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layer_norm_cuda.cpp
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#include <torch/extension.h>
#include <vector>
#include <cassert>
#include "compat.h"
namespace {
void compute_n1_n2(
at::Tensor input,
#ifdef VERSION_GE_1_1
at::IntArrayRef normalized_shape,
#else
at::IntList normalized_shape,
#endif
int& n1,
int& n2)
{
int idiff = input.ndimension() - normalized_shape.size();
n2 = 1;
for (int i = 0; i < (int)normalized_shape.size(); ++i) {
assert( input.sizes()[i+idiff] == normalized_shape[i] );
n2 *= normalized_shape[i];
}
n1 = 1;
for (int i = 0; i < idiff; ++i) {
n1 *= input.sizes()[i];
}
}
void check_args(
#ifdef VERSION_GE_1_1
at::IntArrayRef normalized_shape,
#else
at::IntList normalized_shape,
#endif
at::Tensor gamma,
at::Tensor beta
)
{
TORCH_CHECK(!gamma.defined() || gamma.sizes().equals(normalized_shape));
TORCH_CHECK(!beta.defined() || beta.sizes().equals(normalized_shape));
}
void check_args(
#ifdef VERSION_GE_1_1
at::IntArrayRef normalized_shape,
#else
at::IntList normalized_shape,
#endif
at::Tensor gamma
)
{
TORCH_CHECK(!gamma.defined() || gamma.sizes().equals(normalized_shape));
}
void check_args(
at::Tensor input,
#ifdef VERSION_GE_1_1
at::IntArrayRef normalized_shape,
#else
at::IntList normalized_shape,
#endif
int& n1,
int& n2
)
{
int64_t normalized_ndim = normalized_shape.size();
if (normalized_ndim < 1) {
std::stringstream ss;
ss << "Expected normalized_shape to be at least 1-dimensional, i.e., "
<< "containing at least one element, but got normalized_shape="
<< normalized_shape;
throw std::runtime_error(ss.str());
}
auto input_shape = input.sizes();
auto input_ndim = input.dim();
if (input_ndim < normalized_ndim ||
!input_shape.slice(input_ndim - normalized_ndim).equals(normalized_shape)) {
std::stringstream ss;
ss << "Given normalized_shape=" << normalized_shape
<< ", expected input with shape [*";
for (auto size : normalized_shape) {
ss << ", " << size;
}
ss << "], but got input of size" << input_shape;
throw std::runtime_error(ss.str());
}
compute_n1_n2(input,normalized_shape,n1,n2);
}
void check_args(
at::Tensor input,
#ifdef VERSION_GE_1_1
at::IntArrayRef normalized_shape,
#else
at::IntList normalized_shape,
#endif
at::Tensor gamma,
at::Tensor beta,
int& n1,
int& n2
)
{
check_args(input,normalized_shape,n1,n2);
check_args(normalized_shape,gamma,beta);
}
void check_args(
at::Tensor input,
#ifdef VERSION_GE_1_1
at::IntArrayRef normalized_shape,
#else
at::IntList normalized_shape,
#endif
at::Tensor gamma,
int& n1,
int& n2
)
{
check_args(input,normalized_shape,n1,n2);
check_args(normalized_shape,gamma);
}
}
void cuda_layer_norm(
at::Tensor* output,
at::Tensor* mean,
at::Tensor* invvar,
at::Tensor* input,
int n1,
int n2,
#ifdef VERSION_GE_1_1
at::IntArrayRef normalized_shape,
#else
at::IntList normalized_shape,
#endif
at::Tensor* gamma,
at::Tensor* beta,
double epsilon);
#define CHECK_CUDA(x) TORCH_CHECK(x.is_cuda(), #x " must be a CUDA tensor")
#define CHECK_CONTIGUOUS(x) TORCH_CHECK(x.is_contiguous(), #x " must be contiguous")
#define CHECK_INPUT(x) CHECK_CUDA(x); CHECK_CONTIGUOUS(x)
std::vector<at::Tensor> layer_norm(
