unsupported/test/cxx11_tensor_morphing_sycl.cpp - eigen - Git at Google

 // This file is part of Eigen, a lightweight C++ template library
 // for linear algebra.
 //
 // Copyright (C) 2016
 // Mehdi Goli    Codeplay Software Ltd.
 // Ralph Potter  Codeplay Software Ltd.
 // Luke Iwanski  Codeplay Software Ltd.
 // Contact: <eigen@codeplay.com>
 // Benoit Steiner <benoit.steiner.goog@gmail.com>
 //
 // This Source Code Form is subject to the terms of the Mozilla
 // Public License v. 2.0. If a copy of the MPL was not distributed
 // with this file, You can obtain one at http://mozilla.org/MPL/2.0/.

 #define EIGEN_TEST_NO_LONGDOUBLE
 #define EIGEN_TEST_NO_COMPLEX

 #define EIGEN_DEFAULT_DENSE_INDEX_TYPE int64_t
 #define EIGEN_USE_SYCL

 #include "main.h"
 #include <unsupported/Eigen/CXX11/Tensor>

 using Eigen::array;
 using Eigen::SyclDevice;
 using Eigen::Tensor;
 using Eigen::TensorMap;

 template <typename DataType, int DataLayout, typename IndexType>
 static void test_simple_reshape(const Eigen::SyclDevice& sycl_device) {
   typename Tensor<DataType, 5, DataLayout, IndexType>::Dimensions dim1(2, 3, 1, 7, 1);
   typename Tensor<DataType, 3, DataLayout, IndexType>::Dimensions dim2(2, 3, 7);
   typename Tensor<DataType, 2, DataLayout, IndexType>::Dimensions dim3(6, 7);
   typename Tensor<DataType, 2, DataLayout, IndexType>::Dimensions dim4(2, 21);

   Tensor<DataType, 5, DataLayout, IndexType> tensor1(dim1);
   Tensor<DataType, 3, DataLayout, IndexType> tensor2(dim2);
   Tensor<DataType, 2, DataLayout, IndexType> tensor3(dim3);
   Tensor<DataType, 2, DataLayout, IndexType> tensor4(dim4);

   tensor1.setRandom();

   DataType* gpu_data1 = static_cast<DataType*>(sycl_device.allocate(tensor1.size() * sizeof(DataType)));
   DataType* gpu_data2 = static_cast<DataType*>(sycl_device.allocate(tensor2.size() * sizeof(DataType)));
   DataType* gpu_data3 = static_cast<DataType*>(sycl_device.allocate(tensor3.size() * sizeof(DataType)));
   DataType* gpu_data4 = static_cast<DataType*>(sycl_device.allocate(tensor4.size() * sizeof(DataType)));

   TensorMap<Tensor<DataType, 5, DataLayout, IndexType>> gpu1(gpu_data1, dim1);
   TensorMap<Tensor<DataType, 3, DataLayout, IndexType>> gpu2(gpu_data2, dim2);
   TensorMap<Tensor<DataType, 2, DataLayout, IndexType>> gpu3(gpu_data3, dim3);
   TensorMap<Tensor<DataType, 2, DataLayout, IndexType>> gpu4(gpu_data4, dim4);

   sycl_device.memcpyHostToDevice(gpu_data1, tensor1.data(), (tensor1.size()) * sizeof(DataType));

   gpu2.device(sycl_device) = gpu1.reshape(dim2);
   sycl_device.memcpyDeviceToHost(tensor2.data(), gpu_data2, (tensor1.size()) * sizeof(DataType));

   gpu3.device(sycl_device) = gpu1.reshape(dim3);
   sycl_device.memcpyDeviceToHost(tensor3.data(), gpu_data3, (tensor3.size()) * sizeof(DataType));

   gpu4.device(sycl_device) = gpu1.reshape(dim2).reshape(dim4);
   sycl_device.memcpyDeviceToHost(tensor4.data(), gpu_data4, (tensor4.size()) * sizeof(DataType));
   for (IndexType i = 0; i < 2; ++i) {
     for (IndexType j = 0; j < 3; ++j) {
       for (IndexType k = 0; k < 7; ++k) {
         VERIFY_IS_EQUAL(tensor1(i, j, 0, k, 0), tensor2(i, j, k));  /// ColMajor
         if (static_cast<int>(DataLayout) == static_cast<int>(ColMajor)) {
           VERIFY_IS_EQUAL(tensor1(i, j, 0, k, 0), tensor3(i + 2 * j, k));  /// ColMajor
           VERIFY_IS_EQUAL(tensor1(i, j, 0, k, 0), tensor4(i, j + 3 * k));  /// ColMajor
         } else {
           // VERIFY_IS_EQUAL(tensor1(i,j,0,k,0), tensor2(i,j,k));      /// RowMajor
           VERIFY_IS_EQUAL(tensor1(i, j, 0, k, 0), tensor4(i, j * 7 + k));  /// RowMajor
           VERIFY_IS_EQUAL(tensor1(i, j, 0, k, 0), tensor3(i * 3 + j, k));  /// RowMajor
         }
       }
     }
   }
   sycl_device.deallocate(gpu_data1);
   sycl_device.deallocate(gpu_data2);
   sycl_device.deallocate(gpu_data3);
   sycl_device.deallocate(gpu_data4);
 }

 template <typename DataType, int DataLayout, typename IndexType>
 static void test_reshape_as_lvalue(const Eigen::SyclDevice& sycl_device) {
   typename Tensor<DataType, 3, DataLayout, IndexType>::Dimensions dim1(2, 3, 7);
   typename Tensor<DataType, 2, DataLayout, IndexType>::Dimensions dim2(6, 7);
   typename Tensor<DataType, 5, DataLayout, IndexType>::Dimensions dim3(2, 3, 1, 7, 1);
   Tensor<DataType, 3, DataLayout, IndexType> tensor(dim1);
   Tensor<DataType, 2, DataLayout, IndexType> tensor2d(dim2);
   Tensor<DataType, 5, DataLayout, IndexType> tensor5d(dim3);

   tensor.setRandom();

