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https://gitlab.kitware.com/vtk/vtk-m
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d1a4aecc59
We have made several improvements to adding data into an `ArrayHandle`. ## Moving data from an `std::vector` For numerous reasons, it is convenient to define data in a `std::vector` and then wrap that into an `ArrayHandle`. It is often the case that an `std::vector` is filled and then becomes unused once it is converted to an `ArrayHandle`. In this case, what we really want is to pass the data off to the `ArrayHandle` so that the `ArrayHandle` is now managing the data and not the `std::vector`. C++11 has a mechanism to do this: move semantics. You can now pass variables to functions as an "rvalue" (right-hand value). When something is passed as an rvalue, it can pull state out of that variable and move it somewhere else. `std::vector` implements this movement so that an rvalue can be moved to another `std::vector` without actually copying the data. `make_ArrayHandle` now also takes advantage of this feature to move rvalue `std::vector`s. There is a special form of `make_ArrayHandle` named `make_ArrayHandleMove` that takes an rvalue. There is also a special overload of `make_ArrayHandle` itself that handles an rvalue `vector`. (However, using the explicit move version is better if you want to make sure the data is actually moved.) ## Make `ArrayHandle` from initalizer list A common use case for using `std::vector` (particularly in our unit tests) is to quickly add an initalizer list into an `ArrayHandle`. Now you can by simply passing an initializer list to `make_ArrayHandle`. ## Deprecated `make_ArrayHandle` with default shallow copy For historical reasons, passing an `std::vector` or a pointer to `make_ArrayHandle` does a shallow copy (i.e. `CopyFlag` defaults to `Off`). Although more efficient, this mode is inherintly unsafe, and making it the default is asking for trouble. To combat this, calling `make_ArrayHandle` without a copy flag is deprecated. In this way, if you wish to do the faster but more unsafe creation of an `ArrayHandle` you should explicitly express that. This requried quite a few changes through the VTK-m source (particularly in the tests). ## Similar changes to `Field` `vtkm::cont::Field` has a `make_Field` helper function that is similar to `make_ArrayHandle`. It also features the ability to create fields from `std::vector`s and C arrays. It also likewise had the same unsafe behavior by default of not copying from the source of the arrays. That behavior has similarly been depreciated. You now have to specify a copy flag. The ability to construct a `Field` from an initializer list of values has also been added.
119 lines
4.4 KiB
C++
119 lines
4.4 KiB
C++
//============================================================================
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// Copyright (c) Kitware, Inc.
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// All rights reserved.
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// See LICENSE.txt for details.
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//
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// This software is distributed WITHOUT ANY WARRANTY; without even
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// the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR
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// PURPOSE. See the above copyright notice for more information.
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//============================================================================
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#include <vtkm/worklet/CrossProduct.h>
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#include <vtkm/worklet/DispatcherMapField.h>
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#include <random>
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#include <vtkm/cont/testing/Testing.h>
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namespace
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{
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std::mt19937 randGenerator;
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template <typename T>
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void createVectors(std::vector<vtkm::Vec<T, 3>>& vecs1, std::vector<vtkm::Vec<T, 3>>& vecs2)
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{
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// First, test the standard directions.
