예제 #1
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def test_scalar_p1_scaled_mesh():
    # Make coarse mesh smaller than fine mesh
    meshc = UnitCubeMesh(MPI.comm_world, 2, 2, 2)
    meshc.geometry.points *= 0.9

    meshf = UnitCubeMesh(MPI.comm_world, 3, 4, 5)

    Vc = FunctionSpace(meshc, "CG", 1)
    Vf = FunctionSpace(meshf, "CG", 1)

    u = Expression("x[0] + 2*x[1] + 3*x[2]", degree=1)
    uc = interpolate(u, Vc)
    uf = interpolate(u, Vf)

    mat = PETScDMCollection.create_transfer_matrix(Vc, Vf).mat()
    Vuc = Function(Vf)
    mat.mult(uc.vector().vec(), Vuc.vector().vec())

    diff = Vuc.vector()
    diff.vec().axpy(-1, uf.vector().vec())

    assert diff.norm(Norm.l2) < 1.0e-12

    # Now make coarse mesh larger than fine mesh
    meshc.geometry.points *= 1.5

    uc = interpolate(u, Vc)

    mat = PETScDMCollection.create_transfer_matrix(Vc, Vf).mat()
    mat.mult(uc.vector().vec(), Vuc.vector().vec())

    diff = Vuc.vector()
    diff.vec().axpy(-1, uf.vector().vec())

    assert diff.norm(Norm.l2) < 1.0e-12
예제 #2
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def test_taylor_hood_cube():
    pytest.xfail("Problem with Mixed Function Spaces")
    meshc = UnitCubeMesh(MPI.comm_world, 2, 2, 2)
    meshf = UnitCubeMesh(MPI.comm_world, 3, 4, 5)

    Ve = VectorElement("CG", meshc.ufl_cell(), 2)
    Qe = FiniteElement("CG", meshc.ufl_cell(), 1)
    Ze = MixedElement([Ve, Qe])

    Zc = FunctionSpace(meshc, Ze)
    Zf = FunctionSpace(meshf, Ze)

    def z(values, x):
        values[:, 0] = x[:, 0] * x[:, 1]
        values[:, 1] = x[:, 1] * x[:, 2]
        values[:, 2] = x[:, 2] * x[:, 0]
        values[:, 3] = x[:, 0] + 3.0 * x[:, 1] + x[:, 2]

    zc = interpolate(z, Zc)
    zf = interpolate(z, Zf)

    mat = PETScDMCollection.create_transfer_matrix(Zc, Zf)
    Zuc = Function(Zf)
    mat.mult(zc.vector, Zuc.vector)
    Zuc.vector.update_ghost_values()

    diff = Function(Zf)
    diff.assign(Zuc - zf)
    assert diff.vector.norm("l2") < 1.0e-12
예제 #3
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def test_vector_p1_3d():
    meshc = UnitCubeMesh(MPI.comm_world, 2, 3, 4)
    meshf = UnitCubeMesh(MPI.comm_world, 3, 4, 5)

    Vc = VectorFunctionSpace(meshc, ("CG", 1))
    Vf = VectorFunctionSpace(meshf, ("CG", 1))

    @function.expression.numba_eval
    def expr_eval(values, x, cell_idx):
        values[:, 0] = x[:, 0] + 2.0 * x[:, 1]
        values[:, 1] = 4.0 * x[:, 0]
        values[:, 2] = 3.0 * x[:, 2] + x[:, 0]

    u = Expression(expr_eval, shape=(3, ))
    uc = interpolate(u, Vc)
    uf = interpolate(u, Vf)

    mat = PETScDMCollection.create_transfer_matrix(Vc._cpp_object,
                                                   Vf._cpp_object)
    Vuc = Function(Vf)
    mat.mult(uc.vector(), Vuc.vector())

    diff = Vuc.vector()
    diff.axpy(-1, uf.vector())
    assert diff.norm() < 1.0e-12
예제 #4
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def test_vector_p1_3d():
    meshc = UnitCubeMesh(MPI.comm_world, 2, 3, 4)
    meshf = UnitCubeMesh(MPI.comm_world, 3, 4, 5)

