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AdaptiveMaxPoolKernel.cpp
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AdaptiveMaxPoolKernel.cpp
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#define TORCH_ASSERT_ONLY_METHOD_OPERATORS
#include <ATen/core/Tensor.h>
#include <ATen/Dispatch.h>
#include <ATen/native/AdaptivePooling.h>
#include <ATen/Parallel.h>
#include <ATen/cpu/vec/vec.h>
#include <ATen/native/cpu/utils.h>
#include <c10/util/irange.h>
namespace at { namespace native {
namespace {
template <typename scalar_t, typename accscalar_t>
void cpu_adaptive_max_pool(
const Tensor& output_,
const Tensor& indices_,
const Tensor& input_,
IntArrayRef output_size) {
auto input = input_.contiguous();
auto output = output_.contiguous();
auto indices = indices_.contiguous();
auto input_data = input.data_ptr<scalar_t>();
auto output_data = output.data_ptr<scalar_t>();
auto indices_data = indices.data_ptr<int64_t>();
int64_t ndim = input.ndimension();
// treat batch size and channels as one dimension
int64_t channels = ndim == 3 ? input.size(0) : input.size(0) * input.size(1);
int64_t input_height = input.size(-2);
int64_t input_width = input.size(-1);
int64_t output_height = output_size[0];
int64_t output_width = output_size[1];
// parallel on dim of N, C
at::parallel_for(0, channels, 0, [&](int64_t begin, int64_t end) {
for (const auto c : c10::irange(begin, end)) {
scalar_t* input_ptr = input_data + c * input_height * input_width;
scalar_t* output_ptr = output_data + c * output_height * output_width;
int64_t* indices_ptr = indices_data + c * output_height * output_width;
for (const auto oh : c10::irange(output_height)) {
int64_t ih0 = start_index(oh, output_height, input_height);
int64_t ih1 = end_index(oh, output_height, input_height);
for (const auto ow : c10::irange(output_width)) {
int64_t iw0 = start_index(ow, output_width, input_width);
int64_t iw1 = end_index(ow, output_width, input_width);
// compute local max
int64_t maxindex = ih0 * input_width + iw0;
accscalar_t maxval = -std::numeric_limits<accscalar_t>::infinity();
for (int64_t ih = ih0; ih < ih1; ih ++) {
for (int64_t iw = iw0; iw < iw1; iw ++) {
int64_t index = ih * input_width + iw;
scalar_t val = input_ptr[index];
if ((val > maxval) || std::isnan(val)) {
maxval = val;
maxindex = index;
}
}
}
// set output to local max and store location of max
output_ptr[oh * output_width + ow] = maxval;
indices_ptr[oh * output_width + ow] = scalar_t(maxindex);
}
}
}
});
if (!output_.is_contiguous()) {
output_.copy_(output);
}
if (!indices_.is_contiguous()) {
indices_.copy_(indices);
}
}
template <typename scalar_t>
void cpu_adaptive_max_pool_channels_last(
const Tensor& output_,
const Tensor& indices_,
const Tensor& input_,
IntArrayRef output_size) {
TORCH_CHECK(input_.ndimension() == 4,
"adaptive max pooling with channels last format supports tensors with 4 dims");
auto memory_format = at::MemoryFormat::ChannelsLast;
auto input = input_.contiguous(memory_format);
auto output = output_.contiguous(memory_format);
auto indices = indices_.contiguous(memory_format);
auto input_data = input.data_ptr<scalar_t>();
auto output_data = output.data_ptr<scalar_t>();
auto indices_data = indices.data_ptr<int64_t>();
int64_t nbatch = input.size(0);
int64_t channels = input.size(1);
int64_t input_height = input.size(2);
int64_t input_width = input.size(3);
int64_t output_height = output_size[0];
int64_t output_width = output_size[1];
using Vec = vec::Vectorized<scalar_t>;
using integer_t = vec::int_same_size_t<scalar_t>;
using iVec = vec::Vectorized<integer_t>;
// for the convience of vectorization, use integer of the same size of scalar_t,
// e.g. int32_t for float, int64_t for double
// need to make sure doesn't overflow
