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fashion-diffusion / preprocess /humanparsing /modules /src /inplace_abn_cuda_half.cu

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	#include <ATen/ATen.h>

	#include <cuda_fp16.h>

	#include <vector>

	#include "utils/checks.h"
	#include "utils/cuda.cuh"
	#include "inplace_abn.h"

	#include <ATen/cuda/CUDAContext.h>

	// Operations for reduce
	struct SumOpH {
	__device__ SumOpH(const half *t, int c, int s)
	: tensor(t), chn(c), sp(s) {}
	__device__ __forceinline__ float operator()(int batch, int plane, int n) {
	return __half2float(tensor[(batch * chn + plane) * sp + n]);
	}
	const half *tensor;
	const int chn;
	const int sp;
	};

	struct VarOpH {
	__device__ VarOpH(float m, const half *t, int c, int s)
	: mean(m), tensor(t), chn(c), sp(s) {}
	__device__ __forceinline__ float operator()(int batch, int plane, int n) {
	const auto t = __half2float(tensor[(batch * chn + plane) * sp + n]);
	return (t - mean) * (t - mean);
	}
	const float mean;
	const half *tensor;
	const int chn;
	const int sp;
	};

	struct GradOpH {
	__device__ GradOpH(float _weight, float _bias, const half _z, const half _dz, int c, int s)
	: weight(_weight), bias(_bias), z(_z), dz(_dz), chn(c), sp(s) {}
	__device__ __forceinline__ Pair<float> operator()(int batch, int plane, int n) {
	float _y = (__half2float(z[(batch * chn + plane) * sp + n]) - bias) / weight;
	float _dz = __half2float(dz[(batch * chn + plane) * sp + n]);
	return Pair<float>(_dz, _y * _dz);
	}
	const float weight;
	const float bias;
	const half *z;
	const half *dz;
	const int chn;
	const int sp;
	};

	/***********
	* mean_var
	***********/

	__global__ void mean_var_kernel_h(const half x, float mean, float *var, int num, int chn, int sp) {
	int plane = blockIdx.x;
	float norm = 1.f / static_cast<float>(num * sp);

	float _mean = reduce<float, SumOpH>(SumOpH(x, chn, sp), plane, num, sp) * norm;
	__syncthreads();
	float _var = reduce<float, VarOpH>(VarOpH(_mean, x, chn, sp), plane, num, sp) * norm;

	if (threadIdx.x == 0) {
	mean[plane] = _mean;
	var[plane] = _var;
	}
	}

	std::vector<at::Tensor> mean_var_cuda_h(at::Tensor x) {
	CHECK_CUDA_INPUT(x);

	// Extract dimensions
	int64_t num, chn, sp;
	get_dims(x, num, chn, sp);

	// Prepare output tensors
	auto mean = at::empty({chn},x.options().dtype(at::kFloat));
	auto var = at::empty({chn},x.options().dtype(at::kFloat));

	// Run kernel
	dim3 blocks(chn);
	dim3 threads(getNumThreads(sp));
	auto stream = at::cuda::getCurrentCUDAStream();
	mean_var_kernel_h<<<blocks, threads, 0, stream>>>(
	reinterpret_cast<half*>(x.data<at::Half>()),
	mean.data<float>(),
	var.data<float>(),
	num, chn, sp);

	return {mean, var};
	}

	/**********
	* forward
	**********/

	__global__ void forward_kernel_h(half x, const float mean, const float var, const float weight, const float *bias,
	bool affine, float eps, int num, int chn, int sp) {
	int plane = blockIdx.x;

	const float _mean = mean[plane];
	const float _var = var[plane];
	const float _weight = affine ? abs(weight[plane]) + eps : 1.f;
	const float _bias = affine ? bias[plane] : 0.f;

	const float mul = rsqrt(_var + eps) * _weight;

	for (int batch = 0; batch < num; ++batch) {
	for (int n = threadIdx.x; n < sp; n += blockDim.x) {
	half x_ptr = x + (batch chn + plane) * sp + n;
	float _x = __half2float(*x_ptr);
	float _y = (_x - _mean) * mul + _bias;

	*x_ptr = __float2half(_y);
	}
	}
	}

	at::Tensor forward_cuda_h(at::Tensor x, at::Tensor mean, at::Tensor var, at::Tensor weight, at::Tensor bias,
	bool affine, float eps) {
	CHECK_CUDA_INPUT(x);
	CHECK_CUDA_INPUT(mean);
	CHECK_CUDA_INPUT(var);
	CHECK_CUDA_INPUT(weight);
	CHECK_CUDA_INPUT(bias);

	// Extract dimensions
	int64_t num, chn, sp;
	get_dims(x, num, chn, sp);

	// Run kernel
	dim3 blocks(chn);
	dim3 threads(getNumThreads(sp));
	auto stream = at::cuda::getCurrentCUDAStream();
	forward_kernel_h<<<blocks, threads, 0, stream>>>(
	reinterpret_cast<half*>(x.data<at::Half>()),
	mean.data<float>(),
	var.data<float>(),
	weight.data<float>(),
	bias.data<float>(),
	affine, eps, num, chn, sp);

	return x;
	}

	__global__ void edz_eydz_kernel_h(const half z, const half dz, const float weight, const float bias,
	float edz, float eydz, bool affine, float eps, int num, int chn, int sp) {
	int plane = blockIdx.x;

	float _weight = affine ? abs(weight[plane]) + eps : 1.f;
	float _bias = affine ? bias[plane] : 0.f;

