from __future__ import print_function, division import sys, petsc4py petsc4py.init(sys.argv) import mpi4py.MPI as mpi from petsc4py import PETSc from elasticity import * def rhs(coords, rhs): rhs[..., 1] = -9.81 OptDB = PETSc.Options() Lx = OptDB.getInt('Lx', 10) Ly = OptDB.getInt('Ly', 1) Lz = OptDB.getInt('Lz', 1) n = OptDB.getInt('n', 16) nx = OptDB.getInt('nx', Lx*n) ny = OptDB.getInt('ny', Ly*n) nz = OptDB.getInt('ny', Lz*n) hx = Lx/(nx - 1) hy = Ly/(ny - 1) hz = Lz/(nz - 1) da = PETSc.DMDA().create([nx, ny, nz], dof=3, stencil_width=1) da.setUniformCoordinates(xmax=Lx, ymax=Ly, zmax=Lz) # constant young modulus E = 30000 # constant Poisson coefficient nu = 0.4 lamb = (nu*E)/((1+nu)*(1-2*nu)) mu = .5*E/(1+nu) x = da.createGlobalVec() b = buildRHS(da, [hx, hy, hz], rhs) A = buildElasticityMatrix(da, [hx, hy, hz], lamb, mu) A.assemble() bcApplyWest(da, A, b) ksp = PETSc.KSP().create() ksp.setOperators(A) ksp.setFromOptions() ksp.solve(b, x) viewer = PETSc.Viewer().createVTK('solution_3d.vts', 'w', comm = PETSc.COMM_WORLD) x.view(viewer)