// 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" namespace paddle { namespace inference { using namespace framework; // NOLINT struct DataRecord { std::vector>> link_step_data_all; std::vector> week_data_all, minute_data_all; std::vector lod1, lod2, lod3; std::vector> rnn_link_data, rnn_week_datas, rnn_minute_datas; size_t batch_iter{0}; size_t batch_size{1}; DataRecord() = default; explicit DataRecord(const std::string &path, int batch_size = 1) : batch_size(batch_size) { Load(path); } 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 <= link_step_data_all.size()) { data.link_step_data_all.assign(link_step_data_all.begin() + batch_iter, link_step_data_all.begin() + batch_end); data.week_data_all.assign(week_data_all.begin() + batch_iter, week_data_all.begin() + batch_end); data.minute_data_all.assign(minute_data_all.begin() + batch_iter, minute_data_all.begin() + batch_end); // Prepare LoDs data.lod1.push_back(0); data.lod2.push_back(0); data.lod3.push_back(0); CHECK(!data.link_step_data_all.empty()) << "empty"; CHECK(!data.week_data_all.empty()); CHECK(!data.minute_data_all.empty()); CHECK_EQ(data.link_step_data_all.size(), data.week_data_all.size()); CHECK_EQ(data.minute_data_all.size(), data.link_step_data_all.size()); for (size_t j = 0; j < data.link_step_data_all.size(); j++) { for (const auto &d : data.link_step_data_all[j]) { data.rnn_link_data.push_back(d); } data.rnn_week_datas.push_back(data.week_data_all[j]); data.rnn_minute_datas.push_back(data.minute_data_all[j]); // calculate lod data.lod1.push_back(data.lod1.back() + data.link_step_data_all[j].size()); data.lod3.push_back(data.lod3.back() + 1); for (size_t i = 1; i < data.link_step_data_all[j].size() + 1; i++) { data.lod2.push_back(data.lod2.back() + data.link_step_data_all[j].size()); } } } batch_iter += batch_size; return data; } void Load(const std::string &path) { std::ifstream file(path); std::string line; int num_lines = 0; while (std::getline(file, line)) { num_lines++; std::vector data; split(line, ':', &data); std::vector> link_step_data; std::vector link_datas; split(data[0], '|', &link_datas); for (auto &step_data : link_datas) { std::vector tmp; split_to_float(step_data, ',', &tmp); link_step_data.push_back(tmp); } // load week data std::vector week_data; split_to_float(data[2], ',', &week_data); // load minute data std::vector minute_data; split_to_float(data[1], ',', &minute_data); link_step_data_all.push_back(std::move(link_step_data)); week_data_all.push_back(std::move(week_data)); minute_data_all.push_back(std::move(minute_data)); } } }; void PrepareInputs(std::vector *input_slots, DataRecord *data, int batch_size) { PaddleTensor lod_attention_tensor, init_zero_tensor, lod_tensor_tensor, week_tensor, minute_tensor; lod_attention_tensor.name = "data_lod_attention"; init_zero_tensor.name = "cell_init"; lod_tensor_tensor.name = "data"; week_tensor.name = "week"; minute_tensor.name = "minute"; auto one_batch = data->NextBatch(); std::vector rnn_link_data_shape( {static_cast(one_batch.rnn_link_data.size()), static_cast(one_batch.rnn_link_data.front().size())}); lod_attention_tensor.shape.assign({1, 2}); lod_attention_tensor.lod.assign({one_batch.lod1, one_batch.lod2}); init_zero_tensor.shape.assign({batch_size, 15}); init_zero_tensor.lod.assign({one_batch.lod3}); lod_tensor_tensor.shape = rnn_link_data_shape; lod_tensor_tensor.lod.assign({one_batch.lod1}); // clang-format off