/* 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 "DataProvider.h" #include #include #include "paddle/legacy/utils/Logging.h" #include "paddle/legacy/utils/Stat.h" #include "paddle/legacy/utils/StringUtil.h" #include "paddle/legacy/utils/Util.h" namespace paddle { void BufferBatch::swap(BufferBatch* bufBatch) { DataBatch* batchData = bufBatch->getDataBatch(); hl_event_t hlEvent = bufBatch->getCuEvent(); hl_stream_t hlStream = bufBatch->getCuStream(); bufBatch->setDataBatch(batchData_); bufBatch->setCuStream(hlStream_); bufBatch->setCuEvent(hlEvent_); batchData_ = batchData; hlEvent_ = hlEvent; hlStream_ = hlStream; } void BufferBatch::clone(DataBatch* srcBatch, bool useGpu) { if (batchData_ == NULL) { batchData_ = new DataBatch(); } std::vector& destData = batchData_->getStreams(); int numStreams = srcBatch->getNumStreams(); destData.resize(numStreams); batchData_->setSize(srcBatch->getSize()); if (useGpu) { createCuEvent(); } for (int i = 0; i < numStreams; i++) { destData[i].resizeAndCopyFrom(srcBatch->getStream(i), useGpu, hlStream_); } if (useGpu) { hl_stream_record_event(hlStream_, hlEvent_); } } DoubleBuffer::DoubleBuffer(DataProvider* dataPool, bool useGpu, int64_t batchSize) { batchSize_ = batchSize; dataPool_ = dataPool; useGpu_ = useGpu; dataQueue_ = new BufferBatchQueue(); bufferQueue_ = new BufferBatchQueue(); // insert a empty buffer bufferQueue_->enqueue(new BufferBatch()); stopping_ = false; pending_ = true; } DoubleBuffer::~DoubleBuffer() { finishAsyncLoad(); while (dataQueue_->size()) { BufferBatch* dataBtch = dataQueue_->dequeue(); delete dataBtch; dataBtch = NULL; } while (bufferQueue_->size()) { BufferBatch* bufBtch = bufferQueue_->dequeue(); delete bufBtch; bufBtch = NULL; } delete dataQueue_; dataQueue_ = NULL; delete bufferQueue_; bufferQueue_ = NULL; } void DoubleBuffer::removeOneBatch(DataBatch* dataBatch) { // get data BufferBatch* batch = dataQueue_->dequeue(); batch->syncEvent(); // when use GPU, need synchronized with the cuEvent *dataBatch = *(batch->getDataBatch()); // push anothor buffer if (*usingBatch_ == nullptr) { *usingBatch_ = std::make_shared(); } // Mark the using-batch batch->swap((*usingBatch_).get()); bufferQueue_->enqueue(batch); if (0 == dataBatch->getSize()) { setPending(true); } } void DoubleBuffer::insertOneBatch(DataBatch* batch) { while (!bufferQueue_->waitNotEmptyFor(2 /* seconds */)) { // time out if (stopping_) return; } BufferBatch* bufBatch = bufferQueue_->dequeue(); // clone and copy the data from an Threadlocal Variable bufBatch->clone(batch, useGpu_); dataQueue_->enqueue(bufBatch); } void DoubleBuffer::asyncLoadBatch() { int64_t actualSize = 0; if (useGpu_) { hl_set_device(FLAGS_gpu_id); } setPending(false); while (true) { taskReadySem_.wait(); if (stopping_) break; while (batchSize_ == 0 && !stopping_) { usleep(5); } if (stopping_) break; do { DataBatch newBatch; { REGISTER_TIMER("getNextBatchInternal"); actualSize = dataPool_->getNextBatchInternal(batchSize_, &newBatch); } insertOneBatch(&newBatch); } while (actualSize > 0 && !stopping_); } } void DoubleBuffer::startAsyncLoad() { if (asyncLoader_ == nullptr) { asyncLoader_.reset(new std::thread([this]() { this->asyncLoadBatch(); })); } taskReadySem_.post(); } ClassRegistrar DataProvider::registrar_; DataProvider* DataProvider::create(const DataConfig& config, const ModelConfig& modelConfig, bool