    Vc = VectorFunctionSpace(meshc, ("CG", 1))
    Vf = VectorFunctionSpace(meshf, ("CG", 1))

    def u(x):
        values0 = x[:, 0] + 2.0 * x[:, 1]
        values1 = 4.0 * x[:, 0]
        values2 = 3.0 * x[:, 2] + x[:, 0]
        return np.stack([values0, values1, values2], axis=1)

    uc, uf = Function(Vc), Function(Vf)
    uc.interpolate(u)
    uf.interpolate(u)

    mat = PETScDMCollection.create_transfer_matrix(Vc._cpp_object,
                                                   Vf._cpp_object)
    Vuc = Function(Vf)
    mat.mult(uc.vector, Vuc.vector)

    diff = Vuc.vector
    diff.axpy(-1, uf.vector)
    assert diff.norm() < 1.0e-12
예제 #5
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def test_taylor_hood_cube():
    pytest.xfail("Problem with Mixed Function Spaces")
    meshc = UnitCubeMesh(MPI.comm_world, 2, 2, 2)
    meshf = UnitCubeMesh(MPI.comm_world, 3, 4, 5)

    Ve = VectorElement("CG", meshc.ufl_cell(), 2)
    Qe = FiniteElement("CG", meshc.ufl_cell(), 1)
    Ze = MixedElement([Ve, Qe])

    Zc = FunctionSpace(meshc, Ze)
    Zf = FunctionSpace(meshf, Ze)

    z = Expression(
        ("x[0]*x[1]", "x[1]*x[2]", "x[2]*x[0]", "x[0] + 3*x[1] + x[2]"),
        degree=2)
    zc = interpolate(z, Zc)
    zf = interpolate(z, Zf)

    mat = PETScDMCollection.create_transfer_matrix(Zc, Zf)
    Zuc = Function(Zf)
    mat.mult(zc.vector(), Zuc.vector())
    Zuc.vector().update_ghost_values()

    diff = Function(Zf)
    diff.assign(Zuc - zf)
    assert diff.vector().norm("l2") < 1.0e-12
예제 #6
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def test_scalar_p1_scaled_mesh():
    # Make coarse mesh smaller than fine mesh
    meshc = UnitCubeMesh(MPI.comm_world, 2, 2, 2)
    meshc.geometry.points *= 0.9

    meshf = UnitCubeMesh(MPI.comm_world, 3, 4, 5)

    Vc = FunctionSpace(meshc, ("CG", 1))
    Vf = FunctionSpace(meshf, ("CG", 1))

    @function.expression.numba_eval
    def expr_eval(values, x, cell_idx):
        values[:, 0] = x[:, 0] + 2.0 * x[:, 1] + 3.0 * x[:, 2]

    u = Expression(expr_eval)
    uc = interpolate(u, Vc)
    uf = interpolate(u, Vf)

    mat = PETScDMCollection.create_transfer_matrix(Vc._cpp_object,
                                                   Vf._cpp_object)
    Vuc = Function(Vf)
    mat.mult(uc.vector(), Vuc.vector())

    diff = Vuc.vector()
    diff.axpy(-1, uf.vector())

    assert diff.norm() < 1.0e-12

    # Now make coarse mesh larger than fine mesh
    meshc.geometry.points *= 1.5

    uc = interpolate(u, Vc)

    mat = PETScDMCollection.create_transfer_matrix(Vc._cpp_object,
                                                   Vf._cpp_object)
    mat.mult(uc.vector(), Vuc.vector())

    diff = Vuc.vector()
    diff.axpy(-1, uf.vector())

    assert diff.norm() < 1.0e-12
예제 #7
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def test_scalar_p1_scaled_mesh():
    # Make coarse mesh smaller than fine mesh
    meshc = UnitCubeMesh(MPI.comm_world, 2, 2, 2)
    meshc.geometry.points *= 0.9

    meshf = UnitCubeMesh(MPI.comm_world, 3, 4, 5)

