/* 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. */ #pragma once #if defined _WIN32 || defined __APPLE__ #else #define _LINUX #endif #include #include // NOLINT #include #include // NOLINT #include #include #include // NOLINT #include #include #include #include #include "paddle/fluid/framework/archive.h" #include "paddle/fluid/framework/blocking_queue.h" #include "paddle/fluid/framework/channel.h" #include "paddle/fluid/framework/data_feed.pb.h" #include "paddle/fluid/framework/fleet/fleet_wrapper.h" #include "paddle/fluid/framework/lod_tensor.h" #include "paddle/fluid/framework/reader.h" #include "paddle/fluid/framework/variable.h" #include "paddle/fluid/platform/timer.h" #include "paddle/fluid/string/string_helper.h" DECLARE_int32(record_pool_max_size); DECLARE_int32(slotpool_thread_num); DECLARE_bool(enable_slotpool_wait_release); DECLARE_bool(enable_slotrecord_reset_shrink); namespace paddle { namespace framework { class DataFeedDesc; class LoDTensor; class Scope; class Variable; } // namespace framework } // namespace paddle namespace paddle { namespace framework { // DataFeed is the base virtual class for all ohther DataFeeds. // It is used to read files and parse the data for subsequent trainer. // Example: // DataFeed* reader = // paddle::framework::DataFeedFactory::CreateDataFeed(data_feed_name); // reader->Init(data_feed_desc); // data_feed_desc is a protobuf object // reader->SetFileList(filelist); // const std::vector & use_slot_alias = // reader->GetUseSlotAlias(); // for (auto name: use_slot_alias){ // for binding memory // reader->AddFeedVar(scope->Var(name), name); // } // reader->Start(); // while (reader->Next()) { // // trainer do something // } template struct SlotValues { std::vector slot_values; std::vector slot_offsets; void add_values(const T* values, uint32_t num) { if (slot_offsets.empty()) { slot_offsets.push_back(0); } if (num > 0) { slot_values.insert(slot_values.end(), values, values + num); } slot_offsets.push_back(static_cast(slot_values.size())); } T* get_values(int idx, size_t* size) { uint32_t& offset = slot_offsets[idx]; (*size) = slot_offsets[idx + 1] - offset; return &slot_values[offset]; } void add_slot_feasigns(const std::vector>& slot_feasigns, uint32_t fea_num) { slot_values.reserve(fea_num); int slot_num = static_cast(slot_feasigns.size()); slot_offsets.resize(slot_num + 1); for (int i = 0; i < slot_num; ++i) { auto& slot_val = slot_feasigns[i]; slot_offsets[i] = static_cast(slot_values.size()); uint32_t num = static_cast(slot_val.size()); if (num > 0) { slot_values.insert(slot_values.end(), slot_val.begin(), slot_val.end()); } } slot_offsets[slot_num] = slot_values.size(); } void clear(bool shrink) { slot_offsets.clear(); slot_values.clear(); if (shrink) { slot_values.shrink_to_fit(); slot_offsets.shrink_to_fit(); } } }; union FeatureFeasign { uint64_t uint64_feasign_; float float_feasign_; }; struct FeatureItem { FeatureItem() {} FeatureItem(FeatureFeasign sign, uint16_t slot) { this->sign() = sign; this->slot() = slot; } FeatureFeasign& sign() { return *(reinterpret_cast(sign_buffer())); } const FeatureFeasign& sign() const { const FeatureFeasign* ret = reinterpret_cast(sign_buffer()); return *ret; } uint16_t& slot() { return slot_; } const uint16_t& slot() const { return slot_; } private: char* sign_buffer() const { return const_cast(sign_); } char sign_[sizeof(FeatureFeasign)]; uint16_t slot_; }; struct AllSlotInfo { std::string slot; std::string type; int used_idx; int slot_value_idx; }; struct UsedSlotInfo { int idx; int slot_value_idx; std::string slot; std::string type; bool dense; std::vector local_shape; int total_dims_without_inductive; int inductive_shape_index; }; struct SlotRecordObject { uint64_t search_id; uint32_t rank; uint32_t cmatch; std::string ins_id_; SlotValues