   DataType* gpu_data1 = static_cast<DataType*>(sycl_device.allocate(tensor.size() * sizeof(DataType)));
   DataType* gpu_data2 = static_cast<DataType*>(sycl_device.allocate(tensor2d.size() * sizeof(DataType)));
   DataType* gpu_data3 = static_cast<DataType*>(sycl_device.allocate(tensor5d.size() * sizeof(DataType)));

   TensorMap<Tensor<DataType, 3, DataLayout, IndexType>> gpu1(gpu_data1, dim1);
   TensorMap<Tensor<DataType, 2, DataLayout, IndexType>> gpu2(gpu_data2, dim2);
   TensorMap<Tensor<DataType, 5, DataLayout, IndexType>> gpu3(gpu_data3, dim3);

   sycl_device.memcpyHostToDevice(gpu_data1, tensor.data(), (tensor.size()) * sizeof(DataType));

   gpu2.reshape(dim1).device(sycl_device) = gpu1;
   sycl_device.memcpyDeviceToHost(tensor2d.data(), gpu_data2, (tensor2d.size()) * sizeof(DataType));

   gpu3.reshape(dim1).device(sycl_device) = gpu1;
   sycl_device.memcpyDeviceToHost(tensor5d.data(), gpu_data3, (tensor5d.size()) * sizeof(DataType));

   for (IndexType i = 0; i < 2; ++i) {
     for (IndexType j = 0; j < 3; ++j) {
       for (IndexType k = 0; k < 7; ++k) {
         VERIFY_IS_EQUAL(tensor5d(i, j, 0, k, 0), tensor(i, j, k));
         if (static_cast<int>(DataLayout) == static_cast<int>(ColMajor)) {
           VERIFY_IS_EQUAL(tensor2d(i + 2 * j, k), tensor(i, j, k));  /// ColMajor
         } else {
           VERIFY_IS_EQUAL(tensor2d(i * 3 + j, k), tensor(i, j, k));  /// RowMajor
         }
       }
     }
   }
   sycl_device.deallocate(gpu_data1);
   sycl_device.deallocate(gpu_data2);
   sycl_device.deallocate(gpu_data3);
 }

 template <typename DataType, int DataLayout, typename IndexType>
 static void test_simple_slice(const Eigen::SyclDevice& sycl_device) {
   IndexType sizeDim1 = 2;
   IndexType sizeDim2 = 3;
   IndexType sizeDim3 = 5;
   IndexType sizeDim4 = 7;
   IndexType sizeDim5 = 11;
   array<IndexType, 5> tensorRange = {{sizeDim1, sizeDim2, sizeDim3, sizeDim4, sizeDim5}};
   Tensor<DataType, 5, DataLayout, IndexType> tensor(tensorRange);
   tensor.setRandom();
   array<IndexType, 5> slice1_range = {{1, 1, 1, 1, 1}};
   Tensor<DataType, 5, DataLayout, IndexType> slice1(slice1_range);

   DataType* gpu_data1 = static_cast<DataType*>(sycl_device.allocate(tensor.size() * sizeof(DataType)));
   DataType* gpu_data2 = static_cast<DataType*>(sycl_device.allocate(slice1.size() * sizeof(DataType)));
   TensorMap<Tensor<DataType, 5, DataLayout, IndexType>> gpu1(gpu_data1, tensorRange);
   TensorMap<Tensor<DataType, 5, DataLayout, IndexType>> gpu2(gpu_data2, slice1_range);
   Eigen::DSizes<IndexType, 5> indices(1, 2, 3, 4, 5);
   Eigen::DSizes<IndexType, 5> sizes(1, 1, 1, 1, 1);
   sycl_device.memcpyHostToDevice(gpu_data1, tensor.data(), (tensor.size()) * sizeof(DataType));
   gpu2.device(sycl_device) = gpu1.slice(indices, sizes);
   sycl_device.memcpyDeviceToHost(slice1.data(), gpu_data2, (slice1.size()) * sizeof(DataType));
   VERIFY_IS_EQUAL(slice1(0, 0, 0, 0, 0), tensor(1, 2, 3, 4, 5));

   array<IndexType, 5> slice2_range = {{1, 1, 2, 2, 3}};
   Tensor<DataType, 5, DataLayout, IndexType> slice2(slice2_range);
   DataType* gpu_data3 = static_cast<DataType*>(sycl_device.allocate(slice2.size() * sizeof(DataType)));
   TensorMap<Tensor<DataType, 5, DataLayout, IndexType>> gpu3(gpu_data3, slice2_range);
   Eigen::DSizes<IndexType, 5> indices2(1, 1, 3, 4, 5);
   Eigen::DSizes<IndexType, 5> sizes2(1, 1, 2, 2, 3);
   gpu3.device(sycl_device) = gpu1.slice(indices2, sizes2);
   sycl_device.memcpyDeviceToHost(slice2.data(), gpu_data3, (slice2.size()) * sizeof(DataType));
   for (IndexType i = 0; i < 2; ++i) {
     for (IndexType j = 0; j < 2; ++j) {
       for (IndexType k = 0; k < 3; ++k) {
         VERIFY_IS_EQUAL(slice2(0, 0, i, j, k), tensor(1, 1, 3 + i, 4 + j, 5 + k));
       }
     }
   }
   sycl_device.deallocate(gpu_data1);
   sycl_device.deallocate(gpu_data2);
   sycl_device.deallocate(gpu_data3);
 }

 template <typename DataType, int DataLayout, typename IndexType>
 static void test_strided_slice_as_rhs_sycl(const Eigen::SyclDevice& sycl_device) {
   IndexType sizeDim1 = 2;
   IndexType sizeDim2 = 3;
   IndexType sizeDim3 = 5;
   IndexType sizeDim4 = 7;
   IndexType sizeDim5 = 11;
   typedef Eigen::DSizes<IndexType, 5> Index5;
   Index5 strides(1L, 1L, 1L, 1L, 1L);
   Index5 indicesStart(1L, 2L, 3L, 4L, 5L);
   Index5 indicesStop(2L, 3L, 4L, 5L, 6L);
   Index5 lengths(1L, 1L, 1L, 1L, 1L);

   array<IndexType, 5> tensorRange = {{sizeDim1, sizeDim2, sizeDim3, sizeDim4, sizeDim5}};
   Tensor<DataType, 5, DataLayout, IndexType> tensor(tensorRange);
   tensor.setRandom();

   array<IndexType, 5> slice1_range = {{1, 1, 1, 1, 1}};
   Tensor<DataType, 5, DataLayout, IndexType> slice1(slice1_range);
   Tensor<DataType, 5, DataLayout, IndexType> slice_stride1(slice1_range);

