
    type = FiniteStrainUObasedCP
    stol = 1e-2
    tan_mod_type = exact
    maximum_substep_iteration = 200
    use_line_search = true
    min_line_search_step_size = 0.01
    uo_slip_rates = 'slip_rate_gss'
    uo_slip_resistances = 'slip_resistance_gss'
    uo_state_vars = 'state_var_gss'
    uo_state_var_evol_rate_comps = 'state_var_evol_rate_comp_gss'
  [../]
  [./strain]
    type = ComputeFiniteStrain
    displacements = 'ux uy uz'
  [../]
  [./elasticity_tensor]
    type = ComputeElasticityTensorCP
    C_ijkl = '1.684e5 1.214e5 1.214e5 1.684e5 1.214e5 1.684e5 0.754e5 0.754e5 0.754e5'
    fill_method = symmetric9
  [../]
[]

[Postprocessors]
  [./stress_zz]
    type = ElementAverageValue
    variable = stress_zz
  [../]
  [./fp_zz]
    type = ElementAverageValue
    variable = fp_zz
  [../]
  [./e_zz]
    type = ElementAverageValue
    variable = e_zz
  [../]
  [./gss]
    type = ElementAverageValue
    variable = gss
  [../]
[]

[Preconditioning]
  [./smp]
    type = SMP
    full = true
  [../]
[]

[Executioner]
  type = Transient
  dt = 0.05
  solve_type = 'PJFNK'

  petsc_options_iname = -pc_hypre_type
  petsc_options_value = boomerang
  nl_abs_tol = 1e-10
  nl_rel_step_tol = 1e-10
  dtmax = 10.0
  nl_rel_tol = 1e-10
  end_time = 1
  dtmin = 0.02
  num_steps = 10
  nl_abs_step_tol = 1e-10
[]

[Outputs]
  exodus = true
[]

(modules/solid_mechanics/test/tests/crystal_plasticity/monolithic_material_based/cp_slip_rate_integ/crysp_substep.i)

[Mesh]
  type = GeneratedMesh
  dim = 3
  elem_type = HEX8
  displacements = 'disp_x disp_y disp_z'
[]

[Variables]
  [./disp_x]
    block = 0
  [../]
  [./disp_y]
    block = 0
  [../]
  [./disp_z]
    block = 0
  [../]
[]

[AuxVariables]
  [./stress_zz]
    order = CONSTANT
    family = MONOMIAL
    block = 0
  [../]
  [./fp_zz]
    order = CONSTANT
    family = MONOMIAL
    block = 0
  [../]
  [./e_zz]
    order = CONSTANT
    family = MONOMIAL
    block = 0
  [../]
  [./gss1]
    order = CONSTANT
    family = MONOMIAL
    block = 0
  [../]
[]

[Functions]
  [./tdisp]
    type = ParsedFunction
    expression = 0.01*t
  [../]
[]

[Kernels]
  [SolidMechanics]
    displacements = 'disp_x disp_y disp_z'
    use_displaced_mesh = true
  [../]
[]

[AuxKernels]
  [./stress_zz]
    type = RankTwoAux
    variable = stress_zz
    rank_two_tensor = stress
    index_j = 2
    index_i = 2
    execute_on = timestep_end
    block = 0
  [../]
  [./fp_zz]
    type = RankTwoAux
    variable = fp_zz
    rank_two_tensor = fp
    index_j = 2
    index_i = 2
    execute_on = timestep_end
    block = 0
  [../]
  [./e_zz]
    type = RankTwoAux
    variable = e_zz
    rank_two_tensor = lage
    index_j = 2
    index_i = 2
    execute_on = timestep_end
    block = 0
  [../]
  [./gss1]
    type = MaterialStdVectorAux
    variable = gss1
    property = gss
    index = 0
    execute_on = timestep_end
    block = 0
  [../]
[]

[BCs]
  [./symmy]
    type = DirichletBC
    variable = disp_y
    boundary = bottom
    value = 0
  [../]
  [./symmx]
    type = DirichletBC
    variable = disp_x
    boundary = left
    value = 0
  [../]
  [./symmz]
    type = DirichletBC
    variable = disp_z
    boundary = back
    value = 0
  [../]
  [./tdisp]
    type = FunctionDirichletBC
    variable = disp_z
    boundary = front
    function = tdisp
  [../]
[]

[Materials]
  [./crysp]
    type = FiniteStrainCPSlipRateRes
    block = 0
    gtol = 1e-2
    slip_sys_file_name = input_slip_sys.txt
    nss = 12
    num_slip_sys_flowrate_props = 2 #Number of properties in a slip system
    flowprops = '1 4 0.001 0.01 5 8 0.001 0.01 9 12 0.001 0.01'
    hprops = '1.0 541.5 60.8 109.8 2.5'
    gprops = '1 4 60.8 5 8 60.8 9 12 60.8'
    tan_mod_type = exact
    slip_incr_tol = 1
    maximum_substep_iteration = 8
  [../]
  [./elasticity_tensor]
    type = ComputeElasticityTensorCP
    block = 0
    C_ijkl = '1.684e5 1.214e5 1.214e5 1.684e5 1.214e5 1.684e5 0.754e5 0.754e5 0.754e5'
    fill_method = symmetric9
  [../]
  [./strain]
    type = ComputeFiniteStrain
    block = 0
    displacements = 'disp_x disp_y disp_z'
  [../]
[]

[Postprocessors]
  [./stress_zz]
    type = ElementAverageValue
    variable = stress_zz
    block = 'ANY_BLOCK_ID 0'
  [../]
  [./fp_zz]
    type = ElementAverageValue
    variable = fp_zz
    block = 'ANY_BLOCK_ID 0'
  [../]
  [./e_zz]
    type = ElementAverageValue
    variable = e_zz
    block = 'ANY_BLOCK_ID 0'
  [../]
  [./gss1]
    type = ElementAverageValue
    variable = gss1
    block = 'ANY_BLOCK_ID 0'
  [../]
[]

[Preconditioning]
  [./smp]
    type = SMP
    full = true
  [../]
[]

[Executioner]
  type = Transient


  #Preconditioned JFNK (default)
  solve_type = 'PJFNK'

  petsc_options_iname = '-pc_type'
  petsc_options_value = 'lu'

  nl_rel_tol = 1e-10
  nl_abs_tol = 1e-10

  dt = 0.2
  dtmax = 10.0
  dtmin = 0.05

  end_time = 1
[]

[Outputs]
  file_base = crysp_substep_out
  exodus = true
  print_linear_residuals = true
  perf_graph = true
[]

(modules/contact/test/tests/verification/hertz_cyl/half_symm_q4/hertz_cyl_half_1deg_template3.i)

[GlobalParams]
  order = FIRST
  family = LAGRANGE
  volumetric_locking_correction = true
  displacements = 'disp_x disp_y'
[]

[Mesh]
  file = hertz_cyl_half_1deg.e
[]

[Problem]
  type = ReferenceResidualProblem
  extra_tag_vectors = 'ref'
  reference_vector = 'ref'
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
[]

[AuxVariables]
  [./stress_xx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./saved_x]
  [../]
  [./saved_y]
  [../]
  [./diag_saved_x]
  [../]
  [./diag_saved_y]
  [../]
  [./inc_slip_x]
  [../]
  [./inc_slip_y]
  [../]
  [./accum_slip_x]
  [../]
  [./accum_slip_y]
  [../]
  [./tang_force_x]
  [../]
  [./tang_force_y]
  [../]
[]

[Functions]
  [./disp_ramp_vert]
    type = PiecewiseLinear
    x = '0. 1. 11.'
    y = '0. -0.0020 -0.0020'
  [../]
  [./disp_ramp_horz]
    type = PiecewiseLinear
    x = '0. 1. 11.'
    y = '0. 0.0 0.0014'
  [../]
[]

[Kernels]
  [./TensorMechanics]
    use_displaced_mesh = true
    extra_vector_tags = 'ref'
    save_in = 'saved_x saved_y'
  [../]
[]

[AuxKernels]
  [./stress_xx]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xx
    index_i = 0
    index_j = 0
    execute_on = timestep_end
  [../]
  [./stress_yy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yy
    index_i = 1
    index_j = 1
    execute_on = timestep_end
  [../]
  [./stress_xy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xy
    index_i = 0
    index_j = 1
    execute_on = timestep_end
  [../]
  [./inc_slip_x]
    type = PenetrationAux
    variable = inc_slip_x
    execute_on = timestep_end
    boundary = 3
    paired_boundary = 2
  [../]
  [./inc_slip_y]
    type = PenetrationAux
    variable = inc_slip_y
    execute_on = timestep_end
    boundary = 3
    paired_boundary = 2
  [../]
  [./accum_slip_x]
    type = PenetrationAux
    variable = accum_slip_x
    execute_on = timestep_end
    boundary = 3
    paired_boundary = 2
  [../]
  [./accum_slip_y]
    type = PenetrationAux
    variable = accum_slip_y
    execute_on = timestep_end
    boundary = 3
    paired_boundary = 2
  [../]
  [./tang_force_x]
    type = PenetrationAux
    variable = tang_force_x
    quantity = tangential_force_x
    boundary = 3
    paired_boundary = 2
  [../]
  [./tang_force_y]
    type = PenetrationAux
    variable = tang_force_y
    quantity = tangential_force_y
    boundary = 3
    paired_boundary = 2
  [../]
  [./penetration]
    type = PenetrationAux
    variable = penetration
    boundary = 3
    paired_boundary = 2
  [../]
[]

[Postprocessors]
  [./bot_react_x]
    type = NodalSum
    variable = saved_x
    boundary = 1
  [../]
  [./bot_react_y]
    type = NodalSum
    variable = saved_y
    boundary = 1
  [../]
  [./top_react_x]
    type = NodalSum
    variable = saved_x
    boundary = 4
  [../]
  [./top_react_y]
    type = NodalSum
    variable = saved_y
    boundary = 4
  [../]
  [./disp_x226]
    type = NodalVariableValue
    nodeid = 225
    variable = disp_x
  [../]
  [./disp_y226]
    type = NodalVariableValue
    nodeid = 225
    variable = disp_y
  [../]
  [./_dt]
    type = TimestepSize
  [../]
  [./num_lin_it]
    type = NumLinearIterations
  [../]
  [./num_nonlin_it]
    type = NumNonlinearIterations
  [../]
[]

[BCs]
  [./side_x]
    type = DirichletBC
    variable = disp_y
    boundary = '1 2'
    value = 0.0
  [../]
  [./bot_y]
    type = DirichletBC
    variable = disp_x
    boundary = '1 2'
    value = 0.0
  [../]
  [./top_y_disp]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = 4
    function = disp_ramp_vert
  [../]
  [./top_x_disp]
    type = FunctionDirichletBC
    variable = disp_x
    boundary = 4
    function = disp_ramp_horz
  [../]
[]

[Materials]
  [./stuff1_elas_tens]
    type = ComputeIsotropicElasticityTensor
    block = '1'
    youngs_modulus = 1e10
    poissons_ratio = 0.0
  [../]
  [./stuff1_strain]
    type = ComputeFiniteStrain
    block = '1'
  [../]
  [./stuff1_stress]
    type = ComputeFiniteStrainElasticStress
    block = '1'
  [../]
  [./stuff2_elas_tens]
    type = ComputeIsotropicElasticityTensor
    block = '2'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./stuff2_strain]
    type = ComputeFiniteStrain
    block = '2'
  [../]
  [./stuff2_stress]
    type = ComputeFiniteStrainElasticStress
    block = '2'
  [../]
  [./stuff3_elas_tens]
    type = ComputeIsotropicElasticityTensor
    block = '3'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./stuff3_strain]
    type = ComputeFiniteStrain
    block = '3'
  [../]
  [./stuff3_stress]
    type = ComputeFiniteStrainElasticStress
    block = '3'
  [../]
  [./stuff4_elas_tens]
    type = ComputeIsotropicElasticityTensor
    block = '4'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./stuff4_strain]
    type = ComputeFiniteStrain
    block = '4'
  [../]
  [./stuff4_stress]
    type = ComputeFiniteStrainElasticStress
    block = '4'
  [../]
  [./stuff5_elas_tens]
    type = ComputeIsotropicElasticityTensor
    block = '5'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./stuff5_strain]
    type = ComputeFiniteStrain
    block = '5'
  [../]
  [./stuff5_stress]
    type = ComputeFiniteStrainElasticStress
    block = '5'
  [../]
  [./stuff6_elas_tens]
    type = ComputeIsotropicElasticityTensor
    block = '6'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./stuff6_strain]
    type = ComputeFiniteStrain
    block = '6'
  [../]
  [./stuff6_stress]
    type = ComputeFiniteStrainElasticStress
    block = '6'
  [../]
  [./stuff7_elas_tens]
    type = ComputeIsotropicElasticityTensor
    block = '7'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./stuff7_strain]
    type = ComputeFiniteStrain
    block = '7'
  [../]
  [./stuff7_stress]
    type = ComputeFiniteStrainElasticStress
    block = '7'
  [../]
[]

[Executioner]
  type = Transient

  #Preconditioned JFNK (default)
  solve_type = 'PJFNK'

  petsc_options_iname = '-pc_type -pc_factor_mat_solver_type'
  petsc_options_value = 'lu     superlu_dist'

  line_search = 'none'

  nl_abs_tol = 1e-7
  nl_rel_tol = 1e-6
  l_max_its = 100
  nl_max_its = 200

  start_time = 0.0
  end_time = 2.0
  l_tol = 5e-4
  dt = 0.1
  dtmin = 0.1
[]

[Preconditioning]
  [./SMP]
    type = SMP
    full = true
  [../]
[]

[VectorPostprocessors]
  [./x_disp]
    type = NodalValueSampler
    variable = disp_x
    boundary = '3 4'
    sort_by = id
  [../]
  [./y_disp]
    type = NodalValueSampler
    variable = disp_y
    boundary = '3 4'
    sort_by = id
  [../]
  [./cont_press]
    type = NodalValueSampler
    variable = contact_pressure
    boundary = '3'
    sort_by = id
  [../]
[]

[Outputs]
  print_linear_residuals = true
  perf_graph = true
  [./exodus]
    type = Exodus
    elemental_as_nodal = true
  [../]
  [./console]
    type = Console
    max_rows = 5
  [../]
  [./chkfile]
    type = CSV
    show = 'x_disp y_disp cont_press'
    start_time = 0.9
    execute_vector_postprocessors_on = timestep_end
  [../]
  [./chkfile2]
    type = CSV
    show = 'bot_react_x bot_react_y disp_x226 disp_y226 top_react_x top_react_y'
    start_time = 0.9
    execute_vector_postprocessors_on = timestep_end
  [../]
  [./outfile]
    type = CSV
    delimiter = ' '
    execute_vector_postprocessors_on = none
  [../]
[]

[Contact]
  [./interface]
    primary = 2
    secondary = 3
    model = coulomb
    friction_coefficient = 0.0
    formulation = penalty
    normalize_penalty = true
    tangential_tolerance = 1e-3
    penalty = 1e+9
  [../]
[]

[Dampers]
  [./contact_slip]
    type = ContactSlipDamper
    primary = '2'
    secondary = '3'
  [../]
[]

(modules/solid_mechanics/test/tests/j2_plasticity/small_deform2.i)

# UserObject J2 test
# apply uniform stretch in z direction to give
# trial stress_zz = 7, so sqrt(3*J2) = 7
# with zero Poisson's ratio, this should return to
# stress_zz = 3, stress_xx = 2 = stress_yy
# (note that stress_zz - stress_xx = stress_zz - stress_yy = 1, so sqrt(3*j2) = 1,
#  and that the mean stress remains = 7/3)

[Mesh]
  type = GeneratedMesh
  dim = 3
  nx = 1
  ny = 1
  nz = 1
  xmin = -0.5
  xmax = 0.5
  ymin = -0.5
  ymax = 0.5
  zmin = -0.5
  zmax = 0.5
[]


[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./disp_z]
  [../]
[]

[Kernels]
  [SolidMechanics]
    displacements = 'disp_x disp_y disp_z'
  [../]
[]


[BCs]
  [./x]
    type = FunctionDirichletBC
    variable = disp_x
    boundary = 'front back'
    function = '0E-6*x'
  [../]
  [./y]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = 'front back'
    function = '0E-6*y'
  [../]
  [./z]
    type = FunctionDirichletBC
    variable = disp_z
    boundary = 'front back'
    function = '3.5E-6*z'
  [../]
[]

[AuxVariables]
  [./stress_xx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_zz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./f]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./iter]
    order = CONSTANT
    family = MONOMIAL
  [../]
[]

[AuxKernels]
  [./stress_xx]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xx
    index_i = 0
    index_j = 0
  [../]
  [./stress_xy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xy
    index_i = 0
    index_j = 1
  [../]
  [./stress_xz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xz
    index_i = 0
    index_j = 2
  [../]
  [./stress_yy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yy
    index_i = 1
    index_j = 1
  [../]
  [./stress_yz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yz
    index_i = 1
    index_j = 2
  [../]
  [./stress_zz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_zz
    index_i = 2
    index_j = 2
  [../]
  [./f]
    type = MaterialStdVectorAux
    index = 0
    property = plastic_yield_function
    variable = f
  [../]
  [./iter]
    type = MaterialRealAux
    property = plastic_NR_iterations
    variable = iter
  [../]
[]

[Postprocessors]
  [./s_xx]
    type = PointValue
    point = '0 0 0'
    variable = stress_xx
  [../]
  [./s_xy]
    type = PointValue
    point = '0 0 0'
    variable = stress_xy
  [../]
  [./s_xz]
    type = PointValue
    point = '0 0 0'
    variable = stress_xz
  [../]
  [./s_yy]
    type = PointValue
    point = '0 0 0'
    variable = stress_yy
  [../]
  [./s_yz]
    type = PointValue
    point = '0 0 0'
    variable = stress_yz
  [../]
  [./s_zz]
    type = PointValue
    point = '0 0 0'
    variable = stress_zz
  [../]
  [./f]
    type = PointValue
    point = '0 0 0'
    variable = f
  [../]
  [./iter]
    type = PointValue
    point = '0 0 0'
    variable = iter
  [../]
[]

[UserObjects]
  [./str]
    type = SolidMechanicsHardeningConstant
    value = 1
  [../]
  [./j2]
    type = SolidMechanicsPlasticJ2
    yield_strength = str
    yield_function_tolerance = 1E-3
    internal_constraint_tolerance = 1E-9
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeElasticityTensor
    block = 0
    fill_method = symmetric_isotropic
    C_ijkl = '0 1E6'
  [../]
  [./strain]
    type = ComputeFiniteStrain
    block = 0
    displacements = 'disp_x disp_y disp_z'
  [../]
  [./mc]
    type = ComputeMultiPlasticityStress
    block = 0
    ep_plastic_tolerance = 1E-9
    plastic_models = j2
    debug_fspb = crash
  [../]
[]


[Executioner]
  end_time = 1
  dt = 1
  type = Transient
[]


[Outputs]
  file_base = small_deform2
  exodus = false
  [./csv]
    type = CSV
    [../]
[]

(modules/solid_mechanics/test/tests/mohr_coulomb/small_deform_hard1.i)

# apply uniform stretches in x, y and z directions.
# let mc_cohesion = 10, mc_cohesion_residual = 2, mc_cohesion_rate =
# With cohesion = C, friction_angle = 60deg, tip_smoother = 4, the
# algorithm should return to
# sigma_m = (C*Cos(60) - 4)/Sin(60)
# This allows checking of the relationship for C

[Mesh]
  type = GeneratedMesh
  dim = 3
  nx = 1
  ny = 1
  nz = 1
  xmin = -0.5
  xmax = 0.5
  ymin = -0.5
  ymax = 0.5
  zmin = -0.5
  zmax = 0.5
[]


[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./disp_z]
  [../]
[]

[Kernels]
  [SolidMechanics]
    displacements = 'disp_x disp_y disp_z'
  [../]
[]


[BCs]
  [./x]
    type = FunctionDirichletBC
    variable = disp_x
    boundary = 'front back'
    function = '1E-6*x*t'
  [../]
  [./y]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = 'front back'
    function = '1E-6*y*t'
  [../]
  [./z]
    type = FunctionDirichletBC
    variable = disp_z
    boundary = 'front back'
    function = '1E-6*z*t'
  [../]
[]

[AuxVariables]
  [./stress_xx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_zz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./mc_int]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./yield_fcn]
    order = CONSTANT
    family = MONOMIAL
  [../]
[]

[AuxKernels]
  [./stress_xx]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xx
    index_i = 0
    index_j = 0
  [../]
  [./stress_xy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xy
    index_i = 0
    index_j = 1
  [../]
  [./stress_xz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xz
    index_i = 0
    index_j = 2
  [../]
  [./stress_yy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yy
    index_i = 1
    index_j = 1
  [../]
  [./stress_yz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yz
    index_i = 1
    index_j = 2
  [../]
  [./stress_zz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_zz
    index_i = 2
    index_j = 2
  [../]
  [./mc_int_auxk]
    type = MaterialStdVectorAux
    index = 0
    property = plastic_internal_parameter
    variable = mc_int
  [../]
  [./yield_fcn_auxk]
    type = MaterialStdVectorAux
    index = 0
    property = plastic_yield_function
    variable = yield_fcn
  [../]
[]

[Postprocessors]
  [./s_xx]
    type = PointValue
    point = '0 0 0'
    variable = stress_xx
  [../]
  [./s_xy]
    type = PointValue
    point = '0 0 0'
    variable = stress_xy
  [../]
  [./s_xz]
    type = PointValue
    point = '0 0 0'
    variable = stress_xz
  [../]
  [./s_yy]
    type = PointValue
    point = '0 0 0'
    variable = stress_yy
  [../]
  [./s_yz]
    type = PointValue
    point = '0 0 0'
    variable = stress_yz
  [../]
  [./s_zz]
    type = PointValue
    point = '0 0 0'
    variable = stress_zz
  [../]
  [./internal]
    type = PointValue
    point = '0 0 0'
    variable = mc_int
  [../]
  [./f]
    type = PointValue
    point = '0 0 0'
    variable = yield_fcn
  [../]
[]