slot_uint64_feasigns_; SlotValues slot_float_feasigns_; ~SlotRecordObject() { clear(true); } void reset(void) { clear(FLAGS_enable_slotrecord_reset_shrink); } void clear(bool shrink) { slot_uint64_feasigns_.clear(shrink); slot_float_feasigns_.clear(shrink); } }; using SlotRecord = SlotRecordObject*; // sizeof Record is much less than std::vector struct Record { std::vector uint64_feasigns_; std::vector float_feasigns_; std::string ins_id_; std::string content_; uint64_t search_id; uint32_t rank; uint32_t cmatch; }; inline SlotRecord make_slotrecord() { static const size_t slot_record_byte_size = sizeof(SlotRecordObject); void* p = malloc(slot_record_byte_size); new (p) SlotRecordObject; return reinterpret_cast(p); } inline void free_slotrecord(SlotRecordObject* p) { p->~SlotRecordObject(); free(p); } template class SlotObjAllocator { public: explicit SlotObjAllocator(std::function deleter) : free_nodes_(NULL), capacity_(0), deleter_(deleter) {} ~SlotObjAllocator() { clear(); } void clear() { T* tmp = NULL; while (free_nodes_ != NULL) { tmp = reinterpret_cast(reinterpret_cast(free_nodes_)); free_nodes_ = free_nodes_->next; deleter_(tmp); --capacity_; } CHECK_EQ(capacity_, static_cast(0)); } T* acquire(void) { T* x = NULL; x = reinterpret_cast(reinterpret_cast(free_nodes_)); free_nodes_ = free_nodes_->next; --capacity_; return x; } void release(T* x) { Node* node = reinterpret_cast(reinterpret_cast(x)); node->next = free_nodes_; free_nodes_ = node; ++capacity_; } size_t capacity(void) { return capacity_; } private: struct alignas(T) Node { union { Node* next; char data[sizeof(T)]; }; }; Node* free_nodes_; // a list size_t capacity_; std::function deleter_ = nullptr; }; static const int OBJPOOL_BLOCK_SIZE = 10000; class SlotObjPool { public: SlotObjPool() : max_capacity_(FLAGS_record_pool_max_size), alloc_(free_slotrecord) { ins_chan_ = MakeChannel(); ins_chan_->SetBlockSize(OBJPOOL_BLOCK_SIZE); for (int i = 0; i < FLAGS_slotpool_thread_num; ++i) { threads_.push_back(std::thread([this]() { run(); })); } disable_pool_ = false; count_ = 0; } ~SlotObjPool() { ins_chan_->Close(); for (auto& t : threads_) { t.join(); } } void disable_pool(bool disable) { disable_pool_ = disable; } void set_max_capacity(size_t max_capacity) { max_capacity_ = max_capacity; } void get(std::vector* output, int n) { output->resize(n); return get(&(*output)[0], n); } void get(SlotRecord* output, int n) { int size = 0; mutex_.lock(); int left = static_cast(alloc_.capacity()); if (left > 0) { size = (left >= n) ? n : left; for (int i = 0; i < size; ++i) { output[i] = alloc_.acquire(); } } mutex_.unlock(); count_ += n; if (size == n) { return; } for (int i = size; i < n; ++i) { output[i] = make_slotrecord(); } } void put(std::vector* input) { size_t size = input->size(); if (size == 0) { return; } put(&(*input)[0], size); input->clear(); } void put(SlotRecord* input, size_t size) { CHECK(ins_chan_->WriteMove(size, input) == size); } void run(void) { std::vector input; while (ins_chan_->ReadOnce(input, OBJPOOL_BLOCK_SIZE)) { if (input.empty()) { continue; } // over max capacity size_t n = input.size(); count_ -= n; if (disable_pool_ || n + capacity() > max_capacity_) { for (auto& t : input) { free_slotrecord(t); } } else { for (auto& t : input) { t->reset(); } mutex_.lock(); for (auto& t : input) { alloc_.release(t); } mutex_.unlock(); } input.clear(); } } void clear(void) { platform::Timer timeline; timeline.Start(); mutex_.lock(); alloc_.clear(); mutex_.unlock(); // wait release channel data if (FLAGS_enable_slotpool_wait_release) { while (!ins_chan_->Empty()) { sleep(1); } } timeline.Pause(); VLOG(3) << "clear slot pool data size=" << count_.load() << ", span=" << timeline.ElapsedSec(); } size_t capacity(void) { mutex_.lock(); size_t total = alloc_.capacity(); mutex_.unlock(); return