/* 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 // NOLINT #include #include #include #include #include #include "glog/logging.h" // For VLOG #include "paddle/fluid/framework/attribute.h" #include "paddle/fluid/framework/block_desc.h" #include "paddle/fluid/framework/framework.pb.h" #include "paddle/fluid/framework/lod_tensor.h" #include "paddle/fluid/framework/op_info.h" #include "paddle/fluid/framework/op_kernel_type.h" #include "paddle/fluid/framework/scope.h" #include "paddle/fluid/framework/selected_rows.h" #include "paddle/fluid/framework/tensor.h" #include "paddle/fluid/framework/unused_var_check.h" #include "paddle/fluid/memory/malloc.h" #include "paddle/fluid/platform/device_context.h" #include "paddle/fluid/platform/variant.h" DECLARE_int32(inner_op_parallelism); namespace paddle { namespace framework { /// If a variable is a empty variable, that name will be used. constexpr char kEmptyVarName[] = "@EMPTY@"; /// If a variable is a temporary variable, that name will be set in Python, /// but it will be convert to a unique name in scope after OpCreator. constexpr char kTempVarName[] = "@TEMP@"; /// If a variable's name has a certain suffix, it means that the /// variable is the gradient of another variable. /// e.g. Variable "x@GRAD" is the gradient of variable "x". constexpr char kGradVarSuffix[] = "@GRAD"; constexpr size_t kGradVarSuffixSize = 5U; /// Variables with this suffix are supposed to be filled up with zeros. constexpr char kZeroVarSuffix[] = "@ZERO"; /// Variables with this suffix are the new Gradient. constexpr char kNewGradSuffix[] = "@NEWGRAD@"; /// Variables with this suffix are the loaded from pre-train model. constexpr char kLoadedVarSuffix[] = "@LOADED"; /// RuntimeContext is used to relate input/output names of Operator with /// the corresponding variables in name scope. /// If an Op has attribute kEnableCacheRuntimeContext, it means that in a same /// name scope, since the input/output names of this Op do not change in the /// execution, RuntimeContext could be created only at the first iteration of /// this Op's execution to save the elapsed time. constexpr char kEnableCacheRuntimeContext[] = "@ENABLE_CACHE_RUNTIME_CONTEXT@"; /// If an Op has this attribute, all its kernels should calculate output /// variable's shape in the corresponding Compute() function. And /// OperatorWithKernel::RunImpl() would skip call this Op's InferShape() /// function in its runtime for speedup. /// TODO(luotao): Note that this temporal attribute would be deleted after all /// ops contain it. constexpr char kAllKernelsMustComputeRuntimeShape[] = "@ALL_KERNELS_MUST_COMPUTE_RUNTIME_SHAPE@"; // define some kernel priority /* Define multiple kernel type fallback order*/ extern std::vector> kKernelPriority; inline std::string GradVarName(const std::string& var_name) { std::string result; result.reserve(var_name.size() + kGradVarSuffixSize); result += var_name; result += kGradVarSuffix; return result; } inline std::string GradOriginalVarName(const std::string& grad_var_name) { std::size_t pos = grad_var_name.rfind(kGradVarSuffix); if (pos == std::string::npos) { return grad_var_name; } else { return grad_var_name.substr(0, pos); } } const Tensor* GetLoDTensorOrSelectedRowsValueFromVar(const Variable& var); Tensor* GetMutableLoDTensorOrSelectedRowsValueFromVar(Variable* var); class OperatorBase; class ExecutionContext; class RuntimeContext { public: RuntimeContext(const VariableNameMap& innames, const VariableNameMap& outnames, const Scope& scope); RuntimeContext(const VariableValueMap& invars, const VariableValueMap& outvars) : inputs(invars), outputs(outvars) {} VariableValueMap inputs; VariableValueMap outputs; }; /** * OperatorBase has the basic elements that Net will call to do computation. * Only CreateOperator from OpRegistry will new Operator directly. User * should always construct a proto