[UserObjects]
  [./mc_coh]
    type = SolidMechanicsHardeningExponential
    value_0 = 10
    value_residual = 2
    rate = 1E4
  [../]
  [./mc_phi]
    type = SolidMechanicsHardeningConstant
    value = 60
    convert_to_radians = true
  [../]
  [./mc_psi]
    type = SolidMechanicsHardeningConstant
    value = 5
    convert_to_radians = true
  [../]
  [./mc]
    type = SolidMechanicsPlasticMohrCoulomb
    cohesion = mc_coh
    friction_angle = mc_phi
    dilation_angle = mc_psi
    mc_tip_smoother = 4
    mc_edge_smoother = 25
    yield_function_tolerance = 1E-3
    internal_constraint_tolerance = 1E-9
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeElasticityTensor
    block = 0
    fill_method = symmetric_isotropic
    C_ijkl = '0 1E7'
  [../]
  [./strain]
    type = ComputeFiniteStrain
    block = 0
    displacements = 'disp_x disp_y disp_z'
  [../]
  [./mc]
    type = ComputeMultiPlasticityStress
    block = 0
    ep_plastic_tolerance = 1E-9
    plastic_models = mc
    debug_fspb = crash
    debug_jac_at_stress = '10 1 2 1 10 3 2 3 10'
    debug_jac_at_pm = 1
    debug_jac_at_intnl = 1E-4
    debug_stress_change = 1E-5
    debug_pm_change = 1E-6
    debug_intnl_change = 1E-8
  [../]
[]


[Executioner]
  end_time = 10
  dt = 1
  type = Transient
[]


[Outputs]
  file_base = small_deform_hard1
  exodus = false
  [./csv]
    type = CSV
    [../]
[]

(modules/combined/test/tests/cavity_pressure/3d.i)

#
# Cavity Pressure Test
#
# This test is designed to compute an internal pressure based on
#   p = n * R * T / V
# where
#   p is the pressure
#   n is the amount of material in the volume (moles)
#   R is the universal gas constant
#   T is the temperature
#   V is the volume
#
# The mesh is composed of one block (1) with an interior cavity of volume 8.
#   Block 2 sits in the cavity and has a volume of 1.  Thus, the total
#   initial volume is 7.
# The test adjusts n, T, and V in the following way:
#   n => n0 + alpha * t
#   T => T0 + beta * t
#   V => V0 + gamma * t
# with
#   alpha = n0
#   beta = T0 / 2
#   gamma = - (0.003322259...) * V0
#   T0 = 240.54443866068704
#   V0 = 7
#   n0 = f(p0)
#   p0 = 100
#   R = 8.314472 J * K^(-1) * mol^(-1)
#
# So, n0 = p0 * V0 / R / T0 = 100 * 7 / 8.314472 / 240.544439
#        = 0.35
#
# The parameters combined at t = 1 gives p = 301.
#

[GlobalParams]
  displacements = 'disp_x disp_y disp_z'
  volumetric_locking_correction = true
[]

[Mesh]
  file = 3d.e
[]

[Functions]
  [displ_positive]
    type = PiecewiseLinear
    x = '0 1'
    y = '0 0.0029069767441859684'
  []
  [displ_negative]
    type = PiecewiseLinear
    x = '0 1'
    y = '0 -0.0029069767441859684'
  []
  [temp1]
    type = PiecewiseLinear
    x = '0 1'
    y = '1 1.5'
    scale_factor = 240.54443866068704
  []
  [material_input_function]
    type = PiecewiseLinear
    x = '0    1'
    y = '0 0.35'
  []
[]

[Variables]
  [disp_x]
  []
  [disp_y]
  []
  [disp_z]
  []
  [temp]
    initial_condition = 240.54443866068704
  []
  [material_input]
  []
[]

[AuxVariables]
  [pressure_residual_x]
  []
  [pressure_residual_y]
  []
  [pressure_residual_z]
  []
  [stress_xx]
    order = CONSTANT
    family = MONOMIAL
  []
  [stress_yy]
    order = CONSTANT
    family = MONOMIAL
  []
  [stress_zz]
    order = CONSTANT
    family = MONOMIAL
  []
  [stress_xy]
    order = CONSTANT
    family = MONOMIAL
  []
  [stress_yz]
    order = CONSTANT
    family = MONOMIAL
  []
  [stress_zx]
    order = CONSTANT
    family = MONOMIAL
  []
[]

[Kernels]
  [TensorMechanics]
    use_displaced_mesh = true
  []
  [heat]
    type = Diffusion
    variable = temp
    use_displaced_mesh = true
  []
  [material_input_dummy]
    type = Diffusion
    variable = material_input
    use_displaced_mesh = true
  []
[]

[AuxKernels]
  [stress_xx]
    type = RankTwoAux
    rank_two_tensor = stress
    index_i = 0
    index_j = 0
    variable = stress_xx
  []
  [stress_yy]
    type = RankTwoAux
    rank_two_tensor = stress
    index_i = 1
    index_j = 1
    variable = stress_yy
  []
  [stress_zz]
    type = RankTwoAux
    rank_two_tensor = stress
    index_i = 2
    index_j = 2
    variable = stress_zz
  []
  [stress_xy]
    type = RankTwoAux
    rank_two_tensor = stress
    index_i = 0
    index_j = 1
    variable = stress_xy
  []
  [stress_yz]
    type = RankTwoAux
    rank_two_tensor = stress
    index_i = 1
    index_j = 2
    variable = stress_yz
  []
  [stress_zx]
    type = RankTwoAux
    rank_two_tensor = stress
    index_i = 2
    index_j = 0
    variable = stress_zx
  []
[]

[BCs]
  [no_x_exterior]
    type = DirichletBC
    variable = disp_x
    boundary = '7 8'
    value = 0.0
  []
  [no_y_exterior]
    type = DirichletBC
    variable = disp_y
    boundary = '9 10'
    value = 0.0
  []
  [no_z_exterior]
    type = DirichletBC
    variable = disp_z
    boundary = '11 12'
    value = 0.0
  []
  [prescribed_left]
    type = FunctionDirichletBC
    variable = disp_x
    boundary = 13
    function = displ_positive
  []
  [prescribed_right]
    type = FunctionDirichletBC
    variable = disp_x
    boundary = 14
    function = displ_negative
  []
  [no_y]
    type = DirichletBC
    variable = disp_y
    boundary = '15 16'
    value = 0.0
  []
  [no_z]
    type = DirichletBC
    variable = disp_z
    boundary = '17 18'
    value = 0.0
  []
  [no_x_interior]
    type = DirichletBC
    variable = disp_x
    boundary = '1 2'
    value = 0.0
  []
  [no_y_interior]
    type = DirichletBC
    variable = disp_y
    boundary = '3 4'
    value = 0.0
  []
  [no_z_interior]
    type = DirichletBC
    variable = disp_z
    boundary = '5 6'
    value = 0.0
  []
  [temperatureInterior]
    type = FunctionDirichletBC
    boundary = 100
    function = temp1
    variable = temp
  []
  [MaterialInput]
    type = FunctionDirichletBC
    boundary = '100 13 14 15 16'
    function = material_input_function
    variable = material_input
  []
  [CavityPressure]
    [1]
      boundary = 100
      initial_pressure = 100
      material_input = materialInput
      R = 8.314472
      temperature = aveTempInterior
      volume = internalVolume
      startup_time = 0.5
      output = ppress
      save_in = 'pressure_residual_x pressure_residual_y pressure_residual_z'
    []
  []
[]

[Materials]
  [elast_tensor1]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 1e1
    poissons_ratio = 0
    block = 1
  []
  [strain1]
    type = ComputeFiniteStrain
    block = 1
  []
  [stress1]
    type = ComputeFiniteStrainElasticStress
    block = 1
  []
  [elast_tensor2]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 1e6
    poissons_ratio = 0
    block = 2
  []
  [strain2]
    type = ComputeFiniteStrain
    block = 2
  []
  [stress2]
    type = ComputeFiniteStrainElasticStress
    block = 2
  []
[]

[Executioner]
  type = Transient

  petsc_options_iname = '-pc_type -sub_pc_type'
  petsc_options_value = 'asm       lu'

  nl_rel_tol = 1e-12
  l_tol = 1e-12

  l_max_its = 20

  dt = 0.5
  end_time = 1.0
  use_pre_SMO_residual = true
[]

[Postprocessors]
  [internalVolume]
    type = InternalVolume
    boundary = 100
    execute_on = 'initial linear'
  []
  [aveTempInterior]
    type = SideAverageValue
    boundary = 100
    variable = temp
    execute_on = 'initial linear'
  []
  [materialInput]
    type = SideAverageValue
    boundary = '7 8 9 10 11 12'
    variable = material_input
    execute_on = linear
  []
[]

[Outputs]
  exodus = true
[]

(modules/contact/test/tests/verification/patch_tests/brick_1/brick1_template1.i)

[GlobalParams]
  volumetric_locking_correction = true
  displacements = 'disp_x disp_y disp_z'
[]

[Mesh]
  file = brick1_mesh.e
[]

[Problem]
  type = ReferenceResidualProblem
  extra_tag_vectors = 'ref'
  reference_vector = 'ref'
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./disp_z]
  [../]
[]

[AuxVariables]
  [./stress_xx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_zz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./penetration]
  [../]
  [./saved_x]
  [../]
  [./saved_y]
  [../]
  [./saved_z]
  [../]
  [./diag_saved_x]
  [../]
  [./diag_saved_y]
  [../]
  [./diag_saved_z]
  [../]
  [./inc_slip_x]
  [../]
  [./inc_slip_y]
  [../]
  [./inc_slip_z]
  [../]
  [./accum_slip_x]
  [../]
  [./accum_slip_y]
  [../]
  [./accum_slip_z]
  [../]
[]

[Kernels]
  [./TensorMechanics]
    use_displaced_mesh = true
    save_in = 'saved_x saved_y saved_z'
    extra_vector_tags = 'ref'
  [../]
[]

[AuxKernels]
  [./stress_xx]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xx
    index_i = 0
    index_j = 0
    execute_on = timestep_end
  [../]
  [./stress_yy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yy
    index_i = 1
    index_j = 1
    execute_on = timestep_end
  [../]
  [./stress_xy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xy
    index_i = 0
    index_j = 1
    execute_on = timestep_end
  [../]
  [./stress_zz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_zz
    index_i = 2
    index_j = 2
    execute_on = timestep_end
  [../]
  [./inc_slip_x]
    type = PenetrationAux
    variable = inc_slip_x
    execute_on = timestep_begin
    boundary = 4
    paired_boundary = 3
  [../]
  [./inc_slip_y]
    type = PenetrationAux
    variable = inc_slip_y
    execute_on = timestep_begin
    boundary = 4
    paired_boundary = 3
  [../]
  [./accum_slip_x]
    type = PenetrationAux
    variable = accum_slip_x
    execute_on = timestep_end
    boundary = 4
    paired_boundary = 3
  [../]
  [./accum_slip_y]
    type = PenetrationAux
    variable = accum_slip_y
    execute_on = timestep_end
    boundary = 4
    paired_boundary = 3
  [../]
  [./penetration]
    type = PenetrationAux
    variable = penetration
    boundary = 4
    paired_boundary = 3
  [../]
[]

[Postprocessors]
  [./bot_react_x]
    type = NodalSum
    variable = saved_x
    boundary = 1
  [../]
  [./bot_react_y]
    type = NodalSum
    variable = saved_y
    boundary = 1
  [../]
  [./top_react_x]
    type = NodalSum
    variable = saved_x
    boundary = 5
  [../]
  [./top_react_y]
    type = NodalSum
    variable = saved_y
    boundary = 5
  [../]
  [./ref_resid_x]
    type = NodalL2Norm
    execute_on = timestep_end
    variable = saved_x
  [../]
  [./ref_resid_y]
    type = NodalL2Norm
    execute_on = timestep_end
    variable = saved_y
  [../]
  [./sigma_yy]
    type = ElementAverageValue
    variable = stress_yy
  [../]
  [./sigma_zz]
    type = ElementAverageValue
    variable = stress_zz
  [../]
  [./disp_x5]
    type = NodalVariableValue
    nodeid = 4
    variable = disp_x
  [../]
  [./disp_x8]
    type = NodalVariableValue
    nodeid = 7
    variable = disp_x
  [../]
  [./disp_x13]
    type = NodalVariableValue
    nodeid = 12
    variable = disp_x
  [../]
  [./disp_x16]
    type = NodalVariableValue
    nodeid = 15
    variable = disp_x
  [../]
  [./disp_y5]
    type = NodalVariableValue
    nodeid = 4
    variable = disp_y
  [../]
  [./disp_y8]
    type = NodalVariableValue
    nodeid = 7
    variable = disp_y
  [../]
  [./disp_y13]
    type = NodalVariableValue
    nodeid = 12
    variable = disp_y
  [../]
  [./disp_y16]
    type = NodalVariableValue
    nodeid = 15
    variable = disp_y
  [../]
  [./_dt]
    type = TimestepSize
  [../]
  [./num_lin_it]
    type = NumLinearIterations
  [../]
  [./num_nonlin_it]
    type = NumNonlinearIterations
  [../]
[]

[BCs]
  [./bot_y]
    type = DirichletBC
    variable = disp_y
    boundary = 1
    value = 0.0
  [../]
  [./side_x]
    type = DirichletBC
    variable = disp_x
    boundary = 2
    value = 0.0
  [../]
  [./back_z]
    type = DirichletBC
    variable = disp_z
    boundary = 6
    value = 0.0
  [../]
  [./top_press]
    type = Pressure
    variable = disp_y
    boundary = 5
    factor = 109.89
  [../]
[]

[Materials]
  [./bot_elas_tens]
    type = ComputeIsotropicElasticityTensor
    block = '1'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./bot_strain]
    type = ComputeFiniteStrain
    block = '1'
  [../]
  [./bot_stress]
    type = ComputeFiniteStrainElasticStress
    block = '1'
  [../]
  [./top_elas_tens]
    type = ComputeIsotropicElasticityTensor
    block = '2'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./top_strain]
    type = ComputeFiniteStrain
    block = '2'
  [../]
  [./top_stress]
    type = ComputeFiniteStrainElasticStress
    block = '2'
  [../]
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'

  petsc_options_iname = '-pc_type -pc_factor_mat_solver_type'
  petsc_options_value = 'lu     superlu_dist'

  line_search = 'none'

  nl_abs_tol = 1e-9
  nl_rel_tol = 1e-8
  l_max_its = 50
  nl_max_its = 100
  dt = 1.0
  end_time = 1.0
  num_steps = 10
  dtmin = 1.0
  l_tol = 1e-5
[]

[VectorPostprocessors]
  [./x_disp]
    type = NodalValueSampler
    variable = disp_x
    boundary = '1 3 4 5'
    sort_by = id
  [../]
  [./y_disp]
    type = NodalValueSampler
    variable = disp_y
    boundary = '1 3 4 5'
    sort_by = id
  [../]
  [./cont_press]
    type = NodalValueSampler
    variable = contact_pressure
    boundary = '3'
    sort_by = id
  [../]
[]

[Outputs]
  print_linear_residuals = true
  perf_graph = true
  [./exodus]
    type = Exodus
    elemental_as_nodal = true
  [../]
  [./console]
    type = Console
    max_rows = 5
  [../]
  [./chkfile]
    type = CSV
    show = 'bot_react_x bot_react_y disp_x5 disp_x8 disp_x13 disp_x16 disp_y5 disp_y8 disp_y13 disp_y16 stress_yy stress_zz top_react_x top_react_y x_disp y_disp cont_press'
    execute_vector_postprocessors_on = timestep_end
  [../]
  [./outfile]
    type = CSV
    delimiter = ' '
    execute_vector_postprocessors_on = none
  [../]
[]

[Contact]
  [./leftright]
    secondary = 3
    primary = 4
    normalize_penalty = true
    tangential_tolerance = 1e-3
    penalty = 1e+9
  [../]
[]

(modules/solid_mechanics/test/tests/multi/three_surface12.i)

# Plasticit models:
# SimpleTester0 with a = 0 and b = 1 and strength = 1
# SimpleTester1 with a = 1 and b = 0 and strength = 1
# SimpleTester2 with a = 1 and b = 1 and strength = 3
#
# Lame lambda = 0 (Poisson=0).  Lame mu = 0.5E6
#
# A single element is stretched by 1.5E-6m in y direction and 1.5E-6 in z direction.
# trial stress_yy = .15 and stress_zz = 1.5
#
# Then SimpleTester0 and SimpleTester1 should activate and the algorithm will return to
# stress_zz=1=stress_yy
# internal0 should be 0.5 and internal1 should be 0.5

[Mesh]
  type = GeneratedMesh
  dim = 3
  nx = 1
  ny = 1
  nz = 1
  xmin = -0.5
  xmax = 0.5
  ymin = -0.5
  ymax = 0.5
  zmin = -0.5
  zmax = 0.5
[]


[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./disp_z]
  [../]
[]

[Kernels]
  [SolidMechanics]
    displacements = 'disp_x disp_y disp_z'
  [../]
[]


[BCs]
  [./x]
    type = FunctionDirichletBC
    variable = disp_x
    boundary = 'front back'
    function = '0E-6*x'
  [../]
  [./y]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = 'front back'
    function = '1.5E-6*y'
  [../]
  [./z]
    type = FunctionDirichletBC
    variable = disp_z
    boundary = 'front back'
    function = '1.5E-6*z'
  [../]
[]

[AuxVariables]
  [./stress_xx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_zz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./f0]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./f1]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./f2]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./int0]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./int1]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./int2]
    order = CONSTANT
    family = MONOMIAL
  [../]
[]

[AuxKernels]
  [./stress_xx]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xx
    index_i = 0
    index_j = 0
  [../]
  [./stress_xy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xy
    index_i = 0
    index_j = 1
  [../]
  [./stress_xz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xz
    index_i = 0
    index_j = 2
  [../]
  [./stress_yy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yy
    index_i = 1
    index_j = 1
  [../]
  [./stress_yz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yz
    index_i = 1
    index_j = 2
  [../]
  [./stress_zz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_zz
    index_i = 2
    index_j = 2
  [../]
  [./f0]
    type = MaterialStdVectorAux
    property = plastic_yield_function
    index = 0
    variable = f0
  [../]
  [./f1]
    type = MaterialStdVectorAux
    property = plastic_yield_function
    index = 1
    variable = f1
  [../]
  [./f2]
    type = MaterialStdVectorAux
    property = plastic_yield_function
    index = 2
    variable = f2
  [../]
  [./int0]
    type = MaterialStdVectorAux
    property = plastic_internal_parameter
    factor = 1E6
    index = 0
    variable = int0
  [../]
  [./int1]
    type = MaterialStdVectorAux
    property = plastic_internal_parameter
    factor = 1E6
    index = 1
    variable = int1
  [../]
  [./int2]
    type = MaterialStdVectorAux
    property = plastic_internal_parameter
    factor = 1E6
    index = 2
    variable = int2
  [../]
[]

[Postprocessors]
  [./s_xx]
    type = PointValue
    point = '0 0 0'
    variable = stress_xx
  [../]
  [./s_xy]
    type = PointValue
    point = '0 0 0'
    variable = stress_xy
  [../]
  [./s_xz]
    type = PointValue
    point = '0 0 0'
    variable = stress_xz
  [../]
  [./s_yy]
    type = PointValue
    point = '0 0 0'
    variable = stress_yy
  [../]
  [./s_yz]
    type = PointValue
    point = '0 0 0'
    variable = stress_yz
  [../]
  [./s_zz]
    type = PointValue
    point = '0 0 0'
    variable = stress_zz
  [../]
  [./f0]
    type = PointValue
    point = '0 0 0'
    variable = f0
  [../]
  [./f1]
    type = PointValue
    point = '0 0 0'
    variable = f1
  [../]
  [./f2]
    type = PointValue
    point = '0 0 0'
    variable = f2
  [../]
  [./int0]
    type = PointValue
    point = '0 0 0'
    variable = int0
  [../]
  [./int1]
    type = PointValue
    point = '0 0 0'
    variable = int1
  [../]
  [./int2]
    type = PointValue
    point = '0 0 0'
    variable = int2
  [../]
[]

[UserObjects]
  [./simple0]
    type = SolidMechanicsPlasticSimpleTester
    a = 0
    b = 1
    strength = 1
    yield_function_tolerance = 1.0E-9
    internal_constraint_tolerance = 1.0E-9
  [../]
  [./simple1]
    type = SolidMechanicsPlasticSimpleTester
    a = 1
    b = 0
    strength = 1
    yield_function_tolerance = 1.0E-9
    internal_constraint_tolerance = 1.0E-9
  [../]
  [./simple2]
    type = SolidMechanicsPlasticSimpleTester
    a = 1
    b = 1
    strength = 3
    yield_function_tolerance = 1.0E-9
    internal_constraint_tolerance = 1.0E-9
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeElasticityTensor
    block = 0
    fill_method = symmetric_isotropic
    C_ijkl = '0 0.5E6'
  [../]
  [./strain]
    type = ComputeFiniteStrain
    block = 0
    displacements = 'disp_x disp_y disp_z'
  [../]
  [./multi]
    type = ComputeMultiPlasticityStress
    block = 0
    ep_plastic_tolerance = 1E-9
    plastic_models = 'simple0 simple1 simple2'
    max_NR_iterations = 2
    min_stepsize = 1
    debug_fspb = crash
    debug_jac_at_stress = '10 0 0 0 10 0 0 0 10'
    debug_jac_at_pm = '1 1'
    debug_jac_at_intnl = '1 1'
    debug_stress_change = 1E-5
    debug_pm_change = '1E-6 1E-6'
    debug_intnl_change = '1E-6 1E-6'
  [../]
[]