total; } private: size_t max_capacity_; Channel ins_chan_; std::vector threads_; std::mutex mutex_; SlotObjAllocator alloc_; bool disable_pool_; std::atomic count_; // NOLINT }; inline SlotObjPool& SlotRecordPool() { static SlotObjPool pool; return pool; } struct PvInstanceObject { std::vector ads; void merge_instance(Record* ins) { ads.push_back(ins); } }; using PvInstance = PvInstanceObject*; inline PvInstance make_pv_instance() { return new PvInstanceObject(); } struct SlotConf { std::string name; std::string type; int use_slots_index; int use_slots_is_dense; }; class CustomParser { public: CustomParser() {} virtual ~CustomParser() {} virtual void Init(const std::vector& slots) = 0; virtual bool Init(const std::vector& slots) = 0; virtual void ParseOneInstance(const char* str, Record* instance) = 0; virtual bool ParseOneInstance( const std::string& line, std::function&, int)> GetInsFunc) { // NOLINT return true; } virtual bool ParseFileInstance( std::function ReadBuffFunc, std::function&, int, int)> PullRecordsFunc, // NOLINT int& lines) { // NOLINT return false; } }; typedef paddle::framework::CustomParser* (*CreateParserObjectFunc)(); class DLManager { struct DLHandle { void* module; paddle::framework::CustomParser* parser; }; public: DLManager() {} ~DLManager() { #ifdef _LINUX std::lock_guard lock(mutex_); for (auto it = handle_map_.begin(); it != handle_map_.end(); ++it) { delete it->second.parser; dlclose(it->second.module); } #endif } bool Close(const std::string& name) { #ifdef _LINUX auto it = handle_map_.find(name); if (it == handle_map_.end()) { return true; } delete it->second.parser; dlclose(it->second.module); #endif VLOG(0) << "Not implement in windows"; return false; } paddle::framework::CustomParser* Load(const std::string& name, const std::vector& conf) { #ifdef _LINUX std::lock_guard lock(mutex_); DLHandle handle; std::map::iterator it = handle_map_.find(name); if (it != handle_map_.end()) { return it->second.parser; } handle.module = dlopen(name.c_str(), RTLD_NOW); if (handle.module == nullptr) { VLOG(0) << "Create so of " << name << " fail"; return nullptr; } CreateParserObjectFunc create_parser_func = (CreateParserObjectFunc)dlsym(handle.module, "CreateParserObject"); handle.parser = create_parser_func(); handle.parser->Init(conf); handle_map_.insert({name, handle}); return handle.parser; #endif VLOG(0) << "Not implement in windows"; return nullptr; } paddle::framework::CustomParser* Load(const std::string& name, const std::vector& conf) { #ifdef _LINUX std::lock_guard lock(mutex_); DLHandle handle; std::map::iterator it = handle_map_.find(name); if (it != handle_map_.end()) { return it->second.parser; } handle.module = dlopen(name.c_str(), RTLD_NOW); if (handle.module == nullptr) { VLOG(0) << "Create so of " << name << " fail"; exit(-1); return nullptr; } CreateParserObjectFunc create_parser_func = (CreateParserObjectFunc)dlsym(handle.module, "CreateParserObject"); handle.parser = create_parser_func(); handle.parser->Init(conf); handle_map_.insert({name, handle}); return handle.parser; #endif VLOG(0) << "Not implement in windows"; return nullptr; } paddle::framework::CustomParser* ReLoad(const std::string& name, const std::vector& conf) { Close(name); return Load(name, conf); } private: std::mutex mutex_; std::map handle_map_; }; class DataFeed { public: DataFeed() { mutex_for_pick_file_ = nullptr; file_idx_ = nullptr; mutex_for_fea_num_ = nullptr; total_fea_num_ = nullptr; } virtual ~DataFeed() {} virtual void Init(const DataFeedDesc& data_feed_desc) = 0; virtual bool CheckFile(const char* filename) { PADDLE_THROW(platform::errors::Unimplemented( "This function(CheckFile) is not implemented.")); } // Set filelist for DataFeed. // Pay attention that it must init all readers before call this function. // Otherwise, Init() function