message OpDesc and call * OpRegistry::CreateOp(op_desc) to get an Operator instance. */ class OperatorBase { public: OperatorBase(const std::string& type, const VariableNameMap& inputs, const VariableNameMap& outputs, const AttributeMap& attrs); virtual ~OperatorBase() {} /// Executor will call this interface function to Run an op. // The implementation should be written at RunImpl void Run(const Scope& scope, const platform::Place& place); // FIXME(typhoonzero): this is only used for recv_op to stop event_loop. virtual void Stop() {} /// if scope is not null, also show dimensions of arguments virtual std::string DebugStringEx(const Scope* scope) const; std::string DebugString() const { return DebugStringEx(nullptr); } virtual bool SupportGPU() const { return false; } const std::string& Type() const { return type_; } bool HasAttr(const std::string& name) const { return attrs_.count(name); } template inline const T& Attr(const std::string& name) const { PADDLE_ENFORCE_NE( attrs_.find(name), attrs_.end(), platform::errors::NotFound("(%s) is not found in AttributeMap.", name)); return BOOST_GET_CONST(T, attrs_.at(name)); } const AttributeMap& Attrs() const { return attrs_; } const VariableNameMap& Inputs() const { return inputs_; } const VariableNameMap& Outputs() const { return outputs_; } const OpInfo& Info() const { PADDLE_ENFORCE_NOT_NULL( info_, platform::errors::NotFound( "OpInfo of operator (%s) is not found.", type_)); return *info_; } bool HasInputs(const std::string& name) const; //! Get a input with argument's name described in `op_proto` std::string Input(const std::string& name) const; //! Get a input which has multiple variables. const std::vector& Inputs(const std::string& name) const; //! Get all inputs variable names std::vector InputVars() const; bool HasOutputs(const std::string& name) const; //! Get a output with argument's name described in `op_proto` std::string Output(const std::string& name) const; //! Get an output which has multiple variables. //! TODO add a vector_view to prevent memory copy. const std::vector& Outputs(const std::string& name) const; //! Get all outputs variable names virtual std::vector OutputVars(bool has_intermediate) const; void SetIsCalledByExecutor(bool x) { run_by_executor_ = x; } virtual void RuntimeInferShape(const Scope& scope, const platform::Place& place, const RuntimeContext& ctx) const {} virtual platform::Place GetExecutionPlace( const platform::Place& place) const { return place; } protected: std::string type_; // NOTE: in case of OpGrad, inputs_ contains: // I (Inputs) // O (Outputs) // OG (Output Gradients) VariableNameMap inputs_; // NOTE: in case of OpGrad, outputs_ contains // IG (Inputs Gradients) VariableNameMap outputs_; AttributeMap attrs_; // OpInfo const OpInfo* info_; // Whether this operator executes in an Executor. bool run_by_executor_{true}; private: void GenerateTemporaryNames(); void CheckAllInputOutputSet() const; virtual void RunImpl(const Scope& scope, const platform::Place& place) const = 0; }; class ExecutionContext { public: ExecutionContext(const OperatorBase& op, const Scope& scope, const platform::DeviceContext& device_context, const RuntimeContext& ctx) : op_(op), scope_(scope), device_context_(device_context), ctx_(ctx) {} virtual ~ExecutionContext() {} virtual std::string InputName(const std::string& name) const { return op_.Input(name); } virtual std::vector InputNames(const std::string& name) const { return op_.Inputs(name); } virtual std::string OutputName(const std::string& name) const { return op_.Output(name); } virtual std::vector OutputNames(const std::string& name) const { return op_.Outputs(name); } virtual bool HasAttr(const std::string& name) const { return op_.HasAttr(name); } virtual const AttributeMap& Attrs() const { return op_.Attrs(); } const std::string& Type() const { return op_.Type(); } const