764 lines
37 KiB
C++
764 lines
37 KiB
C++
//
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// QNNConvolution.cpp
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// MNN
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//
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// Created by MNN on b'2025/04/10'.
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// Copyright © 2018, Alibaba Group Holding Limited
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//
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#include "QNNConvolution.hpp"
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#include <cmath>
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namespace MNN {
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namespace QNN {
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#ifdef ENABLE_QNN_ONLINE_FINALIZE
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static std::pair<int, int> closest_factors(int n) {
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int a = static_cast<int>(std::sqrt(n));
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for (; a >= 1; --a) {
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if (n % a == 0) {
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int b = n / a;
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return {a, b};
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}
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}
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return {1, n};
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}
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void QNNConvolution::isWeightQuantSupported(const Tensor *input, const int ic, const int oc){
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Qnn_DataType_t dataType = mBackend->getNativeTensor(input)->v1.dataType;
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if(mOp->main_as_Convolution2D()->quanParameter() == nullptr){
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mWeightQuant = false;
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return;
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}else{
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bool hasBias = false;
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auto bias = mOp->main_as_Convolution2D()->bias();
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auto biasPtr = (float*)bias->data();
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for(int i = 0; i < oc; ++i){
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if(biasPtr[i] != 0.0f){
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hasBias = true;
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break;
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}
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}
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std::shared_ptr<ConvolutionCommon::Int8Common> quanCommon = ConvolutionCommon::load(mOp, this->backend(), false, true);
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int totalCount = quanCommon->alpha.size();
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mBlockSize = totalCount / oc;
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if(quanCommon->asymmetric){
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// not support asymmetric and mBlockSize > 1 results incorrect now
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mWeightQuant = false;
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return;
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}
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if(dataType == QNN_DATATYPE_FLOAT_16 || dataType == QNN_DATATYPE_FLOAT_32){
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if(mIsMatMul && mBlockSize == 1){
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mWeightQuant = true;
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}else{
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mWeightQuant = false;
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}
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return;
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}
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if(mBlockSize > 1){
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if(mIs1x1Conv && hasBias == false && (ic / mBlockSize) >= 16){
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mWeightQuant = true;
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}else{
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mWeightQuant = false;
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}
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}else{
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mWeightQuant = true;
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}
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}
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}
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ErrorCode QNNConvolution::onEncode(const std::vector<Tensor *> &inputs, const std::vector<Tensor *> &outputs) {
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auto conv2D = mOp->main_as_Convolution2D();
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auto common = conv2D->common();
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Qnn_DataType_t dataType = mBackend->getNativeTensor(inputs[0])->v1.dataType;
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int n;
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int ih, iw, ic;
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int oh, ow, oc;
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int kernelH, kernelW;
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int strideH, strideW;
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int padTop, padBottom, padLeft, padRight;
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int dilationH, dilationW;
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int group;
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// compute shape
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{
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n = inputs[0]->batch();