at::Tensor input,
#ifdef VERSION_GE_1_1
at::IntArrayRef normalized_shape,
#else
at::IntList normalized_shape,
#endif
double epsilon) {
CHECK_INPUT(input);
int n1,n2;
check_args(input,normalized_shape,n1,n2);
at::Tensor output = at::empty_like(input);
at::Tensor mean = at::empty({n1}, input.options().dtype(input.scalar_type()==at::ScalarType::Half || input.scalar_type()==at::ScalarType::BFloat16 ? at::ScalarType::Float : input.scalar_type()));
at::Tensor invvar = at::empty_like(mean);
cuda_layer_norm(&output,&mean,&invvar,&input,n1,n2,
normalized_shape,NULL,NULL,epsilon);
return {output, mean, invvar};
}
std::vector<at::Tensor> layer_norm_affine(
at::Tensor input,
#ifdef VERSION_GE_1_1
at::IntArrayRef normalized_shape,
#else
at::IntList normalized_shape,
#endif
at::Tensor gamma,
at::Tensor beta,
double epsilon) {
CHECK_INPUT(input);
CHECK_INPUT(gamma);
CHECK_INPUT(beta);
int n1,n2;
check_args(input,normalized_shape,gamma,beta,n1,n2);
at::Tensor output = at::empty_like(input);
const auto stats_dtype = (input.scalar_type() == at::ScalarType::Half || input.scalar_type() == at::ScalarType::BFloat16) ? at::ScalarType::Float : input.scalar_type();
at::Tensor mean = at::empty({n1}, input.options().dtype(stats_dtype));
at::Tensor invvar = at::empty_like(mean);
cuda_layer_norm(&output,&mean,&invvar,&input,n1,n2,
normalized_shape,&gamma,&beta,epsilon);
return {output, mean, invvar};
}
std::vector<at::Tensor> layer_norm_affine_mixed_dtypes(
at::Tensor input,
#ifdef VERSION_GE_1_1
at::IntArrayRef normalized_shape,
#else
at::IntList normalized_shape,
#endif
at::Tensor gamma,
at::Tensor beta,
double epsilon) {
CHECK_INPUT(input);
int n1, n2;
check_args(input, normalized_shape, n1, n2);
at::Tensor output = at::empty_like(input, gamma.options().dtype(gamma.scalar_type()));
at::Tensor mean = at::empty({n1}, input.options().dtype(input.scalar_type() == at::ScalarType::Half || input.scalar_type() == at::ScalarType::BFloat16 ? at::ScalarType::Float : input.scalar_type()));
at::Tensor invvar = at::empty_like(mean);
cuda_layer_norm(&output, &mean, &invvar, &input, n1, n2,
normalized_shape, &gamma, &beta, epsilon);
return {output, mean, invvar};
}
void cuda_layer_norm_gradient(
at::Tensor* dout,
at::Tensor* mean,
at::Tensor* invvar,
at::Tensor* input_or_output,
int n1,
int n2,
#ifdef VERSION_GE_1_1
at::IntArrayRef normalized_shape,
#else
at::IntList normalized_shape,
#endif
at::Tensor* gamma,
at::Tensor* beta,
double epsilon,
at::Tensor* grad_input,
at::Tensor* grad_gamma,
at::Tensor* grad_beta,
bool memory_efficient
);
at::Tensor layer_norm_gradient(
at::Tensor dout,
c10::optional<at::Tensor> mean_,
at::Tensor invvar,
at::Tensor input_or_output,
#ifdef VERSION_GE_1_1
at::IntArrayRef normalized_shape,
#else
at::IntList normalized_shape,
#endif
double epsilon,
bool memory_efficient) {
CHECK_INPUT(dout);
CHECK_INPUT(invvar);
CHECK_INPUT(input_or_output);
int n1,n2;
check_args(input_or_output,normalized_shape,n1,n2);
at::Tensor grad_input = at::empty_like(input_or_output);
if (mean_.has_value()) {
cuda_layer_norm_gradient(&dout,&mean_.value(),&invvar,&input_or_output,n1,n2,
normalized_shape,NULL,NULL,epsilon,
