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layer_norm_kernel.cpp
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layer_norm_kernel.cpp
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#define TORCH_ASSERT_ONLY_METHOD_OPERATORS
#include <ATen/native/layer_norm.h>
#include <cmath>
#include <tuple>
#include <ATen/core/Tensor.h>
#include <ATen/Dispatch.h>
#include <ATen/cpu/vec/functional.h>
#include <ATen/cpu/vec/vec.h>
#include <ATen/native/cpu/moments_utils.h>
#include <c10/util/irange.h>
#ifndef AT_PER_OPERATOR_HEADERS
#include <ATen/Functions.h>
#else
#include <ATen/ops/empty.h>
#endif
namespace at {
namespace native {
namespace {
template <typename T>
void LayerNormKernelImplInternal(
const Tensor& X,
const Tensor& gamma,
const Tensor& beta,
int64_t M,
int64_t N,
T eps,
Tensor* Y,
Tensor* mean,
Tensor* rstd) {
using T_ACC = vec::vec_scalar_t<T>;
using Vec = vec::Vectorized<T_ACC>;
TORCH_DCHECK_EQ(X.numel(), M * N);
DCHECK(!gamma.defined() || gamma.numel() == N);
DCHECK(!beta.defined() || beta.numel() == N);
const T* X_data = X.data_ptr<T>();
const T* gamma_data = gamma.defined() ? gamma.data_ptr<T>() : nullptr;
const T* beta_data = beta.defined() ? beta.data_ptr<T>() : nullptr;
T* Y_data = Y->data_ptr<T>();
T* mean_data = mean ? mean->data_ptr<T>() : nullptr;
T* rstd_data = rstd ? rstd->data_ptr<T>() : nullptr;
const bool gamma_null = gamma_data == nullptr;
const bool beta_null = beta_data == nullptr;
const bool mean_null = mean_data == nullptr;
const bool rstd_null = rstd_data == nullptr;
at::parallel_for(0, M, 1, [&](int64_t start, int64_t end) {
for (const auto i : c10::irange(start, end)) {
const T* X_ptr = X_data + i * N;
T* Y_ptr = Y_data + i * N;
T mean_val;
T rstd_val;
std::tie(mean_val, rstd_val) = utils::RowwiseMoments(X_ptr, N);
rstd_val = T(1) / std::sqrt(rstd_val + eps);
const T_ACC scale = rstd_val;
const T_ACC bias = -rstd_val * mean_val;
if (gamma_null || beta_null) {
for (const auto j : c10::irange(N)) {
const T gamma_v = gamma_null ? T(1) : gamma_data[j];
const T beta_v = beta_null ? T(0) : beta_data[j];
Y_ptr[j] = (X_ptr[j] * scale + bias) * gamma_v + beta_v;
}
} else {
vec::map3<T>(
[scale, bias](Vec x, Vec gamma, Vec beta) {
return (x * Vec(scale) + Vec(bias)) * gamma + beta;
},
Y_ptr,
X_ptr,
gamma_data,
beta_data,
N);
}
if (!mean_null) {
mean_data[i] = mean_val;
}
if (!rstd_null) {
rstd_data[i] = rstd_val;
}
}
});
}
void LayerNormKernelImpl(
const Tensor& X,
const Tensor& gamma,
const Tensor& beta,
int64_t M,
int64_t N,
double eps,
Tensor* Y,
Tensor* mean,
Tensor* rstd) {
AT_DISPATCH_FLOATING_TYPES_AND(at::ScalarType::BFloat16, X.scalar_type(),
"LayerNormKernelImpl", [&]() {
LayerNormKernelImplInternal<scalar_t>(
X, gamma, beta, M, N, static_cast<scalar_t>(eps), Y, mean, rstd);
});
}
template <typename T>