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ih = inputs[0]->height(); iw = inputs[0]->width(); ic = inputs[0]->channel();
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oh = outputs[0]->height(); ow = outputs[0]->width(); oc = outputs[0]->channel();
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kernelH = common->kernelY(); kernelW = common->kernelX();
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strideH = common->strideY(); strideW = common->strideX();
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auto pads = ConvolutionCommon::convolutionPadFull(inputs[0], outputs[0], common);
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padTop = std::get<1>(pads); padBottom = std::get<3>(pads); padLeft = std::get<0>(pads); padRight = std::get<2>(pads);
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dilationH = common->dilateY(); dilationW = common->dilateX();
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group = common->group();
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}
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mIs1x1Conv = kernelW==1 && strideH==1 && \
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strideW==1 && dilationH==1 && dilationW==1 && group==1 && \
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padTop==0 && padBottom==0 && padLeft==0 && padRight==0;
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mIsMatMul = mIs1x1Conv;
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isWeightQuantSupported(inputs[0], ic, oc);
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if(mIsMatMul && mWeightQuant && (dataType == QNN_DATATYPE_FLOAT_16 || dataType == QNN_DATATYPE_FLOAT_32)){
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return onEncodeFpAIntBMatMul(inputs[0], outputs[0], n, ih, iw, ic, oc);
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}
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// MNN_PRINT("mIs1x1Conv:%d mIsMatMul:%d mWeightQuant:%d, Conv k%dx%d s%dx%d d%dx%d g%d nhw:%d %d %d, ic%d oc%d\n", mIs1x1Conv, mIsMatMul, mWeightQuant, kernelW, kernelH, strideW, strideH, dilationW, dilationH, group, n, ih, iw, ic, oc);
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// create all tensors and params
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{
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std::vector<uint32_t> strideData = {(uint32_t)strideH, (uint32_t)strideW};
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std::vector<uint32_t> padAmountData = {(uint32_t)padTop, (uint32_t)padBottom, (uint32_t)padLeft, (uint32_t)padRight};
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std::vector<uint32_t> dilationData = {(uint32_t)dilationH, (uint32_t)dilationW};
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this->createParamTensor("stride", QNN_DATATYPE_UINT_32, {2}, (void *)strideData.data());
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this->createParamTensor("pad_amount", QNN_DATATYPE_UINT_32, {2, 2}, (void *)padAmountData.data());
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this->createParamTensor("dilation", QNN_DATATYPE_UINT_32, {2}, (void *)dilationData.data());
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this->createParamScalar("group", (uint32_t)group);
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}
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this->createWeightAndBias(dataType, inputs[0], oc, ic, kernelH, kernelW, group);
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// dequant input and quant output
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if(mWeightQuant == false && dataType != QNN_DATATYPE_FLOAT_16 && dataType != QNN_DATATYPE_FLOAT_32){
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return this->onEncodeQuantDequantConv(inputs[0], outputs[0], n, ic, oc);
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}
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if (common->relu() || common->relu6()) {
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this->createStageTensor("ReluTensor", dataType, getNHWCShape(outputs[0]), outputs[0]);
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}
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// add nodes
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{
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if (common->relu() || common->relu6()) {
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// Stage one
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{
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mNodeType = "Conv2d";
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std::string name = mNodeName + "_conv";
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mParams.push_back(*(mParamTensorWrappers[0]->getNativeParam())); // stride
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mParams.push_back(*(mParamTensorWrappers[1]->getNativeParam())); // pad_amount
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mParams.push_back(*(mParamTensorWrappers[2]->getNativeParam())); // dilation
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mParams.push_back(*(mParamScalarWrappers[0]->getNativeParam())); // group
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mInputs.push_back(*(mBackend->getNativeTensor(inputs[0]))); // input
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mInputs.push_back(*(mTempTensorWrappers[0]->getNativeTensor())); // weight
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mInputs.push_back(*(mTempTensorWrappers[1]->getNativeTensor())); // bias
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mOutputs.push_back(*(mTempTensorWrappers[2]->getNativeTensor())); // stage tensor
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mBackend->addNodeToGraph(mOpConfigVersion, name.c_str(), mPackageName.c_str(), mNodeType.c_str(), mParams, mInputs, mOutputs);
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}
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// Stage two
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{
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mNodeType.clear();