&grad_input,NULL,NULL,memory_efficient);
} else {
cuda_layer_norm_gradient(&dout,NULL,&invvar,&input_or_output,n1,n2,
normalized_shape,NULL,NULL,epsilon,
&grad_input,NULL,NULL,memory_efficient);
}
return grad_input;
}
std::vector<at::Tensor> layer_norm_gradient_affine(
at::Tensor dout,
c10::optional<at::Tensor> mean_,
at::Tensor invvar,
at::Tensor input_or_output,
#ifdef VERSION_GE_1_1
at::IntArrayRef normalized_shape,
#else
at::IntList normalized_shape,
#endif
at::Tensor gamma,
at::Tensor beta,
double epsilon,
bool memory_efficient) {
CHECK_INPUT(dout);
CHECK_INPUT(invvar);
CHECK_INPUT(input_or_output);
CHECK_INPUT(gamma);
CHECK_INPUT(beta);
int n1,n2;
check_args(input_or_output,normalized_shape,gamma,beta,n1,n2);
at::Tensor grad_input = at::empty_like(input_or_output);
at::Tensor grad_gamma = at::empty_like(gamma);
at::Tensor grad_beta = at::empty_like(beta);
// at::Tensor *mean = mean_.has_value() ? &mean_.value() : NULL;
if (mean_.has_value()) {
cuda_layer_norm_gradient(&dout,&mean_.value(),&invvar,&input_or_output,n1,n2,
normalized_shape,&gamma,&beta,epsilon,
&grad_input,&grad_gamma,&grad_beta,memory_efficient);
} else {
cuda_layer_norm_gradient(&dout,NULL,&invvar,&input_or_output,n1,n2,
normalized_shape,&gamma,&beta,epsilon,
&grad_input,&grad_gamma,&grad_beta,memory_efficient);
}
return {grad_input, grad_gamma, grad_beta};
}
void cuda_rms_norm(
at::Tensor* output,
at::Tensor* invvar,
at::Tensor* input,
int n1,
int n2,
#ifdef VERSION_GE_1_1
at::IntArrayRef normalized_shape,
#else
at::IntList normalized_shape,
#endif
at::Tensor* gamma,
double epsilon);
#define CHECK_CUDA(x) TORCH_CHECK(x.is_cuda(), #x " must be a CUDA tensor")
#define CHECK_CONTIGUOUS(x) TORCH_CHECK(x.is_contiguous(), #x " must be contiguous")
#define CHECK_INPUT(x) CHECK_CUDA(x); CHECK_CONTIGUOUS(x)
std::vector<at::Tensor> rms_norm(
at::Tensor input,
#ifdef VERSION_GE_1_1
at::IntArrayRef normalized_shape,
#else
at::IntList normalized_shape,
#endif
double epsilon) {
CHECK_INPUT(input);
int n1,n2;
check_args(input,normalized_shape,n1,n2);
at::Tensor output = at::empty_like(input);
at::Tensor invvar = at::empty({n1}, input.options().dtype(input.scalar_type()==at::ScalarType::Half || input.scalar_type()==at::ScalarType::BFloat16 ? at::ScalarType::Float : input.scalar_type()));
cuda_rms_norm(&output,&invvar,&input,n1,n2,
normalized_shape,NULL,epsilon);
return {output, invvar};
}
std::vector<at::Tensor> rms_norm_affine(
at::Tensor input,
#ifdef VERSION_GE_1_1
at::IntArrayRef normalized_shape,
#else
at::IntList normalized_shape,
#endif
at::Tensor gamma,
double epsilon) {
CHECK_INPUT(input);
CHECK_INPUT(gamma);
int n1,n2;
check_args(input,normalized_shape,gamma,n1,n2);
at::Tensor output = at::empty_like(input);
const auto stats_dtype = (input.scalar_type() == at::ScalarType::Half || input.scalar_type() == at::ScalarType::BFloat16) ? at::ScalarType::Float : input.scalar_type();
at::Tensor invvar = at::empty({n1}, input.options().dtype(stats_dtype));
cuda_rms_norm(&output,&invvar,&input,n1,n2,
normalized_shape,&gamma,epsilon);
return {output, invvar};
}
std::vector<at::Tensor> rms_norm_affine_mixed_dtypes(
at::Tensor input,
