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alibaba--mnn/source/backend/vulkan/buffer/execution/VulkanLayernorm.cpp
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2026-07-13 13:33:03 +08:00

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//
// VulkanLayernorm.cpp
// MNN
//
// Created by MNN on 2019/01/31.
// Copyright © 2018, Alibaba Group Holding Limited
//
#include "VulkanLayernorm.hpp"
#include "core/Macro.h"
namespace MNN {
struct Param {
ivec4 size;
float eps;
};
VulkanLayernorm::VulkanLayernorm(const Op* op, Backend* backend, Tensor * tensor) : VulkanBasicExecution(backend) {
auto layer_norm_param = op->main_as_LayerNorm();
auto vkbackend = static_cast<VulkanBackend*>(backend);
if (nullptr != layer_norm_param->axis()) {
mAxisSize = layer_norm_param->axis()->size();
}
mGroup = layer_norm_param->group();
mUseRMSNorm = layer_norm_param->useRMSNorm();
mParam = vkbackend->allocUniform();
mEps = layer_norm_param->epsilon();
mFP16 = tensor->getType().code == halide_type_float && vkbackend->useFP16();
if (layer_norm_param->gamma() && layer_norm_param->beta()) {
mHasScale = true;
int size = layer_norm_param->gamma()->size();
auto prepareParam = [&](std::shared_ptr<Tensor>& paramTensor, const float* sourceData, const char* errorName) {
paramTensor.reset(Tensor::createDevice<float>({size}));
auto status = backend->onAcquireBuffer(paramTensor.get(), Backend::STATIC);
if (!status) {
MNN_ERROR("Out of memory when %s is acquired in LayerNorm.\n", errorName);
return false;
}
const void * paramData;
std::vector<int16_t> paramFP16;
if (mFP16) {
paramFP16.resize(size);
FLOAT_TO_HALF(sourceData, paramFP16.data(), size);
paramData = paramFP16.data();
} else {
paramData = (const void *) sourceData;
}
auto paramBuffer = vkbackend->getBuffer(paramTensor.get());
vkbackend->copyToGPUBuffer(paramData, std::get<0>(paramBuffer), std::get<1>(paramBuffer), std::get<2>(paramBuffer));
return true;
};
if (!prepareParam(mGamma, layer_norm_param->gamma()->data(), "gamma")) {
return;
}
if (layer_norm_param->beta()->size() != size) {
MNN_ERROR("Size of gamma and beta are not match in LayerNorm.\n");
return;
}
if (!prepareParam(mBias, layer_norm_param->beta()->data(), "beta")) {
return;
}
}
mKey = "glsl_norm_";
if (!mHasScale) {
mDesTypes = {
VK_DESCRIPTOR_TYPE_STORAGE_BUFFER,
VK_DESCRIPTOR_TYPE_STORAGE_BUFFER,
VK_DESCRIPTOR_TYPE_UNIFORM_BUFFER,
};
} else {
mDesTypes = {
VK_DESCRIPTOR_TYPE_STORAGE_BUFFER,
VK_DESCRIPTOR_TYPE_STORAGE_BUFFER,
VK_DESCRIPTOR_TYPE_UNIFORM_BUFFER,
VK_DESCRIPTOR_TYPE_STORAGE_BUFFER,
VK_DESCRIPTOR_TYPE_STORAGE_BUFFER,
};
mKey += "LAYERNORM_SCALE_";
}
if (mFP16) {
mKey += "FP16_";
}
mKey += "comp";
std::vector<uint32_t> spec = {mUseRMSNorm ? 1u : 0u};
mPipeline = vkbackend->getPipeline(mKey, mDesTypes, {}, spec);
mDesSet.reset(mPipeline->createSet());
mOptKey = "glsl_norm_opt_";
if (mHasScale) {
mOptKey += "LAYERNORM_SCALE_";
}
if (mFP16) {
mOptKey += "FP16_";
}
mOptKey += "comp";
mOptPipeline = vkbackend->getPipeline(mOptKey, mDesTypes, {}, spec);
mOptDesSet.reset(mOptPipeline->createSet());
}
VulkanLayernorm::VulkanLayernorm(Backend* bn, const VulkanLayernorm* src)
: VulkanBasicExecution(bn)
, mEps(src->mEps)
, mHasScale(src->mHasScale)
, mUseRMSNorm(src->mUseRMSNorm)
, mGroup(src->mGroup)
, mAxisSize(src->mAxisSize)