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mParams.clear();
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mInputs.clear();
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mOutputs.clear();
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mNodeType = common->relu6() ? "Relu6" : "Relu";
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std::string name = mNodeName + "_relu";
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mInputs.push_back(*(mTempTensorWrappers[2]->getNativeTensor())); // stage tensor
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mOutputs.push_back(*(mBackend->getNativeTensor(outputs[0]))); // output
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mBackend->addNodeToGraph(mOpConfigVersion, name.c_str(), mPackageName.c_str(), mNodeType.c_str(), mParams, mInputs, mOutputs);
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}
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} else {
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if(mIsMatMul && n > 1) {
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auto num = closest_factors(n);
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{
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this->createStageTensor("InputReshapeTensor", dataType, std::vector<int>({1, num.first, num.second, ic}), inputs[0]);
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}
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{
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this->createStageTensor("OutputReshapeTensor", dataType, std::vector<int>({1, num.first, num.second, oc}), outputs[0]);
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}
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#ifdef QNN_VERBOSE
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MNN_PRINT("Matmul2Conv, start reshape batch:%d -> %dx%d\n", n, num.first, num.second);
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#endif
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// reshape input
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{
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std::string name = mNodeName + "_input_reshape";
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mParams.clear();
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mInputs.clear();
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mOutputs.clear();
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mNodeType = "Reshape";
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mInputs.push_back(*(mBackend->getNativeTensor(inputs[0]))); // input0
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mOutputs.push_back(*(mTempTensorWrappers[2]->getNativeTensor())); // temp input
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mBackend->addNodeToGraph(mOpConfigVersion, name.c_str(), mPackageName.c_str(), mNodeType.c_str(), mParams, mInputs, mOutputs);
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}
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// conv2d
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{
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std::string name = mNodeName;
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mParams.clear();
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mInputs.clear();
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mOutputs.clear();
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mNodeType = "Conv2d";
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mParams.push_back(*(mParamTensorWrappers[0]->getNativeParam())); // stride
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mParams.push_back(*(mParamTensorWrappers[1]->getNativeParam())); // pad_amount
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mParams.push_back(*(mParamTensorWrappers[2]->getNativeParam())); // dilation
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mParams.push_back(*(mParamScalarWrappers[0]->getNativeParam())); // group
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mInputs.push_back(*(mTempTensorWrappers[2]->getNativeTensor())); // input0
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mInputs.push_back(*(mTempTensorWrappers[0]->getNativeTensor())); // weight
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mInputs.push_back(*(mTempTensorWrappers[1]->getNativeTensor())); // bias
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mOutputs.push_back(*(mTempTensorWrappers[3]->getNativeTensor())); // temp output
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mBackend->addNodeToGraph(mOpConfigVersion, name.c_str(), mPackageName.c_str(), mNodeType.c_str(), mParams, mInputs, mOutputs);
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}
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// reshape output
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{
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std::string name = mNodeName + "_output_reshape";
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mParams.clear();
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mInputs.clear();
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mOutputs.clear();
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mNodeType = "Reshape";
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mInputs.push_back(*(mTempTensorWrappers[3]->getNativeTensor())); // temp output
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mOutputs.push_back(*(mBackend->getNativeTensor(outputs[0]))); // input0
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mBackend->addNodeToGraph(mOpConfigVersion, name.c_str(), mPackageName.c_str(), mNodeType.c_str(), mParams, mInputs, mOutputs);
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}
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return NO_ERROR;
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}
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mNodeType = "Conv2d";
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mParams.push_back(*(mParamTensorWrappers[0]->getNativeParam())); // stride
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mParams.push_back(*(mParamTensorWrappers[1]->getNativeParam())); // pad_amount