will init finish_set_filelist_ flag. virtual bool SetFileList(const std::vector& files); virtual bool Start() = 0; // The trainer calls the Next() function, and the DataFeed will load a new // batch to the feed_vec. The return value of this function is the batch // size of the current batch. virtual int Next() = 0; // Get all slots' alias which defined in protofile virtual const std::vector& GetAllSlotAlias() { return all_slots_; } // Get used slots' alias which defined in protofile virtual const std::vector& GetUseSlotAlias() { return use_slots_; } // This function is used for binding feed_vec memory virtual void AddFeedVar(Variable* var, const std::string& name); // This function is used for binding feed_vec memory in a given scope virtual void AssignFeedVar(const Scope& scope); // This function will do nothing at default virtual void SetInputPvChannel(void* channel) {} // This function will do nothing at default virtual void SetOutputPvChannel(void* channel) {} // This function will do nothing at default virtual void SetConsumePvChannel(void* channel) {} // This function will do nothing at default virtual void SetInputChannel(void* channel) {} // This function will do nothing at default virtual void SetOutputChannel(void* channel) {} // This function will do nothing at default virtual void SetConsumeChannel(void* channel) {} // This function will do nothing at default virtual void SetThreadId(int thread_id) {} // This function will do nothing at default virtual void SetThreadNum(int thread_num) {} // This function will do nothing at default virtual void SetParseInsId(bool parse_ins_id) {} virtual void SetParseContent(bool parse_content) {} virtual void SetParseLogKey(bool parse_logkey) {} virtual void SetEnablePvMerge(bool enable_pv_merge) {} virtual void SetCurrentPhase(int current_phase) {} virtual void SetFileListMutex(std::mutex* mutex) { mutex_for_pick_file_ = mutex; } virtual void SetFeaNumMutex(std::mutex* mutex) { mutex_for_fea_num_ = mutex; } virtual void SetFileListIndex(size_t* file_index) { file_idx_ = file_index; } virtual void SetFeaNum(uint64_t* fea_num) { total_fea_num_ = fea_num; } virtual const std::vector& GetInsIdVec() const { return ins_id_vec_; } virtual const std::vector& GetInsContentVec() const { return ins_content_vec_; } virtual int GetCurBatchSize() { return batch_size_; } virtual void LoadIntoMemory() { PADDLE_THROW(platform::errors::Unimplemented( "This function(LoadIntoMemory) is not implemented.")); } virtual void SetPlace(const paddle::platform::Place& place) { place_ = place; } virtual const paddle::platform::Place& GetPlace() const { return place_; } protected: // The following three functions are used to check if it is executed in this // order: // Init() -> SetFileList() -> Start() -> Next() virtual void CheckInit(); virtual void CheckSetFileList(); virtual void CheckStart(); virtual void SetBatchSize( int batch); // batch size will be set in Init() function // This function is used to pick one file from the global filelist(thread // safe). virtual bool PickOneFile(std::string* filename); virtual void CopyToFeedTensor(void* dst, const void* src, size_t size); std::vector filelist_; size_t* file_idx_; std::mutex* mutex_for_pick_file_; std::mutex* mutex_for_fea_num_ = nullptr; uint64_t* total_fea_num_ = nullptr; uint64_t fea_num_ = 0; // the alias of used slots, and its order is determined by // data_feed_desc(proto object) std::vector use_slots_; std::vector use_slots_is_dense_; // the alias of all slots, and its order is determined by data_feed_desc(proto // object) std::vector all_slots_; std::vector all_slots_type_; std::vector> use_slots_shape_; std::vector inductive_shape_index_; std::vector total_dims_without_inductive_; // For the inductive shape passed within data std::vector> multi_inductive_shape_index_; std::vector