TORCH_CHECK(input_height * input_width <= std::numeric_limits<integer_t>::max());
// parallel on dim of N, H, W
at::parallel_for(0, nbatch * output_height * output_width, 0, [&](int64_t begin, int64_t end) {
int64_t n = 0;
int64_t oh = 0;
int64_t ow = 0;
data_index_init(begin, n, nbatch, oh, output_height, ow, output_width);
int64_t size = channels;
int64_t len = size - (size % Vec::size());
// temp buffer holding index with integer_t
std::unique_ptr<integer_t []> index_buffer(new integer_t[len]);
for (const auto i : c10::irange(begin, end)) {
int64_t ih0 = start_index(oh, output_height, input_height);
int64_t ih1 = end_index(oh, output_height, input_height);
int64_t iw0 = start_index(ow, output_width, input_width);
int64_t iw1 = end_index(ow, output_width, input_width);
scalar_t* out = output_data + i * channels;
int64_t* ind = indices_data + i * channels;
// Pass I: init out lane
iVec index0_vec = iVec(ih0 * input_width + iw0);
Vec out_vec = Vec(-std::numeric_limits<scalar_t>::infinity());
int64_t d1 = 0;
for (; d1 < len; d1 += Vec::size()) {
index0_vec.store(index_buffer.get() + d1);
out_vec.store(out + d1);
}
for (; d1 < size; d1++) {
ind[d1] = ih0 * input_width + iw0;
out[d1] = -std::numeric_limits<scalar_t>::infinity();
}
// Pass II: compute local max
for (int64_t ih = ih0; ih < ih1; ih ++) {
for (int64_t iw = iw0; iw < iw1; iw ++) {
scalar_t* in = input_data + n * input_height * input_width * channels +
ih * input_width * channels + iw * channels;
int64_t d2 = 0;
for (; d2 < len; d2 += Vec::size()) {
iVec index_vec = iVec(ih * input_width + iw);
Vec val_vec = Vec::loadu(in + d2);
iVec maxindex_vec = iVec::loadu(index_buffer.get() + d2);
Vec maxval_vec = Vec::loadu(out + d2);
// true = all ones, false = all zeros
Vec mask = (val_vec > maxval_vec) | val_vec.isnan();
iVec imask = vec::cast<integer_t>(mask);
Vec out_vec = Vec::blendv(maxval_vec, val_vec, mask);
iVec ind_vec = iVec::blendv(maxindex_vec, index_vec, imask);
out_vec.store(out + d2);
ind_vec.store(index_buffer.get() + d2);
}
for (; d2 < size; d2++) {
int64_t index = ih * input_width + iw;
scalar_t val = in[d2];
int64_t maxindex = ind[d2];
scalar_t maxval = out[d2];
bool mask = (val > maxval) || std::isnan(val);
out[d2] = mask ? val : maxval;
ind[d2] = mask ? index : maxindex;
}
}
}
// convert indice data type
vec::convert<integer_t, int64_t>(index_buffer.get(), ind, len);
// move on to next output index
data_index_step(n, nbatch, oh, output_height, ow, output_width);
}
});
if (!output_.is_contiguous(memory_format)) {
output_.copy_(output);
}
if (!indices_.is_contiguous(memory_format)) {
indices_.copy_(indices);
}
}
template <>
void cpu_adaptive_max_pool_channels_last<BFloat16>(
const Tensor& output_,
const Tensor& indices_,
const Tensor& input_,
IntArrayRef output_size) {
TORCH_CHECK(input_.ndimension() == 4,
"adaptive max pooling with channels last format supports tensors with 4 dims");
auto memory_format = at::MemoryFormat::ChannelsLast;
auto input = input_.contiguous(memory_format);
auto output = output_.contiguous(memory_format);
auto indices = indices_.contiguous(memory_format);
auto input_data = input.data_ptr<BFloat16>();
auto output_data = output.data_ptr<BFloat16>();
auto indices_data = indices.data_ptr<int64_t>();
int64_t nbatch = input.size(0);
int64_t channels = input.size(1);
int64_t input_height = input.size(2);
int64_t input_width = input.size(3);
int64_t output_height = output_size[0];
int64_t output_width = output_size[1];
using bVec = vec::Vectorized<BFloat16>;
using fVec = vec::Vectorized<float>;
using iVec = vec::Vectorized<int32_t>;
// need to make sure doesn't overflow
TORCH_CHECK(input_height * input_width <= std::numeric_limits<int32_t>::max());
// parallel on dim of N, H, W
at::parallel_for(0, nbatch * output_height * output_width, 0, [&](int64_t begin, int64_t end) {