	Pair<float> res = reduce<Pair<float>, GradOpH>(GradOpH(_weight, _bias, z, dz, chn, sp), plane, num, sp);
	__syncthreads();

	if (threadIdx.x == 0) {
	edz[plane] = res.v1;
	eydz[plane] = res.v2;
	}
	}

	std::vector<at::Tensor> edz_eydz_cuda_h(at::Tensor z, at::Tensor dz, at::Tensor weight, at::Tensor bias,
	bool affine, float eps) {
	CHECK_CUDA_INPUT(z);
	CHECK_CUDA_INPUT(dz);
	CHECK_CUDA_INPUT(weight);
	CHECK_CUDA_INPUT(bias);

	// Extract dimensions
	int64_t num, chn, sp;
	get_dims(z, num, chn, sp);

	auto edz = at::empty({chn},z.options().dtype(at::kFloat));
	auto eydz = at::empty({chn},z.options().dtype(at::kFloat));

	// Run kernel
	dim3 blocks(chn);
	dim3 threads(getNumThreads(sp));
	auto stream = at::cuda::getCurrentCUDAStream();
	edz_eydz_kernel_h<<<blocks, threads, 0, stream>>>(
	reinterpret_cast<half*>(z.data<at::Half>()),
	reinterpret_cast<half*>(dz.data<at::Half>()),
	weight.data<float>(),
	bias.data<float>(),
	edz.data<float>(),
	eydz.data<float>(),
	affine, eps, num, chn, sp);

	return {edz, eydz};
	}

	__global__ void backward_kernel_h(const half z, const half dz, const float var, const float weight, const float bias, const float edz,
	const float eydz, half dx, bool affine, float eps, int num, int chn, int sp) {
	int plane = blockIdx.x;

	float _weight = affine ? abs(weight[plane]) + eps : 1.f;
	float _bias = affine ? bias[plane] : 0.f;
	float _var = var[plane];
	float _edz = edz[plane];
	float _eydz = eydz[plane];

	float _mul = _weight * rsqrt(_var + eps);
	float count = float(num * sp);

	for (int batch = 0; batch < num; ++batch) {
	for (int n = threadIdx.x; n < sp; n += blockDim.x) {
	float _dz = __half2float(dz[(batch * chn + plane) * sp + n]);
	float _y = (__half2float(z[(batch * chn + plane) * sp + n]) - _bias) / _weight;

	dx[(batch * chn + plane) * sp + n] = __float2half((_dz - _edz / count - _y * _eydz / count) * _mul);
	}
	}
	}

	at::Tensor backward_cuda_h(at::Tensor z, at::Tensor dz, at::Tensor var, at::Tensor weight, at::Tensor bias,
	at::Tensor edz, at::Tensor eydz, bool affine, float eps) {
	CHECK_CUDA_INPUT(z);
	CHECK_CUDA_INPUT(dz);
	CHECK_CUDA_INPUT(var);
	CHECK_CUDA_INPUT(weight);
	CHECK_CUDA_INPUT(bias);
	CHECK_CUDA_INPUT(edz);
	CHECK_CUDA_INPUT(eydz);

	// Extract dimensions
	int64_t num, chn, sp;
	get_dims(z, num, chn, sp);

	auto dx = at::zeros_like(z);

	// Run kernel
	dim3 blocks(chn);
	dim3 threads(getNumThreads(sp));
	auto stream = at::cuda::getCurrentCUDAStream();
	backward_kernel_h<<<blocks, threads, 0, stream>>>(
	reinterpret_cast<half*>(z.data<at::Half>()),
	reinterpret_cast<half*>(dz.data<at::Half>()),
	var.data<float>(),
	weight.data<float>(),
	bias.data<float>(),
	edz.data<float>(),
	eydz.data<float>(),
	reinterpret_cast<half*>(dx.data<at::Half>()),
	affine, eps, num, chn, sp);

	return dx;
	}

	__global__ void leaky_relu_backward_impl_h(half z, half dz, float slope, int64_t count) {
	for (int i = blockIdx.x * blockDim.x + threadIdx.x; i < count; i += blockDim.x * gridDim.x){
	float _z = __half2float(z[i]);
	if (_z < 0) {
	dz[i] = __float2half(__half2float(dz[i]) * slope);
	z[i] = __float2half(_z / slope);
	}
	}
	}

	void leaky_relu_backward_cuda_h(at::Tensor z, at::Tensor dz, float slope) {
	CHECK_CUDA_INPUT(z);
	CHECK_CUDA_INPUT(dz);

	int64_t count = z.numel();
	dim3 threads(getNumThreads(count));
	dim3 blocks = (count + threads.x - 1) / threads.x;
	auto stream = at::cuda::getCurrentCUDAStream();
	leaky_relu_backward_impl_h<<<blocks, threads, 0, stream>>>(
	reinterpret_cast<half*>(z.data<at::Half>()),
	reinterpret_cast<half*>(dz.data<at::Half>()),
	slope, count);
	}