[Executioner]
  end_time = 1
  dt = 1
  type = Transient
[]


[Outputs]
  file_base = three_surface12
  exodus = false
  [./csv]
    type = CSV
    [../]
[]

(modules/solid_mechanics/test/tests/auxkernels/ranktwoscalaraux.i)

[Mesh]
  displacements = 'disp_x disp_y disp_z'
  [generated_mesh]
    type = GeneratedMeshGenerator
    elem_type = HEX8
    dim = 3
    nx = 1
    ny = 1
    nz = 1
    xmin = 0.0
    xmax = 1.0
    ymin = 0.0
    ymax = 1.0
    zmin = 0.0
    zmax = 1.0
  []
  [node]
    type = ExtraNodesetGenerator
    coord = '0.0 0.0 0.0'
    new_boundary = 6
    input = generated_mesh
  []
  [snode]
    type = ExtraNodesetGenerator
    coord = '1.0 0.0 0.0'
    new_boundary = 7
    input = node
  []
[]

[Variables]
  [./disp_x]
    order = FIRST
    family = LAGRANGE
  [../]
 [./disp_y]
    order = FIRST
    family = LAGRANGE
  [../]
  [./disp_z]
    order = FIRST
    family = LAGRANGE
  [../]
[]

[Kernels]
  [SolidMechanics]
    displacements = 'disp_x disp_y disp_z'
  [../]
[]



[Materials]
  [./fplastic]
    type = FiniteStrainPlasticMaterial
    block = 0
    yield_stress='0. 445. 0.05 610. 0.1 680. 0.38 810. 0.95 920. 2. 950.'
  [../]
  [./elasticity_tensor]
    type = ComputeElasticityTensor
    block = 0
    C_ijkl = '2.827e5 1.21e5 1.21e5 2.827e5 1.21e5 2.827e5 0.808e5 0.808e5 0.808e5'
    fill_method = symmetric9
  [../]
  [./strain]
    type = ComputeFiniteStrain
    block = 0
    displacements = 'disp_x disp_y disp_z'
  [../]
[]

[Functions]
 [./topfunc]
   type = ParsedFunction
   expression = 't'
 [../]
[]

[BCs]
  [./bottom3]
    type = DirichletBC
    variable = disp_z
    boundary = 0
    value = 0.0
  [../]
  [./top]
    type = FunctionDirichletBC
    variable = disp_z
    boundary = 5
    function = topfunc
  [../]
  [./corner1]
    type = DirichletBC
    variable = disp_x
    boundary = 6
    value = 0.0
  [../]
  [./corner2]
    type = DirichletBC
    variable = disp_y
    boundary = 6
    value = 0.0
  [../]
  [./corner3]
    type = DirichletBC
    variable = disp_z
    boundary = 6
    value = 0.0
  [../]
  [./side1]
    type = DirichletBC
    variable = disp_y
    boundary = 7
    value = 0.0
  [../]
  [./side2]
    type = DirichletBC
    variable = disp_z
    boundary = 7
    value = 0.0
  [../]
[]

[AuxVariables]
  [./stress_zz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./vonmises]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./hydrostatic]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./L2norm]
    order = CONSTANT
    family = MONOMIAL
  [../]
[]

[AuxKernels]
  [./stress_zz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_zz
    index_i = 2
    index_j = 2
  [../]
  [./vonmises]
    type = RankTwoScalarAux
    rank_two_tensor = stress
    variable = vonmises
    scalar_type = VonMisesStress
  [../]
  [./hydrostatic]
    type = RankTwoScalarAux
    rank_two_tensor = stress
    variable = hydrostatic
    scalar_type = Hydrostatic
  [../]
  [./L2norm]
    type = RankTwoScalarAux
    rank_two_tensor = stress
    variable = L2norm
    scalar_type = L2norm
  [../]
[]

[Postprocessors]
  [./stress_zz]
    type = ElementAverageValue
    variable = stress_zz
  [../]
  [./vonmises]
    type = ElementAverageValue
    variable = vonmises
  [../]
  [./hydrostatic]
    type = ElementAverageValue
    variable = hydrostatic
  [../]
  [./L2norm]
    type = ElementAverageValue
    variable = L2norm
  [../]
[]

[Executioner]

  type = Transient

  dt=0.1
  dtmin=0.1
  dtmax=1
  end_time=1.0

  #Preconditioned JFNK (default)
  solve_type = 'PJFNK'

  nl_rel_tol = 1e-10
  nl_abs_tol = 1e-10
[]

[Outputs]
  exodus = true
[]

(modules/solid_mechanics/test/tests/mohr_coulomb/small_deform2.i)

# apply repeated stretches in x, y and z directions, so that mean_stress = 0
# This maps out the yield surface in the octahedral plane for zero mean stress

[Mesh]
  type = GeneratedMesh
  dim = 3
  nx = 1
  ny = 1
  nz = 1
  xmin = -0.5
  xmax = 0.5
  ymin = -0.5
  ymax = 0.5
  zmin = -0.5
  zmax = 0.5
[]


[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./disp_z]
  [../]
[]

[Kernels]
  [SolidMechanics]
    displacements = 'disp_x disp_y disp_z'
  [../]
[]


[BCs]
  [./x]
    type = FunctionDirichletBC
    variable = disp_x
    boundary = 'front back'
    function = '2E-6*x*sin(t)'
  [../]
  [./y]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = 'front back'
    function = '2E-6*y*sin(2*t)'
  [../]
  [./z]
    type = FunctionDirichletBC
    variable = disp_z
    boundary = 'front back'
    function = '-2E-6*z*(sin(t)+sin(2*t))'
  [../]
[]

[AuxVariables]
  [./stress_xx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_zz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./yield_fcn]
    order = CONSTANT
    family = MONOMIAL
  [../]
[]

[AuxKernels]
  [./stress_xx]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xx
    index_i = 0
    index_j = 0
  [../]
  [./stress_xy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xy
    index_i = 0
    index_j = 1
  [../]
  [./stress_xz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xz
    index_i = 0
    index_j = 2
  [../]
  [./stress_yy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yy
    index_i = 1
    index_j = 1
  [../]
  [./stress_yz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yz
    index_i = 1
    index_j = 2
  [../]
  [./stress_zz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_zz
    index_i = 2
    index_j = 2
  [../]
  [./yield_fcn_auxk]
    type = MaterialStdVectorAux
    index = 0
    property = plastic_yield_function
    variable = yield_fcn
  [../]
[]

[Postprocessors]
  [./s_xx]
    type = PointValue
    point = '0 0 0'
    variable = stress_xx
  [../]
  [./s_xy]
    type = PointValue
    point = '0 0 0'
    variable = stress_xy
  [../]
  [./s_xz]
    type = PointValue
    point = '0 0 0'
    variable = stress_xz
  [../]
  [./s_yy]
    type = PointValue
    point = '0 0 0'
    variable = stress_yy
  [../]
  [./s_yz]
    type = PointValue
    point = '0 0 0'
    variable = stress_yz
  [../]
  [./s_zz]
    type = PointValue
    point = '0 0 0'
    variable = stress_zz
  [../]
  [./f]
    type = PointValue
    point = '0 0 0'
    variable = yield_fcn
  [../]
  [./f0]
    type = PointValue
    point = '0 0 0'
    variable = yield_fcn
  [../]
  [./f1]
    type = PointValue
    point = '0 0 0'
    variable = yield_fcn
  [../]
[]

[UserObjects]
  [./mc_coh]
    type = SolidMechanicsHardeningConstant
    value = 10
  [../]
  [./mc_phi]
    type = SolidMechanicsHardeningConstant
    value = 20
    convert_to_radians = true
  [../]
  [./mc_psi]
    type = SolidMechanicsHardeningConstant
    value = 0
  [../]
  [./mc]
    type = SolidMechanicsPlasticMohrCoulomb
    cohesion = mc_coh
    friction_angle = mc_phi
    dilation_angle = mc_psi
    mc_tip_smoother = 4
    mc_edge_smoother = 20
    yield_function_tolerance = 1E-3
    internal_constraint_tolerance = 1E-9
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeElasticityTensor
    block = 0
    fill_method = symmetric_isotropic
    C_ijkl = '0 1E7'
  [../]
  [./strain]
    type = ComputeFiniteStrain
    block = 0
    displacements = 'disp_x disp_y disp_z'
  [../]
  [./mc]
    type = ComputeMultiPlasticityStress
    block = 0
    ep_plastic_tolerance = 1E-9
    plastic_models = mc
    debug_fspb = crash
  [../]
[]


[Executioner]
  end_time = 100
  dt = 1
  type = Transient
[]


[Outputs]
  file_base = small_deform2
  exodus = false
  [./csv]
    type = CSV
    [../]
[]

(modules/solid_mechanics/test/tests/mohr_coulomb/uni_axial1.i)

[Mesh]
  type = GeneratedMesh
  dim = 3
  nx = 1
  ny = 1
  nz = 1
  xmin = -0.5
  xmax = 0.5
  ymin = -0.5
  ymax = 0.5
  zmin = -0.5
  zmax = 0.5
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./disp_z]
  [../]
[]

[Kernels]
  [SolidMechanics]
    displacements = 'disp_x disp_y disp_z'
  [../]
[]


[BCs]
  # back = zmin
  # front = zmax
  # bottom = ymin
  # top = ymax
  # left = xmin
  # right = xmax
  [./xmin_xzero]
    type = DirichletBC
    variable = disp_x
    boundary = 'left'
    value = '0'
  [../]
  [./ymin_yzero]
    type = DirichletBC
    variable = disp_y
    boundary = 'bottom'
    value = '0'
  [../]
  [./zmin_zzero]
    type = DirichletBC
    variable = disp_z
    boundary = 'back'
    value = '0'
  [../]
  [./zmax_disp]
    type = FunctionDirichletBC
    variable = disp_z
    boundary = 'front'
    function = '-1E-3*t'
  [../]
[]

[AuxVariables]
  [./stress_xx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_zz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./mc_int]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./yield_fcn]
    order = CONSTANT
    family = MONOMIAL
  [../]
[]

[AuxKernels]
  [./stress_xx]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xx
    index_i = 0
    index_j = 0
  [../]
  [./stress_xy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xy
    index_i = 0
    index_j = 1
  [../]
  [./stress_xz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xz
    index_i = 0
    index_j = 2
  [../]
  [./stress_yy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yy
    index_i = 1
    index_j = 1
  [../]
  [./stress_yz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yz
    index_i = 1
    index_j = 2
  [../]
  [./stress_zz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_zz
    index_i = 2
    index_j = 2
  [../]
  [./mc_int_auxk]
    type = MaterialStdVectorAux
    index = 0
    property = plastic_internal_parameter
    variable = mc_int
  [../]
  [./yield_fcn_auxk]
    type = MaterialStdVectorAux
    index = 0
    property = plastic_yield_function
    variable = yield_fcn
  [../]
[]

[Postprocessors]
  [./s_xx]
    type = PointValue
    point = '0 0 0'
    variable = stress_xx
  [../]
  [./s_xy]
    type = PointValue
    point = '0 0 0'
    variable = stress_xy
  [../]
  [./s_xz]
    type = PointValue
    point = '0 0 0'
    variable = stress_xz
  [../]
  [./s_yy]
    type = PointValue
    point = '0 0 0'
    variable = stress_yy
  [../]
  [./s_yz]
    type = PointValue
    point = '0 0 0'
    variable = stress_yz
  [../]
  [./s_zz]
    type = PointValue
    point = '0 0 0'
    variable = stress_zz
  [../]
  [./mc_int]
    type = PointValue
    point = '0 0 0'
    variable = mc_int
  [../]
  [./f]
    type = PointValue
    point = '0 0 0'
    variable = yield_fcn
  [../]
[]

[UserObjects]
  [./mc_coh]
    type = SolidMechanicsHardeningConstant
    value = 10E6
  [../]
  [./mc_phi]
    type = SolidMechanicsHardeningExponential
    value_0 = 0
    value_residual = 0.6981317 # 40deg
    rate = 10000
  [../]
  [./mc_psi]
    type = SolidMechanicsHardeningConstant
    value = 0
  [../]
  [./mc]
    type = SolidMechanicsPlasticMohrCoulomb
    cohesion = mc_coh
    friction_angle = mc_phi
    dilation_angle = mc_psi
    mc_tip_smoother = 0
    mc_edge_smoother = 25
    yield_function_tolerance = 1E-3
    internal_constraint_tolerance = 1E-10
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeElasticityTensor
    block = 0
    fill_method = symmetric_isotropic
    C_ijkl = '5.77E10 3.85E10' # young = 100Gpa, poisson = 0.3
  [../]
  [./strain]
    type = ComputeFiniteStrain
    block = 0
    displacements = 'disp_x disp_y disp_z'
  [../]
  [./mc]
    type = ComputeMultiPlasticityStress
    block = 0
    ep_plastic_tolerance = 1E-10
    plastic_models = mc
    max_NR_iterations = 1000
    debug_fspb = crash
  [../]
[]

[Preconditioning]
  [./andy]
    type = SMP
    full = true
  [../]
[]


[Executioner]
  end_time = 0.5
  dt = 0.05
  solve_type = PJFNK  # cannot use NEWTON because we are using ComputeFiniteStrain, and hence the Jacobian contributions will not be correct, even though ComputeMultiPlasticityStress will compute the correct consistent tangent operator for small strains
  type = Transient

  line_search = 'none'
  nl_rel_tol = 1E-10
  l_tol = 1E-3
  l_max_its = 200
  nl_max_its = 10

  petsc_options_iname = '-pc_type -pc_asm_overlap -sub_pc_type -ksp_type -ksp_gmres_restart'
  petsc_options_value = ' asm      2              lu            gmres     200'
[]



[Outputs]
  file_base = uni_axial1
  exodus = true
  [./csv]
    type = CSV
    [../]
[]

(modules/solid_mechanics/test/tests/multi/four_surface24.i)

# Plasticit models:
# SimpleTester0 with a = 0 and b = 1 and strength = 1
# SimpleTester1 with a = 1 and b = 0 and strength = 1
# SimpleTester2 with a = 1 and b = 2 and strength = 3.1
# SimpleTester3 with a = 2 and b = 1 and strength = 3.1
#
# Lame lambda = 0 (Poisson=0).  Lame mu = 0.5E6
#
# A single element is stretched by 2.1E-6m in y direction and 3E-6 in z direction.
# trial stress_yy = 2.1 and stress_zz = 3.0
#
# This is similar to four_surface14.i, and a description is found there.
# The result should be stress_zz=1=stress_yy, with internal0=2
# and internal1=1.1

[Mesh]
  type = GeneratedMesh
  dim = 3
  nx = 1
  ny = 1
  nz = 1
  xmin = -0.5
  xmax = 0.5
  ymin = -0.5
  ymax = 0.5
  zmin = -0.5
  zmax = 0.5
[]


[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./disp_z]
  [../]
[]

[Kernels]
  [SolidMechanics]
    displacements = 'disp_x disp_y disp_z'
  [../]
[]


[BCs]
  [./x]
    type = FunctionDirichletBC
    variable = disp_x
    boundary = 'front back'
    function = '0E-6*x'
  [../]
  [./y]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = 'front back'
    function = '2.1E-6*y'
  [../]
  [./z]
    type = FunctionDirichletBC
    variable = disp_z
    boundary = 'front back'
    function = '3.0E-6*z'
  [../]
[]

[AuxVariables]
  [./stress_xx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_zz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./f0]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./f1]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./f2]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./f3]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./int0]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./int1]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./int2]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./int3]
    order = CONSTANT
    family = MONOMIAL
  [../]
[]

[AuxKernels]
  [./stress_xx]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xx
    index_i = 0
    index_j = 0
  [../]
  [./stress_xy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xy
    index_i = 0
    index_j = 1
  [../]
  [./stress_xz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xz
    index_i = 0
    index_j = 2
  [../]
  [./stress_yy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yy
    index_i = 1
    index_j = 1
  [../]
  [./stress_yz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yz
    index_i = 1
    index_j = 2
  [../]
  [./stress_zz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_zz
    index_i = 2
    index_j = 2
  [../]
  [./f0]
    type = MaterialStdVectorAux
    property = plastic_yield_function
    index = 0
    variable = f0
  [../]
  [./f1]
    type = MaterialStdVectorAux
    property = plastic_yield_function
    index = 1
    variable = f1
  [../]
  [./f2]
    type = MaterialStdVectorAux
    property = plastic_yield_function
    index = 2
    variable = f2
  [../]
  [./f3]
    type = MaterialStdVectorAux
    property = plastic_yield_function
    index = 3
    variable = f3
  [../]
  [./int0]
    type = MaterialStdVectorAux
    property = plastic_internal_parameter
    factor = 1E6
    index = 0
    variable = int0
  [../]
  [./int1]
    type = MaterialStdVectorAux
    property = plastic_internal_parameter
    factor = 1E6
    index = 1
    variable = int1
  [../]
  [./int2]
    type = MaterialStdVectorAux
    property = plastic_internal_parameter
    factor = 1E6
    index = 2
    variable = int2
  [../]
  [./int3]
    type = MaterialStdVectorAux
    property = plastic_internal_parameter
    factor = 1E6
    index = 3
    variable = int3
  [../]
[]

[Postprocessors]
  [./s_xx]
    type = PointValue
    point = '0 0 0'
    variable = stress_xx
  [../]
  [./s_xy]
    type = PointValue
    point = '0 0 0'
    variable = stress_xy
  [../]
  [./s_xz]
    type = PointValue
    point = '0 0 0'
    variable = stress_xz
  [../]
  [./s_yy]
    type = PointValue
    point = '0 0 0'
    variable = stress_yy
  [../]
  [./s_yz]
    type = PointValue
    point = '0 0 0'
    variable = stress_yz
  [../]
  [./s_zz]
    type = PointValue
    point = '0 0 0'
    variable = stress_zz
  [../]
  [./f0]
    type = PointValue
    point = '0 0 0'
    variable = f0
  [../]
  [./f1]
    type = PointValue
    point = '0 0 0'
    variable = f1
  [../]
  [./f2]
    type = PointValue
    point = '0 0 0'
    variable = f2
  [../]
  [./f3]
    type = PointValue
    point = '0 0 0'
    variable = f3
  [../]
  [./int0]
    type = PointValue
    point = '0 0 0'
    variable = int0
  [../]
  [./int1]
    type = PointValue
    point = '0 0 0'
    variable = int1
  [../]
  [./int2]
    type = PointValue
    point = '0 0 0'
    variable = int2
  [../]
  [./int3]
    type = PointValue
    point = '0 0 0'
    variable = int3
  [../]
[]

[UserObjects]
  [./simple0]
    type = SolidMechanicsPlasticSimpleTester
    a = 0
    b = 1
    strength = 1
    yield_function_tolerance = 1.0E-6
    internal_constraint_tolerance = 1.0E-6
  [../]
  [./simple1]
    type = SolidMechanicsPlasticSimpleTester
    a = 1
    b = 0
    strength = 1
    yield_function_tolerance = 1.0E-6
    internal_constraint_tolerance = 1.0E-6
  [../]
  [./simple2]
    type = SolidMechanicsPlasticSimpleTester
    a = 1
    b = 2
    strength = 3.1
    yield_function_tolerance = 1.0E-6
    internal_constraint_tolerance = 1.0E-6
  [../]
  [./simple3]
    type = SolidMechanicsPlasticSimpleTester
    a = 2
    b = 1
    strength = 3.1
    yield_function_tolerance = 1.0E-6
    internal_constraint_tolerance = 1.0E-6
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeElasticityTensor
    block = 0
    fill_method = symmetric_isotropic
    C_ijkl = '0 0.5E6'
  [../]
  [./strain]
    type = ComputeFiniteStrain
    block = 0
    displacements = 'disp_x disp_y disp_z'
  [../]
  [./multi]
    type = ComputeMultiPlasticityStress
    block = 0
    ep_plastic_tolerance = 1E-9
    plastic_models = 'simple0 simple1 simple2 simple3'
    deactivation_scheme = 'optimized_to_safe'
    max_NR_iterations = 4
    min_stepsize = 1
    debug_fspb = crash
    debug_jac_at_stress = '10 0 0 0 10 0 0 0 10'
    debug_jac_at_pm = '1 1 1'
    debug_jac_at_intnl = '1 1 1'
    debug_stress_change = 1E-5
    debug_pm_change = '1E-6 1E-6 1E-6'
    debug_intnl_change = '1E-6 1E-6 1E-6'
  [../]
[]


[Executioner]
  end_time = 1
  dt = 1
  type = Transient
[]


[Outputs]
  file_base = four_surface24
  exodus = false
  [./csv]
    type = CSV
    [../]
[]

(modules/solid_mechanics/test/tests/hyperelastic_viscoplastic/one_elem_linear_harden.i)

[Mesh]
  type = GeneratedMesh
  dim = 3
  elem_type = HEX8
  displacements = 'ux uy uz'
[]

[Variables]
  [./ux]
    block = 0
  [../]
  [./uy]
    block = 0
  [../]
  [./uz]
    block = 0
  [../]
[]

[Kernels]
  [SolidMechanics]
    displacements = 'ux uy uz'
    use_displaced_mesh = true
  [../]
[]

[AuxVariables]
  [./stress_zz]
    order = CONSTANT
    family = MONOMIAL
    block = 0
  [../]
  [./peeq]
    order = CONSTANT
    family = MONOMIAL
    block = 0
  [../]
  [./fp_zz]
    order = CONSTANT
    family = MONOMIAL
    block = 0
  [../]
[]