int64_t n = 0;
int64_t oh = 0;
int64_t ow = 0;
data_index_init(begin, n, nbatch, oh, output_height, ow, output_width);
int64_t size = channels;
int64_t len = size - (size % bVec::size());
// temp buffer holding index with integer_t
std::unique_ptr<int32_t []> index_buffer(new int32_t[len]);
// temp buffer holding max value with float
std::unique_ptr<float []> max_arr(new float[size]);
float* max = max_arr.get();
for (const auto i : c10::irange(begin, end)) {
int64_t ih0 = start_index(oh, output_height, input_height);
int64_t ih1 = end_index(oh, output_height, input_height);
int64_t iw0 = start_index(ow, output_width, input_width);
int64_t iw1 = end_index(ow, output_width, input_width);
BFloat16* out = output_data + i * channels;
int64_t* ind = indices_data + i * channels;
// Pass I: init out lane
iVec index0_ivec = iVec(ih0 * input_width + iw0);
fVec max_fvec = fVec(-std::numeric_limits<float>::infinity());
int64_t d1 = 0;
for (; d1 < len; d1 += fVec::size()) {
index0_ivec.store(index_buffer.get() + d1);
max_fvec.store(max + d1);
}
for (; d1 < size; d1++) {
ind[d1] = ih0 * input_width + iw0;
max[d1] = -std::numeric_limits<float>::infinity();
}
// Pass II: compute local max
for (int64_t ih = ih0; ih < ih1; ih ++) {
for (int64_t iw = iw0; iw < iw1; iw ++) {
BFloat16* in = input_data + n * input_height * input_width * channels +
ih * input_width * channels + iw * channels;
int64_t d2 = 0;
for (; d2 < len; d2 += bVec::size()) {
iVec index_ivec = iVec(ih * input_width + iw);
bVec val_bvec = bVec::loadu(in + d2);
fVec val_fvec0, val_fvec1;
std::tie(val_fvec0, val_fvec1) = convert_bfloat16_float(val_bvec);
iVec maxindex_ivec0 = iVec::loadu(index_buffer.get() + d2);
iVec maxindex_ivec1 = iVec::loadu(index_buffer.get() + d2 + iVec::size());
fVec maxval_fvec0 = fVec::loadu(max + d2);
fVec maxval_fvec1 = fVec::loadu(max + d2 + fVec::size());
// true = all ones, false = all zeros
fVec mask0 = (val_fvec0 > maxval_fvec0) | val_fvec0.isnan();
fVec mask1 = (val_fvec1 > maxval_fvec1) | val_fvec1.isnan();
iVec imask0 = vec::cast<int32_t>(mask0);
iVec imask1 = vec::cast<int32_t>(mask1);
fVec max_fvec0 = fVec::blendv(maxval_fvec0, val_fvec0, mask0);
fVec max_fvec1 = fVec::blendv(maxval_fvec1, val_fvec1, mask1);
iVec ind_ivec0 = iVec::blendv(maxindex_ivec0, index_ivec, imask0);
iVec ind_ivec1 = iVec::blendv(maxindex_ivec1, index_ivec, imask1);
max_fvec0.store(max + d2);
max_fvec1.store(max + d2 + fVec::size());
ind_ivec0.store(index_buffer.get() + d2);
ind_ivec1.store(index_buffer.get() + d2 + iVec::size());
}
for (; d2 < size; d2++) {
int64_t index = ih * input_width + iw;
float val = float(in[d2]);
int64_t maxindex = ind[d2];
float maxval = max[d2];
bool mask = (val > maxval) || std::isnan(val);
max[d2] = mask ? val : maxval;
ind[d2] = mask ? index : maxindex;
}
}
}
// Pass III: convert max values from float to bfloat16
int64_t d3 = 0;
for (; d3 < len; d3 += bVec::size()) {
fVec max_fvec0 = fVec::loadu(max + d3);
fVec max_fvec1 = fVec::loadu(max + d3 + fVec::size());
bVec max_bvec = convert_float_bfloat16(max_fvec0, max_fvec1);
max_bvec.store(out + d3);
}
for (; d3 < size; d3++) {
out[d3] = BFloat16(max[d3]);
}
// convert indice data type
vec::convert<int32_t, int64_t>(index_buffer.get(), ind, len);
// move on to next output index
data_index_step(n, nbatch, oh, output_height, ow, output_width);
}
});
if (!output_.is_contiguous(memory_format)) {
output_.copy_(output);
}
if (!indices_.is_contiguous(memory_format)) {
indices_.copy_(indices);
}
}
template <typename scalar_t>
void cpu_adaptive_max_pool_backward(
const Tensor& grad_input_,
const Tensor& grad_output_,
const Tensor& indices_) {
auto grad_output = grad_output_.contiguous();
auto indices = indices_.contiguous();
auto grad_input = grad_input_.contiguous();
