// Copyright (c) 2021 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/fluid/eager/tests/performance_tests/benchmark_utils.h" #include #include #include #include #include // Eager #include "paddle/fluid/eager/api/all.h" #include "paddle/fluid/eager/autograd_meta.h" #include "paddle/fluid/eager/backward.h" #include "paddle/fluid/eager/tests/test_utils.h" #include "paddle/fluid/eager/utils.h" // Eager Generated #include "paddle/fluid/eager/api/generated/eager_generated/forwards/dygraph_functions.h" #include "paddle/fluid/eager/api/generated/fluid_generated/dygraph_forward_api.h" // Fluid #include "paddle/fluid/framework/op_registry.h" #include "paddle/fluid/imperative/basic_engine.h" #include "paddle/fluid/imperative/tracer.h" #include "paddle/fluid/memory/memcpy.h" static size_t max_num_benchmark_runs = 5000; namespace egr { /* --------------------- */ /* ---- Eager Scale ---- */ /* --------------------- */ void benchmark_eager_scale(const paddle::experimental::Tensor& tensor, bool accuracy_check) { paddle::experimental::Tensor input_tensor = tensor; float scale = 2.0; float bias = 3.0; size_t max_num_runs = accuracy_check ? 10 : max_num_benchmark_runs; for (size_t i = 0; i < max_num_runs; i++) { input_tensor = egr::scale(input_tensor, scale, bias, true /*bias_after_scale*/, true /*trace_backward*/); } std::vector target_tensors = {input_tensor}; Backward(target_tensors, {}); if (accuracy_check) { // Examine Forward Grad (w.r.t max_num_runs = 10) eager_test::CompareTensorWithValue(input_tensor, 8189.0); // Examine Backward Grad (w.r.t max_num_runs = 10) eager_test::CompareGradTensorWithValue(tensor, 1024.0); } } void benchmark_eager_matmul(const paddle::experimental::Tensor& X, const paddle::experimental::Tensor& Y, bool accuracy_check) { paddle::experimental::Tensor input_tensor0 = X; size_t max_num_runs = accuracy_check ? 2 : max_num_benchmark_runs; for (size_t i = 0; i < max_num_runs; i++) { input_tensor0 = matmul_final_state_dygraph_function(input_tensor0, Y, false, false); } std::vector target_tensors = {input_tensor0}; Backward(target_tensors, {}); if (accuracy_check) { // Examine Forward Grad (w.r.t max_num_runs = 2) eager_test::CompareTensorWithValue(input_tensor0, 16); // Examine Backward Grad (w.r.t max_num_runs = 2) eager_test::CompareGradTensorWithValue(X, 16); eager_test::CompareGradTensorWithValue(Y, 16); } } /* ----------------------------------- */ /* ---- Eager Intermediate Matmul ---- */ /* ----------------------------------- */ void benchmark_eager_intermediate_matmul(const paddle::experimental::Tensor& X, const paddle::experimental::Tensor& Y, bool accuracy_check) { paddle::experimental::Tensor input_tensor0 = X; size_t max_num_runs = accuracy_check ? 2 : max_num_benchmark_runs; for (size_t i = 0; i < max_num_runs; i++) { input_tensor0 = matmul_v2_dygraph_function( input_tensor0, Y, {{"trans_x", false}, {"trans_y", false}}); } std::vector target_tensors = {input_tensor0}; Backward(target_tensors, {}); if (accuracy_check) { // Examine Forward Grad (w.r.t max_num_runs = 2) eager_test::CompareTensorWithValue(input_tensor0, 16); // Examine Backward Grad (w.r.t max_num_runs = 2) eager_test::CompareGradTensorWithValue(X, 16); eager_test::CompareGradTensorWithValue(Y, 16); } } /* -------------------------------- */ /* ---- Eager Intermediate MLP ---- */ /* -------------------------------- */ void benchmark_eager_intermediate_mlp( const paddle::experimental::Tensor& X, const std::vector& Ws, const std::vector& Bs, bool accuracy_check) { paddle::experimental::Tensor input0 = X; for (size_t i = 0; i < MLP_NUM_LINEAR; i++) { paddle::experimental::Tensor Out = matmul_v2_dygraph_function( input0, Ws[i], {{"trans_x", false}, {"trans_y", false}}); input0 = elementwise_add_dygraph_function(Out, Bs[i], {}); } paddle::experimental::Tensor Out = reduce_sum_dygraph_function(input0, {{"reduce_all", true}}); std::vector target_tensors = {Out}; Backward(target_tensors, {}); if (accuracy_check) { std::unordered_map result = compute_mlp_expected_results(); // Examine Forward Grad (w.r.t max_num_runs = 2) eager_test::CompareTensorWithValue(Out, result["Out"]); // Examine Backward Grad (w.r.t max_num_runs = 2) eager_test::CompareGradTensorWithValue(X, result["GradX"]); eager_test::CompareGradTensorWithValue(Ws[0], result["GradW"]); } } } // namespace egr namespace paddle { namespace imperative { static void FluidCheckTensorValue(const std::shared_ptr& X, const paddle::platform::Place& place, float value) { auto* tensor = X->MutableVar()->GetMutable(); float* t_ptr = tensor->mutable_data(place); std::vector host_data(tensor->numel()); #if defined(PADDLE_WITH_CUDA) || defined(PADDLE_WITH_HIP) if (place == paddle::platform::CUDAPlace()) { paddle::platform::DeviceContextPool& pool = paddle::platform::DeviceContextPool::Instance(); auto* dev_ctx = dynamic_cast(pool.Get(place)); auto stream = dev_ctx->stream(); paddle::memory::Copy(paddle::platform::CPUPlace(), host_data.data(), paddle::platform::CUDAPlace(), t_ptr, sizeof(float) * tensor->numel(), stream); t_ptr = host_data.data(); } #endif VLOG(6) << "Tensor Value: " << t_ptr[0] << ", Expected Value: " << value; PADDLE_ENFORCE( t_ptr[0] == value, paddle::platform::errors::Fatal( "Detected numerical Error, Expected %f but got %f", value, t_ptr[0])); } static void FluidCheckGradTensorValue( const std::shared_ptr& X, const paddle::platform::Place& place, float value) { auto* grad_tensor = X->MutableGradVar()->GetMutable(); float* g_ptr = grad_tensor->mutable_data(place); std::vector g_host_data(grad_tensor->numel()); #if defined(PADDLE_WITH_CUDA) || defined(PADDLE_WITH_HIP) if (place == paddle::platform::CUDAPlace()) { paddle::platform::DeviceContextPool& pool = paddle::platform::DeviceContextPool::Instance(); auto* dev_ctx = dynamic_cast(pool.Get(place)); auto stream = dev_ctx->stream(); paddle::memory::Copy(paddle::platform::CPUPlace(), g_host_data.data(), paddle::platform::CUDAPlace(), g_ptr, sizeof(float) * grad_tensor->numel(), stream); g_ptr = g_host_data.data(); } #endif VLOG(6) << "Tensor Value: " << g_ptr[0] << ", Expected Value: " << value; PADDLE_ENFORCE( g_ptr[0] == value, paddle::platform::errors::Fatal( "Detected numerical Error, Expected %f but got %f", value, g_ptr[0])); } /* --------------------- */ /* ---- Fluid Scale ---- */ /* --------------------- */ // TODO(jiabin): Change this and remove nolint void benchmark_fluid_scale(const std::shared_ptr& X, const paddle::platform::Place& place, bool accuracy_check) { imperative::Tracer tracer; framework::AttributeMap attrs; attrs["use_mkldnn"] = false; attrs["scale"] = 2; attrs["bias"] = 3; attrs["bias_after_scale"] = true; std::shared_ptr tmp_out = X; size_t max_num_runs = accuracy_check ? 