static char help[] = "Heat Equation in 2d and 3d with finite elements.\n\ We solve the heat equation in a rectangular\n\ domain, using a parallel unstructured mesh (DMPLEX) to discretize it.\n\ Contributed by: Julian Andrej \n\n\n"; #include #include #include /* Heat equation: du/dt - \Delta u + f = 0 */ typedef enum {SOL_QUADRATIC_LINEAR, SOL_QUADRATIC_TRIG, SOL_TRIG_LINEAR, SOL_TRIG_TRIG, NUM_SOLUTION_TYPES} SolutionType; const char *solutionTypes[NUM_SOLUTION_TYPES+1] = {"quadratic_linear", "quadratic_trig", "trig_linear", "trig_trig", "unknown"}; typedef struct { SolutionType solType; /* Type of exact solution */ /* Solver setup */ PetscBool expTS; /* Flag for explicit timestepping */ PetscBool lumped; /* Lump the mass matrix */ } AppCtx; /* Exact 2D solution: u = 2t + x^2 + y^2 u_t = 2 \Delta u = 2 + 2 = 4 f = 2 F(u) = 2 - (2 + 2) + 2 = 0 Exact 3D solution: u = 3t + x^2 + y^2 + z^2 F(u) = 3 - (2 + 2 + 2) + 3 = 0 */ static PetscErrorCode mms_quad_lin(PetscInt dim, PetscReal time, const PetscReal x[], PetscInt Nc, PetscScalar *u, void *ctx) { PetscInt d; *u = dim*time; for (d = 0; d < dim; ++d) *u += x[d]*x[d]; return 0; } static PetscErrorCode mms_quad_lin_t(PetscInt dim, PetscReal time, const PetscReal x[], PetscInt Nc, PetscScalar *u, void *ctx) { *u = dim; return 0; } static void f0_quad_lin_exp(PetscInt dim, PetscInt Nf, PetscInt NfAux, const PetscInt uOff[], const PetscInt uOff_x[], const PetscScalar u[], const PetscScalar u_t[], const PetscScalar u_x[], const PetscInt aOff[], const PetscInt aOff_x[], const PetscScalar a[], const PetscScalar a_t[], const PetscScalar a_x[], PetscReal t, const PetscReal x[], PetscInt numConstants, const PetscScalar constants[], PetscScalar f0[]) { f0[0] = -(PetscScalar) dim; } static void f0_quad_lin(PetscInt dim, PetscInt Nf, PetscInt NfAux, const PetscInt uOff[], const PetscInt uOff_x[], const PetscScalar u[], const PetscScalar u_t[], const PetscScalar u_x[], const PetscInt aOff[], const PetscInt aOff_x[], const PetscScalar a[], const PetscScalar a_t[], const PetscScalar a_x[], PetscReal t, const PetscReal x[], PetscInt numConstants, const PetscScalar constants[], PetscScalar f0[]) { PetscScalar exp[1] = {0.}; f0_quad_lin_exp(dim, Nf, NfAux, uOff, uOff_x, u, u_t, u_x, aOff, aOff_x, a, a_t, a_x, t, x, numConstants, constants, exp); f0[0] = u_t[0] - exp[0]; } /* Exact 2D solution: u = 2*cos(t) + x^2 + y^2 F(u) = -2*sint(t) - (2 + 2) + 2*sin(t) + 4 = 0 Exact 3D solution: u = 3*cos(t) + x^2 + y^2 + z^2 F(u) = -3*sin(t) - (2 + 2 + 2) + 3*sin(t) + 6 = 0 */ static PetscErrorCode mms_quad_trig(PetscInt dim, PetscReal time, const PetscReal x[], PetscInt Nc, PetscScalar *u, void *ctx) { PetscInt d; *u = dim*PetscCosReal(time); for (d = 0; d < dim; ++d) *u += x[d]*x[d]; return 0; } static PetscErrorCode mms_quad_trig_t(PetscInt dim, PetscReal time, const PetscReal x[], PetscInt Nc, PetscScalar *u, void *ctx) { *u = -dim*PetscSinReal(time); return 0; } static void f0_quad_trig_exp(PetscInt dim, PetscInt Nf, PetscInt NfAux, const PetscInt uOff[], const PetscInt uOff_x[], const PetscScalar u[], const PetscScalar u_t[], const PetscScalar u_x[], const PetscInt aOff[], const PetscInt aOff_x[], const PetscScalar a[], const