week_tensor.shape.assign( {static_cast(one_batch.rnn_week_datas.size()), static_cast(one_batch.rnn_week_datas.front().size())}); week_tensor.lod.assign({one_batch.lod3}); minute_tensor.shape.assign( {static_cast(one_batch.rnn_minute_datas.size()), static_cast(one_batch.rnn_minute_datas.front().size())}); minute_tensor.lod.assign({one_batch.lod3}); // clang-format on // assign data TensorAssignData(&lod_attention_tensor, std::vector>({{0, 0}})); std::vector tmp_zeros(batch_size * 15, 0.); TensorAssignData(&init_zero_tensor, {tmp_zeros}); TensorAssignData(&lod_tensor_tensor, one_batch.rnn_link_data); TensorAssignData(&week_tensor, one_batch.rnn_week_datas); TensorAssignData(&minute_tensor, one_batch.rnn_minute_datas); // Set inputs. auto init_zero_tensor1 = init_zero_tensor; init_zero_tensor1.name = "hidden_init"; input_slots->assign({week_tensor, init_zero_tensor, minute_tensor, init_zero_tensor1, lod_attention_tensor, lod_tensor_tensor}); for (auto &tensor : *input_slots) { tensor.dtype = PaddleDType::FLOAT32; } } // Test with a really complicate model. void TestRNN1Prediction(bool use_analysis, bool activate_ir, int num_threads) { AnalysisConfig config; config.prog_file = FLAGS_infer_model + "/__model__"; config.param_file = FLAGS_infer_model + "/param"; config.use_gpu = false; config.device = 0; config.specify_input_name = true; config.enable_ir_optim = activate_ir; PADDLE_ENFORCE(config.ir_mode == AnalysisConfig::IrPassMode::kExclude); // default config.ir_passes.clear(); // Do not exclude any pass. int batch_size = FLAGS_batch_size; auto base_predictor = CreatePaddlePredictor(config); auto predictor = CreatePaddlePredictor( config); std::vector input_slots; DataRecord data(FLAGS_infer_data, batch_size); // Prepare inputs. PrepareInputs(&input_slots, &data, batch_size); std::vector outputs, base_outputs; base_predictor->Run(input_slots, &base_outputs); std::vector> input_slots_all; input_slots_all.emplace_back(input_slots); if (num_threads == 1) { TestOneThreadPrediction(config, input_slots_all, &outputs); CompareResult(outputs, base_outputs); } else { // only return the output of first thread TestMultiThreadPrediction(config, input_slots_all, &outputs, num_threads); } if (use_analysis && activate_ir) { AnalysisPredictor *analysis_predictor = dynamic_cast(predictor.get()); auto &fuse_statis = analysis_predictor->analysis_argument() .Get>( framework::ir::kFuseStatisAttr); for (auto &item : fuse_statis) { LOG(INFO) << "fused " << item.first << " " << item.second; } int num_ops = 0; for (auto &node : analysis_predictor->analysis_argument().main_dfg->nodes.nodes()) { if (node->IsFunction()) { ++num_ops; } } LOG(INFO) << "has num ops: " << num_ops; ASSERT_TRUE(fuse_statis.count("fc_fuse")); EXPECT_EQ(fuse_statis.at("fc_fuse"), 1); EXPECT_EQ(fuse_statis.at("fc_nobias_lstm_fuse"), 2); // bi-directional LSTM EXPECT_EQ(fuse_statis.at("seq_concat_fc_fuse"), 1); EXPECT_EQ(num_ops, 13); // After graph optimization, only 13 operators exists. } } // Inference with analysis and IR, easy for profiling independently. TEST(Analyzer, rnn1) { TestRNN1Prediction(true, true, FLAGS_num_threads); } // Other unit-tests of RNN1, test different options of use_analysis, // activate_ir and multi-threads. TEST(Analyzer, RNN_tests) { int num_threads[2] = {1, 4}; for (auto i : num_threads) { // Directly infer with the original model. TestRNN1Prediction(false, false, i); // Inference with the original model with the analysis turned on, the // analysis module will transform the program to a data flow graph. TestRNN1Prediction(true, false, i); // Inference with analysis and IR. The IR module will fuse some large // kernels. TestRNN1Prediction(true, true, i); } } } // namespace inference } // namespace paddle