#ifdef VERSION_GE_1_1
at::IntArrayRef normalized_shape,
#else
at::IntList normalized_shape,
#endif
at::Tensor gamma,
double epsilon) {
CHECK_INPUT(input);
int n1, n2;
check_args(input, normalized_shape, n1, n2);
at::Tensor output = at::empty_like(input, gamma.options().dtype(gamma.scalar_type()));
at::Tensor invvar = at::empty({n1}, input.options().dtype(input.scalar_type() == at::ScalarType::Half || input.scalar_type() == at::ScalarType::BFloat16 ? at::ScalarType::Float : input.scalar_type()));
cuda_rms_norm(&output,&invvar, &input, n1, n2,
normalized_shape, &gamma,epsilon);
return {output,invvar};
}
void cuda_rms_norm_gradient(
at::Tensor* dout,
at::Tensor* invvar,
at::Tensor* input_or_output,
int n1,
int n2,
#ifdef VERSION_GE_1_1
at::IntArrayRef normalized_shape,
#else
at::IntList normalized_shape,
#endif
at::Tensor* gamma,
double epsilon,
at::Tensor* grad_input,
at::Tensor* grad_gamma,
bool memory_efficient);
at::Tensor rms_norm_gradient(
at::Tensor dout,
at::Tensor invvar,
at::Tensor input_or_output,
#ifdef VERSION_GE_1_1
at::IntArrayRef normalized_shape,
#else
at::IntList normalized_shape,
#endif
double epsilon,
bool memory_efficient) {
CHECK_INPUT(dout);
CHECK_INPUT(invvar);
CHECK_INPUT(input_or_output);
int n1,n2;
check_args(input_or_output,normalized_shape,n1,n2);
at::Tensor grad_input = at::empty_like(input_or_output);
cuda_rms_norm_gradient(&dout,&invvar,&input_or_output,n1,n2,
normalized_shape,NULL,epsilon,
&grad_input,NULL,memory_efficient);
return grad_input;
}
std::vector<at::Tensor> rms_norm_gradient_affine(
at::Tensor dout,
at::Tensor invvar,
at::Tensor input_or_output,
#ifdef VERSION_GE_1_1
at::IntArrayRef normalized_shape,
#else
at::IntList normalized_shape,
#endif
at::Tensor gamma,
double epsilon,
bool memory_efficient) {
CHECK_INPUT(dout);
CHECK_INPUT(invvar);
CHECK_INPUT(input_or_output);
CHECK_INPUT(gamma);
int n1,n2;
check_args(input_or_output,normalized_shape,gamma,n1,n2);
at::Tensor grad_input = at::empty_like(input_or_output);
at::Tensor grad_gamma = at::empty_like(gamma);
cuda_rms_norm_gradient(&dout,&invvar,&input_or_output,n1,n2,
normalized_shape,&gamma,epsilon,
&grad_input,&grad_gamma,memory_efficient);
return {grad_input, grad_gamma};
}
PYBIND11_MODULE(TORCH_EXTENSION_NAME, m) {
m.def("forward_affine", &layer_norm_affine, "LayerNorm forward (CUDA)");
m.def("forward", &layer_norm, "LayerNorm forward (CUDA)");
m.def("backward_affine", &layer_norm_gradient_affine, "LayerNorm backward (CUDA)");
m.def("backward", &layer_norm_gradient, "LayerNorm backward (CUDA)");
m.def("forward_affine_mixed_dtypes", &layer_norm_affine_mixed_dtypes, "LayerNorm forward with mixed dtypes (CUDA) compatible with Megatron's implementation");
m.def("rms_forward_affine", &rms_norm_affine, "RMSNorm forward (CUDA)");
m.def("rms_forward", &rms_norm, "RMSNorm forward (CUDA)");
m.def("rms_backward_affine", &rms_norm_gradient_affine, "RMSNorm backward (CUDA)");
m.def("rms_backward", &rms_norm_gradient, "RMSNorm backward (CUDA)");
m.def("rms_forward_affine_mixed_dtypes", &rms_norm_affine_mixed_dtypes, "RMSNorm forward with mixed dtypes (CUDA) compatible with Megatron's implementation");
}