PetscScalar a_t[], const PetscScalar a_x[], PetscReal t, const PetscReal x[], PetscInt numConstants, const PetscScalar constants[], PetscScalar f0[]) { f0[0] = -dim*(PetscSinReal(t) + 2.0); } static void f0_quad_trig(PetscInt dim, PetscInt Nf, PetscInt NfAux, const PetscInt uOff[], const PetscInt uOff_x[], const PetscScalar u[], const PetscScalar u_t[], const PetscScalar u_x[], const PetscInt aOff[], const PetscInt aOff_x[], const PetscScalar a[], const PetscScalar a_t[], const PetscScalar a_x[], PetscReal t, const PetscReal x[], PetscInt numConstants, const PetscScalar constants[], PetscScalar f0[]) { PetscScalar exp[1] = {0.}; f0_quad_trig_exp(dim, Nf, NfAux, uOff, uOff_x, u, u_t, u_x, aOff, aOff_x, a, a_t, a_x, t, x, numConstants, constants, exp); f0[0] = u_t[0] - exp[0]; } /* Exact 2D solution: u = 2\pi^2 t + cos(\pi x) + cos(\pi y) F(u) = 2\pi^2 - \pi^2 (cos(\pi x) + cos(\pi y)) + \pi^2 (cos(\pi x) + cos(\pi y)) - 2\pi^2 = 0 Exact 3D solution: u = 3\pi^2 t + cos(\pi x) + cos(\pi y) + cos(\pi z) F(u) = 3\pi^2 - \pi^2 (cos(\pi x) + cos(\pi y) + cos(\pi z)) + \pi^2 (cos(\pi x) + cos(\pi y) + cos(\pi z)) - 3\pi^2 = 0 */ static PetscErrorCode mms_trig_lin(PetscInt dim, PetscReal time, const PetscReal x[], PetscInt Nc, PetscScalar *u, void *ctx) { PetscInt d; *u = dim*PetscSqr(PETSC_PI)*time; for (d = 0; d < dim; ++d) *u += PetscCosReal(PETSC_PI*x[d]); return 0; } static PetscErrorCode mms_trig_lin_t(PetscInt dim, PetscReal time, const PetscReal x[], PetscInt Nc, PetscScalar *u, void *ctx) { *u = dim*PetscSqr(PETSC_PI); return 0; } static void f0_trig_lin(PetscInt dim, PetscInt Nf, PetscInt NfAux, const PetscInt uOff[], const PetscInt uOff_x[], const PetscScalar u[], const PetscScalar u_t[], const PetscScalar u_x[], const PetscInt aOff[], const PetscInt aOff_x[], const PetscScalar a[], const PetscScalar a_t[], const PetscScalar a_x[], PetscReal t, const PetscReal x[], PetscInt numConstants, const PetscScalar constants[], PetscScalar f0[]) { PetscInt d; f0[0] = u_t[0]; for (d = 0; d < dim; ++d) f0[0] += PetscSqr(PETSC_PI)*(PetscCosReal(PETSC_PI*x[d]) - 1.0); } /* Exact 2D solution: u = pi^2 cos(t) + cos(\pi x) + cos(\pi y) u_t = -pi^2 sin(t) \Delta u = -\pi^2 (cos(\pi x) + cos(\pi y)) f = pi^2 sin(t) - \pi^2 (cos(\pi x) + cos(\pi y)) F(u) = -\pi^2 sin(t) + \pi^2 (cos(\pi x) + cos(\pi y)) - \pi^2 (cos(\pi x) + cos(\pi y)) + \pi^2 sin(t) = 0 Exact 3D solution: u = pi^2 cos(t) + cos(\pi x) + cos(\pi y) + cos(\pi z) u_t = -pi^2 sin(t) \Delta u = -\pi^2 (cos(\pi x) + cos(\pi y) + cos(\pi z)) f = pi^2 sin(t) - \pi^2 (cos(\pi x) + cos(\pi y) + cos(\pi z)) F(u) = -\pi^2 sin(t) + \pi^2 (cos(\pi x) + cos(\pi y) + cos(\pi z)) - \pi^2 (cos(\pi x) + cos(\pi y) + cos(\pi z)) + \pi^2 sin(t) = 0 */ static PetscErrorCode mms_trig_trig(PetscInt dim, PetscReal time, const PetscReal x[], PetscInt Nc, PetscScalar *u, void *ctx) { PetscInt d; *u = PetscSqr(PETSC_PI)*PetscCosReal(time); for (d = 0; d < dim; ++d) *u += PetscCosReal(PETSC_PI*x[d]); return 0; } static PetscErrorCode mms_trig_trig_t(PetscInt dim, PetscReal time, const PetscReal x[], PetscInt Nc, PetscScalar *u, void *ctx) { *u = -PetscSqr(PETSC_PI)*PetscSinReal(time); return 0; } static void f0_trig_trig_exp(PetscInt