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mParams.push_back(*(mParamTensorWrappers[2]->getNativeParam())); // dilation
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mParams.push_back(*(mParamScalarWrappers[0]->getNativeParam())); // group
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mInputs.push_back(*(mBackend->getNativeTensor(inputs[0]))); // input
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mInputs.push_back(*(mTempTensorWrappers[0]->getNativeTensor())); // weight
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mInputs.push_back(*(mTempTensorWrappers[1]->getNativeTensor())); // bias
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mOutputs.push_back(*(mBackend->getNativeTensor(outputs[0]))); // output
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mBackend->addNodeToGraph(mOpConfigVersion, mNodeName.c_str(), mPackageName.c_str(), mNodeType.c_str(), mParams, mInputs, mOutputs);
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}
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}
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return NO_ERROR;
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}
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ErrorCode QNNConvolution::onEncodeQuantDequantConv(Tensor *input, Tensor *output, const int n, const int ic, const int oc) {
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auto conv2D = mOp->main_as_Convolution2D();
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auto common = conv2D->common();
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Qnn_DataType_t dataType = QNN_DATATYPE_FLOAT_32;
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if(mBackend->getUseFP16()){
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dataType = QNN_DATATYPE_FLOAT_16;
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}
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// create dequant input stage tensor
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this->createStageTensor("DequantInput", dataType, getNHWCShape(input)); // mTempTensorWrappers[2]
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this->createStageTensor("QuantOutput", dataType, getNHWCShape(output)); // mTempTensorWrappers[3]
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// add nodes
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{
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// dequant input
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{
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mParams.clear();
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mInputs.clear();
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mOutputs.clear();
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mNodeType = "Dequantize";
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std::string name = mNodeName + "_dequant_input";
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mInputs.push_back(*(mBackend->getNativeTensor(input))); // input
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mOutputs.push_back(*(mTempTensorWrappers[2]->getNativeTensor())); // DequantInput
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mBackend->addNodeToGraph(mOpConfigVersion, name.c_str(), mPackageName.c_str(), mNodeType.c_str(), mParams, mInputs, mOutputs);
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}
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if (common->relu() || common->relu6()) {
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this->createStageTensor("ReluTensor", dataType, getNHWCShape(output)); // mTempTensorWrappers[4]
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// Stage one
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{
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mParams.clear();
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mInputs.clear();
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mOutputs.clear();
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mNodeType = "Conv2d";
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std::string name = mNodeName + "_conv";
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mParams.push_back(*(mParamTensorWrappers[0]->getNativeParam())); // stride
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mParams.push_back(*(mParamTensorWrappers[1]->getNativeParam())); // pad_amount
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mParams.push_back(*(mParamTensorWrappers[2]->getNativeParam())); // dilation
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mParams.push_back(*(mParamScalarWrappers[0]->getNativeParam())); // group
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mInputs.push_back(*(mTempTensorWrappers[2]->getNativeTensor())); // DequantInput
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mInputs.push_back(*(mTempTensorWrappers[0]->getNativeTensor())); // weight
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mInputs.push_back(*(mTempTensorWrappers[1]->getNativeTensor())); // bias
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mOutputs.push_back(*(mTempTensorWrappers[4]->getNativeTensor())); // ReluTensor
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mBackend->addNodeToGraph(mOpConfigVersion, name.c_str(), mPackageName.c_str(), mNodeType.c_str(), mParams, mInputs, mOutputs);
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}
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// Stage two
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{
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mParams.clear();
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mInputs.clear();
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mOutputs.clear();
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mNodeType = common->relu6() ? "Relu6" : "Relu";
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std::string name = mNodeName + "_relu";
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mInputs.push_back(*(mTempTensorWrappers[4]->getNativeTensor())); // ReluTensor
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mOutputs.push_back(*(mTempTensorWrappers[3]->getNativeTensor())); // QuantOutput