   DataType* gpu_data1 = static_cast<DataType*>(sycl_device.allocate(tensor.size() * sizeof(DataType)));
   DataType* gpu_data2 = static_cast<DataType*>(sycl_device.allocate(slice1.size() * sizeof(DataType)));
   DataType* gpu_data_stride2 = static_cast<DataType*>(sycl_device.allocate(slice_stride1.size() * sizeof(DataType)));

   TensorMap<Tensor<DataType, 5, DataLayout, IndexType>> gpu1(gpu_data1, tensorRange);
   TensorMap<Tensor<DataType, 5, DataLayout, IndexType>> gpu2(gpu_data2, slice1_range);
   TensorMap<Tensor<DataType, 5, DataLayout, IndexType>> gpu_stride2(gpu_data_stride2, slice1_range);

   Eigen::DSizes<IndexType, 5> indices(1, 2, 3, 4, 5);
   Eigen::DSizes<IndexType, 5> sizes(1, 1, 1, 1, 1);
   sycl_device.memcpyHostToDevice(gpu_data1, tensor.data(), (tensor.size()) * sizeof(DataType));
   gpu2.device(sycl_device) = gpu1.slice(indices, sizes);
   sycl_device.memcpyDeviceToHost(slice1.data(), gpu_data2, (slice1.size()) * sizeof(DataType));

   gpu_stride2.device(sycl_device) = gpu1.stridedSlice(indicesStart, indicesStop, strides);
   sycl_device.memcpyDeviceToHost(slice_stride1.data(), gpu_data_stride2, (slice_stride1.size()) * sizeof(DataType));

   VERIFY_IS_EQUAL(slice1(0, 0, 0, 0, 0), tensor(1, 2, 3, 4, 5));
   VERIFY_IS_EQUAL(slice_stride1(0, 0, 0, 0, 0), tensor(1, 2, 3, 4, 5));

   array<IndexType, 5> slice2_range = {{1, 1, 2, 2, 3}};
   Tensor<DataType, 5, DataLayout, IndexType> slice2(slice2_range);
   Tensor<DataType, 5, DataLayout, IndexType> strideSlice2(slice2_range);

   DataType* gpu_data3 = static_cast<DataType*>(sycl_device.allocate(slice2.size() * sizeof(DataType)));
   DataType* gpu_data_stride3 = static_cast<DataType*>(sycl_device.allocate(strideSlice2.size() * sizeof(DataType)));
   TensorMap<Tensor<DataType, 5, DataLayout, IndexType>> gpu3(gpu_data3, slice2_range);
   TensorMap<Tensor<DataType, 5, DataLayout, IndexType>> gpu_stride3(gpu_data_stride3, slice2_range);
   Eigen::DSizes<IndexType, 5> indices2(1, 1, 3, 4, 5);
   Eigen::DSizes<IndexType, 5> sizes2(1, 1, 2, 2, 3);
   Index5 strides2(1L, 1L, 1L, 1L, 1L);
   Index5 indicesStart2(1L, 1L, 3L, 4L, 5L);
   Index5 indicesStop2(2L, 2L, 5L, 6L, 8L);

   gpu3.device(sycl_device) = gpu1.slice(indices2, sizes2);
   sycl_device.memcpyDeviceToHost(slice2.data(), gpu_data3, (slice2.size()) * sizeof(DataType));

   gpu_stride3.device(sycl_device) = gpu1.stridedSlice(indicesStart2, indicesStop2, strides2);
   sycl_device.memcpyDeviceToHost(strideSlice2.data(), gpu_data_stride3, (strideSlice2.size()) * sizeof(DataType));

   for (IndexType i = 0; i < 2; ++i) {
     for (IndexType j = 0; j < 2; ++j) {
       for (IndexType k = 0; k < 3; ++k) {
         VERIFY_IS_EQUAL(slice2(0, 0, i, j, k), tensor(1, 1, 3 + i, 4 + j, 5 + k));
         VERIFY_IS_EQUAL(strideSlice2(0, 0, i, j, k), tensor(1, 1, 3 + i, 4 + j, 5 + k));
       }
     }
   }
   sycl_device.deallocate(gpu_data1);
   sycl_device.deallocate(gpu_data2);
   sycl_device.deallocate(gpu_data3);
 }

 template <typename DataType, int DataLayout, typename IndexType>
 static void test_strided_slice_write_sycl(const Eigen::SyclDevice& sycl_device) {
   typedef Tensor<DataType, 2, DataLayout, IndexType> Tensor2f;
   typedef Eigen::DSizes<IndexType, 2> Index2;
   IndexType sizeDim1 = 7L;
   IndexType sizeDim2 = 11L;
   array<IndexType, 2> tensorRange = {{sizeDim1, sizeDim2}};
   Tensor<DataType, 2, DataLayout, IndexType> tensor(tensorRange), tensor2(tensorRange);
   IndexType sliceDim1 = 2;
   IndexType sliceDim2 = 3;
   array<IndexType, 2> sliceRange = {{sliceDim1, sliceDim2}};
   Tensor2f slice(sliceRange);
   Index2 strides(1L, 1L);
   Index2 indicesStart(3L, 4L);
   Index2 indicesStop(5L, 7L);
   Index2 lengths(2L, 3L);