[AuxKernels]
  [./stress_zz]
    type = RankTwoAux
    variable = stress_zz
    rank_two_tensor = stress
    index_j = 2
    index_i = 2
    execute_on = timestep_end
    block = 0
  [../]
  [./fp_zz]
    type = RankTwoAux
    variable = fp_zz
    rank_two_tensor = fp
    index_j = 2
    index_i = 2
    execute_on = timestep_end
    block = 0
  [../]
  [./peeq]
    type = MaterialRealAux
    variable = peeq
    property = ep_eqv
    execute_on = timestep_end
    block = 0
  [../]
[]

[BCs]
  [./symmy]
    type = DirichletBC
    variable = uy
    boundary = bottom
    value = 0
  [../]
  [./symmx]
    type = DirichletBC
    variable = ux
    boundary = left
    value = 0
  [../]
  [./symmz]
    type = DirichletBC
    variable = uz
    boundary = back
    value = 0
  [../]
  [./tdisp]
    type = FunctionDirichletBC
    variable = uz
    boundary = front
    function = '0.01*t'
  [../]
[]

[UserObjects]
  [./flowstress]
    type = HEVPLinearHardening
    yield_stress = 100
    slope = 10
    intvar_prop_name = ep_eqv
  [../]
  [./flowrate]
    type = HEVPFlowRatePowerLawJ2
    reference_flow_rate = 0.0001
    flow_rate_exponent = 50.0
    flow_rate_tol = 1
    strength_prop_name = flowstress
  [../]
  [./ep_eqv]
     type = HEVPEqvPlasticStrain
     intvar_rate_prop_name = ep_eqv_rate
  [../]
  [./ep_eqv_rate]
     type = HEVPEqvPlasticStrainRate
     flow_rate_prop_name = flowrate
  [../]
[]

[Materials]
  [./strain]
    type = ComputeFiniteStrain
    block = 0
    displacements = 'ux uy uz'
  [../]
  [./viscop]
    type = FiniteStrainHyperElasticViscoPlastic
    block = 0
    resid_abs_tol = 1e-18
    resid_rel_tol = 1e-8
    maxiters = 50
    max_substep_iteration = 5
    flow_rate_user_objects = 'flowrate'
    strength_user_objects = 'flowstress'
    internal_var_user_objects = 'ep_eqv'
    internal_var_rate_user_objects = 'ep_eqv_rate'
  [../]
  [./elasticity_tensor]
    type = ComputeElasticityTensor
    block = 0
    C_ijkl = '2.8e5 1.2e5 1.2e5 2.8e5 1.2e5 2.8e5 0.8e5 0.8e5 0.8e5'
    fill_method = symmetric9
  [../]
[]

[Postprocessors]
  [./stress_zz]
    type = ElementAverageValue
    variable = stress_zz
    block = 'ANY_BLOCK_ID 0'
  [../]
  [./fp_zz]
    type = ElementAverageValue
    variable = fp_zz
    block = 'ANY_BLOCK_ID 0'
  [../]
  [./peeq]
    type = ElementAverageValue
    variable = peeq
    block = 'ANY_BLOCK_ID 0'
  [../]
[]

[Preconditioning]
  [./smp]
    type = SMP
    full = true
  [../]
[]

[Executioner]
  type = Transient
  dt = 0.02
  #Preconditioned JFNK (default)
  solve_type = 'PJFNK'
  petsc_options_iname = -pc_hypre_type
  petsc_options_value = boomerang
  dtmax = 10.0
  nl_rel_tol = 1e-10
  dtmin = 0.02
  num_steps = 10
[]

[Outputs]
  file_base = one_elem_linear_harden
  exodus = true
  csv = false
[]

(modules/contact/test/tests/verification/overclosure_removal/overclosure.i)

# ---------------------------------------------------------------------------------------------------------
# REGRESSION TEST FOR OVERCLOSURE REMOVAL
# =======================================
# THIS TEST DEMONSTRATES THAT THE CODE IS CAPABLE OF REMOVING A SIZEABLE OVERCLOSURE IN A SINGLE TIME-STEP
# --------------------------------------------------------------------------------------------------------


[Mesh]
  file = oc_mesh.e
[]

[GlobalParams]
  volumetric_locking_correction = true
  displacements = 'disp_x disp_y'
[]

[Problem]
  type = ReferenceResidualProblem
  extra_tag_vectors = 'ref'
  reference_vector = 'ref'
[]

[Variables]
  [./disp_x]
    order = FIRST
    family = LAGRANGE
  [../]
  [./disp_y]
    order = FIRST
    family = LAGRANGE
  [../]
[]

[AuxVariables]
  [./penetration]
    order = FIRST
    family = LAGRANGE
  [../]
  [./saved_x]
  [../]
  [./saved_y]
  [../]
[]

[Kernels]
  [./TensorMechanics]
    use_displaced_mesh = true
    save_in = 'saved_x saved_y'
    extra_vector_tags = 'ref'
    use_finite_deform_jacobian = true
  [../]
[]

[AuxKernels]
  [./penetration]
    type = PenetrationAux
    variable = penetration
    boundary = 4
    paired_boundary = 3
  [../]
[]

[Postprocessors]
  [./bot_react_x]
    type = NodalSum
    variable = saved_x
    boundary = 1
  [../]
  [./bot_react_y]
    type = NodalSum
    variable = saved_y
    boundary = 1
  [../]
  [./top_react_x]
    type = NodalSum
    variable = saved_x
    boundary = 5
  [../]
  [./top_react_y]
    type = NodalSum
    variable = saved_y
    boundary = 5
  [../]
  [./ref_resid_x]
    type = NodalL2Norm
    execute_on = timestep_end
    variable = saved_x
  [../]
  [./ref_resid_y]
    type = NodalL2Norm
    execute_on = timestep_end
    variable = saved_y
  [../]
  [./_dt]
    type = TimestepSize
  [../]
[]

[BCs]
  [./bot_y]
    type = DirichletBC
    variable = disp_y
    boundary = 1
    value = 0.0
  [../]
  [./side1_x]
    type = DirichletBC
    variable = disp_x
    boundary = 2
    value = 0.0
  [../]
  [./top_y]
    type = DirichletBC
    variable = disp_y
    boundary = 5
    value = 0.0
  [../]
  [./top_x]
    type = DirichletBC
    variable = disp_x
    boundary = 1001    #nodeset 1001 top central node
    value = 0.0
  [../]
[]

[Materials]
  [./bot_elas_tens]
    type = ComputeIsotropicElasticityTensor
    block = '1'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./bot_strain]
    type = ComputeFiniteStrain
    decomposition_method = EigenSolution
    block = '1'
  [../]
  [./bot_stress]
    type = ComputeFiniteStrainElasticStress
    block = '1'
  [../]

  [./top_elas_tens]
    type = ComputeIsotropicElasticityTensor
    block = '2'
    youngs_modulus = 1e5
    poissons_ratio = 0.3
  [../]
  [./top_strain]
    type = ComputeFiniteStrain
    decomposition_method = EigenSolution
    block = '2'
  [../]
  [./top_stress]
    type = ComputeFiniteStrainElasticStress
    block = '2'
  [../]
[]

[Preconditioning]
  [./smp]
    type = SMP
    full = true
  [../]
[]

[Executioner]
  type = Transient

  solve_type = 'PJFNK'

  petsc_options_iname = '-pc_type -pc_factor_mat_solver_type'
  petsc_options_value = 'lu     superlu_dist'

  line_search = 'none'

  nl_abs_tol = 1e-8
  nl_rel_tol = 1e-9
  l_max_its = 100
  nl_max_its = 200
  dt = 1.0
  end_time = 1.0
  dtmin = 1.0
  l_tol = 1e-3

[]

[Outputs]
  print_linear_residuals = true
  perf_graph = true
  [./exodus]
    type = Exodus
    elemental_as_nodal = true
  [../]
  [./console]
    type = Console
    max_rows = 5
  [../]
[]

[Contact]
  [./leftright]
    secondary = 4
    primary = 3
    model = frictionless
    formulation = penalty
    normalize_penalty = true
    tangential_tolerance = 1e-3
    penalty = 1e+9
  [../]
[]

(modules/solid_mechanics/test/tests/multi/special_rock1.i)

# Plasticity models:
# Mohr-Coulomb with cohesion = 40MPa, friction angle = 35deg, dilation angle = 5deg
# Tensile with strength = 1MPa
#
# Lame lambda = 1GPa.  Lame mu = 1.3GPa
#
# A line of elements is perturbed randomly, and return to the yield surface at each quadpoint is checked
#
# NOTE: The yield function tolerances here are set at 100-times what i would usually use
# This is because otherwise the test fails on the 'pearcey' architecture.
# This is because identical stress tensors yield slightly different eigenvalues
# (and hence return-map residuals) on 'pearcey' than elsewhere, which results in
# a different number of NR iterations are needed to return to the yield surface.
# This is presumably because of compiler internals, or the BLAS routines being
# optimised differently or something similar.

[Mesh]
  type = GeneratedMesh
  dim = 3
  nx = 1000
  ny = 125
  nz = 1
  xmin = 0
  xmax = 1000
  ymin = 0
  ymax = 125
  zmin = 0
  zmax = 1
[]


[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./disp_z]
  [../]
[]

[GlobalParams]
  volumetric_locking_correction=true
[]

[Kernels]
  [SolidMechanics]
    displacements = 'disp_x disp_y disp_z'
  [../]
[]


[ICs]
  [./x]
    type = RandomIC
    min = -0.1
    max = 0.1
    variable = disp_x
  [../]
  [./y]
    type = RandomIC
    min = -0.1
    max = 0.1
    variable = disp_y
  [../]
  [./z]
    type = RandomIC
    min = -0.1
    max = 0.1
    variable = disp_z
  [../]
[]

[BCs]
  [./x]
    type = FunctionDirichletBC
    variable = disp_x
    boundary = 'front back'
    function = '0'
  [../]
  [./y]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = 'front back'
    function = '0'
  [../]
  [./z]
    type = FunctionDirichletBC
    variable = disp_z
    boundary = 'front back'
    function = '0'
  [../]
[]

[AuxVariables]
  [./stress_xx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_zz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./linesearch]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./ld]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./constr_added]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./iter]
    order = CONSTANT
    family = MONOMIAL
  [../]
[]

[AuxKernels]
  [./stress_xx]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xx
    index_i = 0
    index_j = 0
  [../]
  [./stress_xy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xy
    index_i = 0
    index_j = 1
  [../]
  [./stress_xz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xz
    index_i = 0
    index_j = 2
  [../]
  [./stress_yy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yy
    index_i = 1
    index_j = 1
  [../]
  [./stress_yz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yz
    index_i = 1
    index_j = 2
  [../]
  [./stress_zz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_zz
    index_i = 2
    index_j = 2
  [../]
  [./linesearch]
    type = MaterialRealAux
    property = plastic_linesearch_needed
    variable = linesearch
  [../]
  [./ld]
    type = MaterialRealAux
    property = plastic_linear_dependence_encountered
    variable = ld
  [../]
  [./constr_added]
    type = MaterialRealAux
    property = plastic_constraints_added
    variable = constr_added
  [../]
  [./iter]
    type = MaterialRealAux
    property = plastic_NR_iterations
    variable = iter
  [../]
[]

[Postprocessors]
  [./max_iter]
    type = ElementExtremeValue
    variable = iter
    outputs = console
  [../]
  [./av_linesearch]
    type = ElementAverageValue
    variable = linesearch
    outputs = 'console csv'
  [../]
  [./av_ld]
    type = ElementAverageValue
    variable = ld
    outputs = 'console csv'
  [../]
  [./av_constr_added]
    type = ElementAverageValue
    variable = constr_added
    outputs = 'console csv'
  [../]
  [./av_iter]
    type = ElementAverageValue
    variable = iter
    outputs = 'console csv'
  [../]
[]


[UserObjects]
  [./mc_coh]
    type = SolidMechanicsHardeningConstant
    value = 4E7
  [../]
  [./mc_phi]
    type = SolidMechanicsHardeningConstant
    value = 35
    convert_to_radians = true
  [../]
  [./mc_psi]
    type = SolidMechanicsHardeningConstant
    value = 5
    convert_to_radians = true
  [../]
  [./mc]
    type = SolidMechanicsPlasticMohrCoulombMulti
    cohesion = mc_coh
    friction_angle = mc_phi
    dilation_angle = mc_psi
    use_custom_returnMap = false
    yield_function_tolerance = 1.0E+2  # Note larger value
    shift = 1.0E+2                     # Note larger value
    internal_constraint_tolerance = 1.0E-7
  [../]
  [./mc_smooth]
    type = SolidMechanicsPlasticMohrCoulomb
    cohesion = mc_coh
    friction_angle = mc_phi
    dilation_angle = mc_psi
    mc_tip_smoother = 4E6
    yield_function_tolerance = 1.0
    internal_constraint_tolerance = 1.0E-7
  [../]

  [./ts]
    type = SolidMechanicsHardeningConstant
    value = 1E6
  [../]
  [./tensile]
    type = SolidMechanicsPlasticTensileMulti
    tensile_strength = ts
    yield_function_tolerance = 1.0E+2  # Note larger value
    shift = 1.0E+2                     # Note larger value
    internal_constraint_tolerance = 1.0E-7
    use_custom_returnMap = false
    use_custom_cto = false
  [../]
  [./tensile_smooth]
    type = SolidMechanicsPlasticTensile
    tensile_strength = ts
    tensile_tip_smoother = 1E5
    yield_function_tolerance = 1.0
    internal_constraint_tolerance = 1.0E-7
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeElasticityTensor
    block = 0
    fill_method = symmetric_isotropic
    C_ijkl = '1.0E9 1.3E9'
  [../]
  [./strain]
    type = ComputeFiniteStrain
    block = 0
    displacements = 'disp_x disp_y disp_z'
  [../]
  [./multi]
    type = ComputeMultiPlasticityStress
    block = 0
    ep_plastic_tolerance = 1E-5  # Note larger value, to match the larger yield_function_tolerances

    plastic_models = 'tensile mc'
    max_NR_iterations = 5
    specialIC = 'rock'
    deactivation_scheme = 'safe'
    min_stepsize = 1
    max_stepsize_for_dumb = 1

    debug_fspb = crash
    debug_jac_at_stress = '10 0 0 0 10 0 0 0 10'
    debug_jac_at_pm = '1 1 1 1'
    debug_jac_at_intnl = '1 1 1 1'
    debug_stress_change = 1E1
    debug_pm_change = '1E-6 1E-6 1E-6 1E-6'
    debug_intnl_change = '1E-6 1E-6 1E-6 1E-6'
  [../]
[]


[Executioner]
  end_time = 1
  dt = 1
  type = Transient
[]


[Outputs]
  file_base = special_rock1
  exodus = false
  csv = true
[]

(modules/solid_mechanics/test/tests/multi/three_surface00.i)

# Plasticit models:
# SimpleTester0 with a = 0 and b = 1 and strength = 1
# SimpleTester1 with a = 1 and b = 0 and strength = 1
# SimpleTester2 with a = 1 and b = 1 and strength = 1.5
#
# Lame lambda = 0 (Poisson=0).  Lame mu = 0.5E6
#
# A single element is stretched by 1E-6m in y direction and 1E-6 in z direction.
# trial stress_yy = 1 and stress_zz = 1
#
# Then SimpleTester2 should activate and the algorithm will return to
# stress_yy = 0.75, stress_zz = 0.75
# internal2 should be 0.25

[Mesh]
  type = GeneratedMesh
  dim = 3
  nx = 1
  ny = 1
  nz = 1
  xmin = -0.5
  xmax = 0.5
  ymin = -0.5
  ymax = 0.5
  zmin = -0.5
  zmax = 0.5
[]


[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./disp_z]
  [../]
[]

[Kernels]
  [SolidMechanics]
    displacements = 'disp_x disp_y disp_z'
  [../]
[]


[BCs]
  [./x]
    type = FunctionDirichletBC
    variable = disp_x
    boundary = 'front back'
    function = '0E-6*x'
  [../]
  [./y]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = 'front back'
    function = '1E-6*y'
  [../]
  [./z]
    type = FunctionDirichletBC
    variable = disp_z
    boundary = 'front back'
    function = '1E-6*z'
  [../]
[]

[AuxVariables]
  [./stress_xx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_zz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./f0]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./f1]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./f2]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./int0]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./int1]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./int2]
    order = CONSTANT
    family = MONOMIAL
  [../]
[]

[AuxKernels]
  [./stress_xx]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xx
    index_i = 0
    index_j = 0
  [../]
  [./stress_xy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xy
    index_i = 0
    index_j = 1
  [../]
  [./stress_xz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xz
    index_i = 0
    index_j = 2
  [../]
  [./stress_yy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yy
    index_i = 1
    index_j = 1
  [../]
  [./stress_yz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yz
    index_i = 1
    index_j = 2
  [../]
  [./stress_zz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_zz
    index_i = 2
    index_j = 2
  [../]
  [./f0]
    type = MaterialStdVectorAux
    property = plastic_yield_function
    index = 0
    variable = f0
  [../]
  [./f1]
    type = MaterialStdVectorAux
    property = plastic_yield_function
    index = 1
    variable = f1
  [../]
  [./f2]
    type = MaterialStdVectorAux
    property = plastic_yield_function
    index = 2
    variable = f2
  [../]
  [./int0]
    type = MaterialStdVectorAux
    property = plastic_internal_parameter
    factor = 1E6
    index = 0
    variable = int0
  [../]
  [./int1]
    type = MaterialStdVectorAux
    property = plastic_internal_parameter
    factor = 1E6
    index = 1
    variable = int1
  [../]
  [./int2]
    type = MaterialStdVectorAux
    property = plastic_internal_parameter
    factor = 1E6
    index = 2
    variable = int2
  [../]
[]

[Postprocessors]
  [./s_xx]
    type = PointValue
    point = '0 0 0'
    variable = stress_xx
  [../]
  [./s_xy]
    type = PointValue
    point = '0 0 0'
    variable = stress_xy
  [../]
  [./s_xz]
    type = PointValue
    point = '0 0 0'
    variable = stress_xz
  [../]
  [./s_yy]
    type = PointValue
    point = '0 0 0'
    variable = stress_yy
  [../]
  [./s_yz]
    type = PointValue
    point = '0 0 0'
    variable = stress_yz
  [../]
  [./s_zz]
    type = PointValue
    point = '0 0 0'
    variable = stress_zz
  [../]
  [./f0]
    type = PointValue
    point = '0 0 0'
    variable = f0
  [../]
  [./f1]
    type = PointValue
    point = '0 0 0'
    variable = f1
  [../]
  [./f2]
    type = PointValue
    point = '0 0 0'
    variable = f2
  [../]
  [./int0]
    type = PointValue
    point = '0 0 0'
    variable = int0
  [../]
  [./int1]
    type = PointValue
    point = '0 0 0'
    variable = int1
  [../]
  [./int2]
    type = PointValue
    point = '0 0 0'
    variable = int2
  [../]
[]

[UserObjects]
  [./simple0]
    type = SolidMechanicsPlasticSimpleTester
    a = 0
    b = 1
    strength = 1
    yield_function_tolerance = 1.0E-9
    internal_constraint_tolerance = 1.0E-9
  [../]
  [./simple1]
    type = SolidMechanicsPlasticSimpleTester
    a = 1
    b = 0
    strength = 1
    yield_function_tolerance = 1.0E-9
    internal_constraint_tolerance = 1.0E-9
  [../]
  [./simple2]
    type = SolidMechanicsPlasticSimpleTester
    a = 1
    b = 1
    strength = 1.5
    yield_function_tolerance = 1.0E-9
    internal_constraint_tolerance = 1.0E-9
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeElasticityTensor
    block = 0
    fill_method = symmetric_isotropic
    C_ijkl = '0 0.5E6'
  [../]
  [./strain]
    type = ComputeFiniteStrain
    block = 0
    displacements = 'disp_x disp_y disp_z'
  [../]
  [./multi]
    type = ComputeMultiPlasticityStress
    block = 0
    ep_plastic_tolerance = 1E-9
    plastic_models = 'simple0 simple1 simple2'
    max_NR_iterations = 2
    min_stepsize = 1
    debug_fspb = crash
    debug_jac_at_stress = '10 0 0 0 10 0 0 0 10'
    debug_jac_at_pm = '1 1 1'
    debug_jac_at_intnl = '1 1 1'
    debug_stress_change = 1E-5
    debug_pm_change = '1E-6 1E-6 1E-6'
    debug_intnl_change = '1E-6 1E-6 1E-6'
  [../]
[]


[Executioner]
  end_time = 1
  dt = 1
  type = Transient
[]


[Outputs]
  file_base = three_surface00
  exodus = false
  [./csv]
    type = CSV
    [../]
[]

(modules/solid_mechanics/test/tests/multi/eight_surface14.i)

# Plasticit models:
# SimpleTester0 with a = 0 and b = 1 and strength = 1
# SimpleTester1 with a = 1 and b = 0 and strength = 1
# SimpleTester2 with a = 1 and b = 1 and strength = 3
# SimpleTester3 with a = 0 and b = 1 and strength = 1.1
# SimpleTester4 with a = 1 and b = 0 and strength = 1.1
# SimpleTester5 with a = 1 and b = 1 and strength = 3.1
# SimpleTester6 with a = 1 and b = 2 and strength = 3.1
# SimpleTester7 with a = 2 and b = 1 and strength = 3.1
#
# Lame lambda = 0 (Poisson=0).  Lame mu = 0.5E6
#
# A single element is stretched by 2.1E-6m in y direction and 3E-6 in z direction.
# trial stress_yy = 2.1 and stress_zz = 3.0
#
# This is similar to three_surface14.i, and a description is found there.
# The result should be stress_zz=1=stress_yy, with internal0=2
# and internal1=1.1