useGpu) { return registrar_.createByType(config.type(), config, modelConfig, useGpu); } REGISTER_DATA_PROVIDER(simple, SimpleDataProvider); REGISTER_DATA_PROVIDER(dummy, DummyDataProvider); int64_t DataProvider::getNextBatch(int64_t size, DataBatch* batch) { int64_t batchSize = doubleBuffer_ ? getNextBatchFromBuffer(size, batch) : getNextBatchInternal(size, batch); if (!batchSize) return 0; if (!config_.constant_slots_size()) return batchSize; auto& constantSlots = *constantSlots_; constantSlots.resize(config_.constant_slots_size()); for (int i = 0; i < config_.constant_slots_size(); ++i) { MemoryHandlePtr handle = constantSlots[i] ? constantSlots[i]->getMemoryHandle() : nullptr; Matrix::resizeOrCreate(constantSlots[i], batchSize, 1, // = width false, // = trans useGpu_); // = useGpu if (handle != constantSlots[i]->getMemoryHandle()) { // memory buf was reallocated. We need to initialize the value constantSlots[i]->assign(config_.constant_slots(i)); } batch->appendData(constantSlots[i], batch->getStream(0).sequenceStartPositions); } return batchSize; } int64_t DataProvider::getNextBatchFromBuffer(int64_t size, DataBatch* batch) { CHECK(doubleBuffer_ != nullptr); if (doubleBuffer_->getBatchSize() != size) { doubleBuffer_->setBatchSize(size); } doubleBuffer_->removeOneBatch(batch); return batch->getSize(); } void DataProvider::initAsyncLoader() { if (doubleBuffer_ == nullptr) { doubleBuffer_.reset(new DoubleBuffer(this, useGpu_)); } useGpu_ = false; // Avoid D2D copy, it will delay the computing performance } SimpleDataProviderBase::SimpleDataProviderBase(const DataConfig& config, bool useGpu, bool withInfo) : DataProvider(config, useGpu) { /* initialize the size of a sample, and the buffer */ sampleDim_ = config_.feat_dim() * (2 * config_.context_len() + 1); bufferCapacity_ = config_.buffer_capacity(); withInfo_ = withInfo; sampleNumInBuf_ = 0; nextItemIndex_ = 0; /* malloc buffer in cpu */ hInputDataBuf_ = std::make_shared(bufferCapacity_, sampleDim_); hInputLabelBuf_ = std::make_shared(bufferCapacity_); hInputInfoBuf_ = std::make_shared(bufferCapacity_); } void SimpleDataProviderBase::shuffle() { int i, t; int len = sampleNumInBuf_; std::vector temp(sampleDim_); real* data = hInputDataBuf_->getData(); int* label = hInputLabelBuf_->getData(); int* info = hInputInfoBuf_->getData(); int sampleSz = sizeof(real) * sampleDim_; for (i = 0; i < len; i++) { int randNum = rand(); // NOLINT TODO(yuyang18): Use rand_r instead? t = randNum % (len - i) + i; // swap if (i != t) { // swap data memcpy(&temp[0], &data[i * sampleDim_], sampleSz); memcpy(&data[i * sampleDim_], &data[t * sampleDim_], sampleSz); memcpy(&data[t * sampleDim_], &temp[0], sampleSz); std::swap(label[i], label[t]); if (withInfo_) { std::swap(info[i], info[t]); } } } } int64_t SimpleDataProviderBase::getNextBatchInternal(int64_t size, DataBatch* batch) { CHECK(batch != NULL); batch->clear(); int64_t startIndex; int64_t cpySize; std::lock_guard guard(lock_); if (sampleNumInBuf_ - nextItemIndex_ < size) { int64_t n = fillBuffer(); VLOG(1) << "fillBuffer return " << n << " samples.