   DataType* gpu_data1 = static_cast<DataType*>(sycl_device.allocate(tensor.size() * sizeof(DataType)));
   DataType* gpu_data2 = static_cast<DataType*>(sycl_device.allocate(tensor2.size() * sizeof(DataType)));
   DataType* gpu_data3 = static_cast<DataType*>(sycl_device.allocate(slice.size() * sizeof(DataType)));
   TensorMap<Tensor<DataType, 2, DataLayout, IndexType>> gpu1(gpu_data1, tensorRange);
   TensorMap<Tensor<DataType, 2, DataLayout, IndexType>> gpu2(gpu_data2, tensorRange);
   TensorMap<Tensor<DataType, 2, DataLayout, IndexType>> gpu3(gpu_data3, sliceRange);

   tensor.setRandom();
   sycl_device.memcpyHostToDevice(gpu_data1, tensor.data(), (tensor.size()) * sizeof(DataType));
   gpu2.device(sycl_device) = gpu1;

   slice.setRandom();
   sycl_device.memcpyHostToDevice(gpu_data3, slice.data(), (slice.size()) * sizeof(DataType));

   gpu1.slice(indicesStart, lengths).device(sycl_device) = gpu3;
   gpu2.stridedSlice(indicesStart, indicesStop, strides).device(sycl_device) = gpu3;
   sycl_device.memcpyDeviceToHost(tensor.data(), gpu_data1, (tensor.size()) * sizeof(DataType));
   sycl_device.memcpyDeviceToHost(tensor2.data(), gpu_data2, (tensor2.size()) * sizeof(DataType));

   for (IndexType i = 0; i < sizeDim1; i++)
     for (IndexType j = 0; j < sizeDim2; j++) {
       VERIFY_IS_EQUAL(tensor(i, j), tensor2(i, j));
     }
   sycl_device.deallocate(gpu_data1);
   sycl_device.deallocate(gpu_data2);
   sycl_device.deallocate(gpu_data3);
 }

 template <typename OutIndex, typename DSizes>
 Eigen::array<OutIndex, DSizes::count> To32BitDims(const DSizes& in) {
   Eigen::array<OutIndex, DSizes::count> out;
   for (int i = 0; i < DSizes::count; ++i) {
     out[i] = in[i];
   }
   return out;
 }

 template <class DataType, int DataLayout, typename IndexType, typename ConvertedIndexType>
 int run_eigen(const SyclDevice& sycl_device) {
   using TensorI64 = Tensor<DataType, 5, DataLayout, IndexType>;
   using TensorI32 = Tensor<DataType, 5, DataLayout, ConvertedIndexType>;
   using TensorMI64 = TensorMap<TensorI64>;
   using TensorMI32 = TensorMap<TensorI32>;
   Eigen::array<IndexType, 5> tensor_range{{4, 1, 1, 1, 6}};
   Eigen::array<IndexType, 5> slice_range{{4, 1, 1, 1, 3}};

   TensorI64 out_tensor_gpu(tensor_range);
   TensorI64 out_tensor_cpu(tensor_range);
   out_tensor_cpu.setRandom();

   TensorI64 sub_tensor(slice_range);
   sub_tensor.setRandom();

   DataType* out_gpu_data = static_cast<DataType*>(sycl_device.allocate(out_tensor_cpu.size() * sizeof(DataType)));
   DataType* sub_gpu_data = static_cast<DataType*>(sycl_device.allocate(sub_tensor.size() * sizeof(DataType)));
   TensorMI64 out_gpu(out_gpu_data, tensor_range);
   TensorMI64 sub_gpu(sub_gpu_data, slice_range);

   sycl_device.memcpyHostToDevice(out_gpu_data, out_tensor_cpu.data(), out_tensor_cpu.size() * sizeof(DataType));
   sycl_device.memcpyHostToDevice(sub_gpu_data, sub_tensor.data(), sub_tensor.size() * sizeof(DataType));

   Eigen::array<ConvertedIndexType, 5> slice_offset_32{{0, 0, 0, 0, 3}};
   Eigen::array<ConvertedIndexType, 5> slice_range_32{{4, 1, 1, 1, 3}};
   TensorMI32 out_cpu_32(out_tensor_cpu.data(), To32BitDims<ConvertedIndexType>(out_tensor_cpu.dimensions()));
   TensorMI32 sub_cpu_32(sub_tensor.data(), To32BitDims<ConvertedIndexType>(sub_tensor.dimensions()));
   TensorMI32 out_gpu_32(out_gpu.data(), To32BitDims<ConvertedIndexType>(out_gpu.dimensions()));
   TensorMI32 sub_gpu_32(sub_gpu.data(), To32BitDims<ConvertedIndexType>(sub_gpu.dimensions()));

   out_gpu_32.slice(slice_offset_32, slice_range_32).device(sycl_device) = sub_gpu_32;

   out_cpu_32.slice(slice_offset_32, slice_range_32) = sub_cpu_32;

   sycl_device.memcpyDeviceToHost(out_tensor_gpu.data(), out_gpu_data, out_tensor_cpu.size() * sizeof(DataType));
   int has_err = 0;
   for (IndexType i = 0; i < out_tensor_cpu.size(); ++i) {
     auto exp = out_tensor_cpu(i);
     auto val = out_tensor_gpu(i);
     if (val != exp) {
       std::cout << "#" << i << " got " << val << " but expected " << exp << std::endl;
       has_err = 1;
     }
   }
   sycl_device.deallocate(out_gpu_data);
   sycl_device.deallocate(sub_gpu_data);
   return has_err;
 }

 template <typename DataType, typename dev_Selector>
 void sycl_morphing_test_per_device(dev_Selector s) {
   QueueInterface queueInterface(s);
   auto sycl_device = Eigen::SyclDevice(&queueInterface);
   test_simple_slice<DataType, RowMajor, int64_t>(sycl_device);
   test_simple_slice<DataType, ColMajor, int64_t>(sycl_device);
   test_simple_reshape<DataType, RowMajor, int64_t>(sycl_device);
   test_simple_reshape<DataType, ColMajor, int64_t>(sycl_device);
   test_reshape_as_lvalue<DataType, RowMajor, int64_t>(sycl_device);
   test_reshape_as_lvalue<DataType, ColMajor, int64_t>(sycl_device);
   test_strided_slice_write_sycl<DataType, ColMajor, int64_t>(sycl_device);
   test_strided_slice_write_sycl<DataType, RowMajor, int64_t>(sycl_device);
   test_strided_slice_as_rhs_sycl<DataType, ColMajor, int64_t>(sycl_device);
   test_strided_slice_as_rhs_sycl<DataType, RowMajor, int64_t>(sycl_device);
   run_eigen<float, RowMajor, long, int>(sycl_device);
 }
 EIGEN_DECLARE_TEST(cxx11_tensor_morphing_sycl) {
   for (const auto& device : Eigen::get_sycl_supported_devices()) {
     CALL_SUBTEST(sycl_morphing_test_per_device<half>(device));
     CALL_SUBTEST(sycl_morphing_test_per_device<float>(device));
   }
 }
	// This file is part of Eigen, a lightweight C++ template library
	// for linear algebra.
	//
	// Copyright (C) 2016
	// Mehdi Goli Codeplay Software Ltd.
	// Ralph Potter Codeplay Software Ltd.
	// Luke Iwanski Codeplay Software Ltd.
	// Contact: <eigen@codeplay.com>
	// Benoit Steiner <benoit.steiner.goog@gmail.com>
	//
	// This Source Code Form is subject to the terms of the Mozilla
	// Public License v. 2.0. If a copy of the MPL was not distributed
	// with this file, You can obtain one at http://mozilla.org/MPL/2.0/.

