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255 lines
8.8 KiB
Plaintext
255 lines
8.8 KiB
Plaintext
// This file is part of Eigen, a lightweight C++ template library
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// for linear algebra.
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//
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// Copyright (C) 2014 Benoit Steiner <benoit.steiner.goog@gmail.com>
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//
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// This Source Code Form is subject to the terms of the Mozilla
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// Public License v. 2.0. If a copy of the MPL was not distributed
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// with this file, You can obtain one at http://mozilla.org/MPL/2.0/.
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#define EIGEN_TEST_NO_LONGDOUBLE
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#define EIGEN_TEST_FUNC cxx11_tensor_cuda
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#define EIGEN_USE_GPU
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#if defined __CUDACC_VER__ && __CUDACC_VER__ >= 70500
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#include <cuda_fp16.h>
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#endif
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#include "main.h"
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#include <unsupported/Eigen/CXX11/Tensor>
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using Eigen::Tensor;
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template <int Layout>
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void test_cuda_simple_argmax()
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{
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Tensor<double, 3, Layout> in(Eigen::array<DenseIndex, 3>(72,53,97));
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Tensor<DenseIndex, 1, Layout> out_max(Eigen::array<DenseIndex, 1>(1));
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Tensor<DenseIndex, 1, Layout> out_min(Eigen::array<DenseIndex, 1>(1));
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in.setRandom();
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in *= in.constant(100.0);
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in(0, 0, 0) = -1000.0;
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in(71, 52, 96) = 1000.0;
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std::size_t in_bytes = in.size() * sizeof(double);
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std::size_t out_bytes = out_max.size() * sizeof(DenseIndex);
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double* d_in;
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DenseIndex* d_out_max;
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DenseIndex* d_out_min;
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cudaMalloc((void**)(&d_in), in_bytes);
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cudaMalloc((void**)(&d_out_max), out_bytes);
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cudaMalloc((void**)(&d_out_min), out_bytes);
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cudaMemcpy(d_in, in.data(), in_bytes, cudaMemcpyHostToDevice);
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Eigen::CudaStreamDevice stream;
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Eigen::GpuDevice gpu_device(&stream);
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Eigen::TensorMap<Eigen::Tensor<double, 3, Layout>, Aligned > gpu_in(d_in, Eigen::array<DenseIndex, 3>(72,53,97));
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Eigen::TensorMap<Eigen::Tensor<DenseIndex, 1, Layout>, Aligned > gpu_out_max(d_out_max, Eigen::array<DenseIndex, 1>(1));
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Eigen::TensorMap<Eigen::Tensor<DenseIndex, 1, Layout>, Aligned > gpu_out_min(d_out_min, Eigen::array<DenseIndex, 1>(1));
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gpu_out_max.device(gpu_device) = gpu_in.argmax();
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gpu_out_min.device(gpu_device) = gpu_in.argmin();
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assert(cudaMemcpyAsync(out_max.data(), d_out_max, out_bytes, cudaMemcpyDeviceToHost, gpu_device.stream()) == cudaSuccess);
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assert(cudaMemcpyAsync(out_min.data(), d_out_min, out_bytes, cudaMemcpyDeviceToHost, gpu_device.stream()) == cudaSuccess);
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assert(cudaStreamSynchronize(gpu_device.stream()) == cudaSuccess);
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VERIFY_IS_EQUAL(out_max(Eigen::array<DenseIndex, 1>(0)), 72*53*97 - 1);
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VERIFY_IS_EQUAL(out_min(Eigen::array<DenseIndex, 1>(0)), 0);
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cudaFree(d_in);
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cudaFree(d_out_max);
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cudaFree(d_out_min);
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}
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template <int DataLayout>
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void test_cuda_argmax_dim()
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{
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Tensor<float, 4, DataLayout> tensor(2,3,5,7);
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std::vector<int> dims;
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dims.push_back(2); dims.push_back(3); dims.push_back(5); dims.push_back(7);
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for (int dim = 0; dim < 4; ++dim) {
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tensor.setRandom();
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tensor = (tensor + tensor.constant(0.5)).log();
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array<DenseIndex, 3> out_shape;
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for (int d = 0; d < 3; ++d) out_shape[d] = (d < dim) ? dims[d] : dims[d+1];
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Tensor<DenseIndex, 3, DataLayout> tensor_arg(out_shape);
