/* Copyright (c) 2016 PaddlePaddle Authors. All Rights Reserved. Licensed under the Apache License, Version 2.0 (the "License"); you may not use this file except in compliance with the License. You may obtain a copy of the License at http://www.apache.org/licenses/LICENSE-2.0 Unless required by applicable law or agreed to in writing, software distributed under the License is distributed on an "AS IS" BASIS, WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. See the License for the specific language governing permissions and limitations under the License. */ #pragma once #include #include #include #include #include #include #include "paddle/fluid/framework/data_type.h" #include "paddle/fluid/framework/dlpack_tensor.h" #include "paddle/fluid/framework/eigen.h" #include "paddle/fluid/framework/string_array.h" #include "paddle/fluid/framework/tensor.h" #include "paddle/fluid/memory/allocation/allocator_facade.h" #ifdef PADDLE_WITH_ASCEND_CL #include "paddle/fluid/memory/allocation/npu_pinned_allocator.h" #endif #include "paddle/fluid/platform/device_context.h" #ifdef PADDLE_WITH_MLU #include "paddle/fluid/platform/device/mlu/device_context.h" #endif #include "paddle/phi/core/dense_tensor.h" namespace paddle { namespace framework { class PrintOptions { public: static PrintOptions& Instance() { static PrintOptions instance; return instance; } ~PrintOptions() {} PrintOptions(const PrintOptions& o) = delete; const PrintOptions& operator=(const PrintOptions& o) = delete; int precision = 8; int threshold = 1000; int edgeitems = 3; int linewidth = 75; bool sci_mode = false; private: PrintOptions() {} }; void TensorToStream(std::ostream& os, const Tensor& tensor, const platform::DeviceContext& dev_ctx); void TensorFromStream(std::istream& is, Tensor* tensor, const platform::DeviceContext& dev_ctx); void TensorFromStream(std::istream& is, Tensor* tensor, const platform::DeviceContext& dev_ctx, const size_t& seek, const std::vector& shape); // NOTE(zcd): Because TensorCopy is an async operation, when the src_place // and dst_place are two different GPU, to ensure that the operation can // be carried out correctly, there is a src_ctx wait operation in TensorCopy. // If ctx_place and src_place are the same, src_ctx.Wait() is added // after memory::Copy; if ctx_place and dst_place are the same, // src_ctx.Wait() is added before memory::Copy. void TensorCopy(const Tensor& src, const platform::Place& dst_place, const platform::DeviceContext& ctx, Tensor* dst); // NOTE(zcd): If the src.place() and dst_place are two different GPU, // the copy operation is carried out on the dst_place's stream. This is // very important, because TensorCopy is an async operator, and in most // case, once this copy operator returns, dst is to be used in dst_place's // stream, if this copy operation is carried out on the src_place's stream, // when dst is used in dst_place's stream the copy operation may be // not completed. void TensorCopy(const Tensor& src, const platform::Place& dst_place, Tensor* dst); void TensorCopySync(const Tensor& src, const platform::Place& dst_place, Tensor* dst); template void TensorFromVector(const std::vector& src, const platform::DeviceContext& ctx, Tensor* dst); template void TensorFromVector(const std::vector& src, Tensor* dst); template void TensorToVector(const Tensor& src, const platform::DeviceContext& ctx, std::vector* dst); template void TesnorToVector(const Tensor& src, std::vector* dst); // copy the result bool to cpu bool TensorContainsNAN(const framework::Tensor& tensor); bool TensorContainsInf(const framework::Tensor& tensor); bool TensorIsfinite(const framework::Tensor& tensor); // store the result bool in gpu tensor, async operation. Faster than above ones. void TensorContainsNAN(const framework::Tensor& tensor, framework::Tensor* out); void TensorContainsInf(const framework::Tensor& tensor, framework::Tensor* out); void TensorIsfinite(const framework::Tensor& tensor, framework::Tensor* out); void TensorToStream(std::ostream& os, const Tensor& tensor, const platform::DeviceContext& dev_ctx); void