//============================================================================ // Copyright (c) Kitware, Inc. // All rights reserved. // See LICENSE.txt for details. // // This software is distributed WITHOUT ANY WARRANTY; without even // the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR // PURPOSE. See the above copyright notice for more information. //============================================================================ #include #include #include #include namespace { void TestPointGradientUniform2D() { std::cout << "Testing PointGradient Worklet on 2D structured data" << std::endl; vtkm::cont::testing::MakeTestDataSet testDataSet; vtkm::cont::DataSet dataSet = testDataSet.Make2DUniformDataSet0(); vtkm::cont::ArrayHandle fieldArray; dataSet.GetField("pointvar").GetData().CopyTo(fieldArray); vtkm::worklet::PointGradient gradient; auto result = gradient.Run(dataSet.GetCellSet(), dataSet.GetCoordinateSystem(), fieldArray); vtkm::Vec3f_32 expected[2] = { { 10, 30, 0 }, { 10, 30, 0 } }; for (int i = 0; i < 2; ++i) { VTKM_TEST_ASSERT(test_equal(result.GetPortalConstControl().Get(i), expected[i]), "Wrong result for PointGradient worklet on 2D uniform data", "\nExpected ", expected[i], "\nGot ", result.GetPortalConstControl().Get(i), "\n"); } } void TestPointGradientUniform3D() { std::cout << "Testing PointGradient Worklet on 3D structured data" << std::endl; vtkm::cont::testing::MakeTestDataSet testDataSet; vtkm::cont::DataSet dataSet = testDataSet.Make3DUniformDataSet0(); vtkm::cont::ArrayHandle fieldArray; dataSet.GetField("pointvar").GetData().CopyTo(fieldArray); vtkm::worklet::PointGradient gradient; auto result = gradient.Run(dataSet.GetCellSet(), dataSet.GetCoordinateSystem(), fieldArray); vtkm::Vec3f_32 expected[4] = { { 10.0f, 30.f, 60.1f }, { 10.0f, 30.1f, 60.1f }, { 10.0f, 30.1f, 60.2f }, { 10.1f, 30.f, 60.2f }, }; for (int i = 0; i < 4; ++i) { VTKM_TEST_ASSERT(test_equal(result.GetPortalConstControl().Get(i), expected[i]), "Wrong result for PointGradient worklet on 3D uniform data", "\nExpected ", expected[i], "\nGot ", result.GetPortalConstControl().Get(i), "\n"); } } void TestPointGradientUniform3DWithVectorField() { std::cout << "Testing PointGradient Worklet with a vector field on 3D structured data" << std::endl; vtkm::cont::testing::MakeTestDataSet testDataSet; vtkm::cont::DataSet dataSet = testDataSet.Make3DUniformDataSet0(); //Verify that we can compute the gradient of a 3 component vector const int nVerts = 18; vtkm::Float64 vars[nVerts] = { 10.1, 20.1, 30.1, 40.1, 50.2, 60.2, 70.2, 80.2, 90.3, 100.3, 110.3, 120.3, 130.4, 140.4, 150.4, 160.4, 170.5, 180.5 }; std::vector vec(18); for (std::size_t i = 0; i < vec.size(); ++i) { vec[i] = vtkm::make_Vec(vars[i], vars[i], vars[i]); } vtkm::cont::ArrayHandle input = vtkm::cont::make_ArrayHandle(vec); vtkm::worklet::PointGradient gradient; auto result = gradient.Run(dataSet.GetCellSet(), dataSet.GetCoordinateSystem(), input); vtkm::Vec expected[4] = { { { 10.0, 10.0, 10.0 }, { 30.0, 30.0, 30.0 }, { 60.1, 60.1, 60.1 } }, { { 10.0, 10.0, 10.0 }, { 30.1, 30.1, 30.1 }, { 60.1, 60.1, 60.1 } }, { { 10.0, 10.0, 10.0 }, { 30.1, 30.1, 30.1 }, { 60.2, 60.2, 60.2 } }, { { 10.1, 