dim, PetscInt Nf, PetscInt NfAux, const PetscInt uOff[], const PetscInt uOff_x[], const PetscScalar u[], const PetscScalar u_t[], const PetscScalar u_x[], const PetscInt aOff[], const PetscInt aOff_x[], const PetscScalar a[], const PetscScalar a_t[], const PetscScalar a_x[], PetscReal t, const PetscReal x[], PetscInt numConstants, const PetscScalar constants[], PetscScalar f0[]) { PetscInt d; f0[0] -= PetscSqr(PETSC_PI)*PetscSinReal(t); for (d = 0; d < dim; ++d) f0[0] += PetscSqr(PETSC_PI)*PetscCosReal(PETSC_PI*x[d]); } static void f0_trig_trig(PetscInt dim, PetscInt Nf, PetscInt NfAux, const PetscInt uOff[], const PetscInt uOff_x[], const PetscScalar u[], const PetscScalar u_t[], const PetscScalar u_x[], const PetscInt aOff[], const PetscInt aOff_x[], const PetscScalar a[], const PetscScalar a_t[], const PetscScalar a_x[], PetscReal t, const PetscReal x[], PetscInt numConstants, const PetscScalar constants[], PetscScalar f0[]) { PetscScalar exp[1] = {0.}; f0_trig_trig_exp(dim, Nf, NfAux, uOff, uOff_x, u, u_t, u_x, aOff, aOff_x, a, a_t, a_x, t, x, numConstants, constants, exp); f0[0] = u_t[0] - exp[0]; } static void f1_temp_exp(PetscInt dim, PetscInt Nf, PetscInt NfAux, const PetscInt uOff[], const PetscInt uOff_x[], const PetscScalar u[], const PetscScalar u_t[], const PetscScalar u_x[], const PetscInt aOff[], const PetscInt aOff_x[], const PetscScalar a[], const PetscScalar a_t[], const PetscScalar a_x[], PetscReal t, const PetscReal x[], PetscInt numConstants, const PetscScalar constants[], PetscScalar f1[]) { PetscInt d; for (d = 0; d < dim; ++d) f1[d] = -u_x[d]; } static void f1_temp(PetscInt dim, PetscInt Nf, PetscInt NfAux, const PetscInt uOff[], const PetscInt uOff_x[], const PetscScalar u[], const PetscScalar u_t[], const PetscScalar u_x[], const PetscInt aOff[], const PetscInt aOff_x[], const PetscScalar a[], const PetscScalar a_t[], const PetscScalar a_x[], PetscReal t, const PetscReal x[], PetscInt numConstants, const PetscScalar constants[], PetscScalar f1[]) { PetscInt d; for (d = 0; d < dim; ++d) f1[d] = u_x[d]; } static void g3_temp(PetscInt dim, PetscInt Nf, PetscInt NfAux, const PetscInt uOff[], const PetscInt uOff_x[], const PetscScalar u[], const PetscScalar u_t[], const PetscScalar u_x[], const PetscInt aOff[], const PetscInt aOff_x[], const PetscScalar a[], const PetscScalar a_t[], const PetscScalar a_x[], PetscReal t, PetscReal u_tShift, const PetscReal x[], PetscInt numConstants, const PetscScalar constants[], PetscScalar g3[]) { PetscInt d; for (d = 0; d < dim; ++d) g3[d*dim+d] = 1.0; } static void g0_temp(PetscInt dim, PetscInt Nf, PetscInt NfAux, const PetscInt uOff[], const PetscInt uOff_x[], const PetscScalar u[], const PetscScalar u_t[], const PetscScalar u_x[], const PetscInt aOff[], const PetscInt aOff_x[], const PetscScalar a[], const PetscScalar a_t[], const PetscScalar a_x[], PetscReal t, PetscReal u_tShift, const PetscReal x[], PetscInt numConstants, const PetscScalar constants[], PetscScalar g0[]) { g0[0] = u_tShift*1.0; } static PetscErrorCode ProcessOptions(MPI_Comm comm, AppCtx *options) { PetscInt sol; PetscErrorCode ierr; PetscFunctionBeginUser; options->solType = SOL_QUADRATIC_LINEAR; options->expTS = PETSC_FALSE; options->lumped = PETSC_TRUE; ierr = PetscOptionsBegin(comm, "", "Heat Equation Options", "DMPLEX");CHKERRQ(ierr); ierr = PetscOptionsEList("-sol_type", "Type of exact solution", "ex45.c", solutionTypes, NUM_SOLUTION_TYPES, solutionTypes[options->solType], &sol, NULL);CHKERRQ(ierr); options->solType = (SolutionType) sol; ierr = PetscOptionsBool("-explicit", "Use explicit timestepping", "ex45.c", options->expTS, &options->expTS, NULL);CHKERRQ(ierr); ierr = PetscOptionsBool("-lumped", "Lump the mass matrix", "ex45.c", options->lumped, &options->lumped, NULL);CHKERRQ(ierr); ierr = PetscOptionsEnd();CHKERRQ(ierr); PetscFunctionReturn(0); } static PetscErrorCode CreateMesh(MPI_Comm comm, DM *dm, AppCtx *ctx) { PetscErrorCode ierr; PetscFunctionBeginUser; ierr = DMCreate(comm, dm);CHKERRQ(ierr); ierr = DMSetType(*dm, DMPLEX);CHKERRQ(ierr); ierr = DMSetFromOptions(*dm);CHKERRQ(ierr); ierr = DMViewFromOptions(*dm, NULL, "-dm_view");CHKERRQ(ierr); PetscFunctionReturn(0); } static PetscErrorCode SetupProblem(DM dm, AppCtx *ctx) { PetscDS ds; DMLabel label; const PetscInt id = 1; PetscErrorCode ierr; PetscFunctionBeginUser; ierr = DMGetLabel(dm, "marker", &label);CHKERRQ(ierr); ierr = DMGetDS(dm, &ds);CHKERRQ(ierr); ierr = PetscDSSetJacobian(ds, 0, 0, g0_temp, NULL, NULL, g3_temp);CHKERRQ(ierr); switch (ctx->solType) { case SOL_QUADRATIC_LINEAR: ierr = PetscDSSetResidual(ds, 0, f0_quad_lin, f1_temp);CHKERRQ(ierr); ierr = PetscDSSetRHSResidual(ds, 0, f0_quad_lin_exp, f1_temp_exp);CHKERRQ(ierr); ierr = PetscDSSetExactSolution(ds, 0, mms_quad_lin, ctx);CHKERRQ(ierr); ierr = PetscDSSetExactSolutionTimeDerivative(ds, 0, mms_quad_lin_t, ctx);CHKERRQ(ierr); ierr = DMAddBoundary(dm, DM_BC_ESSENTIAL, "wall", label, 1, &id, 0, 0, NULL, (void (*)(void)) mms_quad_lin, (void (*)(void)) mms_quad_lin_t, ctx, NULL);CHKERRQ(ierr); break; case SOL_QUADRATIC_TRIG: ierr = PetscDSSetResidual(ds, 0, f0_quad_trig, f1_temp);CHKERRQ(ierr); ierr = PetscDSSetRHSResidual(ds, 0, f0_quad_trig_exp, f1_temp_exp);CHKERRQ(ierr); ierr = PetscDSSetExactSolution(ds, 0, mms_quad_trig, ctx);CHKERRQ(ierr); ierr = PetscDSSetExactSolutionTimeDerivative(ds, 0, mms_quad_trig_t, ctx);CHKERRQ(ierr); ierr = DMAddBoundary(dm, DM_BC_ESSENTIAL, "wall", label, 1, &id, 0, 0, NULL, (void (*)(void)) mms_quad_trig, (void (*)(void)) mms_quad_trig_t, ctx, NULL);CHKERRQ(ierr); break; case SOL_TRIG_LINEAR: ierr = PetscDSSetResidual(ds, 0, f0_trig_lin, f1_temp);CHKERRQ(ierr); ierr = PetscDSSetExactSolution(ds, 0, mms_trig_lin, ctx);CHKERRQ(ierr); ierr = PetscDSSetExactSolutionTimeDerivative(ds, 0, mms_trig_lin_t, ctx);CHKERRQ(ierr); ierr = DMAddBoundary(dm, DM_BC_ESSENTIAL, "wall", label, 1, &id, 0, 0, NULL, (void (*)(void)) mms_trig_lin, (void (*)(void)) mms_trig_lin_t, ctx, NULL);CHKERRQ(ierr); break; case SOL_TRIG_TRIG: ierr = PetscDSSetResidual(ds, 0, f0_trig_trig, f1_temp);CHKERRQ(ierr); ierr = PetscDSSetRHSResidual(ds, 0, f0_trig_trig_exp, f1_temp_exp);CHKERRQ(ierr); ierr = PetscDSSetExactSolution(ds, 0, mms_trig_trig, ctx);CHKERRQ(ierr); ierr = PetscDSSetExactSolutionTimeDerivative(ds, 0, mms_trig_trig_t, ctx);CHKERRQ(ierr); break; default: SETERRQ(PetscObjectComm((PetscObject) dm), PETSC_ERR_ARG_WRONG, "Invalid