/* 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. */ #include "paddle/fluid/framework/data_feed.h" #include #include #include "gflags/gflags.h" #include "google/protobuf/io/zero_copy_stream_impl.h" #include "google/protobuf/message.h" #include "google/protobuf/text_format.h" #include "io/fs.h" #include "io/shell.h" #include "paddle/fluid/framework/feed_fetch_method.h" #include "paddle/fluid/framework/feed_fetch_type.h" namespace paddle { namespace framework { std::vector DataFeed::filelist_; size_t DataFeed::file_idx_; std::mutex DataFeed::mutex_for_pick_file_; bool DataFeed::finish_set_filelist_; void DataFeed::AddFeedVar(Variable* var, const std::string& name) { CheckInit(); for (size_t i = 0; i < use_slots_.size(); ++i) { if (name == use_slots_[i]) { feed_vec_[i] = var->GetMutable(); } } } bool DataFeed::SetFileList(const std::vector& files) { std::unique_lock lock(mutex_for_pick_file_); CheckInit(); // Do not set finish_set_filelist_ flag, // since a user may set file many times after init reader /* if (finish_set_filelist_) { VLOG(3) << "info: you have set the filelist."; return false; } */ PADDLE_ENFORCE(files.size(), "You have set an empty filelist."); filelist_.assign(files.begin(), files.end()); file_idx_ = 0; finish_set_filelist_ = true; return true; } void DataFeed::SetBatchSize(int batch_size) { PADDLE_ENFORCE(batch_size > 0, "Illegal batch size: %d.", batch_size); default_batch_size_ = batch_size; } bool DataFeed::PickOneFile(std::string* filename) { std::unique_lock lock(mutex_for_pick_file_); if (file_idx_ == filelist_.size()) { VLOG(3) << "DataFeed::PickOneFile no more file to pick"; return false; } VLOG(3) << "file_idx_=" << file_idx_; *filename = filelist_[file_idx_++]; // LOG(ERROR) << "pick file:" << *filename; return true; } void DataFeed::CheckInit() { PADDLE_ENFORCE(finish_init_, "Initialization did not succeed."); } void DataFeed::CheckSetFileList() { PADDLE_ENFORCE(finish_set_filelist_, "Set filelist did not succeed."); } void DataFeed::CheckStart() { PADDLE_ENFORCE(finish_start_, "Datafeed has not started running yet."); } template void PrivateQueueDataFeed::SetQueueSize(int queue_size) { PADDLE_ENFORCE(queue_size > 0, "Illegal queue size: %d.", queue_size); queue_size_ = queue_size; queue_ = std::unique_ptr>( new paddle::operators::reader::BlockingQueue(queue_size_)); } template bool PrivateQueueDataFeed::Start() { CheckSetFileList(); read_thread_ = std::thread(&PrivateQueueDataFeed::ReadThread, this); read_thread_.detach(); finish_start_ = true; return true; } template void PrivateQueueDataFeed::ReadThread() { std::string filename; while (PickOneFile(&filename)) { int err_no = 0; fp_ = fs_open_read(filename, &err_no, pipe_command_); __fsetlocking(&*fp_, FSETLOCKING_BYCALLER); thread_local string::LineFileReader reader; T instance; while (ParseOneInstanceFromPipe(&instance)) { queue_->Send(instance); } } queue_->Close(); } template int PrivateQueueDataFeed::Next() { CheckStart(); int index = 0; T instance; T ins_vec; while (index < default_batch_size_) { if (!queue_->Receive(&instance)) { break; } AddInstanceToInsVec(&ins_vec, instance, index++); } batch_size_ = index; if (batch_size_ != 0) { PutToFeedVec(ins_vec); } return batch_size_; } // explicit instantiation template class PrivateQueueDataFeed>; template InMemoryDataFeed::InMemoryDataFeed() { cur_channel_ = 0; shuffled_ins_ = std::make_shared>(); shuffled_ins_out_ = std::make_shared>(); fleet_send_batch_size_ = 10000; } template bool InMemoryDataFeed::Start() { DataFeed::CheckSetFileList(); if (shuffled_ins_->Size() == 0 && shuffled_ins_out_->Size() == 0) { FillMemoryDataToChannel(); } DataFeed::finish_start_ = true; return true; } template int InMemoryDataFeed::Next() { DataFeed::CheckStart(); std::shared_ptr> in_channel = nullptr; std::shared_ptr> out_channel = nullptr; if (cur_channel_ == 0) { in_channel = shuffled_ins_; out_channel = shuffled_ins_out_; } else { in_channel = shuffled_ins_out_; out_channel = shuffled_ins_; } CHECK(in_channel != nullptr); CHECK(out_channel != nullptr); int index = 0; T instance; T ins_vec; while (index < DataFeed::default_batch_size_) { if (in_channel->Size() == 0) { break; } in_channel->Pop(instance); AddInstanceToInsVec(&ins_vec, instance, index++); out_channel->Push(std::move(instance)); } DataFeed::batch_size_ = index; if (DataFeed::batch_size_ != 0) { PutToFeedVec(ins_vec); } else { cur_channel_ = 1 - cur_channel_; } return DataFeed::batch_size_; } template void InMemoryDataFeed::SetMemoryData(void* memory_data) { memory_data_ = static_cast*>(memory_data); } template void InMemoryDataFeed::SetMemoryDataMutex(std::mutex* mutex) { mutex_for_update_memory_data_ = mutex; } template void InMemoryDataFeed::SetThreadId(int thread_id) { thread_id_ = thread_id; } template void InMemoryDataFeed::SetThreadNum(int thread_num) { thread_num_ = thread_num; } template void InMemoryDataFeed::SetTrainerNum(int trainer_num) { trainer_num_ = trainer_num; } template void InMemoryDataFeed::PutInsToChannel(const std::string& ins_str) { T ins; DeserializeIns(&ins, ins_str); shuffled_ins_->Push(std::move(ins)); } template void InMemoryDataFeed::FillMemoryDataToChannel() { VLOG(3) << "FillMemoryDataToChannel, thread_id=" << thread_id_; int64_t start = 0; int64_t end = 0; int64_t size = memory_data_->size(); VLOG(3) << "memory_data size=" << size; for (int64_t i = 0; i <= static_cast(thread_id_); ++i) { int64_t len = size / static_cast(thread_num_) + (i < (size % static_cast(thread_num_))); start = end; end += len; } for (int64_t i = start; i < end; ++i) { T& t = (*memory_data_)[i]; shuffled_ins_->Push(std::move(t)); } } template void InMemoryDataFeed::FillChannelToMemoryData() { VLOG(3) << "FillChannelToMemoryData, thread_id=" << thread_id_; std::vector local_vec; std::shared_ptr> channel = nullptr; if (cur_channel_ == 0) { channel = shuffled_ins_; } else { channel = shuffled_ins_out_; } CHECK(channel != nullptr); local_vec.reserve(channel->Size()); for (int64_t i = 0; i < channel->Size(); ++i) { channel->Pop(local_vec[i]); } std::unique_lock lock(*mutex_for_update_memory_data_); lock.lock(); memory_data_->insert(memory_data_->end(), local_vec.begin(), local_vec.end()); lock.unlock(); std::vector().swap(local_vec); } template void InMemoryDataFeed::LoadIntoMemory() { VLOG(3) << "LoadIntoMemory() begin, thread_id=" << thread_id_; std::vector local_vec; std::string filename; while (DataFeed::PickOneFile(&filename)) { VLOG(3) << "PickOneFile, filename=" << filename << ", thread_id=" << thread_id_; int err_no = 0; PrivateQueueDataFeed::fp_ = fs_open_read(filename, &err_no, PrivateQueueDataFeed::pipe_command_); __fsetlocking(&*PrivateQueueDataFeed::fp_, FSETLOCKING_BYCALLER); T instance; while (ParseOneInstanceFromPipe(&instance)) { local_vec.push_back(instance); } VLOG(3) << "LoadIntoMemory() read all lines, file=" << filename <<", thread_id=" << thread_id_; { std::lock_guard lock(*mutex_for_update_memory_data_); memory_data_->insert(memory_data_->end(), local_vec.begin(), local_vec.end()); } std::vector().swap(local_vec); } VLOG(3) << "LoadIntoMemory() end, thread_id=" << thread_id_; } template void InMemoryDataFeed::LocalShuffle() { VLOG(3) << "LocalShuffle() begin, thread_id=" << thread_id_; FillMemoryDataToChannel(); VLOG(3) << "LocalShuffle() end, thread_id=" << thread_id_; } template void InMemoryDataFeed::GlobalShuffle() { VLOG(3) << "GlobalShuffle(), thread_id=" << thread_id_; auto fleet_ptr = FleetWrapper::GetInstance(); std::vector send_str_vec(trainer_num_); for (int64_t i = 0; i < memory_data_->size(); ++i) { // todo get ins id // std::string