// Copyright (c) 2018 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/inference/tests/api/tester_helper.h" DEFINE_int32(max_turn_num, 9, "The max turn number: 1 for the small and 9 for the normal."); namespace paddle { namespace inference { using contrib::AnalysisConfig; constexpr int32_t kMaxTurnLen = 50; static std::vector result_data; struct DataRecord { std::vector> *turns; std::vector> *turns_mask; std::vector> response; // response data : 1 std::vector> response_mask; // response mask data : 1 size_t batch_iter{0}; size_t batch_size{1}; size_t num_samples; // total number of samples DataRecord() { turns = new std::vector>[FLAGS_max_turn_num]; // turns data : FLAGS_max_turn_num turns_mask = new std::vector>[FLAGS_max_turn_num]; // turns mask data : FLAGS_max_turn_num } explicit DataRecord(const std::string &path, int batch_size = 1) : DataRecord() { this->batch_size = batch_size; Load(path); } ~DataRecord() { delete[] turns; delete[] turns_mask; } DataRecord NextBatch() { DataRecord data; size_t batch_end = batch_iter + batch_size; // NOTE skip the final batch, if no enough data is provided. if (batch_end <= response.size()) { for (int i = 0; i < FLAGS_max_turn_num; ++i) { data.turns[i].assign(turns[i].begin() + batch_iter, turns[i].begin() + batch_end); } for (int i = 0; i < FLAGS_max_turn_num; ++i) { data.turns_mask[i].assign(turns_mask[i].begin() + batch_iter, turns_mask[i].begin() + batch_end); } data.response.assign(response.begin() + batch_iter, response.begin() + batch_end); data.response_mask.assign(response_mask.begin() + batch_iter, response_mask.begin() + batch_end); CHECK(!data.response.empty()); CHECK(!data.response_mask.empty()); CHECK_EQ(data.response.size(), data.response_mask.size()); } batch_iter += batch_size; return data; } void Load(const std::string &path) { std::ifstream file(path); std::string line; size_t num_lines = 0; result_data.clear(); while (std::getline(file, line)) { num_lines++; std::vector data; split(line, ',', &data); CHECK_EQ(data.size(), (size_t)(2 * FLAGS_max_turn_num + 3)); // load turn data std::vector turns_tmp[FLAGS_max_turn_num]; for (int i = 0; i < FLAGS_max_turn_num; ++i) { split_to_int64(data[i], ' ', &turns_tmp[i]); turns[i].push_back(std::move(turns_tmp[i])); } // load turn_mask data std::vector turns_mask_tmp[FLAGS_max_turn_num]; for (int i = 0; i < FLAGS_max_turn_num; ++i) { split_to_float(data[FLAGS_max_turn_num + i], ' ', &turns_mask_tmp[i]); turns_mask[i].push_back(std::move(turns_mask_tmp[i])); } // load response data std::vector response_tmp; split_to_int64(data[2 * FLAGS_max_turn_num], ' ', &response_tmp); response.push_back(std::move(response_tmp)); // load response_mask data std::vector response_mask_tmp; split_to_float(data[2 * FLAGS_max_turn_num + 1], ' ', &response_mask_tmp); response_mask.push_back(std::move(response_mask_tmp)); // load result data float result_tmp; result_tmp = std::stof(data[2 * FLAGS_max_turn_num + 2]); result_data.push_back(result_tmp); } num_samples = num_lines; } }; void PrepareInputs(std::vector *input_slots, DataRecord *data, int batch_size) { PaddleTensor turns_tensor[FLAGS_max_turn_num]; PaddleTensor turns_mask_tensor[FLAGS_max_turn_num]; PaddleTensor response_tensor; PaddleTensor response_mask_tensor; std::string turn_pre = "turn_"; std::string turn_mask_pre = "turn_mask_"; auto one_batch = data->NextBatch(); int size = one_batch.response[0].size(); CHECK_EQ(size, kMaxTurnLen); // turn tensor assignment for (int i = 0; i < FLAGS_max_turn_num; ++i) { turns_tensor[i].name = turn_pre + std::to_string(i); turns_tensor[i].shape.assign({batch_size, size, 1}); turns_tensor[i].dtype = PaddleDType::INT64; TensorAssignData(&turns_tensor[i], one_batch.turns[i]); } // turn