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

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//
// VulkanUnary.cpp
// MNN
//
// Created by MNN on 2019/01/31.
// Copyright © 2018, Alibaba Group Holding Limited
//
#include "VulkanUnary.hpp"
#include "core/Macro.h"
#include "core/TensorUtils.hpp"
namespace MNN {
struct Param {
ivec4 size;
vec4 slope;
};
VulkanUnary::VulkanUnary(const std::string& midType, Backend* bn, bool isInt, float slope0, float slope1, bool iscast) : VulkanBasicExecution(bn) {
mSlopes[0] = slope0;
mSlopes[1] = slope1;
auto vkbackend = static_cast<VulkanBackend*>(bn);
mParam = std::make_shared<VulkanBuffer>(vkbackend->getMemoryPool(), false, sizeof(Param), nullptr,
VK_BUFFER_USAGE_UNIFORM_BUFFER_BIT);
auto types = {
VK_DESCRIPTOR_TYPE_STORAGE_BUFFER,
VK_DESCRIPTOR_TYPE_STORAGE_BUFFER,
VK_DESCRIPTOR_TYPE_UNIFORM_BUFFER,
};
if (iscast) {
mUnaryPipeline = vkbackend->getPipeline(midType, types);
} else {
if (!midType.empty()) {
std::string pKey = "glsl_unary_";
if (isInt) {
pKey += "int_";
}
pKey += midType;
pKey += "_";
if (!isInt && vkbackend->useFP16()) {
pKey += "FP16_";
}
pKey += "comp";
mUnaryPipeline = vkbackend->getPipeline(pKey, types);
} else {
std::string pKey = (vkbackend->useFP16() && !isInt) ? "glsl_unary_FP16_comp" : "glsl_unary_comp";
mUnaryPipeline = vkbackend->getPipeline(pKey, types);
}
}
mDesSet.reset(mUnaryPipeline->createSet());
}
VulkanUnary::~VulkanUnary() {
}
static std::string _getMidType(const Op* op) {
std::string midType = "";
if (op->type() == OpType_TanH) {
midType = "TANH";
} else if (op->type() == OpType_Sigmoid) {
midType = "SIGMOID";
} else {
// unary op
auto unaryType = op->main_as_UnaryOp()->opType();
#define SETTYPE(type, name) if (unaryType == type) {midType = name; break;}
do {
SETTYPE(UnaryOpOperation_SIGMOID, "SIGMOID");
SETTYPE(UnaryOpOperation_TANH, "TANH");
SETTYPE(UnaryOpOperation_RSQRT, "RSQRT");
SETTYPE(UnaryOpOperation_SIGN, "SIGN");
SETTYPE(UnaryOpOperation_ABS, "ABS");
SETTYPE(UnaryOpOperation_NEG, "NEG");
SETTYPE(UnaryOpOperation_EXP, "EXP");
SETTYPE(UnaryOpOperation_SQRT, "SQRT");
SETTYPE(UnaryOpOperation_SQUARE, "SQUARE");
SETTYPE(UnaryOpOperation_LOG, "LOG");
SETTYPE(UnaryOpOperation_GELU, "GELU");
// Since SPIR-V lacks a built-in erf (gauss error function) instruction and the existing shader implementation of GELU is essentially an approximation of erf, there is no need to add a new implementation of GELU_STANDARD.