ins_id = memory_data_[i].ins_id; // todo hash int64_t random_num = fleet_ptr->local_random_engine()(); int64_t node_id = random_num % trainer_num_; std::string str; SerializeIns((*memory_data_)[i], &str); send_str_vec[node_id] += str; if (i % fleet_send_batch_size_ == 0 && i != 0) { for (int j = 0; j < send_str_vec.size(); ++j) { fleet_ptr->send_client2client_msg(0, j, send_str_vec[j]); send_str_vec[j] = ""; } } } for (int j = 0; j < send_str_vec.size(); ++j) { if (send_str_vec[j].length() != 0) { fleet_ptr->send_client2client_msg(0, j, send_str_vec[j]); } } } // explicit instantiation template class InMemoryDataFeed>; void MultiSlotDataFeed::Init( const paddle::framework::DataFeedDesc& data_feed_desc) { finish_init_ = false; finish_set_filelist_ = false; finish_start_ = false; PADDLE_ENFORCE(data_feed_desc.has_multi_slot_desc(), "Multi_slot_desc has not been set."); paddle::framework::MultiSlotDesc multi_slot_desc = data_feed_desc.multi_slot_desc(); SetBatchSize(data_feed_desc.batch_size()); SetQueueSize(data_feed_desc.batch_size()); size_t all_slot_num = multi_slot_desc.slots_size(); all_slots_.resize(all_slot_num); all_slots_type_.resize(all_slot_num); use_slots_index_.resize(all_slot_num); use_slots_.clear(); use_slots_is_dense_.clear(); for (size_t i = 0; i < all_slot_num; ++i) { const auto& slot = multi_slot_desc.slots(i); all_slots_[i] = slot.name(); all_slots_type_[i] = slot.type(); use_slots_index_[i] = slot.is_used() ? use_slots_.size() : -1; if (slot.is_used()) { use_slots_.push_back(all_slots_[i]); use_slots_is_dense_.push_back(slot.is_dense()); } } feed_vec_.resize(use_slots_.size()); pipe_command_ = data_feed_desc.pipe_command(); finish_init_ = true; } void MultiSlotDataFeed::ReadThread() { std::string filename; while (PickOneFile(&filename)) { int err_no = 0; fp_ = fs_open_read(filename, &err_no, pipe_command_); CHECK(fp_ != nullptr); __fsetlocking(&*fp_, FSETLOCKING_BYCALLER); thread_local string::LineFileReader reader; std::vector instance; int ins_num = 0; while (ParseOneInstanceFromPipe(&instance)) { ins_num++; queue_->Send(instance); } VLOG(3) << "filename: " << filename << " inst num: " << ins_num; } queue_->Close(); } bool MultiSlotDataFeed::CheckFile(const char* filename) { CheckInit(); // get info of slots std::ifstream fin(filename); if (!fin.good()) { VLOG(1) << "error: open file<" << filename << "> fail"; return false; } std::string line; int instance_cout = 0; std::string all_slots_alias = ""; for (const auto& alias : all_slots_) { all_slots_alias += alias + " "; } std::string use_slots_alias = ""; for (const auto& alias : use_slots_) { use_slots_alias += alias + " "; } VLOG(3) << "total slots num: " << all_slots_.size(); VLOG(3) << "total slots alias: " << all_slots_alias; VLOG(3) << "used slots num: " << use_slots_.size(); VLOG(3) << "used slots alias: " << use_slots_alias; while (getline(fin, line)) { ++instance_cout; const char* str = line.c_str(); char* endptr = const_cast(str); int len = line.length(); for (size_t i = 0; i < all_slots_.size(); ++i) { int num = strtol(endptr, &endptr, 10); if (num < 0) { VLOG(0) << "error: the number of ids is a negative number: " << num; VLOG(0) << "please check line<" << instance_cout << "> in file<" << filename << ">"; return false; } else if (num == 0) { VLOG(0) << "error: the number of ids can not be zero, you need " "padding it in data generator; or if there is something wrong" " with the data, please check if the data contains unresolvable " "characters."; VLOG(0) << "please check line<" << instance_cout << "> in file<" << filename << ">"; return false; } else if (errno == ERANGE || num > INT_MAX) { VLOG(0) << "error: the number of ids greater than INT_MAX"; VLOG(0) << "please check line<" << instance_cout << "> in file<" << filename << ">"; return