use_slots_index_; // -1: not used; >=0: the index of use_slots_ // The data read by DataFeed will be stored here std::vector feed_vec_; LoDTensor* rank_offset_; // the batch size defined by user int default_batch_size_; // current batch size int batch_size_; bool finish_init_; bool finish_set_filelist_; bool finish_start_; std::string pipe_command_; std::string so_parser_name_; std::vector slot_conf_; std::vector ins_id_vec_; std::vector ins_content_vec_; platform::Place place_; // The input type of pipe reader, 0 for one sample, 1 for one batch int input_type_; }; // PrivateQueueDataFeed is the base virtual class for ohther DataFeeds. // It use a read-thread to read file and parse data to a private-queue // (thread level), and get data from this queue when trainer call Next(). template class PrivateQueueDataFeed : public DataFeed { public: PrivateQueueDataFeed() {} virtual ~PrivateQueueDataFeed() {} virtual bool Start(); virtual int Next(); protected: // The thread implementation function for reading file and parse. virtual void ReadThread(); // This function is used to set private-queue size, and the most // efficient when the queue size is close to the batch size. virtual void SetQueueSize(int queue_size); // The reading and parsing method called in the ReadThread. virtual bool ParseOneInstance(T* instance) = 0; virtual bool ParseOneInstanceFromPipe(T* instance) = 0; // This function is used to put instance to vec_ins virtual void AddInstanceToInsVec(T* vec_ins, const T& instance, int index) = 0; // This function is used to put ins_vec to feed_vec virtual void PutToFeedVec(const T& ins_vec) = 0; // The thread for read files std::thread read_thread_; // using ifstream one line and one line parse is faster // than using fread one buffer and one buffer parse. // for a 601M real data: // ifstream one line and one line parse: 6034 ms // fread one buffer and one buffer parse: 7097 ms std::ifstream file_; std::shared_ptr fp_; size_t queue_size_; string::LineFileReader reader_; // The queue for store parsed data std::shared_ptr> queue_; }; template class InMemoryDataFeed : public DataFeed { public: InMemoryDataFeed(); virtual ~InMemoryDataFeed() {} virtual void Init(const DataFeedDesc& data_feed_desc) = 0; virtual bool Start(); virtual int Next(); virtual void SetInputPvChannel(void* channel); virtual void SetOutputPvChannel(void* channel); virtual void SetConsumePvChannel(void* channel); virtual void SetInputChannel(void* channel); virtual void SetOutputChannel(void* channel); virtual void SetConsumeChannel(void* channel); virtual void SetThreadId(int thread_id); virtual void SetThreadNum(int thread_num); virtual void SetParseInsId(bool parse_ins_id); virtual void SetParseContent(bool parse_content); virtual void SetParseLogKey(bool parse_logkey); virtual void SetEnablePvMerge(bool enable_pv_merge); virtual void SetCurrentPhase(int current_phase); virtual void LoadIntoMemory(); virtual void LoadIntoMemoryFromSo(); virtual void SetRecord(T* records) { records_ = records; } int GetDefaultBatchSize() { return default_batch_size_; } void AddBatchOffset(const std::pair& offset) { batch_offsets_.push_back(offset); } protected: virtual bool ParseOneInstance(T* instance) = 0; virtual bool ParseOneInstanceFromPipe(T* instance) = 0; virtual void ParseOneInstanceFromSo(const char* str, T* instance, CustomParser* parser) {} virtual void PutToFeedVec(const std::vector& ins_vec) = 0; virtual void PutToFeedVec(const T* ins_vec, int num) = 0; std::vector> batch_float_feasigns_; std::vector> batch_uint64_feasigns_; std::vector> offset_; std::vector visit_; int thread_id_; int thread_num_; bool parse_ins_id_; bool parse_content_; bool parse_logkey_; bool enable_pv_merge_; int current_phase_{-1}; // only for untest std::ifstream file_; std::shared_ptr