mask tensor assignment for (int i = 0; i < FLAGS_max_turn_num; ++i) { turns_mask_tensor[i].name = turn_mask_pre + std::to_string(i); turns_mask_tensor[i].shape.assign({batch_size, size, 1}); turns_mask_tensor[i].dtype = PaddleDType::FLOAT32; TensorAssignData(&turns_mask_tensor[i], one_batch.turns_mask[i]); } // response tensor assignment response_tensor.name = "response"; response_tensor.shape.assign({batch_size, size, 1}); response_tensor.dtype = PaddleDType::INT64; TensorAssignData(&response_tensor, one_batch.response); // response mask tensor assignment response_mask_tensor.name = "response_mask"; response_mask_tensor.shape.assign({batch_size, size, 1}); response_mask_tensor.dtype = PaddleDType::FLOAT32; TensorAssignData(&response_mask_tensor, one_batch.response_mask); // Set inputs. for (int i = 0; i < FLAGS_max_turn_num; ++i) { input_slots->push_back(std::move(turns_tensor[i])); } for (int i = 0; i < FLAGS_max_turn_num; ++i) { input_slots->push_back(std::move(turns_mask_tensor[i])); } input_slots->push_back(std::move(response_tensor)); input_slots->push_back(std::move(response_mask_tensor)); } void SetConfig(contrib::AnalysisConfig *cfg) { cfg->SetModel(FLAGS_infer_model + "/__model__", FLAGS_infer_model + "/param"); cfg->SwitchSpecifyInputNames(); cfg->SwitchIrOptim(true); } void SetInput(std::vector> *inputs) { DataRecord data(FLAGS_infer_data, FLAGS_batch_size); std::vector input_slots; int test_batch_num = FLAGS_test_all_data ? data.num_samples / FLAGS_batch_size : 1; LOG(INFO) << "The number of samples to be test: " << test_batch_num * FLAGS_batch_size; for (int bid = 0; bid < test_batch_num; ++bid) { input_slots.clear(); PrepareInputs(&input_slots, &data, FLAGS_batch_size); (*inputs).emplace_back(input_slots); } } // Easy for profiling independently. void profile(bool use_mkldnn = false) { contrib::AnalysisConfig cfg; SetConfig(&cfg); if (use_mkldnn) { cfg.EnableMKLDNN(); std::unordered_set op_list = {"conv3d"}; cfg.SetMKLDNNOp(op_list); } std::vector outputs; std::vector> input_slots_all; SetInput(&input_slots_all); TestPrediction(reinterpret_cast(&cfg), input_slots_all, &outputs, FLAGS_num_threads); if (FLAGS_num_threads == 1 && !FLAGS_test_all_data) { PADDLE_ENFORCE_GT(outputs.size(), 0); size_t size = GetSize(outputs[0]); PADDLE_ENFORCE_GT(size, 0); float *result = static_cast(outputs[0].data.data()); for (size_t i = 0; i < size; i++) { EXPECT_NEAR(result[i], result_data[i], 1e-3); } } } TEST(Analyzer_dam, profile) { profile(); } #ifdef PADDLE_WITH_MKLDNN TEST(Analyzer_dam, profile_mkldnn) { profile(true /* use_mkldnn */); } #endif // Check the fuse status TEST(Analyzer_dam, fuse_statis) { contrib::AnalysisConfig cfg; SetConfig(&cfg); int num_ops; auto predictor = CreatePaddlePredictor(cfg); auto fuse_statis = GetFuseStatis( static_cast(predictor.get()), &num_ops); ASSERT_TRUE(fuse_statis.count("fc_fuse")); } // Compare result of NativeConfig and AnalysisConfig void compare(bool use_mkldnn = false) { AnalysisConfig cfg; SetConfig(&cfg); if (use_mkldnn) { cfg.EnableMKLDNN(); std::unordered_set op_list = {"conv3d"}; cfg.SetMKLDNNOp(op_list); } std::vector> input_slots_all; SetInput(&input_slots_all); CompareNativeAndAnalysis( reinterpret_cast(&cfg), input_slots_all); } TEST(Analyzer_dam, compare) { compare(); } #ifdef PADDLE_WITH_MKLDNN TEST(Analyzer_dam, compare_mkldnn) { compare(true /* use_mkldnn */); } #endif // Compare Deterministic result TEST(Analyzer_dam, compare_determine) { AnalysisConfig cfg; SetConfig(&cfg); std::vector> input_slots_all; SetInput(&input_slots_all); CompareDeterministic(reinterpret_cast(&cfg), input_slots_all); } } // namespace inference } // namespace paddle