false; } if (all_slots_type_[i] == "float") { for (int i = 0; i < num; ++i) { strtof(endptr, &endptr); if (errno == ERANGE) { VLOG(0) << "error: the value is out of the range of " "representable values for float"; VLOG(0) << "please check line<" << instance_cout << "> in file<" << filename << ">"; return false; } if (i + 1 != num && endptr - str == len) { VLOG(0) << "error: there is a wrong with the number of ids."; VLOG(0) << "please check line<" << instance_cout << "> in file<" << filename << ">"; return false; } } } else if (all_slots_type_[i] == "uint64") { for (int i = 0; i < num; ++i) { strtoull(endptr, &endptr, 10); if (errno == ERANGE) { VLOG(0) << "error: the value is out of the range of " "representable values for uint64_t"; VLOG(0) << "please check line<" << instance_cout << "> in file<" << filename << ">"; return false; } if (i + 1 != num && endptr - str == len) { VLOG(0) << "error: there is a wrong with the number of ids."; VLOG(0) << "please check line<" << instance_cout << "> in file<" << filename << ">"; return false; } } } else { VLOG(0) << "error: this type<" << all_slots_type_[i] << "> is not supported"; return false; } } // It may be added '\t' character to the end of the output of reduce // task when processes data by Hadoop(when the output of the reduce // task of Hadoop has only one field, it will add a '\t' at the end // of the line by default, and you can use this option to avoid it: // `-D mapred.textoutputformat.ignoreseparator=true`), which does // not affect the correctness of the data. Therefore, it should be // judged that the data is not normal when the end of each line of // data contains characters which are not spaces. while (endptr - str != len) { if (!isspace(*(endptr++))) { VLOG(0) << "error: there is some extra characters at the end of the line."; VLOG(0) << "please check line<" << instance_cout << "> in file<" << filename << ">"; return false; } } } VLOG(3) << "instances cout: " << instance_cout; VLOG(3) << "The file format is correct"; return true; } bool MultiSlotDataFeed::ParseOneInstanceFromPipe( std::vector* instance) { thread_local string::LineFileReader reader; if (!reader.getline(&*(fp_.get()))) { return false; } else { int use_slots_num = use_slots_.size(); instance->resize(use_slots_num); const char* str = reader.get(); std::string line = std::string(str); VLOG(3) << line; char* endptr = const_cast(str); int pos = 0; for (size_t i = 0; i < use_slots_index_.size(); ++i) { int idx = use_slots_index_[i]; int num = strtol(&str[pos], &endptr, 10); PADDLE_ENFORCE( num, "The number of ids can not be zero, you need padding " "it in data generator; or if there is something wrong with " "the data, please check if the data contains unresolvable " "characters.\nplease check this error line: %s", str); if (idx != -1) { (*instance)[idx].Init(all_slots_type_[i]); if ((*instance)[idx].GetType()[0] == 'f') { // float for (int j = 0; j < num; ++j) { float feasign = strtof(endptr, &endptr); (*instance)[idx].AddValue(feasign); } } else if ((*instance)[idx].GetType()[0] == 'u') { // uint64 for (int j = 0; j < num; ++j) { uint64_t feasign = (uint64_t)strtoull(endptr, &endptr, 10); (*instance)[idx].AddValue(feasign); } } pos = endptr - str; } else { for (int j = 0; j <= num; ++j) { // pos = line.find_first_of(' ', pos + 1); while (line[pos + 1] != ' ') { pos++; } } } } return true; } } bool MultiSlotDataFeed::ParseOneInstance(std::vector* instance) { std::string line; if (getline(file_, line)) { int use_slots_num = use_slots_.size(); instance->resize(use_slots_num); // parse line const char* str = line.c_str(); char* endptr = const_cast(str); int pos = 0; for (size_t i = 0; i < use_slots_index_.size(); ++i) { int idx = use_slots_index_[i]; int num = strtol(&str[pos], &endptr, 10); PADDLE_ENFORCE( num, "The number of ids can not be zero, you need padding " "it in data generator; or if there is something wrong with " "the data, please check if the data contains unresolvable " "characters.