10 : max_num_benchmark_runs; for (size_t i = 0; i < max_num_runs; i++) { imperative::NameVarBaseMap ins = {{"X", {tmp_out}}}; imperative::NameVarBaseMap outs = { {"Out", {std::shared_ptr( new imperative::VarBase(true, "Out"))}}}; tracer.TraceOp("scale", ins, outs, attrs, place, true); tmp_out = outs["Out"][0]; } auto* engine = tracer.GetEngine(); std::vector> grad_tensors{nullptr}; engine->Init({tmp_out}, grad_tensors, false /*retain_graph*/); engine->Execute(); if (accuracy_check) { FluidCheckTensorValue(tmp_out, place, 8189.0); FluidCheckGradTensorValue(X, place, 1024.0); } } /* ---------------------- */ /* ---- Fluid Matmul ---- */ /* ---------------------- */ void benchmark_fluid_matmul(const std::shared_ptr& X, const std::shared_ptr& Y, const paddle::platform::Place& place, bool accuracy_check) { imperative::Tracer tracer; std::shared_ptr tmp_out = X; size_t max_num_runs = accuracy_check ? 2 : max_num_benchmark_runs; for (size_t i = 0; i < max_num_runs; i++) { framework::AttributeMap attrs; imperative::NameVarBaseMap ins = {{"X", {tmp_out}}, {"Y", {Y}}}; imperative::NameVarBaseMap outs = { {"Out", {std::shared_ptr( new imperative::VarBase(true, "Out"))}}}; tracer.TraceOp("matmul_v2", ins, outs, attrs, place, true); tmp_out = outs["Out"][0]; } auto* engine = tracer.GetEngine(); std::vector> grad_tensors{nullptr}; engine->Init({tmp_out}, grad_tensors, false /*retain_graph*/); engine->Execute(); if (accuracy_check) { FluidCheckTensorValue(tmp_out, place, 16); FluidCheckGradTensorValue(X, place, 16); FluidCheckGradTensorValue(Y, place, 16); } } /* ------------------- */ /* ---- Fluid MLP ---- */ /* ------------------- */ void benchmark_fluid_mlp( const std::shared_ptr& X, const std::vector>& Ws, const std::vector>& Bs, const paddle::platform::Place& place, bool accuracy_check) { imperative::Tracer tracer; imperative::NameVarBaseMap ins; imperative::NameVarBaseMap outs; framework::AttributeMap attrs; std::shared_ptr input0 = X; for (size_t i = 0; i < MLP_NUM_LINEAR; i++) { // Matmul0 ins = {{"X", {input0}}, {"Y", {Ws[0]}}}; outs = {{"Out", {std::shared_ptr( new imperative::VarBase(true, "Out"))}}}; tracer.TraceOp("matmul_v2", ins, outs, attrs, place, true); // EW-Add0 ins = {{"X", outs["Out"]}, {"Y", {Bs[i]}}}; outs = {{"Out", {std::shared_ptr( new imperative::VarBase(true, "Out"))}}}; tracer.TraceOp("elementwise_add", ins, outs, attrs, place, true); input0 = outs["Out"][0]; } // ReduceSum ins = {{"X", {input0}}}; outs = {{"Out", {std::shared_ptr( new imperative::VarBase(true, "Out"))}}}; attrs = {{"reduce_all", true}}; tracer.TraceOp("reduce_sum", ins, outs, attrs, place, true); auto* engine = tracer.GetEngine(); std::vector> grad_tensors{nullptr}; engine->Init(outs["Out"], grad_tensors, false /*retain_graph*/); engine->Execute(); if (accuracy_check) { std::unordered_map result = egr::compute_mlp_expected_results(); FluidCheckTensorValue(outs["Out"][0], place, result["Out"]); FluidCheckGradTensorValue(X, place, result["GradX"]); FluidCheckGradTensorValue(Ws[0], place, result["GradW"]); } } } // namespace imperative } // namespace paddle