void LayerNormBackwardKernelImplInternal(
const Tensor& dY,
const Tensor& X,
const Tensor& mean,
const Tensor& rstd,
const Tensor& gamma,
int64_t M,
int64_t N,
Tensor* dX,
Tensor* dgamma,
Tensor* dbeta) {
using T_ACC = vec::vec_scalar_t<T>;
using Vec = vec::Vectorized<T_ACC>;
TORCH_DCHECK_EQ(dY.numel(), M * N);
TORCH_DCHECK_EQ(X.numel(), M * N);
TORCH_DCHECK_EQ(mean.numel(), M);
TORCH_DCHECK_EQ(rstd.numel(), M);
DCHECK(!gamma.defined() || gamma.numel() == N);
const T* dY_data = dY.template data_ptr<T>();
const T* X_data = X.template data_ptr<T>();
const T* mean_data = mean.template data_ptr<T>();
const T* rstd_data = rstd.template data_ptr<T>();
const T* gamma_data =
gamma.defined() ? gamma.template data_ptr<T>() : nullptr;
T* dX_data = dX->defined() ? dX->template data_ptr<T>() : nullptr;
T* dgamma_data = dgamma->defined() ? dgamma->template data_ptr<T>() : nullptr;
T* dbeta_data = dbeta->defined() ? dbeta->template data_ptr<T>() : nullptr;
const T_ACC scale = T_ACC(1) / static_cast<T_ACC>(N);
const bool gamma_null = gamma_data == nullptr;
const bool dX_null = dX_data == nullptr;
const bool dgamma_null = dgamma_data == nullptr;
const bool dbeta_null = dbeta_data == nullptr;
// 1. Use two path parallel reduction for dgamma and dbeta:
// First path: allocate an immediate buffer of size {2, max_threads, N},
// dgamma_buffer = buffer[0], dbeta_buffer = buffer[1]
// Parallel along dim0 and reduce dY and X along dim0 to buffer.
// Second path: parallel along dim1 and reduce buffer to dgamma and dbeta.
//
// 2. Fuse first path of dgamma/dbeta with dX to reuse X[i] and dY[i] in L1
// cache.
//
int num_threads = at::get_num_threads();
Tensor buffer = at::empty({0}, X.options());
T* buffer_data = nullptr;
if (!dgamma_null || !dbeta_null) {
// zero the immediate buffer and skip zero dgamma and dbeta
buffer.resize_({2, num_threads, N}).zero_();
buffer_data = buffer.template data_ptr<T>();
}
// First path of dgamma/dbeta and dX
at::parallel_for(0, M, 1, [&](int64_t start, int64_t end) {
int tid = at::get_thread_num();
TORCH_CHECK(
tid < num_threads,
"expect thread id smaller than ",
num_threads,
", got thread id ",
tid);
T* dgamma_buffer_ptr = dgamma_null ? nullptr : buffer_data + tid * N;
T* dbeta_buffer_ptr =
dbeta_null ? nullptr : buffer_data + num_threads * N + tid * N;
for (const auto i : c10::irange(start, end)) {
const T* dY_ptr = dY_data + i * N;
const T* X_ptr = X_data + i * N;
if (!dgamma_null) {
const T_ACC a = rstd_data[i];
const T_ACC b = -a * mean_data[i];
// Scalar math:
// for (const auto j : c10::irange(N)) {
// dgamma_data[j] += dY_ptr[j] * (a * X_ptr[j] + b);
// }
vec::map3<T>(
[a, b](Vec dgamma, Vec dy, Vec x) {
return dgamma + dy * (Vec(a) * x + Vec(b));
},
dgamma_buffer_ptr,
dgamma_buffer_ptr,
dY_ptr,
X_ptr,
N);
}
