/* Copyright (c) 2016 Baidu, Inc. All Rights Reserve. 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/utils/Stat.h" #ifndef PADDLE_ONLY_CPU #include "hl_batch_transpose.h" #endif #include "BatchNormalizationLayer.h" namespace paddle { REGISTER_LAYER(batch_norm, BatchNormalizationLayer); const real BatchNormalizationLayer::EPS = 1E-5; bool BatchNormalizationLayer::init(const LayerMap& layerMap, const ParameterMap& parameterMap) { /* Initialize the basic parent class */ if (!BatchNormBaseLayer::init(layerMap, parameterMap)) return false; return true; } void BatchNormalizationLayer::calMeanAndStd(const MatrixPtr& mat) { int numSamples = mat->getHeight(); Matrix::resizeOrCreate(tmpMat_, numSamples, channels_, false, useGpu_); savedMean_->zeroMem(); savedMean_->accumulateColSum(*mat); savedMean_->mulScalar(1.0 / numSamples); // E[x] tmpMat_->assign(*mat); tmpMat_->square(); savedInvVar_->zeroMem(); savedInvVar_->accumulateColSum(*tmpMat_); savedInvVar_->mulScalar(1.0 / numSamples); // E[x^2] savedInvVar_->addSquare(*savedMean_, -1.0); // E[x^2] - E^2[x] // Variance may be small negative value // because of the subtraction operation. // Here using clipping. savedInvVar_->downClip(real(0.0)); calMovingMeanAndVar(); savedInvVar_->subScalar(-EPS); savedInvVar_->sqrt(*savedInvVar_); } void BatchNormalizationLayer::calMovingMeanAndVar() { // calculating and saving moving mean and variance MatrixPtr movingMean = movingMean_->getW(); MatrixPtr movingVar = movingVar_->getW(); if (!useGpu_ && FLAGS_trainer_count > 1) { auto mvMean = std::dynamic_pointer_cast(movingMean); auto mvVar = std::dynamic_pointer_cast(movingVar); CHECK(mvMean && mvVar); mvMean->add(*savedMean_, movingAvgFraction_, 1.0 - movingAvgFraction_); mvVar->add(*savedInvVar_, movingAvgFraction_, 1.0 - movingAvgFraction_); } else { // movingMean = movingMean * movingAvgFraction_ // + savedMean_ * (1 - movingAvgFraction_) movingMean->add(*savedMean_, movingAvgFraction_, 1.0 - movingAvgFraction_); // movingVar = movingVar * movingAvgFraction_ // + savedInvVar_ * (1 - movingAvgFraction_) movingVar->add(*savedInvVar_, movingAvgFraction_, 1.0 - movingAvgFraction_); } } void BatchNormalizationLayer::setMeanAndStd() { savedMean_->copyFrom(*(movingMean_->getW())); savedInvVar_->copyFrom(*(movingVar_->getW())); savedInvVar_->downClip(real(0.0)); savedInvVar_->subScalar(-EPS); savedInvVar_->sqrt(*savedInvVar_); } void BatchNormalizationLayer::expandMat(const MatrixPtr& in, MatrixPtr& out) { CHECK_EQ(in->getWidth(), static_cast(channels_ * imgPixels_)); CHECK_EQ(out->getWidth(), static_cast(channels_)); CHECK(!in->isTransposed()); CHECK(!out->isTransposed()); if (imgPixels_ == 1) { out->assign(*in); return; } size_t batchSize = in->getHeight(); CHECK_EQ(out->getHeight(), batchSize * imgPixels_); if (useGpu_) { #ifdef PADDLE_ONLY_CPU LOG(FATAL) << "paddle is compiled only for cpu"; #else batchTranspose(in->getData(), out->getData(), imgPixels_, channels_, batchSize); #endif } else { for (size_t i = 0; i < batchSize; i++) { const MatrixPtr inTmp = Matrix::create(in->getData() + i * imgPixels_ * channels_, channels_, imgPixels_, false, useGpu_); MatrixPtr outTmp = Matrix::create(out->getData() + i * imgPixels_ * channels_, imgPixels_, channels_, false, useGpu_); inTmp->transpose(outTmp, false); } } } void BatchNormalizationLayer::shrinkMat(const MatrixPtr& in, MatrixPtr& out) { CHECK_EQ(in->getWidth(), static_cast(channels_)); CHECK_EQ(out->getWidth(), static_cast(channels_ * imgPixels_)); size_t batchSize = out->getHeight(); CHECK(!in->isTransposed()); CHECK(!out->isTransposed()); if (imgPixels_ == 1) { out->assign(*in); return; } CHECK_EQ(in->getHeight(), static_cast(batchSize * imgPixels_)); if (useGpu_) { #ifdef PADDLE_ONLY_CPU LOG(FATAL) << "paddle is compiled only for cpu"; #else batchTranspose(in->getData(), out->getData(), channels_, imgPixels_, batchSize); #endif } else { for (size_t i = 0; i < batchSize; i++) { const MatrixPtr inTmp = Matrix::create(in->getData() + i * channels_ * imgPixels_, imgPixels_, channels_, false, useGpu_); MatrixPtr outTmp = Matrix::create(out->getData() + i * imgPixels_ * channels_, channels_, imgPixels_, useGpu_); inTmp->transpose(outTmp, false); } } } void BatchNormalizationLayer::forward(PassType passType) { Layer::forward(passType); int batchSize = getInputValue(0)->getHeight(); calFeatureMapSize(); resetOutput(batchSize, getInputValue(0)->getWidth()); // for testing in training peroid. useGlobalStats_ = (passType == PASS_TEST); if (passType == PASS_TEST && config_.has_use_global_stats()) { useGlobalStats_ = config_.use_global_stats(); } Matrix::resizeOrCreate(expandedIn_, batchSize * imgPixels_, channels_, false, useGpu_); Matrix::resizeOrCreate(normIn_, batchSize * imgPixels_, channels_, false, useGpu_); Matrix::resizeOrCreate(expandedOut_, batchSize * imgPixels_, channels_, false, useGpu_); expandMat(getInputValue(0), expandedIn_); if (useGlobalStats_) { if (firstTest_) { setMeanAndStd(); firstTest_ = false; } } else { calMeanAndStd(expandedIn_); firstTest_ = true; } normIn_->assign(*expandedIn_); normIn_->addBias(*savedMean_, -1); // subtract mean. normIn_->divRowVector(*savedInvVar_); // divide std. expandedOut_->assign(*normIn_); expandedOut_->mulRowVector(*weight_->getW()); // multiple gamma. if (biases_) { expandedOut_->addBias(*(biases_->getW()), 1); // add beta. } MatrixPtr out = getOutputValue(); shrinkMat(expandedOut_, out); /* activation */ { REGISTER_TIMER_INFO("FwAtvTimer", getName().c_str()); forwardActivation(); } } void BatchNormalizationLayer::backward(const UpdateCallback& callback) { /* Do derivation */ { REGISTER_TIMER_INFO("BpAvtTimer", getName().c_str()); backwardActivation(); } int batchSize = getInputValue(0)->getHeight(); Matrix::resizeOrCreate(meanGrad_, 1, channels_, false, useGpu_); Matrix::resizeOrCreate(stdGrad_, 1, channels_, false, useGpu_); Matrix::resizeOrCreate(expandedInGrad_, batchSize * imgPixels_, channels_, false, useGpu_); Matrix::resizeOrCreate(inGrad_, batchSize, imgPixels_ * channels_, false, useGpu_); Matrix::resizeOrCreate(normInGrad_, batchSize * imgPixels_, channels_, false, useGpu_); Matrix::resizeOrCreate(expandedOutGrad_, batchSize * imgPixels_, channels_, false, useGpu_); Matrix::resizeOrCreate(tmpMat_, batchSize * imgPixels_, channels_, false, useGpu_); Matrix::resizeOrCreate(tmpGrad_, batchSize * imgPixels_, channels_, false, useGpu_); expandMat(getOutputGrad(), expandedOutGrad_); // compute derivatives. if (biases_ && biases_->getWGrad()) { REGISTER_TIMER_INFO("BpBiasTimer", getName().c_str()); biases_->getWGrad()->collectBias(*expandedOutGrad_, 1); /* Increasing the number of gradient */ biases_->getParameterPtr()->incUpdate(callback); } if (weight_->getWGrad()) { tmpMat_->dotMul(*expandedOutGrad_, *normIn_); weight_->getWGrad()->collectBias(*tmpMat_, 1); } // compute input gradients. normInGrad_->assign(*expandedOutGrad_); normInGrad_->mulRowVector(*(weight_->getW())); // multiple gamma. // normInGrad * (x - \mu)/ \sqrt(\delta^2) tmpMat_->dotMul(*normInGrad_, *normIn_); stdGrad_->zeroMem(); stdGrad_->collectBias(*tmpMat_, -1.0 / (batchSize * imgPixels_)); tmpGrad_->assign(*normIn_); tmpGrad_->mulRowVector(*stdGrad_); meanGrad_->zeroMem(); meanGrad_->collectBias(*normInGrad_, -1.0 / (batchSize * imgPixels_)); expandedInGrad_->zeroMem(); expandedInGrad_->add(*normInGrad_, *tmpGrad_); expandedInGrad_->addRowVector(*meanGrad_); expandedInGrad_->divRowVector(*savedInvVar_); shrinkMat(expandedInGrad_, inGrad_); if (getInputGrad(0)) { getInputGrad(0)->add(*getInputGrad(0), *inGrad_); } { REGISTER_TIMER_INFO("WeightUpdate", getName().c_str()); weight_->getParameterPtr()->incUpdate(callback); } } } // namespace paddle