[Mesh]
  type = GeneratedMesh
  dim = 3
  nx = 1
  ny = 1
  nz = 1
  xmin = -0.5
  xmax = 0.5
  ymin = -0.5
  ymax = 0.5
  zmin = -0.5
  zmax = 0.5
[]


[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./disp_z]
  [../]
[]

[Kernels]
  [SolidMechanics]
    displacements = 'disp_x disp_y disp_z'
  [../]
[]


[BCs]
  [./x]
    type = FunctionDirichletBC
    variable = disp_x
    boundary = 'front back'
    function = '0E-6*x'
  [../]
  [./y]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = 'front back'
    function = '2.1E-6*y'
  [../]
  [./z]
    type = FunctionDirichletBC
    variable = disp_z
    boundary = 'front back'
    function = '3.0E-6*z'
  [../]
[]

[AuxVariables]
  [./stress_xx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_zz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./f0]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./f1]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./f2]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./f3]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./f4]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./f5]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./f6]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./f7]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./int0]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./int1]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./int2]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./int3]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./int4]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./int5]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./int6]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./int7]
    order = CONSTANT
    family = MONOMIAL
  [../]
[]

[AuxKernels]
  [./stress_xx]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xx
    index_i = 0
    index_j = 0
  [../]
  [./stress_xy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xy
    index_i = 0
    index_j = 1
  [../]
  [./stress_xz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xz
    index_i = 0
    index_j = 2
  [../]
  [./stress_yy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yy
    index_i = 1
    index_j = 1
  [../]
  [./stress_yz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yz
    index_i = 1
    index_j = 2
  [../]
  [./stress_zz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_zz
    index_i = 2
    index_j = 2
  [../]
  [./f0]
    type = MaterialStdVectorAux
    property = plastic_yield_function
    index = 0
    variable = f0
  [../]
  [./f1]
    type = MaterialStdVectorAux
    property = plastic_yield_function
    index = 1
    variable = f1
  [../]
  [./f2]
    type = MaterialStdVectorAux
    property = plastic_yield_function
    index = 2
    variable = f2
  [../]
  [./f3]
    type = MaterialStdVectorAux
    property = plastic_yield_function
    index = 3
    variable = f3
  [../]
  [./f4]
    type = MaterialStdVectorAux
    property = plastic_yield_function
    index = 4
    variable = f4
  [../]
  [./f5]
    type = MaterialStdVectorAux
    property = plastic_yield_function
    index = 5
    variable = f5
  [../]
  [./f6]
    type = MaterialStdVectorAux
    property = plastic_yield_function
    index = 6
    variable = f6
  [../]
  [./f7]
    type = MaterialStdVectorAux
    property = plastic_yield_function
    index = 7
    variable = f7
  [../]
  [./int0]
    type = MaterialStdVectorAux
    property = plastic_internal_parameter
    factor = 1E6
    index = 0
    variable = int0
  [../]
  [./int1]
    type = MaterialStdVectorAux
    property = plastic_internal_parameter
    factor = 1E6
    index = 1
    variable = int1
  [../]
  [./int2]
    type = MaterialStdVectorAux
    property = plastic_internal_parameter
    factor = 1E6
    index = 2
    variable = int2
  [../]
  [./int3]
    type = MaterialStdVectorAux
    property = plastic_internal_parameter
    factor = 1E6
    index = 3
    variable = int3
  [../]
  [./int4]
    type = MaterialStdVectorAux
    property = plastic_internal_parameter
    factor = 1E6
    index = 4
    variable = int4
  [../]
  [./int5]
    type = MaterialStdVectorAux
    property = plastic_internal_parameter
    factor = 1E6
    index = 5
    variable = int5
  [../]
  [./int6]
    type = MaterialStdVectorAux
    property = plastic_internal_parameter
    factor = 1E6
    index = 6
    variable = int6
  [../]
  [./int7]
    type = MaterialStdVectorAux
    property = plastic_internal_parameter
    factor = 1E6
    index = 7
    variable = int7
  [../]
[]

[Postprocessors]
  [./s_xx]
    type = PointValue
    point = '0 0 0'
    variable = stress_xx
  [../]
  [./s_xy]
    type = PointValue
    point = '0 0 0'
    variable = stress_xy
  [../]
  [./s_xz]
    type = PointValue
    point = '0 0 0'
    variable = stress_xz
  [../]
  [./s_yy]
    type = PointValue
    point = '0 0 0'
    variable = stress_yy
  [../]
  [./s_yz]
    type = PointValue
    point = '0 0 0'
    variable = stress_yz
  [../]
  [./s_zz]
    type = PointValue
    point = '0 0 0'
    variable = stress_zz
  [../]
  [./f0]
    type = PointValue
    point = '0 0 0'
    variable = f0
  [../]
  [./f1]
    type = PointValue
    point = '0 0 0'
    variable = f1
  [../]
  [./f2]
    type = PointValue
    point = '0 0 0'
    variable = f2
  [../]
  [./f3]
    type = PointValue
    point = '0 0 0'
    variable = f3
  [../]
  [./f4]
    type = PointValue
    point = '0 0 0'
    variable = f4
  [../]
  [./f5]
    type = PointValue
    point = '0 0 0'
    variable = f5
  [../]
  [./f6]
    type = PointValue
    point = '0 0 0'
    variable = f6
  [../]
  [./f7]
    type = PointValue
    point = '0 0 0'
    variable = f7
  [../]
  [./int0]
    type = PointValue
    point = '0 0 0'
    variable = int0
  [../]
  [./int1]
    type = PointValue
    point = '0 0 0'
    variable = int1
  [../]
  [./int2]
    type = PointValue
    point = '0 0 0'
    variable = int2
  [../]
  [./int3]
    type = PointValue
    point = '0 0 0'
    variable = int3
  [../]
  [./int4]
    type = PointValue
    point = '0 0 0'
    variable = int4
  [../]
  [./int5]
    type = PointValue
    point = '0 0 0'
    variable = int5
  [../]
  [./int6]
    type = PointValue
    point = '0 0 0'
    variable = int6
  [../]
  [./int7]
    type = PointValue
    point = '0 0 0'
    variable = int7
  [../]
[]

[UserObjects]
  [./simple0]
    type = SolidMechanicsPlasticSimpleTester
    a = 0
    b = 1
    strength = 1
    yield_function_tolerance = 1.0E-6
    internal_constraint_tolerance = 1.0E-6
  [../]
  [./simple1]
    type = SolidMechanicsPlasticSimpleTester
    a = 1
    b = 0
    strength = 1
    yield_function_tolerance = 1.0E-6
    internal_constraint_tolerance = 1.0E-6
  [../]
  [./simple2]
    type = SolidMechanicsPlasticSimpleTester
    a = 1
    b = 1
    strength = 3
    yield_function_tolerance = 1.0E-6
    internal_constraint_tolerance = 1.0E-6
  [../]
  [./simple3]
    type = SolidMechanicsPlasticSimpleTester
    a = 0
    b = 1
    strength = 1.1
    yield_function_tolerance = 1.0E-6
    internal_constraint_tolerance = 1.0E-6
  [../]
  [./simple4]
    type = SolidMechanicsPlasticSimpleTester
    a = 1
    b = 0
    strength = 1.1
    yield_function_tolerance = 1.0E-6
    internal_constraint_tolerance = 1.0E-6
  [../]
  [./simple5]
    type = SolidMechanicsPlasticSimpleTester
    a = 1
    b = 1
    strength = 3.1
    yield_function_tolerance = 1.0E-6
    internal_constraint_tolerance = 1.0E-6
  [../]
  [./simple6]
    type = SolidMechanicsPlasticSimpleTester
    a = 1
    b = 2
    strength = 3.1
    yield_function_tolerance = 1.0E-6
    internal_constraint_tolerance = 1.0E-6
  [../]
  [./simple7]
    type = SolidMechanicsPlasticSimpleTester
    a = 2
    b = 1
    strength = 3.1
    yield_function_tolerance = 1.0E-6
    internal_constraint_tolerance = 1.0E-6
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeElasticityTensor
    block = 0
    fill_method = symmetric_isotropic
    C_ijkl = '0 0.5E6'
  [../]
  [./strain]
    type = ComputeFiniteStrain
    block = 0
    displacements = 'disp_x disp_y disp_z'
  [../]
  [./multi]
    type = ComputeMultiPlasticityStress
    block = 0
    ep_plastic_tolerance = 1E-9
    plastic_models = 'simple0 simple1 simple2 simple3 simple4 simple5 simple6 simple7'
    deactivation_scheme = optimized_to_safe
    max_NR_iterations = 4
    min_stepsize = 1
    debug_fspb = crash
    debug_jac_at_stress = '10 0 0 0 10 0 0 0 10'
    debug_jac_at_pm = '1 1 1'
    debug_jac_at_intnl = '1 1 1'
    debug_stress_change = 1E-5
    debug_pm_change = '1E-6 1E-6 1E-6'
    debug_intnl_change = '1E-6 1E-6 1E-6'
  [../]
[]


[Executioner]
  end_time = 1
  dt = 1
  type = Transient
[]


[Outputs]
  file_base = eight_surface14
  exodus = false
  [./csv]
    type = CSV
    [../]
[]

(modules/solid_mechanics/test/tests/multi/three_surface22.i)

# Plasticit models:
# SimpleTester0 with a = 0 and b = 1 and strength = 1
# SimpleTester1 with a = 1 and b = 0 and strength = 1
# SimpleTester2 with a = 1 and b = 1 and strength = 1.5
#
# Lame lambda = 0 (Poisson=0).  Lame mu = 0.5E6
#
# A single element is stretched by 1.7E-6m in y direction and 1.1E-6 in z direction.
# trial stress_yy = 1.7 and stress_zz = 1.1
#
# Then all yield functions will activate
# However, there is linear dependence.  SimpleTester0 will be rutned off.
# The algorithm will return to
# stress_yy=1.0 and stress_zz=0.5
# internal1=0.1, internal2=0.6


[Mesh]
  type = GeneratedMesh
  dim = 3
  nx = 1
  ny = 1
  nz = 1
  xmin = -0.5
  xmax = 0.5
  ymin = -0.5
  ymax = 0.5
  zmin = -0.5
  zmax = 0.5
[]


[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./disp_z]
  [../]
[]

[Kernels]
  [SolidMechanics]
    displacements = 'disp_x disp_y disp_z'
  [../]
[]


[BCs]
  [./x]
    type = FunctionDirichletBC
    variable = disp_x
    boundary = 'front back'
    function = '0E-6*x'
  [../]
  [./y]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = 'front back'
    function = '1.7E-6*y'
  [../]
  [./z]
    type = FunctionDirichletBC
    variable = disp_z
    boundary = 'front back'
    function = '1.1E-6*z'
  [../]
[]

[AuxVariables]
  [./stress_xx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_zz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./f0]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./f1]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./f2]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./int0]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./int1]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./int2]
    order = CONSTANT
    family = MONOMIAL
  [../]
[]

[AuxKernels]
  [./stress_xx]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xx
    index_i = 0
    index_j = 0
  [../]
  [./stress_xy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xy
    index_i = 0
    index_j = 1
  [../]
  [./stress_xz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xz
    index_i = 0
    index_j = 2
  [../]
  [./stress_yy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yy
    index_i = 1
    index_j = 1
  [../]
  [./stress_yz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yz
    index_i = 1
    index_j = 2
  [../]
  [./stress_zz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_zz
    index_i = 2
    index_j = 2
  [../]
  [./f0]
    type = MaterialStdVectorAux
    property = plastic_yield_function
    index = 0
    variable = f0
  [../]
  [./f1]
    type = MaterialStdVectorAux
    property = plastic_yield_function
    index = 1
    variable = f1
  [../]
  [./f2]
    type = MaterialStdVectorAux
    property = plastic_yield_function
    index = 2
    variable = f2
  [../]
  [./int0]
    type = MaterialStdVectorAux
    property = plastic_internal_parameter
    factor = 1E6
    index = 0
    variable = int0
  [../]
  [./int1]
    type = MaterialStdVectorAux
    property = plastic_internal_parameter
    factor = 1E6
    index = 1
    variable = int1
  [../]
  [./int2]
    type = MaterialStdVectorAux
    property = plastic_internal_parameter
    factor = 1E6
    index = 2
    variable = int2
  [../]
[]

[Postprocessors]
  [./s_xx]
    type = PointValue
    point = '0 0 0'
    variable = stress_xx
  [../]
  [./s_xy]
    type = PointValue
    point = '0 0 0'
    variable = stress_xy
  [../]
  [./s_xz]
    type = PointValue
    point = '0 0 0'
    variable = stress_xz
  [../]
  [./s_yy]
    type = PointValue
    point = '0 0 0'
    variable = stress_yy
  [../]
  [./s_yz]
    type = PointValue
    point = '0 0 0'
    variable = stress_yz
  [../]
  [./s_zz]
    type = PointValue
    point = '0 0 0'
    variable = stress_zz
  [../]
  [./f0]
    type = PointValue
    point = '0 0 0'
    variable = f0
  [../]
  [./f1]
    type = PointValue
    point = '0 0 0'
    variable = f1
  [../]
  [./f2]
    type = PointValue
    point = '0 0 0'
    variable = f2
  [../]
  [./int0]
    type = PointValue
    point = '0 0 0'
    variable = int0
  [../]
  [./int1]
    type = PointValue
    point = '0 0 0'
    variable = int1
  [../]
  [./int2]
    type = PointValue
    point = '0 0 0'
    variable = int2
  [../]
[]

[UserObjects]
  [./simple0]
    type = SolidMechanicsPlasticSimpleTester
    a = 0
    b = 1
    strength = 1
    yield_function_tolerance = 1.0E-9
    internal_constraint_tolerance = 1.0E-9
  [../]
  [./simple1]
    type = SolidMechanicsPlasticSimpleTester
    a = 1
    b = 0
    strength = 1
    yield_function_tolerance = 1.0E-9
    internal_constraint_tolerance = 1.0E-9
  [../]
  [./simple2]
    type = SolidMechanicsPlasticSimpleTester
    a = 1
    b = 1
    strength = 1.5
    yield_function_tolerance = 1.0E-9
    internal_constraint_tolerance = 1.0E-9
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeElasticityTensor
    block = 0
    fill_method = symmetric_isotropic
    C_ijkl = '0 0.5E6'
  [../]
  [./strain]
    type = ComputeFiniteStrain
    block = 0
    displacements = 'disp_x disp_y disp_z'
  [../]
  [./multi]
    type = ComputeMultiPlasticityStress
    block = 0
    ep_plastic_tolerance = 1E-9
    plastic_models = 'simple0 simple1 simple2'
    max_NR_iterations = 2
    min_stepsize = 1
    debug_fspb = crash
    debug_jac_at_stress = '10 0 0 0 10 0 0 0 10'
    debug_jac_at_pm = '1 1'
    debug_jac_at_intnl = '1 1'
    debug_stress_change = 1E-5
    debug_pm_change = '1E-6 1E-6'
    debug_intnl_change = '1E-6 1E-6'
  [../]
[]


[Executioner]
  end_time = 1
  dt = 1
  type = Transient
[]


[Outputs]
  file_base = three_surface22
  exodus = false
  [./csv]
    type = CSV
    [../]
[]

(modules/solid_mechanics/test/tests/mohr_coulomb/planar1.i)

# apply uniform stretch in x, y and z directions.
# With cohesion = 10, friction_angle = 60deg, the
# algorithm should return to
# sigma_m = 10*Cos(60)/Sin(60) = 5.773503
# using planar surfaces (not smoothed)

[Mesh]
  type = GeneratedMesh
  dim = 3
  nx = 1
  ny = 1
  nz = 1
  xmin = -0.5
  xmax = 0.5
  ymin = -0.5
  ymax = 0.5
  zmin = -0.5
  zmax = 0.5
[]


[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./disp_z]
  [../]
[]

[Kernels]
  [SolidMechanics]
    displacements = 'disp_x disp_y disp_z'
  [../]
[]


[BCs]
  [./x]
    type = FunctionDirichletBC
    variable = disp_x
    boundary = 'front back'
    function = '1E-6*x'
  [../]
  [./y]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = 'front back'
    function = '1.1E-6*y'
  [../]
  [./z]
    type = FunctionDirichletBC
    variable = disp_z
    boundary = 'front back'
    function = '1.2E-6*z'
  [../]
[]

[AuxVariables]
  [./stress_xx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_zz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./f]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./iter]
    order = CONSTANT
    family = MONOMIAL
  [../]
[]

[AuxKernels]
  [./stress_xx]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xx
    index_i = 0
    index_j = 0
  [../]
  [./stress_xy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xy
    index_i = 0
    index_j = 1
  [../]
  [./stress_xz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xz
    index_i = 0
    index_j = 2
  [../]
  [./stress_yy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yy
    index_i = 1
    index_j = 1
  [../]
  [./stress_yz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yz
    index_i = 1
    index_j = 2
  [../]
  [./stress_zz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_zz
    index_i = 2
    index_j = 2
  [../]
  [./f]
    type = MaterialStdVectorAux
    index = 0
    property = plastic_yield_function
    variable = f
  [../]
  [./iter]
    type = MaterialRealAux
    property = plastic_NR_iterations
    variable = iter
  [../]
[]

[Postprocessors]
  [./s_xx]
    type = PointValue
    point = '0 0 0'
    variable = stress_xx
  [../]
  [./s_xy]
    type = PointValue
    point = '0 0 0'
    variable = stress_xy
  [../]
  [./s_xz]
    type = PointValue
    point = '0 0 0'
    variable = stress_xz
  [../]
  [./s_yy]
    type = PointValue
    point = '0 0 0'
    variable = stress_yy
  [../]
  [./s_yz]
    type = PointValue
    point = '0 0 0'
    variable = stress_yz
  [../]
  [./s_zz]
    type = PointValue
    point = '0 0 0'
    variable = stress_zz
  [../]
  [./f]
    type = PointValue
    point = '0 0 0'
    variable = f
  [../]
  [./iter]
    type = PointValue
    point = '0 0 0'
    variable = iter
  [../]
[]

[UserObjects]
  [./coh]
    type = SolidMechanicsHardeningConstant
    value = 10
  [../]
  [./phi]
    type = SolidMechanicsHardeningConstant
    value = 1.04719756
  [../]
  [./psi]
    type = SolidMechanicsHardeningConstant
    value = 0.1
  [../]
  [./mc]
    type = SolidMechanicsPlasticMohrCoulombMulti
    cohesion = coh
    friction_angle = phi
    dilation_angle = psi
    yield_function_tolerance = 1E-3
    shift = 1E-12
    internal_constraint_tolerance = 1E-9
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeElasticityTensor
    block = 0
    fill_method = symmetric_isotropic
    C_ijkl = '0 1E7'
  [../]
  [./strain]
    type = ComputeFiniteStrain
    block = 0
    displacements = 'disp_x disp_y disp_z'
  [../]
  [./mc]
    type = ComputeMultiPlasticityStress
    block = 0
    ep_plastic_tolerance = 1E-10
    deactivation_scheme = safe
    plastic_models = mc
    debug_fspb = crash
    debug_jac_at_stress = '10 0 0 0 10 0 0 0 10'
    debug_jac_at_pm = 1
    debug_jac_at_intnl = 1
    debug_stress_change = 1E-5
    debug_pm_change = 1E-6
    debug_intnl_change = 1E-6
  [../]
[]


[Executioner]
  end_time = 1
  dt = 1
  type = Transient
[]


[Outputs]
  file_base = planar1
  exodus = false
  [./csv]
    type = CSV
    [../]
[]

(modules/solid_mechanics/test/tests/mohr_coulomb/planar_hard2.i)

# apply uniform stretches in x, y and z directions.
# let friction_angle = 60deg, friction_angle_residual=10deg, friction_angle_rate = 0.5E4
# With cohesion = C, friction_angle = phi, the
# algorithm should return to
# sigma_m = C*Cos(phi)/Sin(phi)
# Or, when T=C,
# phi = arctan(C/sigma_m)

[Mesh]
  type = GeneratedMesh
  dim = 3
  nx = 1
  ny = 1
  nz = 1
  xmin = -0.5
  xmax = 0.5
  ymin = -0.5
  ymax = 0.5
  zmin = -0.5
  zmax = 0.5
[]


[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./disp_z]
  [../]
[]

[Kernels]
  [SolidMechanics]
    displacements = 'disp_x disp_y disp_z'
  [../]
[]


[BCs]
  [./x]
    type = FunctionDirichletBC
    variable = disp_x
    boundary = 'front back'
    function = '1E-6*x*t'
  [../]
  [./y]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = 'front back'
    function = '1E-6*y*t'
  [../]
  [./z]
    type = FunctionDirichletBC
    variable = disp_z
    boundary = 'front back'
    function = '1E-6*z*t'
  [../]
[]

[AuxVariables]
  [./stress_xx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_zz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./mc_int]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./yield_fcn]
    order = CONSTANT
    family = MONOMIAL
  [../]
[]

[AuxKernels]
  [./stress_xx]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xx
    index_i = 0
    index_j = 0
  [../]
  [./stress_xy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xy
    index_i = 0
    index_j = 1
  [../]
  [./stress_xz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xz
    index_i = 0
    index_j = 2
  [../]
  [./stress_yy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yy
    index_i = 1
    index_j = 1
  [../]
  [./stress_yz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yz
    index_i = 1
    index_j = 2
  [../]
  [./stress_zz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_zz
    index_i = 2
    index_j = 2
  [../]
  [./mc_int_auxk]
    type = MaterialStdVectorAux
    index = 0
    property = plastic_internal_parameter
    variable = mc_int
  [../]
  [./yield_fcn_auxk]
    type = MaterialStdVectorAux
    index = 0
    property = plastic_yield_function
    variable = yield_fcn
  [../]
[]