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mBackend->addNodeToGraph(mOpConfigVersion, name.c_str(), mPackageName.c_str(), mNodeType.c_str(), mParams, mInputs, mOutputs);
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}
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} else {
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if(mIsMatMul && n > 1) {
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auto num = closest_factors(n);
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this->createStageTensor("InputReshapeTensor", dataType, std::vector<int>({1, num.first, num.second, ic})); // mTempTensorWrappers[4]
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this->createStageTensor("OutputReshapeTensor", dataType, std::vector<int>({1, num.first, num.second, oc})); // mTempTensorWrappers[5]
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#ifdef QNN_VERBOSE
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MNN_PRINT("Matmul2Conv, start reshape batch:%d -> %dx%d\n", n, num.first, num.second);
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#endif
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// reshape input
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{
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std::string name = mNodeName + "_input_reshape";
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mParams.clear();
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mInputs.clear();
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mOutputs.clear();
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mNodeType = "Reshape";
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mInputs.push_back(*(mTempTensorWrappers[2]->getNativeTensor())); // DequantInput
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mOutputs.push_back(*(mTempTensorWrappers[4]->getNativeTensor())); // InputReshapeTensor
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mBackend->addNodeToGraph(mOpConfigVersion, name.c_str(), mPackageName.c_str(), mNodeType.c_str(), mParams, mInputs, mOutputs);
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}
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// conv2d
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{
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std::string name = mNodeName;
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mParams.clear();
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mInputs.clear();
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mOutputs.clear();
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mNodeType = "Conv2d";
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mParams.push_back(*(mParamTensorWrappers[0]->getNativeParam())); // stride
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mParams.push_back(*(mParamTensorWrappers[1]->getNativeParam())); // pad_amount
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mParams.push_back(*(mParamTensorWrappers[2]->getNativeParam())); // dilation
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mParams.push_back(*(mParamScalarWrappers[0]->getNativeParam())); // group
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mInputs.push_back(*(mTempTensorWrappers[4]->getNativeTensor())); // InputReshapeTensor
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mInputs.push_back(*(mTempTensorWrappers[0]->getNativeTensor())); // weight
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mInputs.push_back(*(mTempTensorWrappers[1]->getNativeTensor())); // bias
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mOutputs.push_back(*(mTempTensorWrappers[5]->getNativeTensor())); // OutputReshapeTensor
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mBackend->addNodeToGraph(mOpConfigVersion, name.c_str(), mPackageName.c_str(), mNodeType.c_str(), mParams, mInputs, mOutputs);
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}
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// reshape output
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{
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std::string name = mNodeName + "_output_reshape";
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mParams.clear();
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mInputs.clear();
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mOutputs.clear();
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mNodeType = "Reshape";
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mInputs.push_back(*(mTempTensorWrappers[5]->getNativeTensor())); // OutputReshapeTensor
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mOutputs.push_back(*(mTempTensorWrappers[3]->getNativeTensor())); // QuantOutput
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mBackend->addNodeToGraph(mOpConfigVersion, name.c_str(), mPackageName.c_str(), mNodeType.c_str(), mParams, mInputs, mOutputs);
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}
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} else{
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mParams.clear();
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mInputs.clear();
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mOutputs.clear();
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mNodeType = "Conv2d";
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mParams.push_back(*(mParamTensorWrappers[0]->getNativeParam())); // stride
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mParams.push_back(*(mParamTensorWrappers[1]->getNativeParam())); // pad_amount
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mParams.push_back(*(mParamTensorWrappers[2]->getNativeParam())); // dilation
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mParams.push_back(*(mParamScalarWrappers[0]->getNativeParam())); // group
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mInputs.push_back(*(mTempTensorWrappers[2]->getNativeTensor())); // DequantInput
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mInputs.push_back(*(mTempTensorWrappers[0]->getNativeTensor())); // weight
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mInputs.push_back(*(mTempTensorWrappers[1]->getNativeTensor())); // bias