solution type: %s (%D)", solutionTypes[PetscMin(ctx->solType, NUM_SOLUTION_TYPES)], ctx->solType); } PetscFunctionReturn(0); } static PetscErrorCode SetupDiscretization(DM dm, AppCtx* ctx) { DM cdm = dm; PetscFE fe; DMPolytopeType ct; PetscBool simplex; PetscInt dim, cStart; PetscErrorCode ierr; PetscFunctionBeginUser; ierr = DMGetDimension(dm, &dim);CHKERRQ(ierr); ierr = DMPlexGetHeightStratum(dm, 0, &cStart, NULL);CHKERRQ(ierr); ierr = DMPlexGetCellType(dm, cStart, &ct);CHKERRQ(ierr); simplex = DMPolytopeTypeGetNumVertices(ct) == DMPolytopeTypeGetDim(ct)+1 ? PETSC_TRUE : PETSC_FALSE; /* Create finite element */ ierr = PetscFECreateDefault(PETSC_COMM_SELF, dim, 1, simplex, "temp_", -1, &fe);CHKERRQ(ierr); ierr = PetscObjectSetName((PetscObject) fe, "temperature");CHKERRQ(ierr); /* Set discretization and boundary conditions for each mesh */ ierr = DMSetField(dm, 0, NULL, (PetscObject) fe);CHKERRQ(ierr); ierr = DMCreateDS(dm);CHKERRQ(ierr); if (ctx->expTS) { PetscDS ds; ierr = DMGetDS(dm, &ds);CHKERRQ(ierr); ierr = PetscDSSetImplicit(ds, 0, PETSC_FALSE);CHKERRQ(ierr); } ierr = SetupProblem(dm, ctx);CHKERRQ(ierr); while (cdm) { ierr = DMCopyDisc(dm, cdm);CHKERRQ(ierr); ierr = DMGetCoarseDM(cdm, &cdm);CHKERRQ(ierr); } ierr = PetscFEDestroy(&fe);CHKERRQ(ierr); PetscFunctionReturn(0); } static PetscErrorCode SetInitialConditions(TS ts, Vec u) { DM dm; PetscReal t; PetscErrorCode ierr; PetscFunctionBegin; ierr = TSGetDM(ts, &dm);CHKERRQ(ierr); ierr = TSGetTime(ts, &t);CHKERRQ(ierr); ierr = DMComputeExactSolution(dm, t, u, NULL);CHKERRQ(ierr); PetscFunctionReturn(0); } int main(int argc, char **argv) { DM dm; TS ts; Vec u; AppCtx ctx; PetscErrorCode ierr; ierr = PetscInitialize(&argc, &argv, NULL, help);if (ierr) return ierr; ierr = ProcessOptions(PETSC_COMM_WORLD, &ctx);CHKERRQ(ierr); ierr = CreateMesh(PETSC_COMM_WORLD, &dm, &ctx);CHKERRQ(ierr); ierr = DMSetApplicationContext(dm, &ctx);CHKERRQ(ierr); ierr = SetupDiscretization(dm, &ctx);CHKERRQ(ierr); ierr = TSCreate(PETSC_COMM_WORLD, &ts);CHKERRQ(ierr); ierr = TSSetDM(ts, dm);CHKERRQ(ierr); ierr = DMTSSetBoundaryLocal(dm, DMPlexTSComputeBoundary, &ctx);CHKERRQ(ierr); if (ctx.expTS) { ierr = DMTSSetRHSFunctionLocal(dm, DMPlexTSComputeRHSFunctionFEM, &ctx);CHKERRQ(ierr); if (ctx.lumped) {ierr = DMTSCreateRHSMassMatrixLumped(dm);CHKERRQ(ierr);} else {ierr = DMTSCreateRHSMassMatrix(dm);CHKERRQ(ierr);} } else { ierr = DMTSSetIFunctionLocal(dm, DMPlexTSComputeIFunctionFEM, &ctx);CHKERRQ(ierr); ierr = DMTSSetIJacobianLocal(dm, DMPlexTSComputeIJacobianFEM, &ctx);CHKERRQ(ierr); } ierr = TSSetExactFinalTime(ts, TS_EXACTFINALTIME_MATCHSTEP);CHKERRQ(ierr); ierr = TSSetFromOptions(ts);CHKERRQ(ierr); ierr = TSSetComputeInitialCondition(ts, SetInitialConditions);CHKERRQ(ierr); ierr = DMCreateGlobalVector(dm, &u);CHKERRQ(ierr); ierr = DMTSCheckFromOptions(ts, u);CHKERRQ(ierr); ierr = SetInitialConditions(ts, u);CHKERRQ(ierr); ierr = PetscObjectSetName((PetscObject) u, "temperature");CHKERRQ(ierr); ierr = TSSolve(ts, u);CHKERRQ(ierr); ierr = DMTSCheckFromOptions(ts, u);CHKERRQ(ierr); if (ctx.expTS) {ierr = DMTSDestroyRHSMassMatrix(dm);CHKERRQ(ierr);} ierr = VecDestroy(&u);CHKERRQ(ierr); ierr = TSDestroy(&ts);CHKERRQ(ierr); ierr = DMDestroy(&dm);CHKERRQ(ierr); ierr = PetscFinalize(); return ierr; } /*TEST test: suffix: 2d_p1 requires: triangle args: -sol_type quadratic_linear -dm_refine 1 -temp_petscspace_degree 1 -dmts_check .0001 \ -ts_type beuler -ts_max_steps 5 -ts_dt 0.1 -snes_error_if_not_converged -pc_type lu test: suffix: 2d_p1_exp requires: triangle args: -sol_type quadratic_linear -dm_refine 1 -temp_petscspace_degree 1 -explicit \ -ts_type euler -ts_max_steps 4 -ts_dt 1e-3 -ts_monitor_error test: # -dm_refine 2 -convest_num_refine 3 get L_2 convergence rate: [1.9] suffix: 2d_p1_sconv requires: triangle args: -sol_type quadratic_linear -temp_petscspace_degree 1 -ts_convergence_estimate -ts_convergence_temporal 0 -convest_num_refine 1 \ -ts_type beuler -ts_max_steps 1 -ts_dt 0.00001 -snes_error_if_not_converged -pc_type lu test: # -dm_refine 2 -convest_num_refine 3 get L_2 convergence rate: [2.1] suffix: 2d_p1_sconv_2 requires: triangle args: -sol_type trig_trig -temp_petscspace_degree 1 -ts_convergence_estimate -ts_convergence_temporal 0 -convest_num_refine 1 \ -ts_type beuler -ts_max_steps 1 -ts_dt 1e-6 -snes_error_if_not_converged -pc_type lu test: # -dm_refine 4 -convest_num_refine 3 get L_2 convergence rate: [1.2] suffix: 2d_p1_tconv requires: triangle args: -sol_type quadratic_trig -temp_petscspace_degree 1 -ts_convergence_estimate -convest_num_refine 1 \ -ts_type beuler -ts_max_steps 4 -ts_dt 0.1 -snes_error_if_not_converged -pc_type lu test: # -dm_refine 6 -convest_num_refine 3 get L_2 convergence rate: [1.0] suffix: 2d_p1_tconv_2 requires: triangle args: -sol_type trig_trig -temp_petscspace_degree 1 -ts_convergence_estimate -convest_num_refine 1 \ -ts_type beuler -ts_max_steps 4 -ts_dt 0.1 -snes_error_if_not_converged -pc_type lu test: # The L_2 convergence rate cannot be seen since stability of the explicit integrator requires that is be more accurate than the grid suffix: 2d_p1_exp_tconv_2 requires: triangle args: -sol_type trig_trig -temp_petscspace_degree 1 -explicit -ts_convergence_estimate -convest_num_refine 1 \ -ts_type euler -ts_max_steps 4 -ts_dt 1e-4 -lumped 0 -mass_pc_type lu test: # The L_2 convergence rate cannot be seen since stability of the explicit integrator requires that is be more accurate than the grid suffix: 2d_p1_exp_tconv_2_lump requires: triangle args: -sol_type trig_trig -temp_petscspace_degree 1 -explicit -ts_convergence_estimate -convest_num_refine 1 \ -ts_type euler -ts_max_steps 4 -ts_dt 1e-4 test: suffix: 2d_p2 requires: triangle args: -sol_type quadratic_linear -dm_refine 0 -temp_petscspace_degree 2 -dmts_check .0001 \ -ts_type beuler -ts_max_steps 5 -ts_dt 0.1 -snes_error_if_not_converged -pc_type lu test: # -dm_refine 2 -convest_num_refine 3 get L_2 convergence rate: [2.9] suffix: 2d_p2_sconv requires: triangle args: -sol_type trig_linear -temp_petscspace_degree 2 -ts_convergence_estimate -ts_convergence_temporal 0 -convest_num_refine 1 \ -ts_type beuler -ts_max_steps 1 -ts_dt 0.00000001 -snes_error_if_not_converged -pc_type lu test: # -dm_refine 2 -convest_num_refine 3 get L_2 convergence rate: [3.1] suffix: 2d_p2_sconv_2 requires: triangle args: -sol_type trig_trig -temp_petscspace_degree 