fp_; paddle::framework::ChannelObject* input_channel_; paddle::framework::ChannelObject* output_channel_; paddle::framework::ChannelObject* consume_channel_; paddle::framework::ChannelObject* input_pv_channel_; paddle::framework::ChannelObject* output_pv_channel_; paddle::framework::ChannelObject* consume_pv_channel_; std::vector> batch_offsets_; uint64_t offset_index_ = 0; bool enable_heterps_ = false; T* records_ = nullptr; }; // This class define the data type of instance(ins_vec) in MultiSlotDataFeed class MultiSlotType { public: MultiSlotType() {} ~MultiSlotType() {} void Init(const std::string& type, size_t reserved_size = 0) { CheckType(type); if (type_[0] == 'f') { float_feasign_.clear(); if (reserved_size) { float_feasign_.reserve(reserved_size); } } else if (type_[0] == 'u') { uint64_feasign_.clear(); if (reserved_size) { uint64_feasign_.reserve(reserved_size); } } type_ = type; } void InitOffset(size_t max_batch_size = 0) { if (max_batch_size > 0) { offset_.reserve(max_batch_size + 1); } offset_.resize(1); // LoDTensor' lod is counted from 0, the size of lod // is one size larger than the size of data. offset_[0] = 0; } const std::vector& GetOffset() const { return offset_; } std::vector& MutableOffset() { return offset_; } void AddValue(const float v) { CheckFloat(); float_feasign_.push_back(v); } void AddValue(const uint64_t v) { CheckUint64(); uint64_feasign_.push_back(v); } void CopyValues(const float* input, size_t size) { CheckFloat(); float_feasign_.resize(size); memcpy(float_feasign_.data(), input, size * sizeof(float)); } void CopyValues(const uint64_t* input, size_t size) { CheckUint64(); uint64_feasign_.resize(size); memcpy(uint64_feasign_.data(), input, size * sizeof(uint64_t)); } void AddIns(const MultiSlotType& ins) { if (ins.GetType()[0] == 'f') { // float CheckFloat(); auto& vec = ins.GetFloatData(); offset_.push_back(offset_.back() + vec.size()); float_feasign_.insert(float_feasign_.end(), vec.begin(), vec.end()); } else if (ins.GetType()[0] == 'u') { // uint64 CheckUint64(); auto& vec = ins.GetUint64Data(); offset_.push_back(offset_.back() + vec.size()); uint64_feasign_.insert(uint64_feasign_.end(), vec.begin(), vec.end()); } } void AppendValues(const uint64_t* input, size_t size) { CheckUint64(); offset_.push_back(offset_.back() + size); uint64_feasign_.insert(uint64_feasign_.end(), input, input + size); } void AppendValues(const float* input, size_t size) { CheckFloat(); offset_.push_back(offset_.back() + size); float_feasign_.insert(float_feasign_.end(), input, input + size); } const std::vector& GetFloatData() const { return float_feasign_; } std::vector& MutableFloatData() { return float_feasign_; } const std::vector& GetUint64Data() const { return uint64_feasign_; } std::vector& MutableUint64Data() { return uint64_feasign_; } const std::string& GetType() const { return type_; } size_t GetBatchSize() { return offset_.size() - 1; } std::string& MutableType() { return type_; } std::string DebugString() { std::stringstream ss; ss << "\ntype: " << type_ << "\n"; ss << "offset: "; ss << "["; for (const size_t& i : offset_) { ss << offset_[i] << ","; } ss << "]\ndata: ["; if (type_[0] == 'f') { for (const float& i : float_feasign_) { ss << i << ","; } } else { for (const uint64_t& i : uint64_feasign_) { ss << i << ","; } } ss << "]\n"; return ss.str(); } private: void CheckType(const std::string& type) const { PADDLE_ENFORCE_EQ((type == "uint64" || type == "float"), true, platform::errors::InvalidArgument( "MultiSlotType error, expect type is uint64 or " "float, but received type is %s.", type)); } void CheckFloat() const { PADDLE_ENFORCE_EQ( type_[0], 'f', platform::errors::InvalidArgument( "MultiSlotType error, add %s value to float slot.", type_)); } void CheckUint64() const { PADDLE_ENFORCE_EQ( type_[0], 