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mOutputs.push_back(*(mTempTensorWrappers[3]->getNativeTensor())); // QuantOutput
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mBackend->addNodeToGraph(mOpConfigVersion, mNodeName.c_str(), mPackageName.c_str(), mNodeType.c_str(), mParams, mInputs, mOutputs);
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}
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}
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// Quant output
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{
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auto QuantOutputTensor = mTempTensorWrappers[3]->getNativeTensor();
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if(mBackend->getUseFP16()){
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this->createStageTensor("CastOutput", QNN_DATATYPE_FLOAT_32, getNHWCShape(output));
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mParams.clear();
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mInputs.clear();
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mOutputs.clear();
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mNodeType = "Cast";
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std::string name = mNodeName + "_Cast_Output";
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mInputs.push_back(*(mTempTensorWrappers[3]->getNativeTensor())); // QuantOutput
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mOutputs.push_back(*(mTempTensorWrappers.back()->getNativeTensor())); // CastOutput
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mBackend->addNodeToGraph(mOpConfigVersion, name.c_str(), mPackageName.c_str(), mNodeType.c_str(), mParams, mInputs, mOutputs);
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QuantOutputTensor = mTempTensorWrappers.back()->getNativeTensor();
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}
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{
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mParams.clear();
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mInputs.clear();
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mOutputs.clear();
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mNodeType = "Quantize";
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std::string name = mNodeName + "_Quant_Output";
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mInputs.push_back(*(QuantOutputTensor)); // stage tensor
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mOutputs.push_back(*(mBackend->getNativeTensor(output))); // output
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mBackend->addNodeToGraph(mOpConfigVersion, name.c_str(), mPackageName.c_str(), mNodeType.c_str(), mParams, mInputs, mOutputs);
|
|
}
|
|
}
|
|
}
|
|
return NO_ERROR;
|
|
}
|
|
|
|
ErrorCode QNNConvolution::onEncodeFpAIntBMatMul(Tensor * input, Tensor * output, int n, int h, int w, int ic, int oc) {
|
|
// create parameters and stage tensors
|
|
auto conv2D = mOp->main_as_Convolution2D();
|
|
auto common = conv2D->common();
|
|
Qnn_DataType_t dataType = mBackend->getNativeTensor(input)->v1.dataType;
|
|
{
|
|
std::vector<uint32_t> tempInputShape = {(uint32_t) n * h * w , (uint32_t) ic};
|
|
std::vector<uint32_t> tempOutputShape = {(uint32_t) n * h * w , (uint32_t) oc};
|
|
this->createStageTensor("tempInput", dataType, tempInputShape);
|
|
this->createStageTensor("tempOutput", dataType, tempOutputShape);
|
|
|
|
// create weight and bias
|
|
{
|
|
Qnn_QuantizeParams_t weightQuantize{};
|
|
std::shared_ptr<ConvolutionCommon::Int8Common> quanCommon = ConvolutionCommon::load(mOp, this->backend(), false, true);
|
|
MNN_ASSERT(!quanCommon->asymmetric);
|
|
const int8_t * source = quanCommon->weight.get();
|
|
std::vector<int8_t> quantWeightData(oc * ic, 0);
|
|
if(quanCommon->canUseInt4){
|
|
for (int o = 0; o < oc; o++) {
|
|
for (int i = 0; i < ic; i++) {
|
|
uint32_t srcOffset = o * ic + i;
|
|
// Reorder weight to [ic, oc], to let 'transpose_1' = false
|
|
uint32_t dstOffset = i * oc + o;
|
|
if(srcOffset % 2 == 0){
|
|
quantWeightData[dstOffset] = ((source[srcOffset / 2] >> 4) & 0x0f) - 8;
|
|
}else{
|
|
quantWeightData[dstOffset] = (source[srcOffset / 2] & 0x0f) - 8;
|
|
}
|
|
}
|
|
}
|
|
}else{
|
|
// Reorder weight to [ic, oc], to let 'transpose_1' = false
|
|
for(int i = 0; i < ic; i++) {
|
|
for(int o = 0; o < oc; o++) {
|
|
quantWeightData[i * oc + o] = source[o * ic + i];
|
|
}
|
|
}
|
|
}
|
|
mDequantAlpha = quanCommon->alpha.get();
|
|
int totalCount = quanCommon->alpha.size();
|
|
mBlockSize = totalCount / oc;
|
|
int blockNum = ic / mBlockSize;
|
|
if(quanCommon->canUseInt4){
|
|
weightQuantize.encodingDefinition = QNN_DEFINITION_DEFINED;
|
|
weightQuantize.quantizationEncoding = QNN_QUANTIZATION_ENCODING_BW_AXIS_SCALE_OFFSET;
|
|
Qnn_BwAxisScaleOffset_t weightBWAxisScaleOffsetEncoding{};
|
|
weightBWAxisScaleOffsetEncoding.bitwidth = 4;
|
|
weightBWAxisScaleOffsetEncoding.axis = 0;
|
|
weightBWAxisScaleOffsetEncoding.numElements = oc;
|
|
mScale.resize(oc);
|
|
std::vector<int32_t> OffsetData(oc);
|
|
for (int i = 0; i < oc; i++) {
|
|
mScale[i] = mDequantAlpha[i];
|
|
}
|
|
weightBWAxisScaleOffsetEncoding.scales = mScale.data();
|
|
weightQuantize.bwAxisScaleOffsetEncoding = weightBWAxisScaleOffsetEncoding;
|
|
|
|
this->createStaticTensor("quantWeight", QNN_DATATYPE_SFIXED_POINT_8, {(uint32_t)ic, (uint32_t)oc}, (void *) quantWeightData.data(), weightQuantize);
|
|
std::function<void()> mReleaseWeightScaleOffset = [&](){
|
|
std::vector<float>().swap(mScale);
|
|
};
|
|
mBackend->pushReleaseFunc(mReleaseWeightScaleOffset);
|
|
}else{
|
|
weightQuantize.encodingDefinition = QNN_DEFINITION_DEFINED;
|
|
weightQuantize.quantizationEncoding = QNN_QUANTIZATION_ENCODING_AXIS_SCALE_OFFSET;
|
|
Qnn_AxisScaleOffset_t weightAxisScaleOffsetEncoding{};
|
|
weightAxisScaleOffsetEncoding.axis = 0;
|
|
weightAxisScaleOffsetEncoding.numScaleOffsets = oc;
|
|
mScaleOffsetData.resize(oc);
|
|
for (int i = 0; i < oc; i++) {
|
|
mScaleOffsetData[i].scale = mDequantAlpha[i];
|
|
mScaleOffsetData[i].offset = 0;
|
|
}
|
|
weightAxisScaleOffsetEncoding.scaleOffset = mScaleOffsetData.data();