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// X x Y
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vecs1.push_back(vtkm::make_Vec(1, 0, 0));
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vecs2.push_back(vtkm::make_Vec(0, 1, 0));
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// Y x Z
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vecs1.push_back(vtkm::make_Vec(0, 1, 0));
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vecs2.push_back(vtkm::make_Vec(0, 0, 1));
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// Z x X
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vecs1.push_back(vtkm::make_Vec(0, 0, 1));
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vecs2.push_back(vtkm::make_Vec(1, 0, 0));
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// Y x X
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vecs1.push_back(vtkm::make_Vec(0, 1, 0));
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vecs2.push_back(vtkm::make_Vec(1, 0, 0));
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// Z x Y
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vecs1.push_back(vtkm::make_Vec(0, 0, 1));
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vecs2.push_back(vtkm::make_Vec(0, 1, 0));
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// X x Z
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vecs1.push_back(vtkm::make_Vec(1, 0, 0));
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vecs2.push_back(vtkm::make_Vec(0, 0, 1));
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//Test some other vector combinations
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std::uniform_real_distribution<vtkm::Float64> randomDist(-10.0, 10.0);
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for (int i = 0; i < 100; i++)
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{
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vecs1.push_back(vtkm::make_Vec(
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randomDist(randGenerator), randomDist(randGenerator), randomDist(randGenerator)));
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vecs2.push_back(vtkm::make_Vec(
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randomDist(randGenerator), randomDist(randGenerator), randomDist(randGenerator)));
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}
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}
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template <typename T>
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void TestCrossProduct()
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{
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std::vector<vtkm::Vec<T, 3>> inputVecs1, inputVecs2;
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createVectors(inputVecs1, inputVecs2);
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vtkm::cont::ArrayHandle<vtkm::Vec<T, 3>> inputArray1, inputArray2;
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vtkm::cont::ArrayHandle<vtkm::Vec<T, 3>> outputArray;
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inputArray1 = vtkm::cont::make_ArrayHandle(inputVecs1, vtkm::CopyFlag::Off);
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inputArray2 = vtkm::cont::make_ArrayHandle(inputVecs2, vtkm::CopyFlag::Off);
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vtkm::worklet::CrossProduct crossProductWorklet;
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vtkm::worklet::DispatcherMapField<vtkm::worklet::CrossProduct> dispatcherCrossProduct(
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crossProductWorklet);
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dispatcherCrossProduct.Invoke(inputArray1, inputArray2, outputArray);
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VTKM_TEST_ASSERT(outputArray.GetNumberOfValues() == inputArray1.GetNumberOfValues(),
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"Wrong number of results for CrossProduct worklet");
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//Test the canonical cases.
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VTKM_TEST_ASSERT(test_equal(outputArray.ReadPortal().Get(0), vtkm::make_Vec(0, 0, 1)) &&
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test_equal(outputArray.ReadPortal().Get(1), vtkm::make_Vec(1, 0, 0)) &&
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test_equal(outputArray.ReadPortal().Get(2), vtkm::make_Vec(0, 1, 0)) &&
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test_equal(outputArray.ReadPortal().Get(3), vtkm::make_Vec(0, 0, -1)) &&
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test_equal(outputArray.ReadPortal().Get(4), vtkm::make_Vec(-1, 0, 0)) &&
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test_equal(outputArray.ReadPortal().Get(5), vtkm::make_Vec(0, -1, 0)),
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"Wrong result for CrossProduct worklet");
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for (vtkm::Id i = 0; i < inputArray1.GetNumberOfValues(); i++)
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{
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vtkm::Vec<T, 3> v1 = inputArray1.ReadPortal().Get(i);
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vtkm::Vec<T, 3> v2 = inputArray2.ReadPortal().Get(i);
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vtkm::Vec<T, 3> res = outputArray.ReadPortal().Get(i);
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//Make sure result is orthogonal each input vector. Need to normalize to compare with zero.
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vtkm::Vec<T, 3> v1N(vtkm::Normal(v1)), v2N(vtkm::Normal(v1)), resN(vtkm::Normal(res));
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VTKM_TEST_ASSERT(test_equal(vtkm::Dot(resN, v1N), T(0.0)), "Wrong result for cross product");
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VTKM_TEST_ASSERT(test_equal(vtkm::Dot(resN, v2N), T(0.0)), "Wrong result for cross product");
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T sinAngle = vtkm::Magnitude(res) * vtkm::RMagnitude(v1) * vtkm::RMagnitude(v2);
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T cosAngle = vtkm::Dot(v1, v2) * vtkm::RMagnitude(v1) * vtkm::RMagnitude(v2);
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VTKM_TEST_ASSERT(test_equal(sinAngle * sinAngle + cosAngle * cosAngle, T(1.0)),
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"Bad cross product length.");
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}
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}
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void TestCrossProductWorklets()
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{
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std::cout << "Testing CrossProduct Worklet" << std::endl;
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TestCrossProduct<vtkm::Float32>();
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TestCrossProduct<vtkm::Float64>();
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}
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}
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int UnitTestCrossProduct(int argc, char* argv[])
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{
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return vtkm::cont::testing::Testing::Run(TestCrossProductWorklets, argc, argv);
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}
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