'u', platform::errors::InvalidArgument( "MultiSlotType error, add %s value to uint64 slot.", type_)); } std::vector float_feasign_; std::vector uint64_feasign_; std::string type_; std::vector offset_; }; template paddle::framework::Archive& operator<<(paddle::framework::Archive& ar, const MultiSlotType& ins) { ar << ins.GetType(); #ifdef _LINUX ar << ins.GetOffset(); #else const auto& offset = ins.GetOffset(); ar << (uint64_t)offset.size(); for (const size_t& x : offset) { ar << (const uint64_t)x; } #endif ar << ins.GetFloatData(); ar << ins.GetUint64Data(); return ar; } template paddle::framework::Archive& operator>>(paddle::framework::Archive& ar, MultiSlotType& ins) { ar >> ins.MutableType(); #ifdef _LINUX ar >> ins.MutableOffset(); #else auto& offset = ins.MutableOffset(); offset.resize(ar.template Get()); for (size_t& x : offset) { uint64_t t; ar >> t; x = static_cast(t); } #endif ar >> ins.MutableFloatData(); ar >> ins.MutableUint64Data(); return ar; } struct RecordCandidate { std::string ins_id_; std::unordered_multimap feas_; size_t shadow_index_ = -1; // Optimization for Reservoir Sample RecordCandidate() {} RecordCandidate(const Record& rec, const std::unordered_set& slot_index_to_replace) { for (const auto& fea : rec.uint64_feasigns_) { if (slot_index_to_replace.find(fea.slot()) != slot_index_to_replace.end()) { feas_.insert({fea.slot(), fea.sign()}); } } } RecordCandidate& operator=(const Record& rec) { feas_.clear(); ins_id_ = rec.ins_id_; for (auto& fea : rec.uint64_feasigns_) { feas_.insert({fea.slot(), fea.sign()}); } return *this; } }; class RecordCandidateList { public: RecordCandidateList() = default; RecordCandidateList(const RecordCandidateList&) {} size_t Size() { return cur_size_; } void ReSize(size_t length); void ReInit(); void ReInitPass() { for (size_t i = 0; i < cur_size_; ++i) { if (candidate_list_[i].shadow_index_ != i) { candidate_list_[i].ins_id_ = candidate_list_[candidate_list_[i].shadow_index_].ins_id_; candidate_list_[i].feas_.swap( candidate_list_[candidate_list_[i].shadow_index_].feas_); candidate_list_[i].shadow_index_ = i; } } candidate_list_.resize(cur_size_); } void AddAndGet(const Record& record, RecordCandidate* result); void AddAndGet(const Record& record, size_t& index_result) { // NOLINT // std::unique_lock lock(mutex_); size_t index = 0; ++total_size_; auto fleet_ptr = FleetWrapper::GetInstance(); if (!full_) { candidate_list_.emplace_back(record, slot_index_to_replace_); candidate_list_.back().shadow_index_ = cur_size_; ++cur_size_; full_ = (cur_size_ == capacity_); } else { index = fleet_ptr->LocalRandomEngine()() % total_size_; if (index < capacity_) { candidate_list_.emplace_back(record, slot_index_to_replace_); candidate_list_[index].shadow_index_ = candidate_list_.size() - 1; } } index = fleet_ptr->LocalRandomEngine()() % cur_size_; index_result = candidate_list_[index].shadow_index_; } const RecordCandidate& Get(size_t index) const { PADDLE_ENFORCE_LT( index, candidate_list_.size(), platform::errors::OutOfRange("Your index [%lu] exceeds the number of " "elements in candidate_list[%lu].", index, candidate_list_.size())); return candidate_list_[index]; } void SetSlotIndexToReplace( const std::unordered_set& slot_index_to_replace) { slot_index_to_replace_ = slot_index_to_replace; } private: size_t capacity_ = 0; std::mutex mutex_; bool full_ = false; size_t cur_size_ = 0; size_t total_size_ = 0; std::vector candidate_list_; std::unordered_set slot_index_to_replace_; }; template paddle::framework::Archive& operator<<(paddle::framework::Archive& ar, const FeatureFeasign& fk) { ar << fk.uint64_feasign_; ar << fk.float_feasign_; return ar; } template paddle::framework::Archive& operator>>(paddle::framework::Archive& ar, FeatureFeasign& fk) { ar >> fk.uint64_feasign_; ar >> fk.float_feasign_; return ar; } template