|
|
weightQuantize.axisScaleOffsetEncoding = weightAxisScaleOffsetEncoding;
|
|
|
|
this->createStaticTensor("quantWeight", QNN_DATATYPE_SFIXED_POINT_8, {(uint32_t)ic, (uint32_t)oc}, (void *) quantWeightData.data(), weightQuantize);
|
|
std::function<void()> mReleaseWeightScaleOffset = [&](){
|
|
std::vector<Qnn_ScaleOffset_t>().swap(mScaleOffsetData);
|
|
};
|
|
mBackend->pushReleaseFunc(mReleaseWeightScaleOffset);
|
|
}
|
|
//create bias
|
|
this->createBias(dataType, oc, input, quanCommon);
|
|
}
|
|
|
|
if (common->relu() || common->relu6()) {
|
|
this->createStageTensor("ReluTensor", dataType, getNHWCShape(output));
|
|
}
|
|
}
|
|
|
|
// Stage One: reshape input
|
|
{
|
|
mNodeType = "Reshape";
|
|
std::string name = mNodeName + "_reshapeInput";
|
|
mParams.clear();
|
|
mInputs.clear();
|
|
mOutputs.clear();
|
|
mInputs.push_back(*(mBackend->getNativeTensor(input)));
|
|
mOutputs.push_back(*(mTempTensorWrappers[0]->getNativeTensor()));
|
|
mBackend->addNodeToGraph(mOpConfigVersion, name.c_str(), mPackageName.c_str(), mNodeType.c_str(), mParams, mInputs, mOutputs);
|
|
}
|
|
|
|
// Stage Two: matmul
|
|
{
|
|
mNodeType = "MatMul";
|
|
std::string name = mNodeName + "_MatMul";
|
|
mParams.clear();
|
|
mInputs.clear();
|
|
mOutputs.clear();
|
|
mInputs.push_back(*(mTempTensorWrappers[0]->getNativeTensor())); // tempInput
|
|
mInputs.push_back(*(mTempTensorWrappers[2]->getNativeTensor())); // weight
|
|
mInputs.push_back(*(mTempTensorWrappers[3]->getNativeTensor())); // bias
|
|
mOutputs.push_back(*(mTempTensorWrappers[1]->getNativeTensor())); // tempOutput
|
|
// mOutputs.push_back(*(mBackend->getNativeTensor(output)));
|
|
mBackend->addNodeToGraph(mOpConfigVersion, name.c_str(), mPackageName.c_str(), mNodeType.c_str(), mParams, mInputs, mOutputs);
|
|
}
|
|
|
|
// Stage Three: reshape output
|
|
{
|
|
mNodeType = "Reshape";
|
|
std::string name = mNodeName + "_reshapeOutput";
|
|
mParams.clear();
|
|
mInputs.clear();
|
|
mOutputs.clear();
|
|
mInputs.push_back(*(mTempTensorWrappers[1]->getNativeTensor()));
|
|
if (common->relu() || common->relu6()){
|
|
mOutputs.push_back(*(mTempTensorWrappers[4]->getNativeTensor())); //ReluTensor
|
|
}else{
|
|
mOutputs.push_back(*(mBackend->getNativeTensor(output)));
|
|
}
|
|
mBackend->addNodeToGraph(mOpConfigVersion, name.c_str(), mPackageName.c_str(), mNodeType.c_str(), mParams, mInputs, mOutputs);
|
|
}
|
|
|
|
// Stage Four: relu or relu6
|
|
if (common->relu() || common->relu6()){
|
|
mNodeType.clear();
|
|
mParams.clear();
|
|
mInputs.clear();
|
|
mOutputs.clear();
|
|
mNodeType = common->relu6() ? "Relu6" : "Relu";
|
|
std::string name = mNodeName + "_relu";
|
|
|
|
mInputs.push_back(*(mTempTensorWrappers[4]->getNativeTensor())); // ReluTensor
|
|
mOutputs.push_back(*(mBackend->getNativeTensor(output))); // output
|
|
mBackend->addNodeToGraph(mOpConfigVersion, name.c_str(), mPackageName.c_str(), mNodeType.c_str(), mParams, mInputs, mOutputs);
|
|
}
|
|
return NO_ERROR;
|
|
}
|
|
|
|
bool QNNConvolution::createWeightAndBias(Qnn_DataType_t dataType, const Tensor *input, int oc, int ic, int kernelH, int kernelW, int group) {
|
|
if(mWeightQuant){
|
|
Qnn_QuantizeParams_t weightQuantize{};
|
|
std::shared_ptr<ConvolutionCommon::Int8Common> quanCommon = ConvolutionCommon::load(mOp, this->backend(), false, true);
|
|
if(quanCommon->asymmetric) {
|
|
MNN_ERROR("[Error]: Qnn weight quant only support symmetric currently\n");
|
|
return false;
|
|
}
|
|
const int8_t * source = quanCommon->weight.get();
|
|
std::vector<int8_t> quantWeightData(oc * (ic / group) * kernelH * kernelW, 0);
|
|
if(quanCommon->canUseInt4){
|
|
for (int o = 0; o < oc; o++) {
|
|
for (int i = 0; i < ic/group; i++) {
|
|
for (int h = 0; h < kernelH; h++) {
|
|
for (int w = 0; w < kernelW; w++) {
|
|
uint32_t srcOffset = w + kernelW * (h + kernelH * (i + ic/group * o));
|
|
uint32_t dstOffset = o + oc * (i + ic/group * (w + kernelW * h));
|
|
if(srcOffset % 2 == 0){
|
|
quantWeightData[dstOffset] = ((source[srcOffset / 2] >> 4) & 0x0f) - 8;
|
|
}else{
|
|
quantWeightData[dstOffset] = (source[srcOffset / 2] & 0x0f) - 8;
|
|
}
|
|
}
|
|
}
|
|
}
|
|
}
|
|
}else{
|
|
convertWeight(source, (int8_t *) quantWeightData.data(), oc, ic/group, kernelH, kernelW);
|
|
}
|
|
mDequantAlpha = quanCommon->alpha.get();
|
|
int totalCount = quanCommon->alpha.size();
|
|
mBlockSize = totalCount / oc;
|
|
// Todo: result is wrong, need to verify
|
|
if(mBlockSize > 1){
|
|
Qnn_QuantizeParams_t weightQuantize{};
|
|
weightQuantize.encodingDefinition = QNN_DEFINITION_DEFINED;
|
|
weightQuantize.quantizationEncoding = QNN_QUANTIZATION_ENCODING_BLOCKWISE_EXPANSION;
|
|
|
|
weightBlockwiseExpansionEncoding.axis = 3;
|
|
weightBlockwiseExpansionEncoding.numBlocksPerAxis = mBlockSize;
|
|
weightBlockwiseExpansionEncoding.blockScaleBitwidth = 4;
|
|
weightBlockwiseExpansionEncoding.blockScaleStorageType = QNN_BLOCKWISE_EXPANSION_BITWIDTH_SCALE_STORAGE_8;
|
|
mBlockScale.resize(oc * mBlockSize);
|
|
mScaleOffsetData.resize(oc);
|
|
for (int i = 0; i < oc; i++) {
|
|
float maxscale = -std::numeric_limits<float>::max();
|
|
for(int j = 0; j < mBlockSize; ++j){
|
|
if(mDequantAlpha[i * mBlockSize + j] > maxscale){
|
|
maxscale = mDequantAlpha[i * mBlockSize + j];
|
|
}
|
|
}
|
|
float blockScale = maxscale / 16.0f;
|
|
for(int j = 0; j < mBlockSize; ++j){
|
|
int quantBlock = round(mDequantAlpha[i * mBlockSize + j] / blockScale);
|
|
mBlockScale[i * mBlockSize + j] = (uint8_t)std::min(std::max(quantBlock, 1), 16);
|
|
}
|
|
mScaleOffsetData[i].scale = blockScale;
|
|
mScaleOffsetData[i].offset = 0;
|
|
}
|
|
weightBlockwiseExpansionEncoding.scaleOffsets = mScaleOffsetData.data();
|
|
weightBlockwiseExpansionEncoding.blocksScale8 = mBlockScale.data();
|
|
weightQuantize.blockwiseExpansion = &weightBlockwiseExpansionEncoding;
|
|
this->createStaticTensor("quantWeight", QNN_DATATYPE_SFIXED_POINT_8, {(uint32_t)kernelH, (uint32_t)kernelW, (uint32_t)ic / (uint32_t)group, (uint32_t)oc}, (void *) quantWeightData.data(), weightQuantize);
|
|
std::function<void()> mReleaseWeightScaleOffset = [&](){
|
|
std::vector<Qnn_ScaleOffset_t>().swap(mScaleOffsetData);
|
|
};
|
|