10.1, 10.1 }, { 30.0, 30.0, 30.0 }, { 60.2, 60.2, 60.2 } } }; for (int i = 0; i < 4; ++i) { vtkm::Vec e = expected[i]; vtkm::Vec r = result.GetPortalConstControl().Get(i); VTKM_TEST_ASSERT(test_equal(e[0], r[0]), "Wrong result for vec field PointGradient worklet on 3D uniform data"); VTKM_TEST_ASSERT(test_equal(e[1], r[1]), "Wrong result for vec field PointGradient worklet on 3D uniform data"); VTKM_TEST_ASSERT(test_equal(e[2], r[2]), "Wrong result for vec field PointGradient worklet on 3D uniform data"); } } void TestPointGradientUniform3DWithVectorField2() { std::cout << "Testing PointGradient Worklet with a vector field on 3D structured data" << std::endl << "Disabling Gradient computation and enabling Divergence, Vorticity, and QCriterion" << std::endl; vtkm::cont::testing::MakeTestDataSet testDataSet; vtkm::cont::DataSet dataSet = testDataSet.Make3DUniformDataSet0(); //Verify that we can compute the gradient of a 3 component vector const int nVerts = 18; vtkm::Float64 vars[nVerts] = { 10.1, 20.1, 30.1, 40.1, 50.2, 60.2, 70.2, 80.2, 90.3, 100.3, 110.3, 120.3, 130.4, 140.4, 150.4, 160.4, 170.5, 180.5 }; std::vector vec(18); for (std::size_t i = 0; i < vec.size(); ++i) { vec[i] = vtkm::make_Vec(vars[i], vars[i], vars[i]); } vtkm::cont::ArrayHandle input = vtkm::cont::make_ArrayHandle(vec); vtkm::worklet::GradientOutputFields extraOutput; extraOutput.SetComputeGradient(false); extraOutput.SetComputeDivergence(true); extraOutput.SetComputeVorticity(true); extraOutput.SetComputeQCriterion(true); vtkm::worklet::PointGradient gradient; auto result = gradient.Run(dataSet.GetCellSet(), dataSet.GetCoordinateSystem(), input, extraOutput); //Verify that the result is 0 size VTKM_TEST_ASSERT((result.GetNumberOfValues() == 0), "Gradient field shouldn't be generated"); //Verify that the extra arrays are the correct size VTKM_TEST_ASSERT((extraOutput.Gradient.GetNumberOfValues() == 0), "Gradient field shouldn't be generated"); VTKM_TEST_ASSERT((extraOutput.Divergence.GetNumberOfValues() == nVerts), "Divergence field should be generated"); VTKM_TEST_ASSERT((extraOutput.Vorticity.GetNumberOfValues() == nVerts), "Vorticity field should be generated"); VTKM_TEST_ASSERT((extraOutput.QCriterion.GetNumberOfValues() == nVerts), "QCriterion field should be generated"); vtkm::Vec expected_gradients[4] = { { { 10.0, 10.0, 10.0 }, { 30.0, 30.0, 30.0 }, { 60.1, 60.1, 60.1 } }, { { 10.0, 10.0, 10.0 }, { 30.1, 30.1, 30.1 }, { 60.1, 60.1, 60.1 } }, { { 10.0, 10.0, 10.0 }, { 30.1, 30.1, 30.1 }, { 60.2, 60.2, 60.2 } }, { { 10.1, 10.1, 10.1 }, { 30.0, 30.0, 30.0 }, { 60.2, 60.2, 60.2 } } }; for (int i = 0; i < 4; ++i) { vtkm::Vec eg = expected_gradients[i]; vtkm::Float64 d = extraOutput.Divergence.GetPortalConstControl().Get(i); VTKM_TEST_ASSERT(test_equal((eg[0][0] + eg[1][1] + eg[2][2]), d), "Wrong result for Divergence on 3D uniform data"); vtkm::Vec3f_64 ev(eg[1][2] - eg[2][1], eg[2][0] - eg[0][2], eg[0][1] - eg[1][0]); vtkm::Vec3f_64 v = extraOutput.Vorticity.GetPortalConstControl().Get(i); VTKM_TEST_ASSERT(test_equal(ev, v), "Wrong result for Vorticity on 3D uniform data"); const vtkm::Vec3f_64 es(eg[1][2] + eg[2][1], eg[2][0] + eg[0][2], eg[0][1] + eg[1][0]); const