/* Copyright (c) 2023 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. */ #include "paddle/phi/api/include/tensor_utils.h" #include "glog/logging.h" #include "paddle/phi/api/lib/api_registry.h" #include "paddle/phi/api/lib/data_transform.h" #include "paddle/phi/core/dense_tensor.h" #include "paddle/phi/core/distributed/auto_parallel/reshard/reshard_utils.h" #include "paddle/phi/core/enforce.h" #if defined(PADDLE_WITH_CUDA) || defined(PADDLE_WITH_HIP) #ifdef PADDLE_WITH_CUDA #include #else #include #endif #endif namespace paddle { PD_REGISTER_API(from_blob) PADDLE_API phi::Place GetPlaceFromPtr(void* data) { #if defined(PADDLE_WITH_CUDA) || defined(PADDLE_WITH_HIP) #ifdef PADDLE_WITH_CUDA cudaPointerAttributes attr = {}; cudaError_t status = cudaPointerGetAttributes(&attr, data); if (status == cudaSuccess) { if (attr.type == cudaMemoryTypeDevice) { return phi::GPUPlace(attr.device); } else if (attr.type == cudaMemoryTypeHost) { return phi::GPUPinnedPlace(); } } #else hipPointerAttribute_t attr = {}; hipError_t status = hipPointerGetAttributes(&attr, data); if (status == hipSuccess) { #if defined(PADDLE_ROCM_VERSION) && PADDLE_ROCM_VERSION >= 70000000 if (attr.type == hipMemoryTypeDevice) { return phi::GPUPlace(attr.device); } else if (attr.type == hipMemoryTypeHost) { return phi::GPUPinnedPlace(); } #else if (attr.memoryType == hipMemoryTypeDevice) { return phi::GPUPlace(attr.device); } else if (attr.memoryType == hipMemoryTypeHost) { return phi::GPUPinnedPlace(); } #endif } #endif #endif return phi::CPUPlace(); } struct DeleterManager { static DeleterManager* Instance() { static DeleterManager instance; return &instance; } DeleterManager() = default; void DeletePtr(void* ptr) { std::lock_guard lock(mutex_); auto it = ptr2deleter_.find(ptr); if (it != ptr2deleter_.end()) { it->second(ptr); ptr2deleter_.erase(it); } else { PADDLE_THROW(common::errors::InvalidArgument( "The deleter of the pointer is not found.")); } } void RegisterPtr(void* ptr, const Deleter& deleter) { std::lock_guard lock(mutex_); ptr2deleter_[ptr] = deleter; } private: std::unordered_map ptr2deleter_; std::mutex mutex_; }; using AllocationDeleter = void (*)(phi::Allocation*); Tensor FromBlobImpl(void* data, const phi::DenseTensorMeta& meta, const phi::Place& place, const Deleter& deleter) { PADDLE_ENFORCE_NOT_NULL( data, common::errors::InvalidArgument("data can not be nullptr.")); phi::Place data_place; if (place.GetType() == phi::AllocationType::UNDEFINED || place.GetType() == phi::AllocationType::CPU || place.GetType() == phi::AllocationType::GPU) { data_place = GetPlaceFromPtr(data); if (place.GetType() != phi::AllocationType::UNDEFINED) { PADDLE_ENFORCE_EQ(data_place, place, common::errors::InvalidArgument( "Specified place does not match place of data. ", "Specified: %s, Expected: %s.", data_place.DebugString(), place.DebugString())); } } else { data_place = place; } // Calculate the number of elements of underlying storage size_t size = 1; for (auto i = 0; i < meta.dims.size(); ++i) { if (meta.dims[i] == 0) { size = 0; break; } size += meta.strides[i] * (meta.dims[i] - 1); } AllocationDeleter alloc_deleter = nullptr; if (deleter) { DeleterManager::Instance()->RegisterPtr(data, deleter); alloc_deleter = [](phi::Allocation* p) { DeleterManager::Instance()->DeletePtr(p->ptr()); }; } auto alloc = std::make_shared( data, size * SizeOf(meta.dtype), alloc_deleter, data_place); return Tensor(std::make_shared(alloc, meta)); } PADDLE_API Tensor from_blob(void* data, const phi::IntArray& shape, phi::DataType dtype, phi::DataLayout layout, const phi::Place& place, const Deleter& deleter) { auto meta = phi::DenseTensorMeta(dtype, common::make_ddim(shape.GetData()), layout); return FromBlobImpl(data, meta, place, deleter); } PADDLE_API Tensor from_blob(void* data, const phi::IntArray& shape, const phi::IntArray& strides, phi::DataType dtype, phi::DataLayout layout, const phi::Place& place, const Deleter& deleter) { auto meta = phi::DenseTensorMeta(dtype, common::make_ddim(shape.GetData()), common::make_ddim(strides.GetData())); return FromBlobImpl(data, meta, place, deleter); } #ifdef PADDLE_WITH_DISTRIBUTE PD_REGISTER_API(reshard) PADDLE_API std::shared_ptr reshard( const paddle::Tensor& input, const phi::distributed::TensorDistAttr& dist_attr) { PADDLE_ENFORCE_EQ(input.is_dist_tensor(), true, common::errors::InvalidArgument( "The input tensor of ReshardFunction should be " "``phi::distributed::DistTensor``. " "However it's %s", typeid(input.impl().get()).name())); auto dev_ctx = phi::distributed::GetDistTensorDeviceContext( static_cast(input.impl().get())); const auto& input_tensor_impl = input.impl(); std::shared_ptr dist_out_ptr = nullptr; if (input_tensor_impl) { phi::distributed::DistTensor* dist_tensor = static_cast(input_tensor_impl.get()); if (!IsCurRankInMesh(dist_attr.process_mesh()) && !IsCurRankInMesh(dist_tensor->dist_attr().process_mesh())) { PADDLE_ENFORCE_EQ( dist_tensor->initialized(), false, common::errors::InvalidArgument( "Only " "uninitialized ``phi::distributed::DistTensor`` is allowed. ")); VLOG(4) << "reshard tensor which is not in current mesh, just set its " "dist_attr " << "from " << dist_tensor->dist_attr() << " to " << dist_attr; phi::distributed::DistTensor* dist_tensor = static_cast(input_tensor_impl.get()); dist_out_ptr = std::make_shared( dist_tensor->dims(), dist_attr); phi::DenseTensor* dense_out = dist_out_ptr->unsafe_mutable_value(); *dense_out = dist_tensor->value(); return dist_out_ptr; } if (dist_tensor->dist_attr() != dist_attr) { auto tensor_name = (input.name().empty() ? "None" : input.name()); VLOG(4) << "Reshard func: tensor(" << tensor_name << ") " << paddle::experimental::ReshardDebugInfo(*dist_tensor, dist_attr); auto* func = phi::distributed::ChooseProperReshardFunction(*dist_tensor, dist_attr); dist_out_ptr = func->Eval(dev_ctx, *dist_tensor, dist_attr); } else { dist_out_ptr = std::static_pointer_cast( input_tensor_impl); } } return dist_out_ptr; } #endif } // namespace paddle