	#define EIGEN_TEST_NO_LONGDOUBLE
	#define EIGEN_TEST_NO_COMPLEX

	#define EIGEN_DEFAULT_DENSE_INDEX_TYPE int64_t
	#define EIGEN_USE_SYCL

	#include "main.h"
	#include <unsupported/Eigen/CXX11/Tensor>

	using Eigen::array;
	using Eigen::SyclDevice;
	using Eigen::Tensor;
	using Eigen::TensorMap;

	template <typename DataType, int DataLayout, typename IndexType>
	static void test_simple_reshape(const Eigen::SyclDevice& sycl_device) {
	typename Tensor<DataType, 5, DataLayout, IndexType>::Dimensions dim1(2, 3, 1, 7, 1);
	typename Tensor<DataType, 3, DataLayout, IndexType>::Dimensions dim2(2, 3, 7);
	typename Tensor<DataType, 2, DataLayout, IndexType>::Dimensions dim3(6, 7);
	typename Tensor<DataType, 2, DataLayout, IndexType>::Dimensions dim4(2, 21);

	Tensor<DataType, 5, DataLayout, IndexType> tensor1(dim1);
	Tensor<DataType, 3, DataLayout, IndexType> tensor2(dim2);
	Tensor<DataType, 2, DataLayout, IndexType> tensor3(dim3);
	Tensor<DataType, 2, DataLayout, IndexType> tensor4(dim4);

	tensor1.setRandom();

	DataType* gpu_data1 = static_cast<DataType>(sycl_device.allocate(tensor1.size() sizeof(DataType)));
	DataType* gpu_data2 = static_cast<DataType>(sycl_device.allocate(tensor2.size() sizeof(DataType)));
	DataType* gpu_data3 = static_cast<DataType>(sycl_device.allocate(tensor3.size() sizeof(DataType)));
	DataType* gpu_data4 = static_cast<DataType>(sycl_device.allocate(tensor4.size() sizeof(DataType)));

	TensorMap<Tensor<DataType, 5, DataLayout, IndexType>> gpu1(gpu_data1, dim1);
	TensorMap<Tensor<DataType, 3, DataLayout, IndexType>> gpu2(gpu_data2, dim2);
	TensorMap<Tensor<DataType, 2, DataLayout, IndexType>> gpu3(gpu_data3, dim3);
	TensorMap<Tensor<DataType, 2, DataLayout, IndexType>> gpu4(gpu_data4, dim4);

	sycl_device.memcpyHostToDevice(gpu_data1, tensor1.data(), (tensor1.size()) * sizeof(DataType));

	gpu2.device(sycl_device) = gpu1.reshape(dim2);
	sycl_device.memcpyDeviceToHost(tensor2.data(), gpu_data2, (tensor1.size()) * sizeof(DataType));

	gpu3.device(sycl_device) = gpu1.reshape(dim3);
	sycl_device.memcpyDeviceToHost(tensor3.data(), gpu_data3, (tensor3.size()) * sizeof(DataType));

	gpu4.device(sycl_device) = gpu1.reshape(dim2).reshape(dim4);
	sycl_device.memcpyDeviceToHost(tensor4.data(), gpu_data4, (tensor4.size()) * sizeof(DataType));
	for (IndexType i = 0; i < 2; ++i) {
	for (IndexType j = 0; j < 3; ++j) {
	for (IndexType k = 0; k < 7; ++k) {
	VERIFY_IS_EQUAL(tensor1(i, j, 0, k, 0), tensor2(i, j, k)); /// ColMajor
	if (static_cast<int>(DataLayout) == static_cast<int>(ColMajor)) {
	VERIFY_IS_EQUAL(tensor1(i, j, 0, k, 0), tensor3(i + 2 * j, k)); /// ColMajor
	VERIFY_IS_EQUAL(tensor1(i, j, 0, k, 0), tensor4(i, j + 3 * k)); /// ColMajor
	} else {
	// VERIFY_IS_EQUAL(tensor1(i,j,0,k,0), tensor2(i,j,k)); /// RowMajor
	VERIFY_IS_EQUAL(tensor1(i, j, 0, k, 0), tensor4(i, j * 7 + k)); /// RowMajor
	VERIFY_IS_EQUAL(tensor1(i, j, 0, k, 0), tensor3(i * 3 + j, k)); /// RowMajor
	}
	}
	}
	}
	sycl_device.deallocate(gpu_data1);
	sycl_device.deallocate(gpu_data2);
	sycl_device.deallocate(gpu_data3);
	sycl_device.deallocate(gpu_data4);
	}

	template <typename DataType, int DataLayout, typename IndexType>
	static void test_reshape_as_lvalue(const Eigen::SyclDevice& sycl_device) {
	typename Tensor<DataType, 3, DataLayout, IndexType>::Dimensions dim1(2, 3, 7);
	typename Tensor<DataType, 2, DataLayout, IndexType>::Dimensions dim2(6, 7);
	typename Tensor<DataType, 5, DataLayout, IndexType>::Dimensions dim3(2, 3, 1, 7, 1);
	Tensor<DataType, 3, DataLayout, IndexType> tensor(dim1);
	Tensor<DataType, 2, DataLayout, IndexType> tensor2d(dim2);
	Tensor<DataType, 5, DataLayout, IndexType> tensor5d(dim3);

	tensor.setRandom();

	DataType* gpu_data1 = static_cast<DataType>(sycl_device.allocate(tensor.size() sizeof(DataType)));
	DataType* gpu_data2 = static_cast<DataType>(sycl_device.allocate(tensor2d.size() sizeof(DataType)));
	DataType* gpu_data3 = static_cast<DataType>(sycl_device.allocate(tensor5d.size() sizeof(DataType)));