paddle::framework::Archive& operator<<(paddle::framework::Archive& ar, const FeatureItem& fi) { ar << fi.sign(); ar << fi.slot(); return ar; } template paddle::framework::Archive& operator>>(paddle::framework::Archive& ar, FeatureItem& fi) { ar >> fi.sign(); ar >> fi.slot(); return ar; } template paddle::framework::Archive& operator<<(paddle::framework::Archive& ar, const Record& r) { ar << r.uint64_feasigns_; ar << r.float_feasigns_; ar << r.ins_id_; return ar; } template paddle::framework::Archive& operator>>(paddle::framework::Archive& ar, Record& r) { ar >> r.uint64_feasigns_; ar >> r.float_feasigns_; ar >> r.ins_id_; return ar; } // This DataFeed is used to feed multi-slot type data. // The format of multi-slot type data: // [n feasign_0 feasign_1 ... feasign_n]* class MultiSlotDataFeed : public PrivateQueueDataFeed> { public: MultiSlotDataFeed() {} virtual ~MultiSlotDataFeed() {} virtual void Init(const DataFeedDesc& data_feed_desc); virtual bool CheckFile(const char* filename); protected: virtual void ReadThread(); virtual void AddInstanceToInsVec(std::vector* vec_ins, const std::vector& instance, int index); virtual bool ParseOneInstance(std::vector* instance); virtual bool ParseOneInstanceFromPipe(std::vector* instance); virtual void PutToFeedVec(const std::vector& ins_vec); }; class MultiSlotInMemoryDataFeed : public InMemoryDataFeed { public: MultiSlotInMemoryDataFeed() {} virtual ~MultiSlotInMemoryDataFeed() {} virtual void Init(const DataFeedDesc& data_feed_desc); // void SetRecord(Record* records) { records_ = records; } protected: virtual bool ParseOneInstance(Record* instance); virtual bool ParseOneInstanceFromPipe(Record* instance); virtual void ParseOneInstanceFromSo(const char* str, Record* instance, CustomParser* parser); virtual void PutToFeedVec(const std::vector& ins_vec); virtual void GetMsgFromLogKey(const std::string& log_key, uint64_t* search_id, uint32_t* cmatch, uint32_t* rank); virtual void PutToFeedVec(const Record* ins_vec, int num); }; class PaddleBoxDataFeed : public MultiSlotInMemoryDataFeed { public: PaddleBoxDataFeed() {} virtual ~PaddleBoxDataFeed() {} protected: virtual void Init(const DataFeedDesc& data_feed_desc); virtual bool Start(); virtual int Next(); virtual void AssignFeedVar(const Scope& scope); virtual void PutToFeedVec(const std::vector& pv_vec); virtual void PutToFeedVec(const std::vector& ins_vec); virtual int GetCurrentPhase(); virtual void GetRankOffset(const std::vector& pv_vec, int ins_number); std::string rank_offset_name_; int pv_batch_size_; }; #if (defined(PADDLE_WITH_CUDA) || defined(PADDLE_WITH_HIP)) && !defined(_WIN32) template class PrivateInstantDataFeed : public DataFeed { public: PrivateInstantDataFeed() {} virtual ~PrivateInstantDataFeed() {} void Init(const DataFeedDesc& data_feed_desc) override; bool Start() override { return true; } int Next() override; protected: // The batched data buffer std::vector ins_vec_; // This function is used to preprocess with a given filename, e.g. open it or // mmap virtual bool Preprocess(const std::string& filename) = 0; // This function is used to postprocess system resource such as closing file // NOTICE: Ensure that it is safe to call before Preprocess virtual bool Postprocess() = 0; // The reading and parsing method. virtual bool ParseOneMiniBatch() = 0; // This function is used to put ins_vec to feed_vec virtual void PutToFeedVec(); }; class MultiSlotFileInstantDataFeed : public PrivateInstantDataFeed> { public: MultiSlotFileInstantDataFeed() {} virtual ~MultiSlotFileInstantDataFeed() {} protected: int fd_{-1}; char* buffer_{nullptr}; size_t end_{0}; size_t offset_{0}; bool Preprocess(const std::string& filename) override; bool Postprocess() override; bool ParseOneMiniBatch() override; }; #endif } // namespace framework } // namespace paddle