2 -ts_convergence_estimate -ts_convergence_temporal 0 -convest_num_refine 1 \ -ts_type beuler -ts_max_steps 1 -ts_dt 0.00000001 -snes_error_if_not_converged -pc_type lu test: # -dm_refine 3 -convest_num_refine 3 get L_2 convergence rate: [1.0] suffix: 2d_p2_tconv requires: triangle args: -sol_type quadratic_trig -temp_petscspace_degree 2 -ts_convergence_estimate -convest_num_refine 1 \ -ts_type beuler -ts_max_steps 4 -ts_dt 0.1 -snes_error_if_not_converged -pc_type lu test: # -dm_refine 3 -convest_num_refine 3 get L_2 convergence rate: [1.0] suffix: 2d_p2_tconv_2 requires: triangle args: -sol_type trig_trig -temp_petscspace_degree 2 -ts_convergence_estimate -convest_num_refine 1 \ -ts_type beuler -ts_max_steps 4 -ts_dt 0.1 -snes_error_if_not_converged -pc_type lu test: suffix: 2d_q1 args: -sol_type quadratic_linear -dm_plex_simplex 0 -dm_refine 1 -temp_petscspace_degree 1 -dmts_check .0001 \ -ts_type beuler -ts_max_steps 5 -ts_dt 0.1 -snes_error_if_not_converged -pc_type lu test: # -dm_refine 2 -convest_num_refine 3 get L_2 convergence rate: [1.9] suffix: 2d_q1_sconv args: -sol_type quadratic_linear -dm_plex_simplex 0 -temp_petscspace_degree 1 -ts_convergence_estimate -ts_convergence_temporal 0 -convest_num_refine 1 \ -ts_type beuler -ts_max_steps 1 -ts_dt 0.00001 -snes_error_if_not_converged -pc_type lu test: # -dm_refine 4 -convest_num_refine 3 get L_2 convergence rate: [1.2] suffix: 2d_q1_tconv args: -sol_type quadratic_trig -dm_plex_simplex 0 -temp_petscspace_degree 1 -ts_convergence_estimate -convest_num_refine 1 \ -ts_type beuler -ts_max_steps 4 -ts_dt 0.1 -snes_error_if_not_converged -pc_type lu test: suffix: 2d_q2 args: -sol_type quadratic_linear -dm_plex_simplex 0 -dm_refine 0 -temp_petscspace_degree 2 -dmts_check .0001 \ -ts_type beuler -ts_max_steps 5 -ts_dt 0.1 -snes_error_if_not_converged -pc_type lu test: # -dm_refine 2 -convest_num_refine 3 get L_2 convergence rate: [2.9] suffix: 2d_q2_sconv args: -sol_type trig_linear -dm_plex_simplex 0 -temp_petscspace_degree 2 -ts_convergence_estimate -ts_convergence_temporal 0 -convest_num_refine 1 \ -ts_type beuler -ts_max_steps 1 -ts_dt 0.00000001 -snes_error_if_not_converged -pc_type lu test: # -dm_refine 3 -convest_num_refine 3 get L_2 convergence rate: [1.0] suffix: 2d_q2_tconv args: -sol_type quadratic_trig -dm_plex_simplex 0 -temp_petscspace_degree 2 -ts_convergence_estimate -convest_num_refine 1 \ -ts_type beuler -ts_max_steps 4 -ts_dt 0.1 -snes_error_if_not_converged -pc_type lu test: suffix: 3d_p1 requires: ctetgen args: -sol_type quadratic_linear -dm_refine 1 -temp_petscspace_degree 1 -dmts_check .0001 \ -ts_type beuler -ts_max_steps 5 -ts_dt 0.1 -snes_error_if_not_converged -pc_type lu test: # -dm_refine 2 -convest_num_refine 3 get L_2 convergence rate: [1.9] suffix: 3d_p1_sconv requires: ctetgen args: -sol_type quadratic_linear -temp_petscspace_degree 1 -ts_convergence_estimate -ts_convergence_temporal 0 -convest_num_refine 1 \ -ts_type beuler -ts_max_steps 1 -ts_dt 0.00001 -snes_error_if_not_converged -pc_type lu test: # -dm_refine 4 -convest_num_refine 3 get L_2 convergence rate: [1.2] suffix: 3d_p1_tconv requires: ctetgen args: -sol_type quadratic_trig -temp_petscspace_degree 