	TensorMap<Tensor<DataType, 3, DataLayout, IndexType>> gpu1(gpu_data1, dim1);
	TensorMap<Tensor<DataType, 2, DataLayout, IndexType>> gpu2(gpu_data2, dim2);
	TensorMap<Tensor<DataType, 5, DataLayout, IndexType>> gpu3(gpu_data3, dim3);

	sycl_device.memcpyHostToDevice(gpu_data1, tensor.data(), (tensor.size()) * sizeof(DataType));

	gpu2.reshape(dim1).device(sycl_device) = gpu1;
	sycl_device.memcpyDeviceToHost(tensor2d.data(), gpu_data2, (tensor2d.size()) * sizeof(DataType));

	gpu3.reshape(dim1).device(sycl_device) = gpu1;
	sycl_device.memcpyDeviceToHost(tensor5d.data(), gpu_data3, (tensor5d.size()) * sizeof(DataType));

	for (IndexType i = 0; i < 2; ++i) {
	for (IndexType j = 0; j < 3; ++j) {
	for (IndexType k = 0; k < 7; ++k) {
	VERIFY_IS_EQUAL(tensor5d(i, j, 0, k, 0), tensor(i, j, k));
	if (static_cast<int>(DataLayout) == static_cast<int>(ColMajor)) {
	VERIFY_IS_EQUAL(tensor2d(i + 2 * j, k), tensor(i, j, k)); /// ColMajor
	} else {
	VERIFY_IS_EQUAL(tensor2d(i * 3 + j, k), tensor(i, j, k)); /// RowMajor
	}
	}
	}
	}
	sycl_device.deallocate(gpu_data1);
	sycl_device.deallocate(gpu_data2);
	sycl_device.deallocate(gpu_data3);
	}

	template <typename DataType, int DataLayout, typename IndexType>
	static void test_simple_slice(const Eigen::SyclDevice& sycl_device) {
	IndexType sizeDim1 = 2;
	IndexType sizeDim2 = 3;
	IndexType sizeDim3 = 5;
	IndexType sizeDim4 = 7;
	IndexType sizeDim5 = 11;
	array<IndexType, 5> tensorRange = {{sizeDim1, sizeDim2, sizeDim3, sizeDim4, sizeDim5}};
	Tensor<DataType, 5, DataLayout, IndexType> tensor(tensorRange);
	tensor.setRandom();
	array<IndexType, 5> slice1_range = {{1, 1, 1, 1, 1}};
	Tensor<DataType, 5, DataLayout, IndexType> slice1(slice1_range);

	DataType* gpu_data1 = static_cast<DataType>(sycl_device.allocate(tensor.size() sizeof(DataType)));
	DataType* gpu_data2 = static_cast<DataType>(sycl_device.allocate(slice1.size() sizeof(DataType)));
	TensorMap<Tensor<DataType, 5, DataLayout, IndexType>> gpu1(gpu_data1, tensorRange);
	TensorMap<Tensor<DataType, 5, DataLayout, IndexType>> gpu2(gpu_data2, slice1_range);
	Eigen::DSizes<IndexType, 5> indices(1, 2, 3, 4, 5);
	Eigen::DSizes<IndexType, 5> sizes(1, 1, 1, 1, 1);
	sycl_device.memcpyHostToDevice(gpu_data1, tensor.data(), (tensor.size()) * sizeof(DataType));
	gpu2.device(sycl_device) = gpu1.slice(indices, sizes);
	sycl_device.memcpyDeviceToHost(slice1.data(), gpu_data2, (slice1.size()) * sizeof(DataType));
	VERIFY_IS_EQUAL(slice1(0, 0, 0, 0, 0), tensor(1, 2, 3, 4, 5));

	array<IndexType, 5> slice2_range = {{1, 1, 2, 2, 3}};
	Tensor<DataType, 5, DataLayout, IndexType> slice2(slice2_range);
	DataType* gpu_data3 = static_cast<DataType>(sycl_device.allocate(slice2.size() sizeof(DataType)));
	TensorMap<Tensor<DataType, 5, DataLayout, IndexType>> gpu3(gpu_data3, slice2_range);
	Eigen::DSizes<IndexType, 5> indices2(1, 1, 3, 4, 5);
	Eigen::DSizes<IndexType, 5> sizes2(1, 1, 2, 2, 3);
	gpu3.device(sycl_device) = gpu1.slice(indices2, sizes2);
	sycl_device.memcpyDeviceToHost(slice2.data(), gpu_data3, (slice2.size()) * sizeof(DataType));
	for (IndexType i = 0; i < 2; ++i) {
	for (IndexType j = 0; j < 2; ++j) {
	for (IndexType k = 0; k < 3; ++k) {
	VERIFY_IS_EQUAL(slice2(0, 0, i, j, k), tensor(1, 1, 3 + i, 4 + j, 5 + k));
	}
	}
	}
	sycl_device.deallocate(gpu_data1);
	sycl_device.deallocate(gpu_data2);
	sycl_device.deallocate(gpu_data3);
	}

	template <typename DataType, int DataLayout, typename IndexType>
	static void test_strided_slice_as_rhs_sycl(const Eigen::SyclDevice& sycl_device) {
	IndexType sizeDim1 = 2;
	IndexType sizeDim2 = 3;
	IndexType sizeDim3 = 5;
	IndexType sizeDim4 = 7;
	IndexType sizeDim5 = 11;
	typedef Eigen::DSizes<IndexType, 5> Index5;
	Index5 strides(1L, 1L, 1L, 1L, 1L);
	Index5 indicesStart(1L, 2L, 3L, 4L, 5L);
	Index5 indicesStop(2L, 3L, 4L, 5L, 6L);
	Index5 lengths(1L, 1L, 1L, 1L, 1L);

	array<IndexType, 5> tensorRange = {{sizeDim1, sizeDim2, sizeDim3, sizeDim4, sizeDim5}};
	Tensor<DataType, 5, DataLayout, IndexType> tensor(tensorRange);
	tensor.setRandom();

	array<IndexType, 5> slice1_range = {{1, 1, 1, 1, 1}};
	Tensor<DataType, 5, DataLayout, IndexType> slice1(slice1_range);
	Tensor<DataType, 5, DataLayout, IndexType> slice_stride1(slice1_range);