[Postprocessors]
  [./s_xx]
    type = PointValue
    point = '0 0 0'
    variable = stress_xx
  [../]
  [./s_xy]
    type = PointValue
    point = '0 0 0'
    variable = stress_xy
  [../]
  [./s_xz]
    type = PointValue
    point = '0 0 0'
    variable = stress_xz
  [../]
  [./s_yy]
    type = PointValue
    point = '0 0 0'
    variable = stress_yy
  [../]
  [./s_yz]
    type = PointValue
    point = '0 0 0'
    variable = stress_yz
  [../]
  [./s_zz]
    type = PointValue
    point = '0 0 0'
    variable = stress_zz
  [../]
  [./internal]
    type = PointValue
    point = '0 0 0'
    variable = mc_int
  [../]
  [./f]
    type = PointValue
    point = '0 0 0'
    variable = yield_fcn
  [../]
[]

[UserObjects]
  [./mc_coh]
    type = SolidMechanicsHardeningConstant
    value = 10
  [../]
  [./mc_phi]
    type = SolidMechanicsHardeningExponential
    value_0 = 1.04719755 # 60deg
    value_residual = 0.17453293 # 10deg
    rate = 0.5E4
  [../]
  [./mc_psi]
    type = SolidMechanicsHardeningConstant
    value = 5
    convert_to_radians = true
  [../]
  [./mc]
    type = SolidMechanicsPlasticMohrCoulombMulti
    cohesion = mc_coh
    friction_angle = mc_phi
    dilation_angle = mc_psi
    shift = 1E-12
    use_custom_returnMap = true
    yield_function_tolerance = 1E-5
    internal_constraint_tolerance = 1E-9
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeElasticityTensor
    block = 0
    fill_method = symmetric_isotropic
    C_ijkl = '0.0E7 1E7'
  [../]
  [./strain]
    type = ComputeFiniteStrain
    block = 0
    displacements = 'disp_x disp_y disp_z'
  [../]
  [./mc]
    type = ComputeMultiPlasticityStress
    block = 0
    ep_plastic_tolerance = 1E-12
    plastic_models = mc
  [../]
[]


[Executioner]
  end_time = 10
  dt = 1
  type = Transient
[]


[Outputs]
  file_base = planar_hard2
  exodus = false
  [./csv]
    type = CSV
    execute_on = timestep_end
    [../]
[]

(modules/solid_mechanics/test/tests/multi/rock1.i)

# Plasticity models:
# Mohr-Coulomb with cohesion = 40MPa, friction angle = 35deg, dilation angle = 10deg
# Tensile with strength = 1MPa
# WeakPlaneShear with cohesion = 1MPa, friction angle = 25deg, dilation angle = 25deg
# WeakPlaneTensile with strength = 0.01MPa
#
# Lame lambda = 1GPa.  Lame mu = 1.3GPa
#
# A line of elements is perturbed randomly, and return to the yield surface at each quadpoint is checked

[Mesh]
  type = GeneratedMesh
  dim = 3
  nx = 1000
  ny = 1234
  nz = 1
  xmin = 0
  xmax = 1000
  ymin = 0
  ymax = 1234
  zmin = 0
  zmax = 1
[]


[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./disp_z]
  [../]
[]

[Kernels]
  [SolidMechanics]
    displacements = 'disp_x disp_y disp_z'
  [../]
[]


[ICs]
  [./x]
    type = RandomIC
    min = -0.1
    max = 0.1
    variable = disp_x
  [../]
  [./y]
    type = RandomIC
    min = -0.1
    max = 0.1
    variable = disp_y
  [../]
  [./z]
    type = RandomIC
    min = -0.1
    max = 0.1
    variable = disp_z
  [../]
[]

[BCs]
  [./x]
    type = FunctionDirichletBC
    variable = disp_x
    boundary = 'front back'
    function = '0'
  [../]
  [./y]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = 'front back'
    function = '0'
  [../]
  [./z]
    type = FunctionDirichletBC
    variable = disp_z
    boundary = 'front back'
    function = '0'
  [../]
[]

[AuxVariables]
  [./stress_xx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_zz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./f0]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./f1]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./f2]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./f3]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./int0]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./int1]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./int2]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./int3]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./iter]
    order = CONSTANT
    family = MONOMIAL
  [../]
[]

[AuxKernels]
  [./stress_xx]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xx
    index_i = 0
    index_j = 0
  [../]
  [./stress_xy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xy
    index_i = 0
    index_j = 1
  [../]
  [./stress_xz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xz
    index_i = 0
    index_j = 2
  [../]
  [./stress_yy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yy
    index_i = 1
    index_j = 1
  [../]
  [./stress_yz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yz
    index_i = 1
    index_j = 2
  [../]
  [./stress_zz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_zz
    index_i = 2
    index_j = 2
  [../]
  [./f0]
    type = MaterialStdVectorAux
    property = plastic_yield_function
    index = 0
    variable = f0
  [../]
  [./f1]
    type = MaterialStdVectorAux
    property = plastic_yield_function
    index = 1
    variable = f1
  [../]
  [./f2]
    type = MaterialStdVectorAux
    property = plastic_yield_function
    index = 2
    variable = f2
  [../]
  [./f3]
    type = MaterialStdVectorAux
    property = plastic_yield_function
    index = 3
    variable = f3
  [../]
  [./int0]
    type = MaterialStdVectorAux
    property = plastic_internal_parameter
    factor = 1E6
    index = 0
    variable = int0
  [../]
  [./int1]
    type = MaterialStdVectorAux
    property = plastic_internal_parameter
    factor = 1E6
    index = 1
    variable = int1
  [../]
  [./int2]
    type = MaterialStdVectorAux
    property = plastic_internal_parameter
    factor = 1E6
    index = 2
    variable = int2
  [../]
  [./int3]
    type = MaterialStdVectorAux
    property = plastic_internal_parameter
    factor = 1E6
    index = 3
    variable = int3
  [../]
  [./iter]
    type = MaterialRealAux
    property = plastic_NR_iterations
    variable = iter
  [../]
[]

[Postprocessors]
  [./raw_f0]
    type = ElementExtremeValue
    variable = f0
    outputs = console
  [../]
  [./raw_f1]
    type = ElementExtremeValue
    variable = f1
    outputs = console
  [../]
  [./raw_f2]
    type = ElementExtremeValue
    variable = f2
    outputs = console
  [../]
  [./raw_f3]
    type = ElementExtremeValue
    variable = f3
    outputs = console
  [../]
  [./iter]
    type = ElementExtremeValue
    variable = iter
    outputs = console
  [../]
  [./f0]
    type = FunctionValuePostprocessor
    function = should_be_zero0_fcn
  [../]
  [./f1]
    type = FunctionValuePostprocessor
    function = should_be_zero1_fcn
  [../]
  [./f2]
    type = FunctionValuePostprocessor
    function = should_be_zero2_fcn
  [../]
  [./f3]
    type = FunctionValuePostprocessor
    function = should_be_zero3_fcn
  [../]
[]

[Functions]
  [./should_be_zero0_fcn]
    type = ParsedFunction
    expression = 'if(a<1E-1,0,a)'
    symbol_names = 'a'
    symbol_values = 'raw_f0'
  [../]
  [./should_be_zero1_fcn]
    type = ParsedFunction
    expression = 'if(a<1E-1,0,a)'
    symbol_names = 'a'
    symbol_values = 'raw_f1'
  [../]
  [./should_be_zero2_fcn]
    type = ParsedFunction
    expression = 'if(a<1E-1,0,a)'
    symbol_names = 'a'
    symbol_values = 'raw_f2'
  [../]
  [./should_be_zero3_fcn]
    type = ParsedFunction
    expression = 'if(a<1E-1,0,a)'
    symbol_names = 'a'
    symbol_values = 'raw_f3'
  [../]
[]

[UserObjects]
  [./mc_coh]
    type = SolidMechanicsHardeningConstant
    value = 4E7
  [../]
  [./mc_phi]
    type = SolidMechanicsHardeningConstant
    value = 35
    convert_to_radians = true
  [../]
  [./mc_psi]
    type = SolidMechanicsHardeningConstant
    value = 10
    convert_to_radians = true
  [../]
  [./mc]
    type = SolidMechanicsPlasticMohrCoulomb
    cohesion = mc_coh
    friction_angle = mc_phi
    dilation_angle = mc_psi
    mc_tip_smoother = 4E6
    yield_function_tolerance = 1.0E-1
    internal_constraint_tolerance = 1.0E-7
  [../]

  [./ts]
    type = SolidMechanicsHardeningConstant
    value = 1E6
  [../]
  [./tensile]
    type = SolidMechanicsPlasticTensile
    tensile_strength = ts
    tensile_tip_smoother = 1E5
    yield_function_tolerance = 1.0E-1
    internal_constraint_tolerance = 1.0E-7
  [../]
  [./coh]
    type = SolidMechanicsHardeningConstant
    value = 1E6
  [../]
  [./tanphi]
    type = SolidMechanicsHardeningConstant
    value = 0.46630766
  [../]
  [./tanpsi]
    type = SolidMechanicsHardeningConstant
    value = 0.46630766
  [../]
  [./wps]
    type = SolidMechanicsPlasticWeakPlaneShear
    cohesion = coh
    tan_friction_angle = tanphi
    tan_dilation_angle = tanpsi
    smoother = 1E5
    yield_function_tolerance = 1.0E-1
    internal_constraint_tolerance = 1.0E-7
  [../]
  [./str]
    type = SolidMechanicsHardeningConstant
    value = 0.01E6
  [../]
  [./wpt]
    type = SolidMechanicsPlasticWeakPlaneTensile
    tensile_strength = str
    yield_function_tolerance = 1.0E-1
    internal_constraint_tolerance = 1.0E-7
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeElasticityTensor
    block = 0
    fill_method = symmetric_isotropic
    C_ijkl = '1E9 1.3E9'
  [../]
  [./strain]
    type = ComputeFiniteStrain
    block = 0
    displacements = 'disp_x disp_y disp_z'
  [../]
  [./multi]
    type = ComputeMultiPlasticityStress
    block = 0
    ep_plastic_tolerance = 1E-7
    plastic_models = 'mc tensile wps wpt'
    deactivation_scheme = 'optimized_to_safe_to_dumb'
    max_NR_iterations = 20
    min_stepsize = 1E-4
    max_stepsize_for_dumb = 1E-3
    debug_fspb = crash
    debug_jac_at_stress = '10 0 0 0 10 0 0 0 10'
    debug_jac_at_pm = '1 1 1 1'
    debug_jac_at_intnl = '1 1 1 1'
    debug_stress_change = 1E1
    debug_pm_change = '1E-6 1E-6 1E-6 1E-6'
    debug_intnl_change = '1E-6 1E-6 1E-6 1E-6'
  [../]
[]


[Executioner]
  end_time = 1
  dt = 1
  type = Transient
[]


[Outputs]
  file_base = rock1
  exodus = false
  [./csv]
    type = CSV
    [../]
[]

(modules/combined/test/tests/poro_mechanics/borehole_lowres.i)

# Poroelastic response of a borehole.
#
# LOWRES VERSION: this version does not give perfect agreement with the analytical solution
#
# A fully-saturated medium contains a fluid with a homogeneous porepressure,
# but an anisitropic insitu stress.  A infinitely-long borehole aligned with
# the $$z$$ axis is instanteously excavated.  The borehole boundary is
# stress-free and allowed to freely drain.  This problem is analysed using
# plane-strain conditions (no $$z$$ displacement).
#
# The solution in Laplace space is found in E Detournay and AHD Cheng "Poroelastic response of a borehole in a non-hydrostatic stress field".  International Journal of Rock Mechanics and Mining Sciences and Geomechanics Abstracts 25 (1988) 171-182.  In the small-time limit, the Laplace transforms may be performed.  There is one typo in the paper.  Equation (A4)'s final term should be -(a/r)\sqrt(4ct/(a^2\pi)), and not +(a/r)\sqrt(4ct/(a^2\pi)).
#
# Because realistic parameters are chosen (below),
# the residual for porepressure is much smaller than
# the residuals for the displacements.  Therefore the
# scaling parameter is chosen.  Also note that the
# insitu stresses are effective stresses, not total
# stresses, but the solution in the above paper is
# expressed in terms of total stresses.
#
# Here are the problem's parameters, and their values:
# Borehole radius.  a = 1
# Rock's Lame lambda.  la = 0.5E9
# Rock's Lame mu, which is also the Rock's shear modulus.  mu = G = 1.5E9
# Rock bulk modulus.  K = la + 2*mu/3 = 1.5E9
# Drained Poisson ratio.  nu = (3K - 2G)/(6K + 2G) = 0.125
# Rock bulk compliance.  1/K = 0.66666666E-9
# Fluid bulk modulus.  Kf = 0.7171315E9
# Fluid bulk compliance.  1/Kf = 1.39444444E-9
# Rock initial porosity.  phi0 = 0.3
# Biot coefficient.  alpha = 0.65
# Biot modulus.  M = 1/(phi0/Kf + (alpha - phi0)(1 - alpha)/K) = 2E9
# Undrained bulk modulus. Ku = K + alpha^2*M = 2.345E9
# Undrained Poisson ratio.  nuu = (3Ku - 2G)/(6Ku + 2G) = 0.2364
# Skempton coefficient.  B = alpha*M/Ku = 0.554
# Fluid mobility (rock permeability/fluid viscosity).  k = 1E-12

[Mesh]
  type = FileMesh
  file = borehole_lowres_input.e
[]

[GlobalParams]
  displacements = 'disp_x disp_y disp_z'
  porepressure = porepressure
  block = 1
[]

[GlobalParams]
  volumetric_locking_correction=true
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./disp_z]
  [../]
  [./porepressure]
    scaling = 1E9  # Notice the scaling, to make porepressure's kernels roughly of same magnitude as disp's kernels
  [../]
[]

[ICs]
  [./initial_p]
    type = ConstantIC
    variable = porepressure
    value = 1E6
  [../]
[]

[BCs]
  [./fixed_outer_x]
    type = DirichletBC
    variable = disp_x
    value = 0
    boundary = outer
  [../]
  [./fixed_outer_y]
    type = DirichletBC
    variable = disp_y
    value = 0
    boundary = outer
  [../]
  [./plane_strain]
    type = DirichletBC
    variable = disp_z
    value = 0
    boundary = 'zmin zmax'
  [../]
  [./borehole_wall]
    type = DirichletBC
    variable = porepressure
    value = 0
    boundary = bh_wall
  [../]
[]



[AuxVariables]
  [./stress_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./tot_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
[]

[AuxKernels]
  [./stress_yy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yy
    index_i = 1
    index_j = 1
  [../]
  [./tot_yy]
    type = ParsedAux
    coupled_variables = 'stress_yy porepressure'
    execute_on = timestep_end
    variable = tot_yy
    expression = 'stress_yy-0.65*porepressure'
  [../]
[]



[Kernels]
  [./grad_stress_x]
    type = StressDivergenceTensors
    variable = disp_x
    component = 0
  [../]
  [./grad_stress_y]
    type = StressDivergenceTensors
    variable = disp_y
    component = 1
  [../]
  [./grad_stress_z]
    type = StressDivergenceTensors
    variable = disp_z
    component = 2
  [../]
  [./poro_x]
    type = PoroMechanicsCoupling
    variable = disp_x
    component = 0
  [../]
  [./poro_y]
    type = PoroMechanicsCoupling
    variable = disp_y
    component = 1
  [../]
  [./poro_z]
    type = PoroMechanicsCoupling
    variable = disp_z
    component = 2
  [../]
  [./poro_timederiv]
    type = PoroFullSatTimeDerivative
    variable = porepressure
  [../]
  [./darcy_flow]
    type = CoefDiffusion
    variable = porepressure
    coef = 1E-12
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeElasticityTensor
    C_ijkl = '0.5E9 1.5E9'
    # bulk modulus is lambda + 2*mu/3 = 0.5 + 2*1.5/3 = 1.5E9
    fill_method = symmetric_isotropic
  [../]
  [./strain]
    type = ComputeFiniteStrain
    displacements = 'disp_x disp_y disp_z'
    eigenstrain_names = ini_stress
  [../]
  [./ini_stress]
    type = ComputeEigenstrainFromInitialStress
    initial_stress = '-1.35E6 0 0  0 -3.35E6 0  0 0 0' # remember this is the effective stress
    eigenstrain_name = ini_stress
  [../]
  [./no_plasticity]
    type = ComputeFiniteStrainElasticStress
  [../]
  [./poro_material]
    type = PoroFullSatMaterial
    porosity0 = 0.3
    biot_coefficient = 0.65
    solid_bulk_compliance = 0.6666666666667E-9
    fluid_bulk_compliance = 1.3944444444444E-9
    constant_porosity = false
  [../]
[]

[Postprocessors]
  [./p00]
    type = PointValue
    variable = porepressure
    point = '1.00 0 0'
    outputs = csv_p
  [../]
  [./p01]
    type = PointValue
    variable = porepressure
    point = '1.01 0 0'
    outputs = csv_p
  [../]
  [./p02]
    type = PointValue
    variable = porepressure
    point = '1.02 0 0'
    outputs = csv_p
  [../]
  [./p03]
    type = PointValue
    variable = porepressure
    point = '1.03 0 0'
    outputs = csv_p
  [../]
  [./p04]
    type = PointValue
    variable = porepressure
    point = '1.04 0 0'
    outputs = csv_p
  [../]
  [./p05]
    type = PointValue
    variable = porepressure
    point = '1.05 0 0'
    outputs = csv_p
  [../]
  [./p06]
    type = PointValue
    variable = porepressure
    point = '1.06 0 0'
    outputs = csv_p
  [../]
  [./p07]
    type = PointValue
    variable = porepressure
    point = '1.07 0 0'
    outputs = csv_p
  [../]
  [./p08]
    type = PointValue
    variable = porepressure
    point = '1.08 0 0'
    outputs = csv_p
  [../]
  [./p09]
    type = PointValue
    variable = porepressure
    point = '1.09 0 0'
    outputs = csv_p
  [../]
  [./p10]
    type = PointValue
    variable = porepressure
    point = '1.10 0 0'
    outputs = csv_p
  [../]
  [./p11]
    type = PointValue
    variable = porepressure
    point = '1.11 0 0'
    outputs = csv_p
  [../]
  [./p12]
    type = PointValue
    variable = porepressure
    point = '1.12 0 0'
    outputs = csv_p
  [../]
  [./p13]
    type = PointValue
    variable = porepressure
    point = '1.13 0 0'
    outputs = csv_p
  [../]
  [./p14]
    type = PointValue
    variable = porepressure
    point = '1.14 0 0'
    outputs = csv_p
  [../]
  [./p15]
    type = PointValue
    variable = porepressure
    point = '1.15 0 0'
    outputs = csv_p
  [../]
  [./p16]
    type = PointValue
    variable = porepressure
    point = '1.16 0 0'
    outputs = csv_p
  [../]
  [./p17]
    type = PointValue
    variable = porepressure
    point = '1.17 0 0'
    outputs = csv_p
  [../]
  [./p18]
    type = PointValue
    variable = porepressure
    point = '1.18 0 0'
    outputs = csv_p
  [../]
  [./p19]
    type = PointValue
    variable = porepressure
    point = '1.19 0 0'
    outputs = csv_p
  [../]
  [./p20]
    type = PointValue
    variable = porepressure
    point = '1.20 0 0'
    outputs = csv_p
  [../]
  [./p21]
    type = PointValue
    variable = porepressure
    point = '1.21 0 0'
    outputs = csv_p
  [../]
  [./p22]
    type = PointValue
    variable = porepressure
    point = '1.22 0 0'
    outputs = csv_p
  [../]
  [./p23]
    type = PointValue
    variable = porepressure
    point = '1.23 0 0'
    outputs = csv_p
  [../]
  [./p24]
    type = PointValue
    variable = porepressure
    point = '1.24 0 0'
    outputs = csv_p
  [../]
  [./p25]
    type = PointValue
    variable = porepressure
    point = '1.25 0 0'
    outputs = csv_p
  [../]