TensorFromStream(std::istream& is, Tensor* tensor, const platform::DeviceContext& dev_ctx); void TensorFromStream(std::istream& is, Tensor* tensor, const platform::DeviceContext& dev_ctx, const size_t& seek, const std::vector& shape); // store the bool result tensor in out tensor void TensorContainsNANV2(const framework::Tensor& tensor, framework::Tensor* out); void TensorContainsInfV2(const framework::Tensor& tensor, framework::Tensor* out); void TensorIsfiniteV2(const framework::Tensor& tensor, framework::Tensor* out); // convert dlpack's DLTensor to tensor void TensorFromDLPack(const ::DLTensor& dl_tensor, framework::Tensor* dst); // // The implementation of template functions. // template void TensorFromArray(const T* src, const size_t& array_size, const platform::DeviceContext& ctx, Tensor* dst) { auto dst_place = ctx.GetPlace(); auto src_ptr = static_cast(src); platform::CPUPlace src_place; dst->Resize({static_cast(array_size)}); auto dst_ptr = static_cast(dst->mutable_data(dst_place)); auto size = array_size * sizeof(T); if (platform::is_cpu_place(dst_place)) { memory::Copy(dst_place, dst_ptr, src_place, src_ptr, size); } #if defined(PADDLE_WITH_CUDA) || defined(PADDLE_WITH_HIP) else if (platform::is_gpu_place(dst_place)) { // NOLINT memory::Copy( dst_place, dst_ptr, src_place, src_ptr, size, reinterpret_cast(ctx).stream()); } #endif #ifdef PADDLE_WITH_ASCEND_CL else if (platform::is_npu_place(dst_place)) { // NOLINT // 1. vector -> npu pinned tensor platform::NPUPinnedPlace npu_pinned_place; Tensor npu_pinned_tensor; npu_pinned_tensor.Resize(dst->dims()); auto npu_pinned_ptr = npu_pinned_tensor.mutable_data(npu_pinned_place, dst->dtype()); memory::Copy(npu_pinned_place, npu_pinned_ptr, src_place, src_ptr, size); // 2. async copy npu pinned tensor -> npu tensor memory::Copy( dst_place, dst_ptr, npu_pinned_place, npu_pinned_ptr, size, reinterpret_cast(ctx).stream()); // 3. record event auto npu_pinned_allocator = static_cast( paddle::memory::allocation::AllocatorFacade::Instance() .GetAllocator(npu_pinned_place) .get()); phi::Allocation* allocation = npu_pinned_tensor.Holder().get(); npu_pinned_allocator->RecordEvent( allocation, reinterpret_cast(ctx).stream()); } #endif #ifdef PADDLE_WITH_MLU else if (platform::is_mlu_place(dst_place)) { // NOLINT memory::Copy(dst_place, dst_ptr, src_place, src_ptr, size, nullptr); } #endif #ifdef PADDLE_WITH_CUSTOM_DEVICE else if (platform::is_custom_place(dst_place)) { // NOLINT memory::Copy( dst_place, dst_ptr, src_place, src_ptr, size, reinterpret_cast(ctx).stream()); } #endif else { // NOLINT PADDLE_THROW(platform::errors::Unimplemented( "TensorFromArray on %s is not supported.", dst_place)); } } template void TensorFromVector(const std::vector& src, const platform::DeviceContext& ctx, Tensor* dst) { auto dst_place = ctx.GetPlace(); auto src_ptr = static_cast(src.data()); platform::CPUPlace src_place; dst->Resize({static_cast(src.size())}); auto dst_ptr = static_cast(dst->mutable_data(dst_place)); auto size = src.size() * sizeof(T); if (platform::is_cpu_place(dst_place)) { memory::Copy(dst_place, dst_ptr, src_place, src_ptr, size); } #if defined(PADDLE_WITH_CUDA) || defined(PADDLE_WITH_HIP) else if (platform::is_gpu_place(dst_place)) { // NOLINT memory::Copy( dst_place, dst_ptr, src_place, src_ptr, size, reinterpret_cast(ctx).stream()); } #endif #ifdef PADDLE_WITH_ASCEND_CL // NOTE(zhiqiu): Becareful that aclrtMemcpyAsync is different from // cudaMemcpyAsync. // cudaMemcpyAsync is actually "sync" between cpu <-> gpu. // aclrtMemcpyAsync is really "async" between cpu <-> npu. // Since vector is on cpu, I think this function should be a "sync" operation, // so pass nullptr as stream to memory::Copy(). else if (platform::is_npu_place(dst_place)) { // NOLINT // 1. vector -> npu pinned tensor Tensor npu_pinned_tensor(dst->dtype()); platform::NPUPinnedPlace npu_pinned_place; auto npu_pinned_ptr = npu_pinned_tensor.mutable_data(dst->dims(), npu_pinned_place); memory::Copy(npu_pinned_place, npu_pinned_ptr, src_place, src_ptr, size); // 2. async copy npu pinned tensor -> npu tensor memory::Copy( dst_place, dst_ptr, npu_pinned_place, npu_pinned_ptr, size, reinterpret_cast(ctx).stream()); // 3. record event auto npu_pinned_allocator = static_cast( paddle::memory::allocation::AllocatorFacade::Instance() .GetAllocator(npu_pinned_place) .get()); phi::Allocation* allocation = npu_pinned_tensor.Holder().get(); npu_pinned_allocator->RecordEvent( allocation, reinterpret_cast(ctx).stream()); } #endif #ifdef PADDLE_WITH_MLU else if (platform::is_mlu_place(dst_place)) { // NOLINT memory::Copy(dst_place, dst_ptr, src_place, src_ptr, size, nullptr); } #endif #ifdef PADDLE_WITH_CUSTOM_DEVICE else if (platform::is_custom_place(dst_place)) { // NOLINT memory::Copy( dst_place, dst_ptr, src_place, src_ptr, size, reinterpret_cast(ctx).stream()); } #endif else { // NOLINT PADDLE_THROW(platform::errors::Unimplemented( "TensorFromVector on %s is not supported.", dst_place)); } } // The fully specialized function should be inline to avoid // multi-definition. template <> inline void TensorFromVector(const std::vector& src, const platform::DeviceContext& ctx, Tensor* dst) { // vector has no data() member, use array instead. // See details: // https://stackoverflow.com/questions/46115669/why-does-stdvectorbool-have-no-data/46115714 bool* array = new bool[src.size()]; for (unsigned int i = 0; i < src.size(); i++) { array[i] = static_cast(src[i]); } auto dst_place = ctx.GetPlace(); auto src_ptr = static_cast(array); platform::CPUPlace src_place; dst->Resize({static_cast(src.size())}); auto dst_ptr = static_cast(dst->mutable_data(dst_place)); auto size = src.size() * sizeof(bool); if (platform::is_cpu_place(dst_place)) { memory::Copy(dst_place, dst_ptr, src_place, src_ptr, size); } #ifdef PADDLE_WITH_CUDA else if (platform::is_gpu_place(dst_place)) { // NOLINT memory::Copy( dst_place, dst_ptr, src_place, src_ptr, size, reinterpret_cast(ctx).stream()); } #endif #ifdef PADDLE_WITH_ASCEND_CL else if (platform::is_npu_place(dst_place)) { // NOLINT // 1. vector -> npu pinned tensor platform::NPUPinnedPlace npu_pinned_place; Tensor npu_pinned_tensor; npu_pinned_tensor.Resize(dst->dims()); auto npu_pinned_ptr = npu_pinned_tensor.mutable_data(npu_pinned_place, dst->dtype()); memory::Copy(npu_pinned_place, npu_pinned_ptr, src_place, src_ptr, size); // 2. async copy npu pinned tensor -> npu tensor memory::Copy( dst_place, dst_ptr, npu_pinned_place, npu_pinned_ptr, size, reinterpret_cast(ctx).stream()); // 3. record event auto npu_pinned_allocator = static_cast( paddle::memory::allocation::AllocatorFacade::Instance() .GetAllocator(npu_pinned_place) .get()); phi::Allocation* allocation = npu_pinned_tensor.Holder().get(); npu_pinned_allocator->RecordEvent( allocation, reinterpret_cast(ctx).stream()); } #endif #ifdef PADDLE_WITH_CUSTOM_DEICE else if (platform::is_custom_place(dst_place)) { // NOLINT auto stream = reinterpret_cast(ctx).stream(); memory::Copy(dst_place, dst_ptr, src_place, src_ptr, size, stream); } #endif else { // NOLINT PADDLE_THROW(platform::errors::Unimplemented( "TensorFromVector on %s is not supported.", dst_place)); } delete[] array; } template void TensorFromVector(const std::vector& src, Tensor* dst) { platform::CPUPlace dst_place = platform::CPUPlace(); auto src_ptr = static_cast(src.data()); platform::CPUPlace src_place; dst->Resize({static_cast(src.size())}); auto dst_ptr = static_cast(dst->mutable_data(dst_place)); auto size = src.size() * sizeof(T); memory::Copy(dst_place, dst_ptr, src_place, src_ptr, size); } template <> inline void TensorFromVector(const std::vector& src, Tensor* dst) { bool* array = new bool[src.size()]; for (unsigned int i = 0; i < src.size(); i++) { array[i] = static_cast(src[i]); } platform::CPUPlace dst_place = platform::CPUPlace(); auto src_ptr = static_cast(array); platform::CPUPlace src_place; dst->Resize({static_cast(src.size())}); auto dst_ptr = static_cast(dst->mutable_data(dst_place)); auto size = src.size() * sizeof(bool); memory::Copy(dst_place, dst_ptr, src_place, src_ptr, size); delete[] array; } template void TensorToVector(const Tensor& src, const