	DataType* gpu_data1 = static_cast<DataType>(sycl_device.allocate(tensor.size() sizeof(DataType)));
	DataType* gpu_data2 = static_cast<DataType>(sycl_device.allocate(slice1.size() sizeof(DataType)));
	DataType* gpu_data_stride2 = static_cast<DataType>(sycl_device.allocate(slice_stride1.size() sizeof(DataType)));

	TensorMap<Tensor<DataType, 5, DataLayout, IndexType>> gpu1(gpu_data1, tensorRange);
	TensorMap<Tensor<DataType, 5, DataLayout, IndexType>> gpu2(gpu_data2, slice1_range);
	TensorMap<Tensor<DataType, 5, DataLayout, IndexType>> gpu_stride2(gpu_data_stride2, slice1_range);

	Eigen::DSizes<IndexType, 5> indices(1, 2, 3, 4, 5);
	Eigen::DSizes<IndexType, 5> sizes(1, 1, 1, 1, 1);
	sycl_device.memcpyHostToDevice(gpu_data1, tensor.data(), (tensor.size()) * sizeof(DataType));
	gpu2.device(sycl_device) = gpu1.slice(indices, sizes);
	sycl_device.memcpyDeviceToHost(slice1.data(), gpu_data2, (slice1.size()) * sizeof(DataType));

	gpu_stride2.device(sycl_device) = gpu1.stridedSlice(indicesStart, indicesStop, strides);
	sycl_device.memcpyDeviceToHost(slice_stride1.data(), gpu_data_stride2, (slice_stride1.size()) * sizeof(DataType));

	VERIFY_IS_EQUAL(slice1(0, 0, 0, 0, 0), tensor(1, 2, 3, 4, 5));
	VERIFY_IS_EQUAL(slice_stride1(0, 0, 0, 0, 0), tensor(1, 2, 3, 4, 5));

	array<IndexType, 5> slice2_range = {{1, 1, 2, 2, 3}};
	Tensor<DataType, 5, DataLayout, IndexType> slice2(slice2_range);
	Tensor<DataType, 5, DataLayout, IndexType> strideSlice2(slice2_range);

	DataType* gpu_data3 = static_cast<DataType>(sycl_device.allocate(slice2.size() sizeof(DataType)));
	DataType* gpu_data_stride3 = static_cast<DataType>(sycl_device.allocate(strideSlice2.size() sizeof(DataType)));
	TensorMap<Tensor<DataType, 5, DataLayout, IndexType>> gpu3(gpu_data3, slice2_range);
	TensorMap<Tensor<DataType, 5, DataLayout, IndexType>> gpu_stride3(gpu_data_stride3, slice2_range);
	Eigen::DSizes<IndexType, 5> indices2(1, 1, 3, 4, 5);
	Eigen::DSizes<IndexType, 5> sizes2(1, 1, 2, 2, 3);
	Index5 strides2(1L, 1L, 1L, 1L, 1L);
	Index5 indicesStart2(1L, 1L, 3L, 4L, 5L);
	Index5 indicesStop2(2L, 2L, 5L, 6L, 8L);

	gpu3.device(sycl_device) = gpu1.slice(indices2, sizes2);
	sycl_device.memcpyDeviceToHost(slice2.data(), gpu_data3, (slice2.size()) * sizeof(DataType));

	gpu_stride3.device(sycl_device) = gpu1.stridedSlice(indicesStart2, indicesStop2, strides2);
	sycl_device.memcpyDeviceToHost(strideSlice2.data(), gpu_data_stride3, (strideSlice2.size()) * sizeof(DataType));

	for (IndexType i = 0; i < 2; ++i) {
	for (IndexType j = 0; j < 2; ++j) {
	for (IndexType k = 0; k < 3; ++k) {
	VERIFY_IS_EQUAL(slice2(0, 0, i, j, k), tensor(1, 1, 3 + i, 4 + j, 5 + k));
	VERIFY_IS_EQUAL(strideSlice2(0, 0, i, j, k), tensor(1, 1, 3 + i, 4 + j, 5 + k));
	}
	}
	}
	sycl_device.deallocate(gpu_data1);
	sycl_device.deallocate(gpu_data2);
	sycl_device.deallocate(gpu_data3);
	}

	template <typename DataType, int DataLayout, typename IndexType>
	static void test_strided_slice_write_sycl(const Eigen::SyclDevice& sycl_device) {
	typedef Tensor<DataType, 2, DataLayout, IndexType> Tensor2f;
	typedef Eigen::DSizes<IndexType, 2> Index2;
	IndexType sizeDim1 = 7L;
	IndexType sizeDim2 = 11L;
	array<IndexType, 2> tensorRange = {{sizeDim1, sizeDim2}};
	Tensor<DataType, 2, DataLayout, IndexType> tensor(tensorRange), tensor2(tensorRange);
	IndexType sliceDim1 = 2;
	IndexType sliceDim2 = 3;
	array<IndexType, 2> sliceRange = {{sliceDim1, sliceDim2}};
	Tensor2f slice(sliceRange);
	Index2 strides(1L, 1L);
	Index2 indicesStart(3L, 4L);
	Index2 indicesStop(5L, 7L);
	Index2 lengths(2L, 3L);