if (!dbeta_null) {
// Scalar math:
// for (const auto j : c10::irange(N)) {
// dbeta_data[j] += dY_ptr[j];
// }
vec::map2<T>(
[](Vec dbeta, Vec dy) { return dbeta + dy; },
dbeta_buffer_ptr,
dbeta_buffer_ptr,
dY_ptr,
N);
}
if (!dX_null) {
T* dX_ptr = dX_data + i * N;
T_ACC ds = T_ACC(0);
T_ACC db = T_ACC(0);
// Scalar math:
// for (const auto j : c10::irange(N)) {
// const T gamma_v = gamma_null ? T(1) : gamma_data[j];
// ds += dY_ptr[j] * X_ptr[j] * gamma_v;
// db += dY_ptr[j] * gamma_v;
// }
if (gamma_null) {
ds = vec::map2_reduce_all<T>(
[](Vec x, Vec y) { return x * y; },
[](Vec x, Vec y) { return x + y; },
dY_ptr,
X_ptr,
N);
db = vec::reduce_all<T>(
[](Vec& x, Vec& y) { return x + y; }, dY_ptr, N);
} else {
ds = vec::map3_reduce_all<T>(
[](Vec x, Vec y, Vec z) { return x * y * z; },
[](Vec x, Vec y) { return x + y; },
dY_ptr,
X_ptr,
gamma_data,
N);
db = vec::map2_reduce_all<T>(
[](Vec x, Vec y) { return x * y; },
[](Vec x, Vec y) { return x + y; },
dY_ptr,
gamma_data,
N);
}
const T_ACC a = rstd_data[i];
const T_ACC b = (db * mean_data[i] - ds) * a * a * a * scale;
const T_ACC c = -b * mean_data[i] - db * a * scale;
// Scalar math:
// for (const auto j : c10::irange(N)) {
// const T gamma_v = gamma_null ? T(1) : gamma_data[j];
// dX_ptr[j] = a * dY_ptr[j] * gamma_v + b * X_ptr[j] + c;
// }
if (gamma_null) {
vec::map2<T>(
[a, b, c](Vec dy, Vec x) {
return Vec(a) * dy + Vec(b) * x + Vec(c);
},
dX_ptr,
dY_ptr,
X_ptr,
N);
} else {
vec::map3<T>(
[a, b, c](Vec dy, Vec gamma, Vec x) {
return Vec(a) * dy * gamma + Vec(b) * x + Vec(c);
},
dX_ptr,
dY_ptr,
gamma_data,
X_ptr,
N);
}
}
}
});
// Second path of dgamma/dbeta
if (buffer_data != nullptr) {
parallel_for(0, N, 1, [&](int64_t start, int64_t end) {
for (const auto j : c10::irange(start, end)) {
T_ACC dgamma_v = T_ACC(0);
T_ACC dbeta_v = T_ACC(0);
for (const auto i : c10::irange(num_threads)) {
dgamma_v += buffer_data[i * N + j];
dbeta_v += buffer_data[num_threads * N + i * N + j];
}
if (!dgamma_null) {
// NOLINTNEXTLINE(clang-analyzer-core.NullDereference)
dgamma_data[j] = dgamma_v;
}
if (!dbeta_null) {
// NOLINTNEXTLINE(clang-analyzer-core.NullDereference)
dbeta_data[j] = dbeta_v;
}
}
});
}
}
void LayerNormBackwardKernelImpl(
const Tensor& dY,
const Tensor& X,
const Tensor& mean,
const Tensor& rstd,
const Tensor& gamma,
int64_t M,
int64_t N,
Tensor* dX,
Tensor* dgamma,
Tensor* dbeta) {
AT_DISPATCH_FLOATING_TYPES_AND(at::ScalarType::BFloat16, X.scalar_type(),
"LayerNormBackwardKernelImpl", [&]() {
LayerNormBackwardKernelImplInternal<scalar_t>(
dY.contiguous(), X, mean, rstd, gamma, M, N, dX, dgamma, dbeta);
});
}
} // namespace
REGISTER_DISPATCH(LayerNormKernel, &LayerNormKernelImpl);
REGISTER_DISPATCH(LayerNormBackwardKernel, &LayerNormBackwardKernelImpl);
} // namespace native
} // namespace at