  [./s00]
    type = PointValue
    variable = disp_x
    point = '1.00 0 0'
    outputs = csv_s
  [../]
  [./s01]
    type = PointValue
    variable = disp_x
    point = '1.01 0 0'
    outputs = csv_s
  [../]
  [./s02]
    type = PointValue
    variable = disp_x
    point = '1.02 0 0'
    outputs = csv_s
  [../]
  [./s03]
    type = PointValue
    variable = disp_x
    point = '1.03 0 0'
    outputs = csv_s
  [../]
  [./s04]
    type = PointValue
    variable = disp_x
    point = '1.04 0 0'
    outputs = csv_s
  [../]
  [./s05]
    type = PointValue
    variable = disp_x
    point = '1.05 0 0'
    outputs = csv_s
  [../]
  [./s06]
    type = PointValue
    variable = disp_x
    point = '1.06 0 0'
    outputs = csv_s
  [../]
  [./s07]
    type = PointValue
    variable = disp_x
    point = '1.07 0 0'
    outputs = csv_s
  [../]
  [./s08]
    type = PointValue
    variable = disp_x
    point = '1.08 0 0'
    outputs = csv_s
  [../]
  [./s09]
    type = PointValue
    variable = disp_x
    point = '1.09 0 0'
    outputs = csv_s
  [../]
  [./s10]
    type = PointValue
    variable = disp_x
    point = '1.10 0 0'
    outputs = csv_s
  [../]
  [./s11]
    type = PointValue
    variable = disp_x
    point = '1.11 0 0'
    outputs = csv_s
  [../]
  [./s12]
    type = PointValue
    variable = disp_x
    point = '1.12 0 0'
    outputs = csv_s
  [../]
  [./s13]
    type = PointValue
    variable = disp_x
    point = '1.13 0 0'
    outputs = csv_s
  [../]
  [./s14]
    type = PointValue
    variable = disp_x
    point = '1.14 0 0'
    outputs = csv_s
  [../]
  [./s15]
    type = PointValue
    variable = disp_x
    point = '1.15 0 0'
    outputs = csv_s
  [../]
  [./s16]
    type = PointValue
    variable = disp_x
    point = '1.16 0 0'
    outputs = csv_s
  [../]
  [./s17]
    type = PointValue
    variable = disp_x
    point = '1.17 0 0'
    outputs = csv_s
  [../]
  [./s18]
    type = PointValue
    variable = disp_x
    point = '1.18 0 0'
    outputs = csv_s
  [../]
  [./s19]
    type = PointValue
    variable = disp_x
    point = '1.19 0 0'
    outputs = csv_s
  [../]
  [./s20]
    type = PointValue
    variable = disp_x
    point = '1.20 0 0'
    outputs = csv_s
  [../]
  [./s21]
    type = PointValue
    variable = disp_x
    point = '1.21 0 0'
    outputs = csv_s
  [../]
  [./s22]
    type = PointValue
    variable = disp_x
    point = '1.22 0 0'
    outputs = csv_s
  [../]
  [./s23]
    type = PointValue
    variable = disp_x
    point = '1.23 0 0'
    outputs = csv_s
  [../]
  [./s24]
    type = PointValue
    variable = disp_x
    point = '1.24 0 0'
    outputs = csv_s
  [../]
  [./s25]
    type = PointValue
    variable = disp_x
    point = '1.25 0 0'
    outputs = csv_s
  [../]

  [./t00]
    type = PointValue
    variable = tot_yy
    point = '1.00 0 0'
    outputs = csv_t
  [../]
  [./t01]
    type = PointValue
    variable = tot_yy
    point = '1.01 0 0'
    outputs = csv_t
  [../]
  [./t02]
    type = PointValue
    variable = tot_yy
    point = '1.02 0 0'
    outputs = csv_t
  [../]
  [./t03]
    type = PointValue
    variable = tot_yy
    point = '1.03 0 0'
    outputs = csv_t
  [../]
  [./t04]
    type = PointValue
    variable = tot_yy
    point = '1.04 0 0'
    outputs = csv_t
  [../]
  [./t05]
    type = PointValue
    variable = tot_yy
    point = '1.05 0 0'
    outputs = csv_t
  [../]
  [./t06]
    type = PointValue
    variable = tot_yy
    point = '1.06 0 0'
    outputs = csv_t
  [../]
  [./t07]
    type = PointValue
    variable = tot_yy
    point = '1.07 0 0'
    outputs = csv_t
  [../]
  [./t08]
    type = PointValue
    variable = tot_yy
    point = '1.08 0 0'
    outputs = csv_t
  [../]
  [./t09]
    type = PointValue
    variable = tot_yy
    point = '1.09 0 0'
    outputs = csv_t
  [../]
  [./t10]
    type = PointValue
    variable = tot_yy
    point = '1.10 0 0'
    outputs = csv_t
  [../]
  [./t11]
    type = PointValue
    variable = tot_yy
    point = '1.11 0 0'
    outputs = csv_t
  [../]
  [./t12]
    type = PointValue
    variable = tot_yy
    point = '1.12 0 0'
    outputs = csv_t
  [../]
  [./t13]
    type = PointValue
    variable = tot_yy
    point = '1.13 0 0'
    outputs = csv_t
  [../]
  [./t14]
    type = PointValue
    variable = tot_yy
    point = '1.14 0 0'
    outputs = csv_t
  [../]
  [./t15]
    type = PointValue
    variable = tot_yy
    point = '1.15 0 0'
    outputs = csv_t
  [../]
  [./t16]
    type = PointValue
    variable = tot_yy
    point = '1.16 0 0'
    outputs = csv_t
  [../]
  [./t17]
    type = PointValue
    variable = tot_yy
    point = '1.17 0 0'
    outputs = csv_t
  [../]
  [./t18]
    type = PointValue
    variable = tot_yy
    point = '1.18 0 0'
    outputs = csv_t
  [../]
  [./t19]
    type = PointValue
    variable = tot_yy
    point = '1.19 0 0'
    outputs = csv_t
  [../]
  [./t20]
    type = PointValue
    variable = tot_yy
    point = '1.20 0 0'
    outputs = csv_t
  [../]
  [./t21]
    type = PointValue
    variable = tot_yy
    point = '1.21 0 0'
    outputs = csv_t
  [../]
  [./t22]
    type = PointValue
    variable = tot_yy
    point = '1.22 0 0'
    outputs = csv_t
  [../]
  [./t23]
    type = PointValue
    variable = tot_yy
    point = '1.23 0 0'
    outputs = csv_t
  [../]
  [./t24]
    type = PointValue
    variable = tot_yy
    point = '1.24 0 0'
    outputs = csv_t
  [../]
  [./t25]
    type = PointValue
    variable = tot_yy
    point = '1.25 0 0'
    outputs = csv_t
  [../]

  [./dt]
    type = FunctionValuePostprocessor
    outputs = console
    function = 2*t
  [../]
[]


[Preconditioning]
  [./andy]
    type = SMP
    full = true
    petsc_options = '-snes_monitor -snes_linesearch_monitor'
    petsc_options_iname = '-ksp_type -pc_type -snes_atol -snes_rtol -snes_max_it -ksp_max_it -sub_pc_type -sub_pc_factor_shift_type'
    petsc_options_value = 'gmres asm 1E0 1E-10 200 500 lu NONZERO'
  [../]
[]

[Executioner]
  type = Transient
  solve_type = Newton
  start_time = 0
  end_time = 0.3
  dt = 0.3
  #[./TimeStepper]
  #  type = PostprocessorDT
  #  postprocessor = dt
  #  dt = 0.003
  #[../]
[]

[Outputs]
  execute_on = 'timestep_end'
  file_base = borehole_lowres
  exodus = true
  sync_times = '0.003 0.3'
  [./csv_p]
    file_base = borehole_lowres_p
    type = CSV
  [../]
  [./csv_s]
    file_base = borehole_lowres_s
    type = CSV
  [../]
  [./csv_t]
    file_base = borehole_lowres_t
    type = CSV
  [../]
[]

(modules/contact/test/tests/glued/glued_contact_mechanical_constraint_test.i)

# This is a mechanical constraint (contact formulation) version of glued_contact_mechanical_constraint.i
[Mesh]
  file = glued_contact_test.e
[]

[GlobalParams]
  volumetric_locking_correction = true
  displacements = 'disp_x disp_y disp_z'
[]

[Functions]
  [./up]
    type = PiecewiseLinear
    x = '0 1'
    y = '0 0.5001'
  [../]

  [./lateral]
    type = PiecewiseLinear
    x = '0 1 2 3'
    y = '0 0 1 0'
    scale_factor = 0.5
  [../]
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./disp_z]
  [../]
[]

[Kernels]
  [./TensorMechanics]
    use_displaced_mesh = true
  [../]
[]

[Contact]
  [./dummy_name]
    primary = 2
    secondary = 3
    penalty = 1e6
    model = glued
    formulation = kinematic
  [../]
[]

[BCs]

  [./bottom_lateral]
    type = FunctionDirichletBC
    variable = disp_x
    boundary = 1
    function = lateral
  [../]

  [./bottom_up]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = 1
    function = up
  [../]

  [./bottom_out]
    type = DirichletBC
    variable = disp_z
    boundary = 1
    value = 0.0
  [../]

  [./top]
    type = DirichletBC
    variable = disp_y
    boundary = 4
    value = 0.0
  [../]
[]

[Materials]
  [./stiffStuff1]
    type = ComputeIsotropicElasticityTensor
    block = '1'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./stiffStuff1_strain]
    type= ComputeFiniteStrain
    block = '1'
  [../]
  [./stiffStuff1_stress]
    type = ComputeFiniteStrainElasticStress
    block = '1'
  [../]

  [./stiffStuff2]
    type = ComputeIsotropicElasticityTensor
    block = '2'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./stiffStuff2_strain]
    type= ComputeFiniteStrain
    block = '2'
  [../]
  [./stiffStuff2_stress]
    type = ComputeFiniteStrainElasticStress
    block = '2'
  [../]
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'

  #petsc_options_iname = '-pc_type -pc_hypre_type -snes_type -snes_ls -snes_linesearch_type -ksp_gmres_restart'
  #petsc_options_value = 'hypre    boomeramg      ls         basic    basic                    101'
  petsc_options_iname = '-pc_type -ksp_gmres_restart'
  petsc_options_value = 'ilu      101'

  line_search = 'none'

  nl_abs_tol = 1e-8
  nl_rel_tol = 1e-8
  l_tol = 1e-4

  l_max_its = 100
  nl_max_its = 10
  dt = 0.1
  num_steps = 30

  [./Predictor]
    type = SimplePredictor
    scale = 1.0
  [../]
[]

[Postprocessors]
  active = ''
  [./resid]
    type = Residual
  [../]
  [./iters]
    type = NumNonlinearIterations
  [../]
[]

[Outputs]
  file_base = mechanical_constraint_out
  exodus = true
[]

(modules/solid_mechanics/test/tests/crystal_plasticity/user_object_based/prop_block_read.i)

[Mesh]
  [gen]
    type = GeneratedMeshGenerator
    dim = 2
    xmin = 0
    ymin = 0
    xmax = 1
    ymax = 1
    nx = 2
    ny = 2
    elem_type = QUAD4
  []
  [./subdomain_id]
    input = gen
    type = SubdomainPerElementGenerator
    subdomain_ids = '0 1
                     0 1'
  [../]
  displacements = 'disp_x disp_y'
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
[]

[GlobalParams]
  volumetric_locking_correction = true
[]

[AuxVariables]
  [./stress_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./e_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./fp_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./gss]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./euler1]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./euler2]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./euler3]
    order = CONSTANT
    family = MONOMIAL
  [../]
[]

[Functions]
  [./tdisp]
    type = ParsedFunction
    expression = 0.01*t
  [../]
[]

[UserObjects]
  [./prop_read]
    type = PropertyReadFile
    prop_file_name = 'euler_ang_file.txt'
    # Enter file data as prop#1, prop#2, .., prop#nprop
    nprop = 3
    read_type = block
    nblock= 2
  [../]
[]

[AuxKernels]
  [./stress_yy]
    type = RankTwoAux
    variable = stress_yy
    rank_two_tensor = stress
    index_j = 1
    index_i = 1
    execute_on = timestep_end
  [../]
  [./e_yy]
    type = RankTwoAux
    variable = e_yy
    rank_two_tensor = lage
    index_j = 1
    index_i = 1
    execute_on = timestep_end
  [../]
  [./fp_yy]
    type = RankTwoAux
    variable = fp_yy
    rank_two_tensor = fp
    index_j = 1
    index_i = 1
    execute_on = timestep_end
  [../]
  [./gss]
    type = MaterialStdVectorAux
    variable = gss
    property = state_var_gss
    index = 0
    execute_on = timestep_end
  [../]
  [./euler1]
    type = MaterialRealVectorValueAux
    variable = euler1
    property = Euler_angles
    component = 0
    execute_on = timestep_end
  [../]
  [./euler2]
    type = MaterialRealVectorValueAux
    variable = euler2
    property = Euler_angles
    component = 1
    execute_on = timestep_end
  [../]
  [./euler3]
    type = MaterialRealVectorValueAux
    variable = euler3
    property = Euler_angles
    component = 2
    execute_on = timestep_end
  [../]
[]

[BCs]
  [./fix_x]
    type = DirichletBC
    variable = disp_x
    boundary = 'left'
    value = 0
  [../]
  [./fix_y]
    type = DirichletBC
    variable = disp_y
    boundary = 'bottom'
    value = 0
  [../]
  [./tdisp]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = top
    function = tdisp
  [../]
[]

[UserObjects]
  [./slip_rate_gss]
    type = CrystalPlasticitySlipRateGSS
    variable_size = 12
    slip_sys_file_name = input_slip_sys.txt
    num_slip_sys_flowrate_props = 2
    flowprops = '1 4 0.001 0.1 5 8 0.001 0.1 9 12 0.001 0.1'
    uo_state_var_name = state_var_gss
  [../]
  [./slip_resistance_gss]
    type = CrystalPlasticitySlipResistanceGSS
    variable_size = 12
    uo_state_var_name = state_var_gss
  [../]
  [./state_var_gss]
    type = CrystalPlasticityStateVariable
    variable_size = 12
    groups = '0 4 8 12'
    group_values = '60.8 60.8 60.8'
    uo_state_var_evol_rate_comp_name = state_var_evol_rate_comp_gss
    scale_factor = 1.0
  [../]
  [./state_var_evol_rate_comp_gss]
    type = CrystalPlasticityStateVarRateComponentGSS
    variable_size = 12
    hprops = '1.0 541.5 109.8 2.5'
    uo_slip_rate_name = slip_rate_gss
    uo_state_var_name = state_var_gss
  [../]
[]

[Materials]
  [./crysp]
    type = FiniteStrainUObasedCP
    stol = 1e-2
    tan_mod_type = exact
    uo_slip_rates = 'slip_rate_gss'
    uo_slip_resistances = 'slip_resistance_gss'
    uo_state_vars = 'state_var_gss'
    uo_state_var_evol_rate_comps = 'state_var_evol_rate_comp_gss'
  [../]
  [./strain]
    type = ComputeFiniteStrain
    displacements = 'disp_x disp_y'
  [../]
  [./elasticity_tensor]
    type = ComputeElasticityTensorCP
    C_ijkl = '1.684e5 1.214e5 1.214e5 1.684e5 1.214e5 1.684e5 0.754e5 0.754e5 0.754e5'
    fill_method = symmetric9
    read_prop_user_object = prop_read
  [../]
[]

[Postprocessors]
  [./stress_yy]
    type = ElementAverageValue
    variable = stress_yy
  [../]
  [./e_yy]
    type = ElementAverageValue
    variable = e_yy
  [../]
  [./fp_yy]
    type = ElementAverageValue
    variable = fp_yy
  [../]
  [./gss]
    type = ElementAverageValue
    variable = gss
  [../]
[]

[Preconditioning]
  [./smp]
    type = SMP
    full = true
  [../]
[]

[Executioner]
  type = Transient
  dt = 0.01
  solve_type = 'PJFNK'

  petsc_options_iname = -pc_hypre_type
  petsc_options_value = boomerang
  nl_abs_tol = 1e-10
  nl_rel_step_tol = 1e-10
  dtmax = 10.0
  nl_rel_tol = 1e-10
  end_time = 1
  dtmin = 0.01
  num_steps = 10
  nl_abs_step_tol = 1e-10
[]

[Outputs]
  exodus = true
[]

[Kernels]
  [SolidMechanics]
    displacements = 'disp_x disp_y'
    use_displaced_mesh = true
  [../]
[]

(modules/solid_mechanics/test/tests/elem_prop_read_user_object/prop_grain_read.i)

[Mesh]
  type = GeneratedMesh
  dim = 2
  elem_type = QUAD4
  displacements = 'disp_x disp_y'
  nx = 10
  ny = 10
[]

[Variables]
  [./disp_x]
    block = 0
  [../]
  [./disp_y]
    block = 0
  [../]
[]

[GlobalParams]
  volumetric_locking_correction=true
[]

[AuxVariables]
  [./stress_yy]
    order = CONSTANT
    family = MONOMIAL
    block = 0
  [../]
  [./e_yy]
    order = CONSTANT
    family = MONOMIAL
    block = 0
  [../]
[]

[Functions]
  [./tdisp]
    type = ParsedFunction
    expression = 0.05*t
  [../]
[]

[UserObjects]
  [./prop_read]
    type = PropertyReadFile
    prop_file_name = 'input_file.txt'
    # Enter file data as prop#1, prop#2, .., prop#nprop
    nprop = 4
    read_type = voronoi
    nvoronoi = 3
    use_random_voronoi = true
    rand_seed = 25346
    rve_type = periodic
  [../]
[]

[AuxKernels]
  [./stress_yy]
    type = RankTwoAux
    variable = stress_yy
    rank_two_tensor = stress
    index_j = 1
    index_i = 1
    execute_on = timestep_end
    block = 0
  [../]
  [./e_yy]
    type = RankTwoAux
    variable = e_yy
    rank_two_tensor = elastic_strain
    index_j = 1
    index_i = 1
    execute_on = timestep_end
    block = 0
  [../]
[]

[BCs]
  [./fix_x]
    type = DirichletBC
    variable = disp_x
    boundary = 'left'
    value = 0
  [../]
  [./fix_y]
    type = DirichletBC
    variable = disp_y
    boundary = 'bottom'
    value = 0
  [../]
  [./tdisp]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = top
    function = tdisp
  [../]
[]

[Materials]
  [./elasticity_tensor_with_Euler]
    type = ComputeElasticityTensorCP
    block = 0
    C_ijkl = '1.684e5 0.176e5 0.176e5 1.684e5 0.176e5 1.684e5 0.754e5 0.754e5 0.754e5'
    fill_method = symmetric9
    read_prop_user_object = prop_read
  [../]
  [./strain]
    type = ComputeFiniteStrain
    block = 0
    displacements = 'disp_x disp_y'
  [../]
  [./stress]
    type = ComputeFiniteStrainElasticStress
    block = 0
  [../]
[]

[Postprocessors]
  [./stress_yy]
    type = ElementAverageValue
    variable = stress_yy
    block = 'ANY_BLOCK_ID 0'
  [../]
  [./e_yy]
    type = ElementAverageValue
    variable = e_yy
    block = 'ANY_BLOCK_ID 0'
  [../]
[]

[Preconditioning]
  [./smp]
    type = SMP
    full = true
  [../]
[]

[Executioner]
  type = Transient
  dt = 0.05

  #Preconditioned JFNK (default)
  solve_type = 'PJFNK'

  petsc_options_iname = -pc_hypre_type
  petsc_options_value = boomerang
  nl_abs_tol = 1e-10
  nl_rel_step_tol = 1e-10
  dtmax = 10.0
  nl_rel_tol = 1e-10
  end_time = 1
  dtmin = 0.05
  num_steps = 1
  nl_abs_step_tol = 1e-10
[]

[Outputs]
  file_base = prop_grain_read_out
  exodus = true
[]

[Kernels]
  [SolidMechanics]
    displacements = 'disp_x disp_y'
    use_displaced_mesh = true
  [../]
[]

(modules/contact/test/tests/verification/patch_tests/brick_4/brick4_template1.i)

[GlobalParams]
  order = SECOND
  displacements = 'disp_x disp_y disp_z'
[]

[Mesh]
  file = brick4_mesh.e
[]

[Problem]
  type = ReferenceResidualProblem
  extra_tag_vectors = 'ref'
  reference_vector = 'ref'
[]

[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./disp_z]
  [../]
[]

[AuxVariables]
  [./stress_xx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_zz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./penetration]
  [../]
  [./saved_x]
  [../]
  [./saved_y]
  [../]
  [./saved_z]
  [../]
  [./diag_saved_x]
  [../]
  [./diag_saved_y]
  [../]
  [./diag_saved_z]
  [../]
  [./inc_slip_x]
  [../]
  [./inc_slip_y]
  [../]
  [./inc_slip_z]
  [../]
  [./accum_slip_x]
  [../]
  [./accum_slip_y]
  [../]
  [./accum_slip_z]
  [../]
[]

[Kernels]
  [./TensorMechanics]
    use_displaced_mesh = true
    save_in = 'saved_x saved_y saved_z'
    extra_vector_tags = 'ref'
  [../]
[]

[AuxKernels]
  [./stress_xx]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xx
    index_i = 0
    index_j = 0
    execute_on = timestep_end
  [../]
  [./stress_yy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yy
    index_i = 1
    index_j = 1
    execute_on = timestep_end
  [../]
  [./stress_xy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xy
    index_i = 0
    index_j = 1
    execute_on = timestep_end
  [../]
  [./stress_zz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_zz
    index_i = 2
    index_j = 2
    execute_on = timestep_end
  [../]
  [./inc_slip_x]
    type = PenetrationAux
    variable = inc_slip_x
    execute_on = timestep_begin
    boundary = 4
    paired_boundary = 3
  [../]
  [./inc_slip_y]
    type = PenetrationAux
    variable = inc_slip_y
    execute_on = timestep_begin
    boundary = 4
    paired_boundary = 3
  [../]
  [./accum_slip_x]
    type = PenetrationAux
    variable = accum_slip_x
    execute_on = timestep_end
    boundary = 4
    paired_boundary = 3
  [../]
  [./accum_slip_y]
    type = PenetrationAux
    variable = accum_slip_y
    execute_on = timestep_end
    boundary = 4
    paired_boundary = 3
  [../]
  [./penetration]
    type = PenetrationAux
    variable = penetration
    boundary = 4
    paired_boundary = 3
  [../]
[]