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array<DenseIndex, 4> ix;
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for (int i = 0; i < 2; ++i) {
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for (int j = 0; j < 3; ++j) {
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for (int k = 0; k < 5; ++k) {
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for (int l = 0; l < 7; ++l) {
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ix[0] = i; ix[1] = j; ix[2] = k; ix[3] = l;
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if (ix[dim] != 0) continue;
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// suppose dim == 1, then for all i, k, l, set tensor(i, 0, k, l) = 10.0
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tensor(ix) = 10.0;
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}
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}
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}
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}
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std::size_t in_bytes = tensor.size() * sizeof(float);
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std::size_t out_bytes = tensor_arg.size() * sizeof(DenseIndex);
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float* d_in;
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DenseIndex* d_out;
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cudaMalloc((void**)(&d_in), in_bytes);
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cudaMalloc((void**)(&d_out), out_bytes);
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cudaMemcpy(d_in, tensor.data(), in_bytes, cudaMemcpyHostToDevice);
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Eigen::CudaStreamDevice stream;
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Eigen::GpuDevice gpu_device(&stream);
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Eigen::TensorMap<Eigen::Tensor<float, 4, DataLayout>, Aligned > gpu_in(d_in, Eigen::array<DenseIndex, 4>(2, 3, 5, 7));
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Eigen::TensorMap<Eigen::Tensor<DenseIndex, 3, DataLayout>, Aligned > gpu_out(d_out, out_shape);
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gpu_out.device(gpu_device) = gpu_in.argmax(dim);
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assert(cudaMemcpyAsync(tensor_arg.data(), d_out, out_bytes, cudaMemcpyDeviceToHost, gpu_device.stream()) == cudaSuccess);
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assert(cudaStreamSynchronize(gpu_device.stream()) == cudaSuccess);
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VERIFY_IS_EQUAL(tensor_arg.size(),
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size_t(2*3*5*7 / tensor.dimension(dim)));
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for (DenseIndex n = 0; n < tensor_arg.size(); ++n) {
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// Expect max to be in the first index of the reduced dimension
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VERIFY_IS_EQUAL(tensor_arg.data()[n], 0);
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}
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for (int i = 0; i < 2; ++i) {
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for (int j = 0; j < 3; ++j) {
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for (int k = 0; k < 5; ++k) {
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for (int l = 0; l < 7; ++l) {
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ix[0] = i; ix[1] = j; ix[2] = k; ix[3] = l;
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if (ix[dim] != tensor.dimension(dim) - 1) continue;
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// suppose dim == 1, then for all i, k, l, set tensor(i, 2, k, l) = 20.0
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tensor(ix) = 20.0;
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}
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}
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}
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}
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cudaMemcpy(d_in, tensor.data(), in_bytes, cudaMemcpyHostToDevice);
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gpu_out.device(gpu_device) = gpu_in.argmax(dim);
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assert(cudaMemcpyAsync(tensor_arg.data(), d_out, out_bytes, cudaMemcpyDeviceToHost, gpu_device.stream()) == cudaSuccess);
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assert(cudaStreamSynchronize(gpu_device.stream()) == cudaSuccess);
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for (DenseIndex n = 0; n < tensor_arg.size(); ++n) {
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// Expect max to be in the last index of the reduced dimension
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VERIFY_IS_EQUAL(tensor_arg.data()[n], tensor.dimension(dim) - 1);
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}
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cudaFree(d_in);
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cudaFree(d_out);
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}
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}
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template <int DataLayout>
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void test_cuda_argmin_dim()
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{
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Tensor<float, 4, DataLayout> tensor(2,3,5,7);
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std::vector<int> dims;
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dims.push_back(2); dims.push_back(3); dims.push_back(5); dims.push_back(7);
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for (int dim = 0; dim < 4; ++dim) {
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tensor.setRandom();
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tensor = (tensor + tensor.constant(0.5)).log();
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array<DenseIndex, 3> out_shape;
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for (int d = 0; d < 3; ++d) out_shape[d] = (d < dim) ? dims[d] : dims[d+1];