	DataType* gpu_data1 = static_cast<DataType>(sycl_device.allocate(tensor.size() sizeof(DataType)));
	DataType* gpu_data2 = static_cast<DataType>(sycl_device.allocate(tensor2.size() sizeof(DataType)));
	DataType* gpu_data3 = static_cast<DataType>(sycl_device.allocate(slice.size() sizeof(DataType)));
	TensorMap<Tensor<DataType, 2, DataLayout, IndexType>> gpu1(gpu_data1, tensorRange);
	TensorMap<Tensor<DataType, 2, DataLayout, IndexType>> gpu2(gpu_data2, tensorRange);
	TensorMap<Tensor<DataType, 2, DataLayout, IndexType>> gpu3(gpu_data3, sliceRange);

	tensor.setRandom();
	sycl_device.memcpyHostToDevice(gpu_data1, tensor.data(), (tensor.size()) * sizeof(DataType));
	gpu2.device(sycl_device) = gpu1;

	slice.setRandom();
	sycl_device.memcpyHostToDevice(gpu_data3, slice.data(), (slice.size()) * sizeof(DataType));

	gpu1.slice(indicesStart, lengths).device(sycl_device) = gpu3;
	gpu2.stridedSlice(indicesStart, indicesStop, strides).device(sycl_device) = gpu3;
	sycl_device.memcpyDeviceToHost(tensor.data(), gpu_data1, (tensor.size()) * sizeof(DataType));
	sycl_device.memcpyDeviceToHost(tensor2.data(), gpu_data2, (tensor2.size()) * sizeof(DataType));

	for (IndexType i = 0; i < sizeDim1; i++)
	for (IndexType j = 0; j < sizeDim2; j++) {
	VERIFY_IS_EQUAL(tensor(i, j), tensor2(i, j));
	}
	sycl_device.deallocate(gpu_data1);
	sycl_device.deallocate(gpu_data2);
	sycl_device.deallocate(gpu_data3);
	}

	template <typename OutIndex, typename DSizes>
	Eigen::array<OutIndex, DSizes::count> To32BitDims(const DSizes& in) {
	Eigen::array<OutIndex, DSizes::count> out;
	for (int i = 0; i < DSizes::count; ++i) {
	out[i] = in[i];
	}
	return out;
	}

	template <class DataType, int DataLayout, typename IndexType, typename ConvertedIndexType>
	int run_eigen(const SyclDevice& sycl_device) {
	using TensorI64 = Tensor<DataType, 5, DataLayout, IndexType>;
	using TensorI32 = Tensor<DataType, 5, DataLayout, ConvertedIndexType>;
	using TensorMI64 = TensorMap<TensorI64>;
	using TensorMI32 = TensorMap<TensorI32>;
	Eigen::array<IndexType, 5> tensor_range{{4, 1, 1, 1, 6}};
	Eigen::array<IndexType, 5> slice_range{{4, 1, 1, 1, 3}};

	TensorI64 out_tensor_gpu(tensor_range);
	TensorI64 out_tensor_cpu(tensor_range);
	out_tensor_cpu.setRandom();

	TensorI64 sub_tensor(slice_range);
	sub_tensor.setRandom();

	DataType* out_gpu_data = static_cast<DataType>(sycl_device.allocate(out_tensor_cpu.size() sizeof(DataType)));
	DataType* sub_gpu_data = static_cast<DataType>(sycl_device.allocate(sub_tensor.size() sizeof(DataType)));
	TensorMI64 out_gpu(out_gpu_data, tensor_range);
	TensorMI64 sub_gpu(sub_gpu_data, slice_range);

	sycl_device.memcpyHostToDevice(out_gpu_data, out_tensor_cpu.data(), out_tensor_cpu.size() * sizeof(DataType));
	sycl_device.memcpyHostToDevice(sub_gpu_data, sub_tensor.data(), sub_tensor.size() * sizeof(DataType));

	Eigen::array<ConvertedIndexType, 5> slice_offset_32{{0, 0, 0, 0, 3}};
	Eigen::array<ConvertedIndexType, 5> slice_range_32{{4, 1, 1, 1, 3}};
	TensorMI32 out_cpu_32(out_tensor_cpu.data(), To32BitDims<ConvertedIndexType>(out_tensor_cpu.dimensions()));
	TensorMI32 sub_cpu_32(sub_tensor.data(), To32BitDims<ConvertedIndexType>(sub_tensor.dimensions()));
	TensorMI32 out_gpu_32(out_gpu.data(), To32BitDims<ConvertedIndexType>(out_gpu.dimensions()));
	TensorMI32 sub_gpu_32(sub_gpu.data(), To32BitDims<ConvertedIndexType>(sub_gpu.dimensions()));

	out_gpu_32.slice(slice_offset_32, slice_range_32).device(sycl_device) = sub_gpu_32;

	out_cpu_32.slice(slice_offset_32, slice_range_32) = sub_cpu_32;

	sycl_device.memcpyDeviceToHost(out_tensor_gpu.data(), out_gpu_data, out_tensor_cpu.size() * sizeof(DataType));
	int has_err = 0;
	for (IndexType i = 0; i < out_tensor_cpu.size(); ++i) {
	auto exp = out_tensor_cpu(i);
	auto val = out_tensor_gpu(i);
	if (val != exp) {
	std::cout << "#" << i << " got " << val << " but expected " << exp << std::endl;
	has_err = 1;
	}
	}
	sycl_device.deallocate(out_gpu_data);
	sycl_device.deallocate(sub_gpu_data);
	return has_err;
	}

	template <typename DataType, typename dev_Selector>
	void sycl_morphing_test_per_device(dev_Selector s) {
	QueueInterface queueInterface(s);
	auto sycl_device = Eigen::SyclDevice(&queueInterface);
	test_simple_slice<DataType, RowMajor, int64_t>(sycl_device);
	test_simple_slice<DataType, ColMajor, int64_t>(sycl_device);
	test_simple_reshape<DataType, RowMajor, int64_t>(sycl_device);
	test_simple_reshape<DataType, ColMajor, int64_t>(sycl_device);
	test_reshape_as_lvalue<DataType, RowMajor, int64_t>(sycl_device);
	test_reshape_as_lvalue<DataType, ColMajor, int64_t>(sycl_device);
	test_strided_slice_write_sycl<DataType, ColMajor, int64_t>(sycl_device);
	test_strided_slice_write_sycl<DataType, RowMajor, int64_t>(sycl_device);
	test_strided_slice_as_rhs_sycl<DataType, ColMajor, int64_t>(sycl_device);
	test_strided_slice_as_rhs_sycl<DataType, RowMajor, int64_t>(sycl_device);
	run_eigen<float, RowMajor, long, int>(sycl_device);
	}
	EIGEN_DECLARE_TEST(cxx11_tensor_morphing_sycl) {
	for (const auto& device : Eigen::get_sycl_supported_devices()) {
	CALL_SUBTEST(sycl_morphing_test_per_device<half>(device));
	CALL_SUBTEST(sycl_morphing_test_per_device<float>(device));
	}
	}