, mFP16(src->mFP16)
, mKey(src->mKey)
, mOptKey(src->mOptKey)
, mDesTypes(src->mDesTypes) {
auto vkbackend = static_cast<VulkanBackend*>(bn);
mParam = vkbackend->allocUniform();
mGamma = src->mGamma;
mBias = src->mBias;
std::vector<uint32_t> spec = {mUseRMSNorm ? 1u : 0u};
mPipeline = vkbackend->getPipeline(mKey, mDesTypes, {}, spec);
mDesSet.reset(mPipeline->createSet());
mOptPipeline = vkbackend->getPipeline(mOptKey, mDesTypes, {}, spec);
mOptDesSet.reset(mOptPipeline->createSet());
}
VulkanLayernorm::~VulkanLayernorm() {
auto vkbackend = static_cast<VulkanBackend*>(backend());
vkbackend->recycleUniform(mParam);
}
bool VulkanLayernorm::onClone(Backend* bn, const Op* op, VulkanBasicExecution** dst) {
if (nullptr == dst) {
return true;
}
auto res = new VulkanLayernorm(bn, this);
*dst = res;
return true;
}
ErrorCode VulkanLayernorm::onEncode(const std::vector<Tensor*>& inputs, const std::vector<Tensor*>& outputs,
const VulkanCommandPool::Buffer* cmdBuffer) {
// set param
auto vkBn = (VulkanBackend*)backend();
auto outside = 1;
auto inside = 1;
int rank = inputs.at(0)->dimensions();
if (mGroup > 1) {
outside = inputs.at(0)->length(0) * mGroup;
for (int i = 1; i < rank; i++) {
inside *= inputs.at(0)->length(i);
}
inside /= mGroup;
} else {
for (int i = 0; i < rank - mAxisSize; ++i) {
outside *= inputs.at(0)->length(i);
}
for (int i = rank - mAxisSize; i < rank; ++i) {
inside *= inputs.at(0)->length(i);
}
}
auto param = reinterpret_cast<Param*>(mParam->map());
param->size[0] = inside;
param->size[1] = outside;
param->size[2] = mUseRMSNorm ? 1 : 0;
param->size[3] = outside;
param->eps = mEps;
mParam->unmap();
auto inputTensor = vkBn->getBuffer(inputs[0]);
auto outputTensor = vkBn->getBuffer(outputs[0]);
auto maxGroupCountX = (int)vkBn->getDevice().proty().limits.maxComputeWorkGroupCount[0];
// LLM-oriented fast path: 1 workgroup per row (outside), parallel reduce over inside.
// Requires inside % 4 == 0; fallback when dispatch count might exceed device limits.
bool useOpt = (outside <= maxGroupCountX) && ((inside & 3) == 0);
if (useOpt) {
mOptDesSet->writeBuffer(outputTensor, 0);
mOptDesSet->writeBuffer(inputTensor, 1);
mOptDesSet->writeBuffer(mParam->buffer(), 2, mParam->size());
if (mHasScale) {
mOptDesSet->writeBuffer(vkBn->getBuffer(mGamma.get()), 3);
mOptDesSet->writeBuffer(vkBn->getBuffer(mBias.get()), 4);
}
mOptPipeline->bind(cmdBuffer->get(), mOptDesSet->get());
vkCmdDispatch(cmdBuffer->get(), outside, 1, 1);
} else {
mDesSet->writeBuffer(outputTensor, 0);
mDesSet->writeBuffer(inputTensor, 1);
mDesSet->writeBuffer(mParam->buffer(), 2, mParam->size());
if (mHasScale) {
mDesSet->writeBuffer(vkBn->getBuffer(mGamma.get()), 3);
mDesSet->writeBuffer(vkBn->getBuffer(mBias.get()), 4);
}
mPipeline->bind(cmdBuffer->get(), mDesSet->get());
vkCmdDispatch(cmdBuffer->get(), UP_DIV(outside, 64), 1, 1);
}
return NO_ERROR;
}
class VulkanLayernormCreator : public VulkanBackend::Creator {
public:
virtual VulkanBasicExecution* onCreate(const std::vector<Tensor*>& inputs, const std::vector<Tensor*>& outputs, const MNN::Op* op, Backend* bn) const override {
return new VulkanLayernorm(op, bn, inputs[0]);
}
};
static bool gResistor = []() {
VulkanBackend::addCreator(OpType_LayerNorm, new VulkanLayernormCreator);
return true;
}();
} // namespace MNN