1 -ts_convergence_estimate -convest_num_refine 1 \ -ts_type beuler -ts_max_steps 4 -ts_dt 0.1 -snes_error_if_not_converged -pc_type lu test: suffix: 3d_p2 requires: ctetgen args: -sol_type quadratic_linear -dm_refine 0 -temp_petscspace_degree 2 -dmts_check .0001 \ -ts_type beuler -ts_max_steps 5 -ts_dt 0.1 -snes_error_if_not_converged -pc_type lu test: # -dm_refine 2 -convest_num_refine 3 get L_2 convergence rate: [2.9] suffix: 3d_p2_sconv requires: ctetgen args: -sol_type trig_linear -temp_petscspace_degree 2 -ts_convergence_estimate -ts_convergence_temporal 0 -convest_num_refine 1 \ -ts_type beuler -ts_max_steps 1 -ts_dt 0.00000001 -snes_error_if_not_converged -pc_type lu test: # -dm_refine 3 -convest_num_refine 3 get L_2 convergence rate: [1.0] suffix: 3d_p2_tconv requires: ctetgen args: -sol_type quadratic_trig -temp_petscspace_degree 2 -ts_convergence_estimate -convest_num_refine 1 \ -ts_type beuler -ts_max_steps 4 -ts_dt 0.1 -snes_error_if_not_converged -pc_type lu test: suffix: 3d_q1 args: -sol_type quadratic_linear -dm_plex_simplex 0 -dm_refine 1 -temp_petscspace_degree 1 -dmts_check .0001 \ -ts_type beuler -ts_max_steps 5 -ts_dt 0.1 -snes_error_if_not_converged -pc_type lu test: # -dm_refine 2 -convest_num_refine 3 get L_2 convergence rate: [1.9] suffix: 3d_q1_sconv args: -sol_type quadratic_linear -dm_plex_simplex 0 -temp_petscspace_degree 1 -ts_convergence_estimate -ts_convergence_temporal 0 -convest_num_refine 1 \ -ts_type beuler -ts_max_steps 1 -ts_dt 0.00001 -snes_error_if_not_converged -pc_type lu test: # -dm_refine 4 -convest_num_refine 3 get L_2 convergence rate: [1.2] suffix: 3d_q1_tconv args: -sol_type quadratic_trig -dm_plex_simplex 0 -temp_petscspace_degree 1 -ts_convergence_estimate -convest_num_refine 1 \ -ts_type beuler -ts_max_steps 4 -ts_dt 0.1 -snes_error_if_not_converged -pc_type lu test: suffix: 3d_q2 args: -sol_type quadratic_linear -dm_plex_simplex 0 -dm_refine 0 -temp_petscspace_degree 2 -dmts_check .0001 \ -ts_type beuler -ts_max_steps 5 -ts_dt 0.1 -snes_error_if_not_converged -pc_type lu test: # -dm_refine 2 -convest_num_refine 3 get L_2 convergence rate: [2.9] suffix: 3d_q2_sconv args: -sol_type trig_linear -dm_plex_simplex 0 -temp_petscspace_degree 2 -ts_convergence_estimate -ts_convergence_temporal 0 -convest_num_refine 1 \ -ts_type beuler -ts_max_steps 1 -ts_dt 0.00000001 -snes_error_if_not_converged -pc_type lu test: # -dm_refine 3 -convest_num_refine 3 get L_2 convergence rate: [1.0] suffix: 3d_q2_tconv args: -sol_type quadratic_trig -dm_plex_simplex 0 -temp_petscspace_degree 2 -ts_convergence_estimate -convest_num_refine 1 \ -ts_type beuler -ts_max_steps 4 -ts_dt 0.1 -snes_error_if_not_converged -pc_type lu test: # For a nice picture, -bd_dm_refine 2 -dm_refine 1 -dm_view hdf5:${PETSC_DIR}/sol.h5 -ts_monitor_solution hdf5:${PETSC_DIR}/sol.h5::append suffix: egads_sphere requires: egads ctetgen args: -sol_type quadratic_linear \ -dm_plex_boundary_filename ${wPETSC_DIR}/share/petsc/datafiles/meshes/unit_sphere.egadslite -dm_plex_boundary_label marker -bd_dm_plex_scale 40 \ -temp_petscspace_degree 2 -dmts_check .0001 \ -ts_type beuler -ts_max_steps 5 -ts_dt 0.1 -snes_error_if_not_converged -pc_type lu TEST*/