[Postprocessors]
  [./bot_react_x]
    type = NodalSum
    variable = saved_x
    boundary = 1
  [../]
  [./bot_react_y]
    type = NodalSum
    variable = saved_y
    boundary = 1
  [../]
  [./top_react_x]
    type = NodalSum
    variable = saved_x
    boundary = 5
  [../]
  [./top_react_y]
    type = NodalSum
    variable = saved_y
    boundary = 5
  [../]
  [./ref_resid_x]
    type = NodalL2Norm
    execute_on = timestep_end
    variable = saved_x
  [../]
  [./ref_resid_y]
    type = NodalL2Norm
    execute_on = timestep_end
    variable = saved_y
  [../]
  [./sigma_yy]
    type = ElementAverageValue
    variable = stress_yy
  [../]
  [./sigma_zz]
    type = ElementAverageValue
    variable = stress_zz
  [../]
  [./disp_x59]
    type = NodalVariableValue
    nodeid = 58
    variable = disp_x
  [../]
  [./disp_x64]
    type = NodalVariableValue
    nodeid = 63
    variable = disp_x
  [../]
  [./disp_y59]
    type = NodalVariableValue
    nodeid = 58
    variable = disp_y
  [../]
  [./disp_y64]
    type = NodalVariableValue
    nodeid = 63
    variable = disp_y
  [../]
  [./_dt]
    type = TimestepSize
  [../]
  [./num_lin_it]
    type = NumLinearIterations
  [../]
  [./num_nonlin_it]
    type = NumNonlinearIterations
  [../]
[]

[BCs]
  [./bot_y]
    type = DirichletBC
    variable = disp_y
    boundary = 1
    value = 0.0
  [../]
  [./side_x]
    type = DirichletBC
    variable = disp_x
    boundary = 2
    value = 0.0
  [../]
  [./back_z]
    type = DirichletBC
    variable = disp_z
    boundary = 6
    value = 0.0
  [../]
  [./top_press]
    type = Pressure
    variable = disp_y
    boundary = 5
    factor = 109.89
  [../]
[]

[Materials]
  [./bot_elas_tens]
    type = ComputeIsotropicElasticityTensor
    block = '1'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./bot_strain]
    type = ComputeFiniteStrain
    block = '1'
  [../]
  [./bot_stress]
    type = ComputeFiniteStrainElasticStress
    block = '1'
  [../]
  [./top_elas_tens]
    type = ComputeIsotropicElasticityTensor
    block = '2'
    youngs_modulus = 1e6
    poissons_ratio = 0.3
  [../]
  [./top_strain]
    type = ComputeFiniteStrain
    block = '2'
  [../]
  [./top_stress]
    type = ComputeFiniteStrainElasticStress
    block = '2'
  [../]
[]

[Executioner]
  type = Transient
  solve_type = 'PJFNK'

  petsc_options_iname = '-pc_type -pc_factor_mat_solver_type'
  petsc_options_value = 'lu     superlu_dist'

  line_search = 'none'

  nl_abs_tol = 1e-7
  nl_rel_tol = 1e-6
  l_max_its = 50
  nl_max_its = 100
  dt = 1.0
  end_time = 1.0
  num_steps = 10
  dtmin = 1.0
  l_tol = 1e-4
[]

[VectorPostprocessors]
  [./x_disp]
    type = NodalValueSampler
    variable = disp_x
    boundary = '1 3 4 5'
    sort_by = id
  [../]
  [./y_disp]
    type = NodalValueSampler
    variable = disp_y
    boundary = '1 3 4 5'
    sort_by = id
  [../]
  [./cont_press]
    type = NodalValueSampler
    variable = contact_pressure
    boundary = '3'
    sort_by = id
  [../]
[]

[Outputs]
  print_linear_residuals = true
  perf_graph = true
  [./exodus]
    type = Exodus
    elemental_as_nodal = true
  [../]
  [./console]
    type = Console
    max_rows = 5
  [../]
  [./chkfile]
    type = CSV
    show = 'bot_react_x bot_react_y disp_x59 disp_y59 disp_x64 disp_y64 stress_yy stress_zz top_react_x top_react_y x_disp y_disp cont_press'
    execute_vector_postprocessors_on = timestep_end
  [../]
  [./outfile]
    type = CSV
    delimiter = ' '
    execute_vector_postprocessors_on = none
  [../]
[]

[Contact]
  [./leftright]
    secondary = 3
    primary = 4
    normalize_penalty = true
    tangential_tolerance = 1e-3
    penalty = 1e+9
  [../]
[]

(modules/solid_mechanics/test/tests/multi/two_surface03.i)

# Plasticit models:
# SimpleTester with a = 0 and b = 1 and strength = 1
# SimpleTester with a = 1 and b = 1 and strength = 2
#
# Lame lambda = 0 (Poisson=0).  Lame mu = 0.5E6
#
# A single element is stretched by 3.0E-6m in z directions and 0.5E-6 in y direction.
# trial stress_zz = 3.0 and stress_yy = 0.5
#
# Then both  SimpleTesters should activate initially and return to the "corner" point
# (stress_zz = 1 = stress_yy), but then the plastic multiplier for SimpleTester2 will
# be negative, and so it will be deactivated, and the algorithm will return to
# stress_zz = 1, stress_yy = 0.5
# internal0 should be 2, and internal1 should be 0

[Mesh]
  type = GeneratedMesh
  dim = 3
  nx = 1
  ny = 1
  nz = 1
  xmin = -0.5
  xmax = 0.5
  ymin = -0.5
  ymax = 0.5
  zmin = -0.5
  zmax = 0.5
[]


[Variables]
  [./disp_x]
  [../]
  [./disp_y]
  [../]
  [./disp_z]
  [../]
[]

[Kernels]
  [SolidMechanics]
    displacements = 'disp_x disp_y disp_z'
  [../]
[]


[BCs]
  [./x]
    type = FunctionDirichletBC
    variable = disp_x
    boundary = 'front back'
    function = '0E-6*x'
  [../]
  [./y]
    type = FunctionDirichletBC
    variable = disp_y
    boundary = 'front back'
    function = '0.5E-6*y'
  [../]
  [./z]
    type = FunctionDirichletBC
    variable = disp_z
    boundary = 'front back'
    function = '3E-6*z'
  [../]
[]

[AuxVariables]
  [./stress_xx]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_xz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yy]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_yz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./stress_zz]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./f0]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./f1]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./int0]
    order = CONSTANT
    family = MONOMIAL
  [../]
  [./int1]
    order = CONSTANT
    family = MONOMIAL
  [../]
[]

[AuxKernels]
  [./stress_xx]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xx
    index_i = 0
    index_j = 0
  [../]
  [./stress_xy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xy
    index_i = 0
    index_j = 1
  [../]
  [./stress_xz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_xz
    index_i = 0
    index_j = 2
  [../]
  [./stress_yy]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yy
    index_i = 1
    index_j = 1
  [../]
  [./stress_yz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_yz
    index_i = 1
    index_j = 2
  [../]
  [./stress_zz]
    type = RankTwoAux
    rank_two_tensor = stress
    variable = stress_zz
    index_i = 2
    index_j = 2
  [../]
  [./f0]
    type = MaterialStdVectorAux
    property = plastic_yield_function
    index = 0
    variable = f0
  [../]
  [./f1]
    type = MaterialStdVectorAux
    property = plastic_yield_function
    index = 1
    variable = f1
  [../]
  [./int0]
    type = MaterialStdVectorAux
    property = plastic_internal_parameter
    factor = 1E6
    index = 0
    variable = int0
  [../]
  [./int1]
    type = MaterialStdVectorAux
    property = plastic_internal_parameter
    factor = 1E6
    index = 1
    variable = int1
  [../]
[]

[Postprocessors]
  [./s_xx]
    type = PointValue
    point = '0 0 0'
    variable = stress_xx
  [../]
  [./s_xy]
    type = PointValue
    point = '0 0 0'
    variable = stress_xy
  [../]
  [./s_xz]
    type = PointValue
    point = '0 0 0'
    variable = stress_xz
  [../]
  [./s_yy]
    type = PointValue
    point = '0 0 0'
    variable = stress_yy
  [../]
  [./s_yz]
    type = PointValue
    point = '0 0 0'
    variable = stress_yz
  [../]
  [./s_zz]
    type = PointValue
    point = '0 0 0'
    variable = stress_zz
  [../]
  [./f0]
    type = PointValue
    point = '0 0 0'
    variable = f0
  [../]
  [./f1]
    type = PointValue
    point = '0 0 0'
    variable = f1
  [../]
  [./int0]
    type = PointValue
    point = '0 0 0'
    variable = int0
  [../]
  [./int1]
    type = PointValue
    point = '0 0 0'
    variable = int1
  [../]
[]

[UserObjects]
  [./simple1]
    type = SolidMechanicsPlasticSimpleTester
    a = 0
    b = 1
    strength = 1
    yield_function_tolerance = 1.0E-9
    internal_constraint_tolerance = 1.0E-9
  [../]
  [./simple2]
    type = SolidMechanicsPlasticSimpleTester
    a = 1
    b = 1
    strength = 2
    yield_function_tolerance = 1.0E-9
    internal_constraint_tolerance = 1.0E-9
  [../]
[]

[Materials]
  [./elasticity_tensor]
    type = ComputeElasticityTensor
    block = 0
    fill_method = symmetric_isotropic
    C_ijkl = '0 0.5E6'
  [../]
  [./strain]
    type = ComputeFiniteStrain
    block = 0
    displacements = 'disp_x disp_y disp_z'
  [../]
  [./multi]
    type = ComputeMultiPlasticityStress
    block = 0
    ep_plastic_tolerance = 1E-9
    plastic_models = 'simple1 simple2'
    max_NR_iterations = 2
    min_stepsize = 1
    debug_fspb = crash
    debug_jac_at_stress = '10 0 0 0 10 0 0 0 10'
    debug_jac_at_pm = '1 1'
    debug_jac_at_intnl = '1 1'
    debug_stress_change = 1E-5
    debug_pm_change = '1E-6 1E-6'
    debug_intnl_change = '1E-6 1E-6'
  [../]
[]


[Executioner]
  end_time = 1
  dt = 1
  type = Transient
[]


[Outputs]
  file_base = two_surface03
  exodus = false
  [./csv]
    type = CSV
    [../]
[]

(modules/combined/test/tests/cavity_pressure/multiple_postprocessors.i)

#
# Cavity Pressure Test (Volume input as a vector of postprocessors)
#
# This test is designed to compute an internal pressure based on
#   p = n * R * T / V
# where
#   p is the pressure
#   n is the amount of material in the volume (moles)
#   R is the universal gas constant
#   T is the temperature
#   V is the volume
#
# The mesh is composed of one block (1) with an interior cavity of volume 8.
#   Block 2 sits in the cavity and has a volume of 1.  Thus, the total
#   initial volume is 7.
# The test adjusts n, T, and V in the following way:
#   n => n0 + alpha * t
#   T => T0 + beta * t
#   V => V0 + gamma * t
# with
#   alpha = n0
#   beta = T0 / 2
#   gamma = - (0.003322259...) * V0
#   T0 = 240.54443866068704
#   V0 = 7
#   n0 = f(p0)
#   p0 = 100
#   R = 8.314472 J * K^(-1) * mol^(-1)
#
# So, n0 = p0 * V0 / R / T0 = 100 * 7 / 8.314472 / 240.544439
#        = 0.35
#
# In this test the internal volume is calculated as the sum of two Postprocessors
# internalVolumeInterior and internalVolumeExterior.  This sum equals the value
# reported by the internalVolume postprocessor.
#
# The parameters combined at t = 1 gives p = 301.
#

[GlobalParams]
  displacements = 'disp_x disp_y disp_z'
  volumetric_locking_correction = true
[]

[Mesh]
  file = 3d.e
[]

[Functions]
  [displ_positive]
    type = PiecewiseLinear
    x = '0 1'
    y = '0 0.0029069767441859684'
  []
  [displ_negative]
    type = PiecewiseLinear
    x = '0 1'
    y = '0 -0.0029069767441859684'
  []
  [temp1]
    type = PiecewiseLinear
    x = '0 1'
    y = '1 1.5'
    scale_factor = 240.54443866068704
  []
  [material_input_function]
    type = PiecewiseLinear
    x = '0    1'
    y = '0 0.35'
  []
[]

[Variables]
  [disp_x]
  []
  [disp_y]
  []
  [disp_z]
  []
  [temp]
    initial_condition = 240.54443866068704
  []
  [material_input]
  []
[]

[AuxVariables]
  [pressure_residual_x]
  []
  [pressure_residual_y]
  []
  [pressure_residual_z]
  []
  [stress_xx]
    order = CONSTANT
    family = MONOMIAL
  []
  [stress_yy]
    order = CONSTANT
    family = MONOMIAL
  []
  [stress_zz]
    order = CONSTANT
    family = MONOMIAL
  []
  [stress_xy]
    order = CONSTANT
    family = MONOMIAL
  []
  [stress_yz]
    order = CONSTANT
    family = MONOMIAL
  []
  [stress_zx]
    order = CONSTANT
    family = MONOMIAL
  []
[]

[Kernels]
  [TensorMechanics]
    use_displaced_mesh = true
  []
  [heat]
    type = Diffusion
    variable = temp
    use_displaced_mesh = true
  []
  [material_input_dummy]
    type = Diffusion
    variable = material_input
    use_displaced_mesh = true
  []
[]

[AuxKernels]
  [stress_xx]
    type = RankTwoAux
    rank_two_tensor = stress
    index_i = 0
    index_j = 0
    variable = stress_xx
  []
  [stress_yy]
    type = RankTwoAux
    rank_two_tensor = stress
    index_i = 1
    index_j = 1
    variable = stress_yy
  []
  [stress_zz]
    type = RankTwoAux
    rank_two_tensor = stress
    index_i = 2
    index_j = 2
    variable = stress_zz
  []
  [stress_xy]
    type = RankTwoAux
    rank_two_tensor = stress
    index_i = 0
    index_j = 1
    variable = stress_xy
  []
  [stress_yz]
    type = RankTwoAux
    rank_two_tensor = stress
    index_i = 1
    index_j = 2
    variable = stress_yz
  []
  [stress_zx]
    type = RankTwoAux
    rank_two_tensor = stress
    index_i = 2
    index_j = 0
    variable = stress_zx
  []
[]

[BCs]
  [no_x_exterior]
    type = DirichletBC
    variable = disp_x
    boundary = '7 8'
    value = 0.0
  []
  [no_y_exterior]
    type = DirichletBC
    variable = disp_y
    boundary = '9 10'
    value = 0.0
  []
  [no_z_exterior]
    type = DirichletBC
    variable = disp_z
    boundary = '11 12'
    value = 0.0
  []
  [prescribed_left]
    type = FunctionDirichletBC
    variable = disp_x
    boundary = 13
    function = displ_positive
  []
  [prescribed_right]
    type = FunctionDirichletBC
    variable = disp_x
    boundary = 14
    function = displ_negative
  []
  [no_y]
    type = DirichletBC
    variable = disp_y
    boundary = '15 16'
    value = 0.0
  []
  [no_z]
    type = DirichletBC
    variable = disp_z
    boundary = '17 18'
    value = 0.0
  []
  [no_x_interior]
    type = DirichletBC
    variable = disp_x
    boundary = '1 2'
    value = 0.0
  []
  [no_y_interior]
    type = DirichletBC
    variable = disp_y
    boundary = '3 4'
    value = 0.0
  []
  [no_z_interior]
    type = DirichletBC
    variable = disp_z
    boundary = '5 6'
    value = 0.0
  []
  [temperatureInterior]
    type = FunctionDirichletBC
    boundary = 100
    function = temp1
    variable = temp
  []
  [MaterialInput]
    type = FunctionDirichletBC
    boundary = '100 13 14 15 16'
    function = material_input_function
    variable = material_input
  []
  [CavityPressure]
    [1]
      boundary = 100
      initial_pressure = 100
      material_input = materialInput
      R = 8.314472
      temperature = aveTempInterior
      volume = 'internalVolumeInterior internalVolumeExterior'
      startup_time = 0.5
      output = ppress
      save_in = 'pressure_residual_x pressure_residual_y pressure_residual_z'
    []
  []
[]

[Materials]
  [elast_tensor1]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 1e1
    poissons_ratio = 0
    block = 1
  []
  [strain1]
    type = ComputeFiniteStrain
    block = 1
  []
  [stress1]
    type = ComputeFiniteStrainElasticStress
    block = 1
  []
  [elast_tensor2]
    type = ComputeIsotropicElasticityTensor
    youngs_modulus = 1e6
    poissons_ratio = 0
    block = 2
  []
  [strain2]
    type = ComputeFiniteStrain
    block = 2
  []
  [stress2]
    type = ComputeFiniteStrainElasticStress
    block = 2
  []
[]

[Executioner]
  type = Transient

  petsc_options_iname = '-pc_type -sub_pc_type'
  petsc_options_value = 'asm       lu'

  nl_rel_tol = 1e-12
  l_tol = 1e-12

  l_max_its = 20

  dt = 0.5
  end_time = 1.0
  use_pre_SMO_residual = true
[]

[Postprocessors]
  [internalVolume]
    type = InternalVolume
    boundary = 100
    execute_on = 'initial linear'
  []
  [aveTempInterior]
    type = SideAverageValue
    boundary = 100
    variable = temp
    execute_on = 'initial linear'
  []
  [internalVolumeInterior]
    type = InternalVolume
    boundary = '1 2 3 4 5 6'
    execute_on = 'initial linear'
  []
  [internalVolumeExterior]
    type = InternalVolume
    boundary = '13 14 15 16 17 18'
    execute_on = 'initial linear'
  []
  [materialInput]
    type = SideAverageValue
    boundary = '7 8 9 10 11 12'
    variable = material_input
    execute_on = linear
  []
[]

[Outputs]
  exodus = true
[]

(modules/solid_mechanics/include/materials/Compute2DFiniteStrain.h)

// This file is part of the MOOSE framework
// https://www.mooseframework.org
//
// All rights reserved, see COPYRIGHT for full restrictions
// https://github.com/idaholab/moose/blob/master/COPYRIGHT
//
// Licensed under LGPL 2.1, please see LICENSE for details
// https://www.gnu.org/licenses/lgpl-2.1.html

#pragma once

#include "ComputeFiniteStrain.h"

/**
 * Compute2DFiniteStrain defines a strain increment and a rotation increment
 * for finite strains in 2D geometries, handling the out of plane strains.
 * Compute2DFiniteStrain contains a virtual method to define the out-of-plane strain
 * as a general nonzero value in the inherited classes ComputePlaneFiniteStrain
 * and ComputeAxisymmetricRZFiniteStrain.
 */
class Compute2DFiniteStrain : public ComputeFiniteStrain
{
public:
  static InputParameters validParams();

  Compute2DFiniteStrain(const InputParameters & parameters);

  void initialSetup() override;

  virtual void computeProperties() override;

protected:
  virtual void displacementIntegrityCheck() override;

  /**
   * Computes the current out-of-plane component of the displacement gradient; as a virtual
   *function, this function is overwritten for the specific geometries defined by inheriting classes
   */
  virtual Real computeOutOfPlaneGradDisp() = 0;

  /**
   * Computes the old out-of-plane component of the displacement gradient; as a virtual function,
   * this function is overwritten for the specific geometries defined by inheriting classes
   */
  virtual Real computeOutOfPlaneGradDispOld() = 0;

  const unsigned int _out_of_plane_direction;
};

(modules/solid_mechanics/include/materials/Compute1DFiniteStrain.h)

// This file is part of the MOOSE framework
// https://www.mooseframework.org
//
// All rights reserved, see COPYRIGHT for full restrictions
// https://github.com/idaholab/moose/blob/master/COPYRIGHT
//
// Licensed under LGPL 2.1, please see LICENSE for details
// https://www.gnu.org/licenses/lgpl-2.1.html

#pragma once

#include "ComputeFiniteStrain.h"

/**
 * Compute1DFiniteStrain defines a strain increment for finite strains in 1D problems,
 * handling strains in other two directions. It contains virtual methods to define
 * the displacement gradients as a general nonzero value.
 */
class Compute1DFiniteStrain : public ComputeFiniteStrain
{
public:
  static InputParameters validParams();

  Compute1DFiniteStrain(const InputParameters & parameters);

  void computeProperties() override;

protected:
  /// Computes the current dUy/dY; as a virtual function, this function is
  /// overwritten for the specific geometries defined by inheriting classes
  virtual Real computeGradDispYY() = 0;

  /// Computes the old dUy/dY; as a virtual function, this function is
  /// overwritten for the specific geometries defined by inheriting classes
  virtual Real computeGradDispYYOld() = 0;

  /// Computes the current dUz/dz; as a virtual function, this function is
  /// overwritten for the specific geometries defined by inheriting classes
  virtual Real computeGradDispZZ() = 0;

  /// Computes the old dUz/dz; as a virtual function, this function is
  /// overwritten for the specific geometries defined by inheriting classes
  virtual Real computeGradDispZZOld() = 0;
};

(modules/solid_mechanics/include/materials/ComputeRSphericalFiniteStrain.h)

// This file is part of the MOOSE framework
// https://www.mooseframework.org
//
// All rights reserved, see COPYRIGHT for full restrictions
// https://github.com/idaholab/moose/blob/master/COPYRIGHT
//
// Licensed under LGPL 2.1, please see LICENSE for details
// https://www.gnu.org/licenses/lgpl-2.1.html

#pragma once

#include "ComputeFiniteStrain.h"

/**
 * ComputeRSphericalFiniteStrain defines a strain increment and a rotation increment
 * for finite strains in 1D spherical symmetry geometries.  The strains in the
 * polar and azimuthal directions are functions of the radial displacement.

 */
class ComputeRSphericalFiniteStrain : public ComputeFiniteStrain
{
public:
  static InputParameters validParams();

  ComputeRSphericalFiniteStrain(const InputParameters & parameters);

  virtual void initialSetup() override;

  /// Computes the current and old deformation gradients with the assumptions for
  /// 1D spherical symmetry geometries: \f$ \epsilon_{\theta} = \epsilon_{\phi} = \frac{u_r}{r} \f$
  virtual void computeProperties() override;

protected:
  virtual void computeQpIncrements(RankTwoTensor & e, RankTwoTensor & r) override;

  /// the old value of the first component of the displacements vector
  const VariableValue & _disp_old_0;
};

Description
Example Input File Syntax
Input Parameters
Input Files
Child Objects
References