    Vc = FunctionSpace(meshc, ("CG", 1))
    Vf = FunctionSpace(meshf, ("CG", 1))

    def u(x):
        return x[:, 0] + 2.0 * x[:, 1] + 3.0 * x[:, 2]

    uc, uf = Function(Vc), Function(Vf)
    uc.interpolate(u)
    uf.interpolate(u)

    mat = PETScDMCollection.create_transfer_matrix(Vc._cpp_object,
                                                   Vf._cpp_object)
    Vuc = Function(Vf)
    mat.mult(uc.vector, Vuc.vector)

    diff = Vuc.vector
    diff.axpy(-1, uf.vector)

    assert diff.norm() < 1.0e-12

    # Now make coarse mesh larger than fine mesh
    meshc.geometry.points *= 1.5
    uc.interpolate(u)

    mat = PETScDMCollection.create_transfer_matrix(Vc._cpp_object,
                                                   Vf._cpp_object)
    mat.mult(uc.vector, Vuc.vector)

    diff = Vuc.vector
    diff.axpy(-1, uf.vector)

    assert diff.norm() < 1.0e-12
예제 #8
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def test_vector_p1_3d():
    meshc = UnitCubeMesh(MPI.comm_world, 2, 3, 4)
    meshf = UnitCubeMesh(MPI.comm_world, 3, 4, 5)

    Vc = VectorFunctionSpace(meshc, "CG", 1)
    Vf = VectorFunctionSpace(meshf, "CG", 1)

    u = Expression(("x[0] + 2*x[1]", "4*x[0]", "3*x[2] + x[0]"), degree=1)
    uc = interpolate(u, Vc)
    uf = interpolate(u, Vf)

    mat = PETScDMCollection.create_transfer_matrix(Vc, Vf).mat()
    Vuc = Function(Vf)
    mat.mult(uc.vector().vec(), Vuc.vector().vec())

    diff = Vuc.vector()
    diff.vec().axpy(-1, uf.vector().vec())
    assert diff.norm(Norm.l2) < 1.0e-12
예제 #9
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def test_vector_p2_2d():
    meshc = UnitSquareMesh(MPI.comm_world, 5, 4)
    meshf = UnitSquareMesh(MPI.comm_world, 5, 8)

    Vc = VectorFunctionSpace(meshc, ("CG", 2))
    Vf = VectorFunctionSpace(meshf, ("CG", 2))

    u = Expression(("x[0] + 2*x[1]*x[0]", "4*x[0]*x[1]"), degree=2)
    uc = interpolate(u, Vc)
    uf = interpolate(u, Vf)

    mat = PETScDMCollection.create_transfer_matrix(Vc._cpp_object,
                                                   Vf._cpp_object).mat()
    Vuc = Function(Vf)
    mat.mult(uc.vector().vec(), Vuc.vector().vec())

    diff = Vuc.vector()
    diff.vec().axpy(-1, uf.vector().vec())
    assert diff.norm(Norm.l2) < 1.0e-12
예제 #10
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def test_scalar_p2():
    meshc = UnitCubeMesh(MPI.comm_world, 2, 2, 2)
    meshf = UnitCubeMesh(MPI.comm_world, 3, 4, 5)

    Vc = FunctionSpace(meshc, ("CG", 2))
    Vf = FunctionSpace(meshf, ("CG", 2))

    u = Expression("x[0]*x[2] + 2*x[1]*x[0] + 3*x[2]", degree=2)
    uc = interpolate(u, Vc)
    uf = interpolate(u, Vf)

    mat = PETScDMCollection.create_transfer_matrix(Vc._cpp_object,
                                                   Vf._cpp_object).mat()
    Vuc = Function(Vf)
    mat.mult(uc.vector().vec(), Vuc.vector().vec())

    diff = Vuc.vector()
    diff.vec().axpy(-1, uf.vector().vec())

    assert diff.norm(Norm.l2) < 1.0e-12
예제 #11
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def test_scalar_p2():
    meshc = UnitCubeMesh(MPI.comm_world, 2, 2, 2)
    meshf = UnitCubeMesh(MPI.comm_world, 3, 4, 5)

    Vc = FunctionSpace(meshc, ("CG", 2))
    Vf = FunctionSpace(meshf, ("CG", 2))

    def u(values, x):
        values[:, 0] = x[:, 0] + 2.0 * x[:, 1] + 3.0 * x[:, 2]

    uc = interpolate(u, Vc)
    uf = interpolate(u, Vf)

    mat = PETScDMCollection.create_transfer_matrix(Vc._cpp_object,
                                                   Vf._cpp_object)
    Vuc = Function(Vf)
    mat.mult(uc.vector, Vuc.vector)

    diff = Vuc.vector
    diff.axpy(-1, uf.vector)

    assert diff.norm() < 1.0e-12
예제 #12
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def test_vector_p2_2d():
    meshc = UnitSquareMesh(MPI.comm_world, 5, 4)
    meshf = UnitSquareMesh(MPI.comm_world, 5, 8)