mBackend->pushReleaseFunc(mReleaseWeightScaleOffset);
|
|
std::function<void()> mReleaseBlockScale = [&](){
|
|
std::vector<uint8_t>().swap(mBlockScale);
|
|
};
|
|
mBackend->pushReleaseFunc(mReleaseBlockScale);
|
|
}else if(quanCommon->canUseInt4){
|
|
weightQuantize.encodingDefinition = QNN_DEFINITION_DEFINED;
|
|
weightQuantize.quantizationEncoding = QNN_QUANTIZATION_ENCODING_BW_AXIS_SCALE_OFFSET;
|
|
Qnn_BwAxisScaleOffset_t weightBWAxisScaleOffsetEncoding{};
|
|
weightBWAxisScaleOffsetEncoding.bitwidth = 4;
|
|
weightBWAxisScaleOffsetEncoding.axis = 3;
|
|
weightBWAxisScaleOffsetEncoding.numElements = oc;
|
|
mScale.resize(oc);
|
|
std::vector<int32_t> OffsetData(oc);
|
|
for (int i = 0; i < oc; i++) {
|
|
mScale[i] = mDequantAlpha[i];
|
|
}
|
|
weightBWAxisScaleOffsetEncoding.scales = mScale.data();
|
|
weightQuantize.bwAxisScaleOffsetEncoding = weightBWAxisScaleOffsetEncoding;
|
|
|
|
this->createStaticTensor("quantWeight", QNN_DATATYPE_SFIXED_POINT_8, {(uint32_t)kernelH, (uint32_t)kernelW, (uint32_t)ic / (uint32_t)group, (uint32_t)oc}, (void *) quantWeightData.data(), weightQuantize);
|
|
std::function<void()> mReleaseWeightScaleOffset = [&](){
|
|
std::vector<float>().swap(mScale);
|
|
};
|
|
mBackend->pushReleaseFunc(mReleaseWeightScaleOffset);
|
|
}else{
|
|
weightQuantize.encodingDefinition = QNN_DEFINITION_DEFINED;
|
|
weightQuantize.quantizationEncoding = QNN_QUANTIZATION_ENCODING_AXIS_SCALE_OFFSET;
|
|
Qnn_AxisScaleOffset_t weightAxisScaleOffsetEncoding{};
|
|
weightAxisScaleOffsetEncoding.axis = 3;
|
|
weightAxisScaleOffsetEncoding.numScaleOffsets = oc;
|
|
mScaleOffsetData.resize(oc);
|
|
for (int i = 0; i < oc; i++) {
|
|
mScaleOffsetData[i].scale = mDequantAlpha[i];
|
|
mScaleOffsetData[i].offset = 0;
|
|
}
|
|
weightAxisScaleOffsetEncoding.scaleOffset = mScaleOffsetData.data();
|
|
weightQuantize.axisScaleOffsetEncoding = weightAxisScaleOffsetEncoding;
|
|
|
|
this->createStaticTensor("quantWeight", QNN_DATATYPE_SFIXED_POINT_8, {(uint32_t)kernelH, (uint32_t)kernelW, (uint32_t)ic / (uint32_t)group, (uint32_t)oc}, (void *) quantWeightData.data(), weightQuantize);
|
|
std::function<void()> mReleaseWeightScaleOffset = [&](){
|
|
std::vector<Qnn_ScaleOffset_t>().swap(mScaleOffsetData);
|
|
};
|
|
mBackend->pushReleaseFunc(mReleaseWeightScaleOffset);
|
|
}
|
|
this->createBias(dataType, oc, input, quanCommon);
|
|
} else {
|
|
std::vector<float> weightData;
|
|
const float* source = nullptr;
|
|
int weightElementNum = 0;
|
|
std::shared_ptr<ConvolutionCommon::Int8Common> quanWeight;
|
|
ConvolutionCommon::getConvParameters(&quanWeight, mBackend, mOp, &source, &weightElementNum);
|
|
// oc ic h w ---> h w ic oc
|
|
weightData.resize(weightElementNum);
|
|
convertWeight(source, (float *) weightData.data(), oc, ic/group, kernelH, kernelW);
|
|
Qnn_DataType_t floatDatatype = QNN_DATATYPE_FLOAT_32;
|
|
if(mBackend->getUseFP16()){
|
|
floatDatatype = QNN_DATATYPE_FLOAT_16;
|
|
}
|
|
this->createStaticFloatTensor("weight", floatDatatype, {(uint32_t)kernelH, (uint32_t)kernelW, (uint32_t)ic / (uint32_t)group, (uint32_t)oc}, weightData.data());
|
|
this->createBias(dataType, oc, input, nullptr);
|
|
}
|
|
return NO_ERROR;
|
|
}
|
|
|
|
|
|
void QNNConvolution::createBias(Qnn_DataType_t dataType, int oc, const Tensor *input, std::shared_ptr<ConvolutionCommon::Int8Common> quanCommon) {
|
|
int biasElementNum = oc;
|
|
if(dataType != QNN_DATATYPE_FLOAT_16 && dataType != QNN_DATATYPE_FLOAT_32 && mWeightQuant){
|
|
mDequantAlpha = quanCommon->alpha.get();
|
|
float inputScale = mBackend->getNativeTensor(input)->v1.quantizeParams.scaleOffsetEncoding.scale;
|
|
int inputOffset = mBackend->getNativeTensor(input)->v1.quantizeParams.scaleOffsetEncoding.offset;
|
|
std::vector<int> biasData;
|
|
biasData.resize(biasElementNum, 0);
|
|
|
|
Qnn_QuantizeParams_t biasQuantize{};
|
|
biasQuantize.encodingDefinition = QNN_DEFINITION_DEFINED;
|
|
biasQuantize.quantizationEncoding = QNN_QUANTIZATION_ENCODING_AXIS_SCALE_OFFSET;
|
|
Qnn_AxisScaleOffset_t biasAxisScaleOffsetEncoding{};
|
|
biasAxisScaleOffsetEncoding.axis = 0;
|
|
biasAxisScaleOffsetEncoding.numScaleOffsets = biasElementNum;
|
|
mBiasScaleOffsetData.resize(biasElementNum);
|
|
|
|
auto bias = mOp->main_as_Convolution2D()->bias();
|
|
auto biasPtr = (float*)bias->data();
|
|
if (nullptr != bias) {
|
|
for(int i = 0; i < biasElementNum; ++i){
|
|
float biasScale = inputScale * mDequantAlpha[i];
|
|
mBiasScaleOffsetData[i].scale = biasScale;
|
|
mBiasScaleOffsetData[i].offset = 0;
|
|
if(biasPtr[i] == 0.0f){
|
|
biasData[i] = 0;
|
|
} else{
|
|
biasData[i] = (int)(biasPtr[i] / biasScale);
|
|
}
|
|
}
|
|
}
|
|
|
|
biasAxisScaleOffsetEncoding.scaleOffset = mBiasScaleOffsetData.data();
|
|
biasQuantize.axisScaleOffsetEncoding = biasAxisScaleOffsetEncoding;
|
|
|
|
this->createStaticTensor("bias", QNN_DATATYPE_SFIXED_POINT_32, {(uint32_t)biasElementNum}, biasData.data(), biasQuantize);
|
|
std::function<void()> mReleaseBiasScaleOffset = [&](){
|
|
std::vector<Qnn_ScaleOffset_t>().swap(mBiasScaleOffsetData);
|
|
};
|
|
mBackend->pushReleaseFunc(mReleaseBiasScaleOffset);
|
|
}else{
|
|
std::vector<float> biasData;
|
|
biasData.resize(biasElementNum, 0);
|
|
auto bias = mOp->main_as_Convolution2D()->bias();
|
|
if (nullptr != bias) {
|
|
::memcpy((void *)biasData.data(), (void *)bias->data(), biasElementNum * sizeof(float));
|
|
}
|
|
Qnn_DataType_t floatDatatype = QNN_DATATYPE_FLOAT_32;
|
|
if(mBackend->getUseFP16()){
|
|
floatDatatype = QNN_DATATYPE_FLOAT_16;
|
|
}
|
|
this->createStaticFloatTensor("bias", floatDatatype, {(uint32_t)oc}, biasData.data());
|
|
}
|
|
}
|
|
|
|
class QNNConvolutionCreator : public QnnBackend::Creator {
|
|
public:
|
|
virtual QNNCommonExecution * onCreate(const std::vector<Tensor*>& inputs, const std::vector<Tensor*>& outputs, const MNN::Op* op,
|
|
Backend* backend) const override {
|
|
if (inputs.size() > 1) {
|
|
MNN_ERROR("QNN only support single conv input\n");
|
|
return nullptr;
|
|
}
|
|
return new QNNConvolution(backend, op);
|
|
}
|
|
};
|
|
|
|
REGISTER_QNN_OP_CREATOR(QNNConvolutionCreator, OpType_Convolution)
|
|
#endif
|
|
} // end namespace QNN
|
|
} // end namespace MNN
|