/* Copyright (c) 2017 PaddlePaddle Authors. 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 "MKLDNNFcLayer.h" #include "paddle/utils/Logging.h" using namespace mkldnn; // NOLINT typedef memory::format format; typedef inner_product_forward fc_fwd; typedef inner_product_backward_weights fc_bwdWgt; typedef inner_product_backward_data fc_bwdData; namespace paddle { REGISTER_LAYER(mkldnn_fc, MKLDNNFcLayer); bool MKLDNNFcLayer::init(const LayerMap& layerMap, const ParameterMap& parameterMap) { if (!MKLDNNLayer::init(layerMap, parameterMap)) { return false; } CHECK_EQ(inputLayers_.size(), 1) << "Only support one input layer yet"; CHECK_EQ(inputLayers_.size(), parameters_.size()); CHECK(!parameters_[0]->isSparse()) << "Do not support sparse yet"; // output size, cat not be changed oc_ = getSize(); oh_ = 1; ow_ = 1; ih_ = 1; iw_ = 1; // input size can not change in FC iLayerSize_ = inputLayers_[0]->getSize(); CHECK_EQ(parameters_[0]->getSize(), iLayerSize_ * oc_); // create weight weight_ = std::unique_ptr(new Weight(oc_, iLayerSize_, parameters_[0], 0)); // create biases if (biasParameter_.get() != NULL) { biases_ = std::unique_ptr(new Weight(1, oc_, biasParameter_)); } return true; } void MKLDNNFcLayer::convertWeightsFromPaddle() { if (hasInitedWgt_) { return; } CHECK(wgtVal_) << "should have been initialized"; bool hasNoSpatial_ = ih_ == 1 && iw_ == 1; auto targetDim = wgtVal_->getDims(); auto srcFmt = hasNoSpatial_ ? memory::format::io : memory::format::ihwo; wgtVal_->reorderDataFrom(wgtVal_, srcFmt, targetDim); hasInitedWgt_ = true; } void MKLDNNFcLayer::convertWeightsToPaddle() { CHECK(wgtVal_) << "should have been initialized"; bool hasNoSpatial_ = ih_ == 1 && iw_ == 1; auto targetDim = wgtVal_->getDims(); auto dstFmt = hasNoSpatial_ ? memory::format::io : memory::format::ihwo; wgtVal_->reorderDataTo(wgtVal_, dstFmt, targetDim); } void MKLDNNFcLayer::reshape() { reshapeInput(); CHECK_EQ(iLayerSize_, inputLayers_[0]->getSize()); ic_ = iLayerSize_ / (ih_ * iw_); CHECK_EQ(size_t(ic_ * ih_ * iw_), iLayerSize_) << "not divisible"; CHECK_EQ(size_t(oc_), getSize()); reshapeOutput(oh_, ow_); resizeOutput(bs_, oc_); printSizeInfo(); } void MKLDNNFcLayer::resetFwd() { bool hasBias = biases_ && biases_->getW(); const MatrixPtr& wgt = weight_->getW(); const MatrixPtr& bias = hasBias ? biases_->getW() : nullptr; const MatrixPtr& out = output_.value; if (inputIsOnlyMKLDNN()) { const MatrixPtr& in = getInputValue(0); inVal_ = std::dynamic_pointer_cast(in); CHECK(inVal_) << "Input should be MKLDNNMatrix"; } else { CHECK_EQ(getPrev(0)->getDeviceId(), CPU_DEVICE) << "Only support CPU yet"; const MatrixPtr& in = getInputValue(0, CPU_DEVICE); inVal_ = MKLDNNMatrix::create( in, memory::dims{bs_, ic_, ih_, iw_}, format::nchw, engine_); } inVal_->downSpatial(); wgtVal_ = MKLDNNMatrix::create( wgt, memory::dims{oc_, ic_, ih_, iw_}, format::oihw, engine_); wgtVal_->downSpatial(); biasVal_ = hasBias ? MKLDNNMatrix::create(bias, {oc_}, format::x, engine_) : nullptr; outVal_ = MKLDNNMatrix::create(out, {bs_, oc_}, format::nc, engine_); // change original output value to mkldnn output value output_.value = std::dynamic_pointer_cast(outVal_); if (!outputIsOnlyMKLDNN()) { // fc cpu output value do not need create convert // just share point getOutput(CPU_DEVICE).value->setData(output_.value->getData()); } // create forward handle prop_kind pk = prop_kind::forward; fc_fwd::desc fwdDesc = hasBias ? fc_fwd::desc(pk, inVal_->getMemoryDesc(), wgtVal_->getMemoryDesc(), biasVal_->getMemoryDesc(), outVal_->getMemoryDesc()) : fc_fwd::desc(pk, inVal_->getMemoryDesc(), wgtVal_->getMemoryDesc(), outVal_->getMemoryDesc()); fc_fwd::primitive_desc fwdPD = fc_fwd::primitive_desc(fwdDesc, engine_); if (hasBias) { fwd_.reset(new fc_fwd(fwdPD, *inVal_, *wgtVal_, *biasVal_, *outVal_)); } else { fwd_.reset(new fc_fwd(fwdPD, *inVal_, *wgtVal_, *outVal_)); } printValueFormatFlow(); pipelineFwd_.clear(); pipelineFwd_.push_back(*fwd_); } void MKLDNNFcLayer::resetBwd() { if (!needResetBwd_) { return; } needResetBwd_ = false; bool hasBias = biases_ && biases_->getWGrad(); /// backward weight CHECK(inVal_) << "Should have input value"; const MatrixPtr& wgt = weight_->getWGrad(); const MatrixPtr& bias = hasBias ? biases_->getWGrad() : nullptr; // TODO(TJ): merge outgrad int device = outputIsOnlyMKLDNN() ? MKLDNN_DEVICE : CPU_DEVICE; // for MKLDNN device: // can not directly cast outputgrad to mkldnnmatrix, // since each layer can not write the inputgrad to mkldnn inputgrad. // So just create from matrix with outputvalue format. // for CPU device: // fc do not need to convert from cpu device since output is always nc format // only need create from cpu device const MatrixPtr& out = getOutput(device).grad; outGrad_ = MKLDNNMatrix::create(out, outVal_->getPrimitiveDesc()); wgtGrad_ = MKLDNNMatrix::create(wgt, wgtVal_->getPrimitiveDesc()); biasGrad_ = hasBias ? MKLDNNMatrix::create(bias, biasVal_->getPrimitiveDesc()) : nullptr; // create memory primitive desc fc_fwd::desc fwdDesc = fc_fwd::desc(prop_kind::forward, inVal_->getMemoryDesc(), wgtGrad_->getMemoryDesc(), outGrad_->getMemoryDesc()); fc_fwd::primitive_desc fwdPD = fc_fwd::primitive_desc(fwdDesc, engine_); fc_bwdWgt::desc bwdWgtDesc = hasBias ? fc_bwdWgt::desc(inVal_->getMemoryDesc(), wgtGrad_->getMemoryDesc(), biasGrad_->getMemoryDesc(), outGrad_->getMemoryDesc()) : fc_bwdWgt::desc(inVal_->getMemoryDesc(), wgtGrad_->getMemoryDesc(), outGrad_->getMemoryDesc()); fc_bwdWgt::primitive_desc bwdWgtPD = fc_bwdWgt::primitive_desc(bwdWgtDesc, engine_, fwdPD); if (hasBias) { bwdWgt_.reset( new fc_bwdWgt(bwdWgtPD, *inVal_, *outGrad_, *wgtGrad_, *biasGrad_)); } else { bwdWgt_.reset(new fc_bwdWgt(bwdWgtPD, *inVal_, *outGrad_, *wgtGrad_)); } pipelineBwd_.clear(); pipelineBwd_.push_back(*bwdWgt_); /// backward data const MatrixPtr& in = inputLayers_[0]->getOutput().grad; if (in == nullptr) { return; } if (getInput(0, MKLDNN_DEVICE).getAllCount() > 1) { // TODO(TJ): use outputMaps_ ways to get the inGrad_ when merge outgrad done } else { inGrad_ = MKLDNNMatrix::create(in, inVal_->getPrimitiveDesc()); } fc_bwdData::desc bwdDataDesc = fc_bwdData::desc(inVal_->getMemoryDesc(), wgtGrad_->getMemoryDesc(), outGrad_->getMemoryDesc()); fc_bwdData::primitive_desc bwdDataPD = fc_bwdData::primitive_desc(bwdDataDesc, engine_, fwdPD); CHECK(wgtVal_) << "Should have weight memory"; bwdData_.reset(new fc_bwdData(bwdDataPD, *outGrad_, *wgtVal_, *inGrad_)); printGradFormatFlow(); pipelineBwd_.push_back(*bwdData_); } void MKLDNNFcLayer::updateInputData() { inVal_->setData(getInputValue(0, CPU_DEVICE)->getData()); } void MKLDNNFcLayer::updateWeights(const UpdateCallback& callback) { weight_->getParameterPtr()->incUpdate(callback); if (biases_ && biases_->getWGrad()) { biases_->getParameterPtr()->incUpdate(callback); } } } // namespace paddle