\n"; } startIndex = nextItemIndex_; cpySize = std::min(size, sampleNumInBuf_ - nextItemIndex_); nextItemIndex_ += cpySize; if (cpySize > 0) { real* data = hInputDataBuf_->getData() + startIndex * sampleDim_; int* label = hInputLabelBuf_->getData() + startIndex; int* info = hInputInfoBuf_->getData() + startIndex; MatrixPtr& dataBatch = *dataBatch_; // get the thread local object IVectorPtr& labelBatch = *labelBatch_; // get the thread local object IVectorPtr& infoBatch = *infoBatch_; // get the thread local object if (!dataBatch) { dataBatch = Matrix::create(cpySize, sampleDim_, false, useGpu_); labelBatch = IVector::create(cpySize, useGpu_); if (withInfo_) { infoBatch = IVector::create(cpySize, 0); } } else { dataBatch->resize(cpySize, sampleDim_); labelBatch->resize(cpySize); if (withInfo_) { infoBatch->resize(cpySize); } } dataBatch->copyFrom(data, cpySize * sampleDim_); labelBatch->copyFrom(label, cpySize); batch->appendData(dataBatch); batch->appendLabel(labelBatch); if (withInfo_) { infoBatch->copyFrom(info, cpySize); batch->appendLabel(infoBatch); } } batch->setSize(cpySize); return cpySize; } void SimpleDataProviderBase::reset() { sampleNumInBuf_ = 0; nextItemIndex_ = 0; DataProvider::reset(); } int64_t SimpleDataProviderBase::getSize() { LOG(FATAL) << "Currently, not implemented"; return 0; } int64_t SimpleDataProviderBase::fillBuffer() { int64_t n = sampleNumInBuf_ - nextItemIndex_; /* flash the remaining data to the beginning of the buffer */ if (n > 0) { hInputDataBuf_->copyFrom( hInputDataBuf_->getData() + nextItemIndex_ * sampleDim_, n * sampleDim_); hInputLabelBuf_->copyFrom(hInputLabelBuf_->getData() + nextItemIndex_, n); if (withInfo_) { hInputInfoBuf_->copyFrom(hInputInfoBuf_->getData() + nextItemIndex_, n); } } sampleNumInBuf_ = n + fillBufferImp(hInputDataBuf_->getData() + n * sampleDim_, hInputLabelBuf_->getData() + n, hInputInfoBuf_->getData() + n, bufferCapacity_ - n); /* for stachastic gradient training */ if (!skipShuffle_) { shuffle(); } nextItemIndex_ = 0; return sampleNumInBuf_; } SimpleDataProvider::SimpleDataProvider(const DataConfig& config, bool useGpu) : SimpleDataProviderBase(config, useGpu, /* withInfo= */ false), currentSampleIndex_(0) { loadData(config_.files()); } SimpleDataProvider::~SimpleDataProvider() {} int64_t SimpleDataProvider::fillBufferImp(real* data, int* label, int* info, int64_t size) { (void)info; int64_t n = std::min(labels_.size() - currentSampleIndex_, size); memcpy(data, &data_[currentSampleIndex_ * sampleDim_], n * sampleDim_ * sizeof(real)); memcpy(label, &labels_[currentSampleIndex_], sizeof(int) * n); currentSampleIndex_ += n; return n; } void SimpleDataProvider::reset() { currentSampleIndex_ = 0; SimpleDataProviderBase::reset(); } void SimpleDataProvider::loadData(const std::string& fileName) { std::ifstream is(fileName); CHECK(is) << "Fail to open " << fileName; std::string line; while (is) { if (!getline(is, line)) break; LOG(INFO) << "load data file " << line; loadDataFile(line); } LOG(INFO) << "read done, num of instance=" << labels_.size() << " data size=" << data_.size(); } void SimpleDataProvider::loadDataFile(const std::string& fileName) { std::ifstream is(fileName); std::string line; std::vector pieces; while (is) { if (!getline(is, line)) break; str::split(line, ' ', &pieces); CHECK_EQ((uint64_t)(sampleDim_ + 1), pieces.size()) << " Dimension mismatch, " << pieces.size() - 1 << " in " << fileName << " " << sampleDim_ << " from config"; labels_.push_back(atoi(pieces[0].c_str())); for (int i = 0; i < sampleDim_; ++i) { data_.push_back(atof(pieces[i + 1].c_str())); } } } } // namespace paddle