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2026-07-13 13:33:03 +08:00

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C++

//
// FuseLayerNorm.cpp
// MNNConverter
//
// Created by MNN on 2020/07/09.
// Copyright © 2018, Alibaba Group Holding Limited
//
#include <unordered_map>
#include "../TemplateMerge.hpp"
#include "MNN/expr/ExprCreator.hpp"
#include "MNN_generated.h"
#include "MergeHelpers.hpp"
namespace MNN {
namespace Express {
static bool loadAxisFromReduction(EXPRP mean_3, std::vector<int>& axis_var_) {
if (mean_3->inputs().size() > 1) {
EXPRP axis = mean_3->inputs().at(1)->expr().first;
auto axis_var = mean_3->inputs().at(1);
if (!helpers::IsConstant(axis)) {
return false;
}
auto info = axis_var->getInfo();
auto dim = axis_var->readMap<int>();
axis_var_.resize(info->size);
::memcpy(axis_var_.data(), dim, info->size * sizeof(int));
} else {
auto reduc = mean_3->get()->main_as_ReductionParam();
if (nullptr == reduc) {
return false;
}
if (reduc->dim() == nullptr) {
return false;
}
axis_var_.resize(reduc->dim()->size());
::memcpy(axis_var_.data(), reduc->dim()->data(), reduc->dim()->size() * sizeof(int));
}
return true;
}
class FuseLayerNorm {
public:
FuseLayerNorm();
private:
std::vector<int> axis_var_;
VARP x_var_;
VARP gamma_var_;
VARP beta_var_;
VARP epsilon_var_;
};
FuseLayerNorm::FuseLayerNorm() {
auto match = [this](EXPRP expr) -> bool {
if (!expr->get() || !helpers::IsBinaryAdd(expr)) {
return false;
}
EXPRP mul_3 = expr->inputs().at(0)->expr().first;
EXPRP beta = expr->inputs().at(1)->expr().first;
if(helpers::IsBinaryMul(beta) && helpers::IsConstant(mul_3)) {
auto temp = beta;
beta = mul_3;
mul_3 = temp;
}
if (!helpers::IsBinaryMul(mul_3) || !helpers::IsConstant(beta)) {
return false;
}
EXPRP mul_2 = mul_3->inputs().at(0)->expr().first;
EXPRP gamma = mul_3->inputs().at(1)->expr().first;
int gamma_index = 1;
if(helpers::IsBinaryMul(gamma) && helpers::IsConstant(mul_2)) {
auto temp = gamma;
gamma = mul_2;
mul_2 = temp;
gamma_index = 0;
}
if (!helpers::IsBinaryMul(mul_2) || !helpers::IsConstant(gamma)) {
return false;
}
EXPRP sub_2 = mul_2->inputs().at(0)->expr().first;
EXPRP rsqrt = mul_2->inputs().at(1)->expr().first;
if (!helpers::IsUnaryRsqrt(rsqrt) || !helpers::IsBinarySub(sub_2)) {
return false;
}
EXPRP add_2 = rsqrt->inputs().at(0)->expr().first;
if (!helpers::IsBinaryAdd(add_2)) {
return false;
}
EXPRP mean_3 = add_2->inputs().at(0)->expr().first;
EXPRP epsilon = add_2->inputs().at(1)->expr().first;
if (!helpers::IsReductionMean(mean_3) || !helpers::IsConstant(epsilon)) {
return false;
}
EXPRP square_1 = mean_3->inputs().at(0)->expr().first;
if (!helpers::IsUnarySquare(square_1)) {
return false;
}
auto axisLoad = loadAxisFromReduction(mean_3, axis_var_);
if (!axisLoad) {
return false;
}
VARP sub_2_var = mul_2->inputs().at(0);
if (square_1->inputs().at(0).get() != sub_2_var.get()) {
return false;
}
EXPRP x = sub_2->inputs().at(0)->expr().first;
EXPRP mean_2 = sub_2->inputs().at(1)->expr().first;
if (!helpers::IsReductionMean(mean_2)) {
return false;
}
VARP x_var = sub_2->inputs().at(0);
if (mean_2->inputs().at(0).get() != x_var.get()) {
return false;
}
std::vector<int> axisV2;
axisLoad = loadAxisFromReduction(mean_2, axisV2);
if (!axisLoad) {
return false;
}
if (axisV2 != axis_var_) {
return false;
}
// TODO(): Check if axis is satisfied or not.
// auto* x_info = x_var->getInfo();
// if (!x_info) {
// return false;
// }
// const int rank = x_info->dim.size();
// auto* axis_info = axis_var->getInfo();
// if (!axis_info) {
// return false;
// }
// std::vector<int> axes(axis_info->size);
// for (int i = 0; i < axis_info->size; ++i) {
// axes[i] = axis_var->readMap<int>()[i];
// if (axes[i] < 0) {
// axes[i] += rank;
// }
// }
// std::sort(axes.begin(), axes.end());
// for (int i = 0; i < axes.size(); ++i) {
// if (axes.at(i) != rank - axes.size() + i) {
// return false;
// }
// }
// Cache the variables to build layer normalization.
x_var_ = x_var;
gamma_var_ = mul_3->inputs().at(gamma_index);
beta_var_ = expr->inputs().at(1);
epsilon_var_ = add_2->inputs().at(1);
return true;
};
auto fold = [this](EXPRP expr) -> bool {
std::unique_ptr<MNN::LayerNormT> layer_norm(new MNN::LayerNormT);
layer_norm->axis = axis_var_;
layer_norm->epsilon = epsilon_var_->readMap<float>()[0];
auto* gamma_info = gamma_var_->getInfo();
auto* beta_info = beta_var_->getInfo();
const float* gamma = gamma_var_->readMap<float>();
const float* beta = beta_var_->readMap<float>();
if (!gamma_info || !beta_info || !gamma || !beta || gamma_info->size != beta_info->size) {
return false;
}
if (expr->name().size() > 0) {
MNN_PRINT("FuseLayerNorm as %s\n", expr->name().c_str());
}
int size = gamma_info->size;
layer_norm->gamma.resize(size);
layer_norm->beta.resize(size);
memcpy(layer_norm->gamma.data(), gamma, size * sizeof(float));
memcpy(layer_norm->beta.data(), beta, size * sizeof(float));
std::unique_ptr<OpT> layer_norm_op(new OpT);
layer_norm_op->name = expr->name();
layer_norm_op->type = OpType_LayerNorm;
layer_norm_op->main.type = OpParameter_LayerNorm;
layer_norm_op->main.value = layer_norm.release();
EXPRP layer_norm_expr = Expr::create(layer_norm_op.get(), {x_var_}, 1);
layer_norm_expr->setName(expr->name());
Expr::replace(expr, layer_norm_expr);
return true /*modified*/;
};
TemplateMerge::getInstance("Merge").insertTemplate("FuseLayerNorm", match, fold);
}
static FuseLayerNorm g_fuse_layer_norm;
} // namespace Express
} // namespace MNN