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Tensor<DenseIndex, 3, DataLayout> tensor_arg(out_shape);
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array<DenseIndex, 4> ix;
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for (int i = 0; i < 2; ++i) {
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for (int j = 0; j < 3; ++j) {
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for (int k = 0; k < 5; ++k) {
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for (int l = 0; l < 7; ++l) {
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ix[0] = i; ix[1] = j; ix[2] = k; ix[3] = l;
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if (ix[dim] != 0) continue;
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// suppose dim == 1, then for all i, k, l, set tensor(i, 0, k, l) = 10.0
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tensor(ix) = -10.0;
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}
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}
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}
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}
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std::size_t in_bytes = tensor.size() * sizeof(float);
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std::size_t out_bytes = tensor_arg.size() * sizeof(DenseIndex);
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float* d_in;
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DenseIndex* d_out;
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cudaMalloc((void**)(&d_in), in_bytes);
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cudaMalloc((void**)(&d_out), out_bytes);
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cudaMemcpy(d_in, tensor.data(), in_bytes, cudaMemcpyHostToDevice);
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Eigen::CudaStreamDevice stream;
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Eigen::GpuDevice gpu_device(&stream);
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Eigen::TensorMap<Eigen::Tensor<float, 4, DataLayout>, Aligned > gpu_in(d_in, Eigen::array<DenseIndex, 4>(2, 3, 5, 7));
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Eigen::TensorMap<Eigen::Tensor<DenseIndex, 3, DataLayout>, Aligned > gpu_out(d_out, out_shape);
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gpu_out.device(gpu_device) = gpu_in.argmin(dim);
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assert(cudaMemcpyAsync(tensor_arg.data(), d_out, out_bytes, cudaMemcpyDeviceToHost, gpu_device.stream()) == cudaSuccess);
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assert(cudaStreamSynchronize(gpu_device.stream()) == cudaSuccess);
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VERIFY_IS_EQUAL(tensor_arg.size(),
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2*3*5*7 / tensor.dimension(dim));
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for (DenseIndex n = 0; n < tensor_arg.size(); ++n) {
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// Expect min to be in the first index of the reduced dimension
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VERIFY_IS_EQUAL(tensor_arg.data()[n], 0);
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}
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for (int i = 0; i < 2; ++i) {
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for (int j = 0; j < 3; ++j) {
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for (int k = 0; k < 5; ++k) {
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for (int l = 0; l < 7; ++l) {
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ix[0] = i; ix[1] = j; ix[2] = k; ix[3] = l;
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if (ix[dim] != tensor.dimension(dim) - 1) continue;
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// suppose dim == 1, then for all i, k, l, set tensor(i, 2, k, l) = 20.0
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tensor(ix) = -20.0;
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}
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}
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}
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}
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cudaMemcpy(d_in, tensor.data(), in_bytes, cudaMemcpyHostToDevice);
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gpu_out.device(gpu_device) = gpu_in.argmin(dim);
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assert(cudaMemcpyAsync(tensor_arg.data(), d_out, out_bytes, cudaMemcpyDeviceToHost, gpu_device.stream()) == cudaSuccess);
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assert(cudaStreamSynchronize(gpu_device.stream()) == cudaSuccess);
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for (DenseIndex n = 0; n < tensor_arg.size(); ++n) {
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// Expect max to be in the last index of the reduced dimension
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VERIFY_IS_EQUAL(tensor_arg.data()[n], tensor.dimension(dim) - 1);
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}
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cudaFree(d_in);
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cudaFree(d_out);
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}
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}
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void test_cxx11_tensor_cuda()
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{
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CALL_SUBTEST_1(test_cuda_simple_argmax<RowMajor>());
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CALL_SUBTEST_1(test_cuda_simple_argmax<ColMajor>());
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CALL_SUBTEST_2(test_cuda_argmax_dim<RowMajor>());
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CALL_SUBTEST_2(test_cuda_argmax_dim<ColMajor>());
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CALL_SUBTEST_3(test_cuda_argmin_dim<RowMajor>());
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CALL_SUBTEST_3(test_cuda_argmin_dim<ColMajor>());
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}
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