    Vc = VectorFunctionSpace(meshc, ("CG", 2))
    Vf = VectorFunctionSpace(meshf, ("CG", 2))

    def u(values, x):
        values[:, 0] = x[:, 0] + 2.0 * x[:, 1]
        values[:, 1] = 4.0 * x[:, 0] * x[:, 1]

    uc = interpolate(u, Vc)
    uf = interpolate(u, Vf)

    mat = PETScDMCollection.create_transfer_matrix(Vc._cpp_object,
                                                   Vf._cpp_object)
    Vuc = Function(Vf)
    mat.mult(uc.vector, Vuc.vector)

    diff = Vuc.vector
    diff.axpy(-1, uf.vector)
    assert diff.norm() < 1.0e-12
예제 #13
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def test_vector_p2_2d():
    meshc = UnitSquareMesh(MPI.comm_world, 5, 4)
    meshf = UnitSquareMesh(MPI.comm_world, 5, 8)

    Vc = VectorFunctionSpace(meshc, ("CG", 2))
    Vf = VectorFunctionSpace(meshf, ("CG", 2))

    def u(x):
        return np.stack([x[:, 0] + 2.0 * x[:, 1], 4.0 * x[:, 0] * x[:, 1]],
                        axis=1)

    uc, uf = Function(Vc), Function(Vf)
    uc.interpolate(u)
    uf.interpolate(u)

    mat = PETScDMCollection.create_transfer_matrix(Vc._cpp_object,
                                                   Vf._cpp_object)
    Vuc = Function(Vf)
    mat.mult(uc.vector, Vuc.vector)

    diff = Vuc.vector
    diff.axpy(-1, uf.vector)
    assert diff.norm() < 1.0e-12
예제 #14
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def test_scalar_p2():
    meshc = UnitCubeMesh(MPI.comm_world, 2, 2, 2)
    meshf = UnitCubeMesh(MPI.comm_world, 3, 4, 5)

    Vc = FunctionSpace(meshc, ("CG", 2))
    Vf = FunctionSpace(meshf, ("CG", 2))

    @function.expression.numba_eval
    def expr_eval(values, x, cell_idx):
        values[:, 0] = x[:, 0] + 2.0 * x[:, 1] + 3.0 * x[:, 2]

    u = Expression(expr_eval)
    uc = interpolate(u, Vc)
    uf = interpolate(u, Vf)

    mat = PETScDMCollection.create_transfer_matrix(Vc._cpp_object,
                                                   Vf._cpp_object).mat()
    Vuc = Function(Vf)
    mat.mult(uc.vector().vec(), Vuc.vector().vec())

    diff = Vuc.vector()
    diff.vec().axpy(-1, uf.vector().vec())

    assert diff.norm(Norm.l2) < 1.0e-12
예제 #15
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def test_vector_p2_2d():
    meshc = UnitSquareMesh(MPI.comm_world, 5, 4)
    meshf = UnitSquareMesh(MPI.comm_world, 5, 8)

    Vc = VectorFunctionSpace(meshc, ("CG", 2))
    Vf = VectorFunctionSpace(meshf, ("CG", 2))

    @function.expression.numba_eval
    def expr_eval(values, x, cell_idx):
        values[:, 0] = x[:, 0] + 2.0 * x[:, 1]
        values[:, 1] = 4.0 * x[:, 0] * x[:, 1]

    u = Expression(expr_eval, shape=(2, ))
    uc = interpolate(u, Vc)
    uf = interpolate(u, Vf)

    mat = PETScDMCollection.create_transfer_matrix(Vc._cpp_object,
                                                   Vf._cpp_object).mat()
    Vuc = Function(Vf)
    mat.mult(uc.vector().vec(), Vuc.vector().vec())

    diff = Vuc.vector()
    diff.vec().axpy(-1, uf.vector().vec())
    assert diff.norm(Norm.l2) < 1.0e-12