Scope& scope() const { return scope_; } template inline const T& Attr(const std::string& name) const { return BOOST_GET_CONST(T, GetAttr(name)); } virtual const Attribute& GetAttr(const std::string& name) const { return op_.Attrs().at(name); } virtual bool HasInput(const std::string& name) const; virtual bool HasOutput(const std::string& name) const; virtual size_t InputSize(const std::string& name) const { return op_.Inputs(name).size(); } virtual size_t OutputSize(const std::string& name) const { return op_.Outputs(name).size(); } virtual const Variable* InputVar(const std::string& name) const; virtual Variable* OutputVar(const std::string& name) const; virtual const std::vector MultiInputVar( const std::string& name) const { LogVarUsageIfUnusedVarCheckEnabled(name); auto it = ctx_.inputs.find(name); if (it == ctx_.inputs.end()) { return {}; } return {it->second.begin(), it->second.end()}; } virtual std::vector MultiOutputVar(const std::string& name) const { auto it = ctx_.outputs.find(name); if (it == ctx_.outputs.end()) { return {}; } return it->second; } virtual std::vector InNameList() const { std::vector vec_temp; vec_temp.reserve(ctx_.inputs.size()); for (auto& input : ctx_.inputs) { vec_temp.push_back(input.first); } return vec_temp; } template const T* Input(const std::string& name) const { auto* var = InputVar(name); return var == nullptr ? nullptr : &var->Get(); } template T* Output(const std::string& name) const { auto var = OutputVar(name); return var == nullptr ? nullptr : var->GetMutable(); } template const std::vector MultiInput(const std::string& name) const { LogVarUsageIfUnusedVarCheckEnabled(name); auto vars = MultiInputVar(name); if (vars.size() == 0) { return {}; } std::vector res; res.reserve(vars.size()); std::transform(vars.begin(), vars.end(), std::back_inserter(res), [&](const Variable* var) -> const T* { return var == nullptr ? nullptr : &var->Get(); }); return res; } template std::vector MultiOutput(const std::string& name) const { auto vars = MultiOutputVar(name); if (vars.size() == 0) { return {}; } std::vector res; res.reserve(vars.size()); std::transform(vars.begin(), vars.end(), std::back_inserter(res), [&](Variable* var) -> T* { return var == nullptr ? nullptr : var->GetMutable(); }); return res; } platform::Place GetPlace() const { return device_context_.GetPlace(); } template const DeviceContextType& device_context() const { return *reinterpret_cast(&device_context_); } const platform::DeviceContext& device_context() const { return device_context_; } #ifdef PADDLE_WITH_CUDA const inline platform::CUDADeviceContext& cuda_device_context() const { PADDLE_ENFORCE_EQ(platform::is_gpu_place(device_context_.GetPlace()), true, platform::errors::PreconditionNotMet( "Current device context place is not GPUPlace.")); return *reinterpret_cast( &device_context_); } #endif template Tensor AllocateTmpTensor(const framework::DDim& dim, const DevContext& dev_ctx) const { auto tmp_allocation_ptr = memory::Alloc(dev_ctx, product(dim) * sizeof(T)); auto& deleter = tmp_allocation_ptr.get_deleter(); auto* allocation_ptr = tmp_allocation_ptr.release(); auto shared_allocation = std::shared_ptr( allocation_ptr, deleter); PADDLE_ENFORCE_GE( allocation_ptr->size(), framework::product(dim) * sizeof(T), platform::errors::PreconditionNotMet( "The data memory size(%d) is less than the tensor needed memory " "size(%d).", allocation_ptr->size(), framework::product(dim) * sizeof(T))); paddle::framework::Tensor temp_tensor( framework::ToDataType(std::type_index(typeid(T)))); temp_tensor.Resize(dim); temp_tensor.ResetHolder(std::move(shared_allocation)); return temp_tensor; } const RuntimeContext Context() const { return ctx_; } std::string DebugString() const { return op_.DebugString(); } private: const OperatorBase& op_; const Scope& scope_; const platform::DeviceContext& device_context_; const RuntimeContext& ctx_; }; template <> const Tensor* ExecutionContext::Input(const std::string& name) const; template <> const std::vector ExecutionContext::MultiInput( const std::string& name) const; template <> Tensor* ExecutionContext::Output(const std::string& name) const; template <> std::vector ExecutionContext::MultiOutput( const std::string& name) const; class OpKernelBase { public: /** * ExecutionContext is the only parameter of Kernel Run function. * Run will get input/output variables, state such as momentum and * device resource such as CUDA stream, cublas handle, etc. from * ExecutionContext. User should construct it before run the Operator. */ virtual void Compute(const ExecutionContext& context) const = 0; virtual ~OpKernelBase() = default; }; template class OpKernel : public OpKernelBase { public: using ELEMENT_TYPE = T; }; class OperatorWithKernel : public OperatorBase { public: using OpKernelFunc = std::function; using OpKernelMap = std::unordered_map; OperatorWithKernel(const std::string& type, const VariableNameMap& inputs, const VariableNameMap& outputs, const AttributeMap& attrs) : OperatorBase(type, inputs, outputs, attrs) {} static std::unordered_map& AllOpKernels() { static std::unordered_map g_all_op_kernels; return g_all_op_kernels; } bool IsMKLDNNType() const { return ((this->kernel_type_) && (this->kernel_type_->data_layout_ == framework::DataLayout::kMKLDNN)); } bool SupportGPU() const override { auto& op_kernels = OperatorWithKernel::AllOpKernels().at(type_); return std::any_of(op_kernels.begin(), op_kernels.end(), [](OpKernelMap::const_reference kern_pair) { return platform::is_gpu_place(kern_pair.first.place_); }); } virtual void InferShape(InferShapeContext* ctx) const = 0; void RuntimeInferShape(const Scope& scope, const platform::Place& place, const RuntimeContext& ctx) const override; proto::VarType::Type IndicateVarDataType(const ExecutionContext& ctx, const std::string& name) const; virtual OpKernelType GetExpectedKernelType(const ExecutionContext& ctx) const; // change this to public so that in dygraph mode we can call it to check if we // need transform data virtual OpKernelType GetKernelTypeForVar( const std::string& var_name, const Tensor& tensor, const OpKernelType& expected_kernel_type) const; platform::Place GetExecutionPlace( const platform::Place& platform) const override { return kernel_type_->place_; } private: void ParseInputDataType(const ExecutionContext& ctx, const std::string& name, proto::VarType::Type* type) const; // indicate kernel DataType by input data. By default all input data must be // same. proto::VarType::Type IndicateDataType(const ExecutionContext& ctx) const; void RunImpl(const Scope& scope, const platform::Place& place) const final; void RunImpl(const Scope& scope, const platform::Place& place, RuntimeContext* runtime_ctx) const; /** * Transfer data from scope to a transferred scope. If there is no data need * to * be tranfered, it returns nullptr. * * * transfered_inplace_vars is a output vector. */ Scope* PrepareData(const Scope& scope, const OpKernelType& expected_kernel_key, std::vector* transfered_inplace_vars, RuntimeContext* ctx) const; void TransferInplaceVarsBack(const Scope& scope, const std::vector& inplace_vars, const Scope& exec_scope) const; void ChooseKernel(const RuntimeContext& ctx, const Scope& scope, const platform::Place& place) const; protected: mutable std::unique_ptr kernel_type_; mutable std::unique_ptr kernel_func_; mutable std::unique_ptr runtime_ctx_; mutable const Scope* pre_scope_ = nullptr; mutable bool need_prepare_data_ = true; mutable bool enable_cache_runtime_context_ = false; mutable bool all_kernels_must_compute_runtime_shape_ = false; mutable std::mutex cache_update_mutex_; mutable bool enable_cache_transfer_scope_ = false; }; extern bool OpSupportGPU(const std::string& op_type); } // namespace framework } // namespace paddle