SETTYPE(UnaryOpOperation_GELU_STANDARD, "GELU");
SETTYPE(UnaryOpOperation_SILU, "SILU");
SETTYPE(UnaryOpOperation_TAN, "TAN");
SETTYPE(UnaryOpOperation_COS, "COS");
SETTYPE(UnaryOpOperation_SIN, "SIN");
SETTYPE(UnaryOpOperation_CEIL, "CEIL");
SETTYPE(UnaryOpOperation_FLOOR, "FLOOR");
SETTYPE(UnaryOpOperation_EXPM1, "EXPM1");
SETTYPE(UnaryOpOperation_RECIPROCAL, "RECIPROCAL");
SETTYPE(UnaryOpOperation_SINH, "SINH");
SETTYPE(UnaryOpOperation_ASIN, "ASIN");
SETTYPE(UnaryOpOperation_ASINH, "ASINH");
SETTYPE(UnaryOpOperation_COSH, "COSH");
SETTYPE(UnaryOpOperation_ACOS, "ACOS");
SETTYPE(UnaryOpOperation_ACOSH, "ACOSH");
SETTYPE(UnaryOpOperation_ATAN, "ATAN");
SETTYPE(UnaryOpOperation_ATANH, "ATANH");
SETTYPE(UnaryOpOperation_LOG1P, "LOG1P");
SETTYPE(UnaryOpOperation_ROUND, "ROUND");
SETTYPE(UnaryOpOperation_HARDSWISH, "HARDSWISH");
} while(false);
#undef SETTYPE
}
return midType;
}
ErrorCode VulkanUnary::onEncode(const std::vector<Tensor*>& inputs, const std::vector<Tensor*>& outputs,
const VulkanCommandPool::Buffer* cmdBuffer) {
// set param
auto size = inputs[0]->elementSize();
auto sizeC4 = UP_DIV(size, 4);
auto paramPtr = reinterpret_cast<Param*>(mParam->map());
paramPtr->size[0] = sizeC4;
::memcpy(paramPtr->slope, mSlopes, sizeof(float) * 4);
mParam->unmap();
auto vkBn = (VulkanBackend*)backend();
auto inputTensor = vkBn->getBuffer(inputs[0]);
auto outputTensor = vkBn->getBuffer(outputs[0]);
mDesSet->writeBuffer(outputTensor, 0);
mDesSet->writeBuffer(inputTensor, 1);
mDesSet->writeBuffer(mParam->buffer(), 2, mParam->size());
mUnaryPipeline->bind(cmdBuffer->get(), mDesSet->get());
vkCmdDispatch(cmdBuffer->get(), UP_DIV(sizeC4, 256), 1, 1);
return NO_ERROR;
}
class VulkanUnaryCreator : 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 {
auto vkBn = static_cast<VulkanBackend *>(bn);
if (op->type() == OpType_ReLU6) {
float minValue = 0.0f;
float maxValue = 6.0f;
if (op->main_as_Relu6() != nullptr) {
minValue = op->main_as_Relu6()->minValue();
maxValue = op->main_as_Relu6()->maxValue();
}
return new VulkanUnary("CLAMP", bn, false, minValue, maxValue);
}
if (op->type() == OpType_ReLU) {
return new VulkanUnary("RELU", bn, false, op->main_as_Relu()->slope());
}
if (op->type() == OpType_Cast) {
if (inputs[0]->getType().bytes() != 4 || outputs[0]->getType().bytes() != 4) {
return nullptr;
}
if (op->main_as_CastParam()->dstT() == MNN::DataType_DT_BOOL) {
return new VulkanUnary("glsl_cast_int_bool_comp", bn, false, 0.0f, 0.0f, true);
}
auto srcCode = inputs[0]->getType().code;
auto dstCode = outputs[0]->getType().code;
if (srcCode == dstCode) {
if (srcCode == halide_type_float || srcCode == halide_type_int) {
return new VulkanUnary("", bn, srcCode == halide_type_int);
}
return nullptr;
}
std::string pKey;
if (srcCode == halide_type_float && dstCode == halide_type_int) {
pKey = "glsl_cast_float_int_";
} else if (srcCode == halide_type_int && dstCode == halide_type_float) {
pKey = "glsl_cast_float_int_REVERT_";
} else {
return nullptr;
}
if (vkBn->useFP16()) {
pKey += "FP16_";
}
pKey += "comp";
return new VulkanUnary(pKey, bn, false, 0.0f, 0.0f, true);
}
auto midType = _getMidType(op);
if (midType.empty()) {
return nullptr;
}
return new VulkanUnary(midType, bn, inputs[0]->getType().code == halide_type_int);
}
};
static bool gResistor = []() {
VulkanBackend::addCreator(OpType_ReLU6, new VulkanUnaryCreator);
VulkanBackend::addCreator(OpType_ReLU, new VulkanUnaryCreator);
VulkanBackend::addCreator(OpType_Cast, new VulkanUnaryCreator);
VulkanBackend::addCreator(OpType_UnaryOp, new VulkanUnaryCreator);
VulkanBackend::addCreator(OpType_TanH, new VulkanUnaryCreator);
VulkanBackend::addCreator(OpType_Sigmoid, new VulkanUnaryCreator);
return true;
}();
} // namespace MNN