vtkm::Vec3f_64 ed(eg[0][0], eg[1][1], eg[2][2]); //compute QCriterion vtkm::Float64 qcriterion = ((vtkm::Dot(ev, ev) / 2.0f) - (vtkm::Dot(ed, ed) + (vtkm::Dot(es, es) / 2.0f))) / 2.0f; vtkm::Float64 q = extraOutput.QCriterion.GetPortalConstControl().Get(i); VTKM_TEST_ASSERT( test_equal(qcriterion, q), "Wrong result for QCriterion field of PointGradient worklet on 3D uniform data"); } } void TestPointGradientExplicit3D() { std::cout << "Testing PointGradient Worklet on Explicit 3D data" << std::endl; vtkm::cont::testing::MakeTestDataSet testDataSet; vtkm::cont::DataSet dataSet = testDataSet.Make3DExplicitDataSet5(); vtkm::cont::ArrayHandle fieldArray; dataSet.GetField("pointvar").GetData().CopyTo(fieldArray); vtkm::worklet::PointGradient gradient; auto result = gradient.Run(dataSet.GetCellSet(), dataSet.GetCoordinateSystem(), fieldArray); //vtkm::cont::printSummary_ArrayHandle(result, std::cout, true); const int nVerts = 11; vtkm::Vec3f_32 expected[nVerts] = { { 10.0f, 40.2f, 30.1f }, { 27.4f, 40.1f, 10.1f }, { 17.425f, 40.0f, 10.1f }, { -10.0f, 40.1f, 30.1f }, { 9.9f, -0.0500011f, 30.0f }, { 16.2125f, -4.55f, 10.0f }, { 6.2f, -4.6f, 10.0f }, { -10.1f, -0.0999985f, 30.0f }, { 22.5125f, -4.575f, 10.025f }, { 1.0f, -40.3f, 30.0f }, { 0.6f, -49.2f, 10.0f } }; for (int i = 0; i < nVerts; ++i) { VTKM_TEST_ASSERT(test_equal(result.GetPortalConstControl().Get(i), expected[i]), "Wrong result for PointGradient worklet on 3D explicit data", "\nExpected ", expected[i], "\nGot ", result.GetPortalConstControl().Get(i), "\n"); } } void TestPointGradientExplicit2D() { std::cout << "Testing PointGradient Worklet on Explicit 2D data" << std::endl; vtkm::cont::testing::MakeTestDataSet testDataSet; vtkm::cont::DataSet dataSet = testDataSet.Make2DExplicitDataSet0(); vtkm::cont::ArrayHandle fieldArray; dataSet.GetField("pointvar").GetData().CopyTo(fieldArray); vtkm::worklet::PointGradient gradient; auto result = gradient.Run(dataSet.GetCellSet(), dataSet.GetCoordinateSystem(), fieldArray); //vtkm::cont::printSummary_ArrayHandle(result, std::cout, true); const int nVerts = 16; vtkm::Vec3f_32 expected[nVerts] = { { -22.0f, -7.0f, 0.0f }, { -25.5f, -7.0f, 0.0f }, { -30.5f, 7.0f, 0.0f }, { -32.0f, 16.0f, 0.0f }, { -23.0f, -42.0f, 0.0f }, { -23.25f, -17.0f, 0.0f }, { -20.6667f, 1.33333f, 0.0f }, { -23.0f, 14.0f, 0.0f }, { -8.0f, -42.0f, 0.0f }, { 2.91546f, -24.8357f, 0.0f }, { -0.140736f, -7.71853f, 0.0f }, { -5.0f, 12.0f, 0.0f }, { 31.8803f, 1.0f, 0.0f }, { -44.8148f, 20.5f, 0.0f }, { 38.5653f, 5.86938f, 0.0f }, { 26.3967f, 86.7934f, 0.0f } }; for (int i = 0; i < nVerts; ++i) { VTKM_TEST_ASSERT(test_equal(result.GetPortalConstControl().Get(i), expected[i]), "Wrong result for PointGradient worklet on 2D explicit data", "\nExpected ", expected[i], "\nGot ", result.GetPortalConstControl().Get(i), "\n"); } } void TestPointGradient() { TestPointGradientUniform2D(); TestPointGradientUniform3D(); TestPointGradientUniform3DWithVectorField(); TestPointGradientUniform3DWithVectorField2(); TestPointGradientExplicit2D(); TestPointGradientExplicit3D(); } } int UnitTestPointGradient(int argc, char* argv[]) { return vtkm::cont::testing::Testing::Run(TestPointGradient, argc, argv); }