\nplease check this error line: %s", str); if (idx != -1) { (*instance)[idx].Init(all_slots_type_[i]); if ((*instance)[idx].GetType()[0] == 'f') { // float for (int j = 0; j < num; ++j) { float feasign = strtof(endptr, &endptr); (*instance)[idx].AddValue(feasign); } } else if ((*instance)[idx].GetType()[0] == 'u') { // uint64 for (int j = 0; j < num; ++j) { uint64_t feasign = (uint64_t)strtoull(endptr, &endptr, 10); (*instance)[idx].AddValue(feasign); } } pos = endptr - str; } else { for (int j = 0; j <= num; ++j) { pos = line.find_first_of(' ', pos + 1); } } } } else { return false; } return true; } void MultiSlotDataFeed::AddInstanceToInsVec( std::vector* ins_vec, const std::vector& instance, int index) { if (index == 0) { ins_vec->resize(instance.size()); for (size_t i = 0; i < instance.size(); ++i) { (*ins_vec)[i].Init(instance[i].GetType()); (*ins_vec)[i].InitOffset(); } } for (size_t i = 0; i < instance.size(); ++i) { (*ins_vec)[i].AddIns(instance[i]); } } void MultiSlotDataFeed::PutToFeedVec( const std::vector& ins_vec) { for (size_t i = 0; i < use_slots_.size(); ++i) { const auto& type = ins_vec[i].GetType(); const auto& offset = ins_vec[i].GetOffset(); int total_instance = static_cast(offset.back()); if (type[0] == 'f') { // float const auto& feasign = ins_vec[i].GetFloatData(); float* tensor_ptr = feed_vec_[i]->mutable_data( {total_instance, 1}, platform::CPUPlace()); memcpy(tensor_ptr, &feasign[0], total_instance * sizeof(float)); } else if (type[0] == 'u') { // uint64 // no uint64_t type in paddlepaddle const auto& feasign = ins_vec[i].GetUint64Data(); int64_t* tensor_ptr = feed_vec_[i]->mutable_data( {total_instance, 1}, platform::CPUPlace()); memcpy(tensor_ptr, &feasign[0], total_instance * sizeof(int64_t)); } LoD data_lod{offset}; feed_vec_[i]->set_lod(data_lod); if (use_slots_is_dense_[i]) { int dim = total_instance / batch_size_; feed_vec_[i]->Resize({batch_size_, dim}); } } } void MultiSlotInMemoryDataFeed::Init( const paddle::framework::DataFeedDesc& data_feed_desc) { finish_init_ = false; finish_set_filelist_ = false; finish_start_ = false; PADDLE_ENFORCE(data_feed_desc.has_multi_slot_desc(), "Multi_slot_desc has not been set."); paddle::framework::MultiSlotDesc multi_slot_desc = data_feed_desc.multi_slot_desc(); SetBatchSize(data_feed_desc.batch_size()); SetQueueSize(data_feed_desc.batch_size()); size_t all_slot_num = multi_slot_desc.slots_size(); all_slots_.resize(all_slot_num); all_slots_type_.resize(all_slot_num); use_slots_index_.resize(all_slot_num); use_slots_.clear(); use_slots_is_dense_.clear(); for (size_t i = 0; i < all_slot_num; ++i) { const auto& slot = multi_slot_desc.slots(i); all_slots_[i] = slot.name(); all_slots_type_[i] = slot.type(); use_slots_index_[i] = slot.is_used() ? use_slots_.size() : -1; if (slot.is_used()) { use_slots_.push_back(all_slots_[i]); use_slots_is_dense_.push_back(slot.is_dense()); } } feed_vec_.resize(use_slots_.size()); pipe_command_ = data_feed_desc.pipe_command(); finish_init_ = true; } bool MultiSlotInMemoryDataFeed::ParseOneInstanceFromPipe( std::vector* instance) { thread_local string::LineFileReader reader; if (!reader.getline(&*(fp_.get()))) { return false; } else { int use_slots_num = use_slots_.size(); instance->resize(use_slots_num); const char* str = reader.get(); std::string line = std::string(str); VLOG(3) << line; char* endptr = const_cast(str); int pos = 0; for (size_t i = 0; i < use_slots_index_.size(); ++i) { int idx = use_slots_index_[i]; int num = strtol(&str[pos], &endptr, 10); PADDLE_ENFORCE( num, "The number of ids can not be zero, you need padding " "it in data generator; or if there is something wrong with " "the data, please check if the data contains unresolvable " "characters.