platform::DeviceContext& ctx, std::vector* dst) { auto src_ptr = static_cast(src.data()); auto size = src.numel() * sizeof(T); platform::CPUPlace dst_place; dst->resize(src.numel()); auto dst_ptr = static_cast(dst->data()); if (platform::is_cpu_place(src.place())) { memory::Copy(dst_place, dst_ptr, src.place(), src_ptr, size); } #if defined(PADDLE_WITH_CUDA) || defined(PADDLE_WITH_HIP) else if (platform::is_gpu_place(src.place())) { // NOLINT memory::Copy( dst_place, dst_ptr, src.place(), src_ptr, size, reinterpret_cast(ctx).stream()); } #endif #if defined(PADDLE_WITH_XPU) else if (platform::is_xpu_place(src.place())) { // NOLINT memory::Copy(dst_place, dst_ptr, src.place(), src_ptr, size); } #endif #ifdef PADDLE_WITH_ASCEND_CL else if (platform::is_npu_place(src.place())) { // NOLINT memory::Copy(dst_place, dst_ptr, src.place(), src_ptr, size, nullptr); } #endif #ifdef PADDLE_WITH_MLU else if (platform::is_mlu_place(src.place())) { // NOLINT memory::Copy( dst_place, dst_ptr, src.place(), src_ptr, size, reinterpret_cast(ctx).stream()); } #endif #ifdef PADDLE_WITH_CUSTOM_DEVICE else if (platform::is_custom_place(src.place())) { // NOLINT memory::Copy(dst_place, dst_ptr, src.place(), src_ptr, size, nullptr); } #endif else { // NOLINT PADDLE_THROW(platform::errors::Unimplemented( "TensorToVector on %s is not supported.", src.place())); } } template <> inline void TensorToVector(const Tensor& src, const platform::DeviceContext& ctx, std::vector* dst) { auto src_ptr = static_cast(src.data()); auto size = src.numel() * sizeof(bool); bool* array = new bool[src.numel()]; platform::CPUPlace dst_place; dst->resize(src.numel()); auto dst_ptr = static_cast(array); if (platform::is_cpu_place(src.place())) { memory::Copy(dst_place, dst_ptr, src.place(), src_ptr, size); } #if defined(PADDLE_WITH_CUDA) || defined(PADDLE_WITH_HIP) else if (platform::is_gpu_place(src.place())) { // NOLINT memory::Copy( dst_place, dst_ptr, src.place(), src_ptr, size, reinterpret_cast(ctx).stream()); } #endif #if defined(PADDLE_WITH_XPU) else if (platform::is_xpu_place(src.place())) { // NOLINT memory::Copy(dst_place, dst_ptr, src.place(), src_ptr, size); } #endif #ifdef PADDLE_WITH_ASCEND_CL else if (platform::is_npu_place(src.place())) { // NOLINT memory::Copy(dst_place, dst_ptr, src.place(), src_ptr, size, nullptr); } #endif #ifdef PADDLE_WITH_MLU else if (platform::is_mlu_place(src.place())) { // NOLINT memory::Copy(dst_place, dst_ptr, src.place(), src_ptr, size, nullptr); } #endif #ifdef PADDLE_WITH_CUSTOM_DEVICE else if (platform::is_custom_place(src.place())) { // NOLINT memory::Copy(dst_place, dst_ptr, src.place(), src_ptr, size, nullptr); } #endif for (unsigned int i = 0; i < src.numel(); i++) { (*dst)[i] = static_cast(array[i]); } delete[] array; } template void TensorToVector(const Tensor& src, std::vector* dst) { auto src_ptr = static_cast(src.data()); auto size = src.numel() * sizeof(T); platform::CPUPlace dst_place; dst->resize(src.numel()); auto dst_ptr = static_cast(dst->data()); PADDLE_ENFORCE_EQ( platform::is_cpu_place(src.place()), true, platform::errors::InvalidArgument( "The input tensor should be CPU device, but actually it is in %s.", src.place())); memory::Copy(dst_place, dst_ptr, src.place(), src_ptr, size); } template <> inline void TensorToVector(const Tensor& src, std::vector* dst) { auto src_ptr = static_cast(src.data()); auto size = src.numel() * sizeof(bool); bool* array = new bool[src.numel()]; platform::CPUPlace dst_place; dst->resize(src.numel()); auto dst_ptr = static_cast(array); PADDLE_ENFORCE_EQ( platform::is_cpu_place(src.place()), true, platform::errors::InvalidArgument( "The input tensor should be CPU device, but actually it is in %s.", src.place())); memory::Copy(dst_place, dst_ptr, src.place(), src_ptr, size); for (unsigned int i = 0; i < src.numel(); i++) { (*dst)[i] = static_cast(array[i]); } delete[] array; } std::ostream& operator<<(std::ostream& os, const LoD& lod); } // namespace framework } // namespace paddle namespace phi { std::ostream& operator<<(std::ostream& os, const DenseTensor& t); }