\nplease check this error line: %s", str); if (idx != -1) { (*instance)[idx].Init(all_slots_type_[i]); if ((*instance)[idx].GetType()[0] == 'f') { // float for (int j = 0; j < num; ++j) { float feasign = strtof(endptr, &endptr); (*instance)[idx].AddValue(feasign); } } else if ((*instance)[idx].GetType()[0] == 'u') { // uint64 for (int j = 0; j < num; ++j) { uint64_t feasign = (uint64_t)strtoull(endptr, &endptr, 10); (*instance)[idx].AddValue(feasign); } } pos = endptr - str; } else { for (int j = 0; j <= num; ++j) { // pos = line.find_first_of(' ', pos + 1); while (line[pos + 1] != ' ') { pos++; } } } } return true; } } bool MultiSlotInMemoryDataFeed::ParseOneInstance( std::vector* instance) { std::string line; if (getline(file_, line)) { int use_slots_num = use_slots_.size(); instance->resize(use_slots_num); VLOG(3) << line; // parse line const char* str = line.c_str(); char* endptr = const_cast(str); int pos = 0; for (size_t i = 0; i < use_slots_index_.size(); ++i) { int idx = use_slots_index_[i]; int num = strtol(&str[pos], &endptr, 10); PADDLE_ENFORCE( num, "The number of ids can not be zero, you need padding " "it in data generator; or if there is something wrong with " "the data, please check if the data contains unresolvable " "characters.\nplease check this error line: %s", str); if (idx != -1) { (*instance)[idx].Init(all_slots_type_[i]); if ((*instance)[idx].GetType()[0] == 'f') { // float for (int j = 0; j < num; ++j) { float feasign = strtof(endptr, &endptr); (*instance)[idx].AddValue(feasign); } } else if ((*instance)[idx].GetType()[0] == 'u') { // uint64 for (int j = 0; j < num; ++j) { uint64_t feasign = (uint64_t)strtoull(endptr, &endptr, 10); (*instance)[idx].AddValue(feasign); } } pos = endptr - str; } else { for (int j = 0; j <= num; ++j) { pos = line.find_first_of(' ', pos + 1); } } } } else { return false; } return true; } void MultiSlotInMemoryDataFeed::AddInstanceToInsVec( std::vector* ins_vec, const std::vector& instance, int index) { if (index == 0) { ins_vec->resize(instance.size()); for (size_t i = 0; i < instance.size(); ++i) { (*ins_vec)[i].Init(instance[i].GetType()); (*ins_vec)[i].InitOffset(); } } for (size_t i = 0; i < instance.size(); ++i) { (*ins_vec)[i].AddIns(instance[i]); } } void MultiSlotInMemoryDataFeed::PutToFeedVec( const std::vector& ins_vec) { for (size_t i = 0; i < use_slots_.size(); ++i) { const auto& type = ins_vec[i].GetType(); const auto& offset = ins_vec[i].GetOffset(); int total_instance = static_cast(offset.back()); if (type[0] == 'f') { // float const auto& feasign = ins_vec[i].GetFloatData(); float* tensor_ptr = feed_vec_[i]->mutable_data( {total_instance, 1}, platform::CPUPlace()); memcpy(tensor_ptr, &feasign[0], total_instance * sizeof(float)); } else if (type[0] == 'u') { // uint64 // no uint64_t type in paddlepaddle const auto& feasign = ins_vec[i].GetUint64Data(); int64_t* tensor_ptr = feed_vec_[i]->mutable_data( {total_instance, 1}, platform::CPUPlace()); memcpy(tensor_ptr, &feasign[0], total_instance * sizeof(int64_t)); } LoD data_lod{offset}; feed_vec_[i]->set_lod(data_lod); if (use_slots_is_dense_[i]) { int dim = total_instance / batch_size_; feed_vec_[i]->Resize({batch_size_, dim}); } } } // todo serialize ins in global shuffle void MultiSlotInMemoryDataFeed::SerializeIns( const std::vector& ins, std::string* str) { auto fleet_ptr = FleetWrapper::GetInstance(); fleet_ptr->Serialize(ins, str); } // todo deserialize ins in global shuffle void MultiSlotInMemoryDataFeed::DeserializeIns(std::vector* ins, const std::string& str) { auto fleet_ptr = FleetWrapper::GetInstance(); fleet_ptr->Deserialize(ins, str); } } // namespace framework } // namespace paddle