auto grad_output_data = grad_output.data_ptr<scalar_t>();
auto indices_data = indices.data_ptr<int64_t>();
auto grad_input_data = grad_input.data_ptr<scalar_t>();
int64_t ndim = grad_output.ndimension();
// treat batch size and channels as one dimension
int64_t channels = ndim == 3 ? grad_output.size(0) : grad_output.size(0) * grad_output.size(1);
int64_t input_height = grad_input.size(-2);
int64_t input_width = grad_input.size(-1);
int64_t output_height = grad_output.size(-2);
int64_t output_width = grad_output.size(-1);
// parallel on dim of N, C
at::parallel_for(0, channels, 0, [&](int64_t begin, int64_t end) {
for (const auto c : c10::irange(begin, end)) {
scalar_t* grad_input_ptr = grad_input_data + c * input_height * input_width;
scalar_t* grad_output_ptr = grad_output_data + c * output_height * output_width;
int64_t* indices_ptr = indices_data + c * output_height * output_width;
for (const auto oh : c10::irange(output_height)) {
for (const auto ow : c10::irange(output_width)) {
// retrieve position of max
int64_t index = oh * output_width + ow;
int64_t maxindex = indices_ptr[index];
// update gradient
grad_input_ptr[maxindex] += grad_output_ptr[index];
}
}
}
});
if (!grad_input_.is_contiguous()) {
grad_input_.copy_(grad_input);
}
}
template <typename scalar_t>
void cpu_adaptive_max_pool_backward_channels_last(
const Tensor& grad_input_,
const Tensor& grad_output_,
const Tensor& indices_) {
TORCH_CHECK(grad_output_.ndimension() == 4,
"adaptive max pooling backward with channels last format supports tensors with 4 dims.");
auto memory_format = at::MemoryFormat::ChannelsLast;
auto grad_input = grad_input_.contiguous(memory_format);
auto grad_output = grad_output_.contiguous(memory_format);
auto indices = indices_.contiguous(memory_format);
auto grad_input_data = grad_input.data_ptr<scalar_t>();
auto grad_output_data = grad_output.data_ptr<scalar_t>();
auto indices_data = indices.data_ptr<int64_t>();
int64_t nbatch = grad_input.size(0);
int64_t channels = grad_input.size(1);
int64_t input_height = grad_input.size(2);
int64_t input_width = grad_input.size(3);
int64_t output_height = grad_output.size(2);
int64_t output_width = grad_output.size(3);
// parallel on dim N
at::parallel_for(0, nbatch, 0, [&](int64_t begin, int64_t end) {
for (const auto n : c10::irange(begin, end)) {
scalar_t* grad_input_ptr = grad_input_data + n * input_height * input_width * channels;
scalar_t* grad_output_ptr = grad_output_data + n * output_height * output_width * channels;
int64_t* indices_ptr = indices_data + n * output_height * output_width * channels;
for (const auto oh : c10::irange(output_height)) {
for (const auto ow : c10::irange(output_width)) {
scalar_t* gout = grad_output_ptr + oh * output_width * channels + ow * channels;
int64_t* ind = indices_ptr + oh * output_width * channels + ow * channels;
// TODO: gcc vectorization
for (const auto c : c10::irange(channels)) {
int64_t maxindex = ind[c];
grad_input_ptr[maxindex * channels + c] += gout[c];
}
}
}
}
});
if (!grad_input_.is_contiguous(memory_format)) {
grad_input_.copy_(grad_input);
}
}
void adaptive_max_pool2d_kernel_impl(
const Tensor& output,
const Tensor& indices,
const Tensor& input,
IntArrayRef output_size) {
switch (input.suggest_memory_format()) {
case at::MemoryFormat::Contiguous: {
AT_DISPATCH_FLOATING_TYPES_AND(ScalarType::BFloat16, input.scalar_type(), "adaptive_max_pool2d", [&] {
if (input.scalar_type() == ScalarType::BFloat16) {
cpu_adaptive_max_pool<BFloat16, /*accscalar_t*/float>(output, indices, input, output_size);
} else {
cpu_adaptive_max_pool<scalar_t, scalar_t>(output, indices, input, output_size);
}
});
break;
}
case at::MemoryFormat::ChannelsLast: {
AT_DISPATCH_FLOATING_TYPES_AND(ScalarType::BFloat16, input.scalar_type(), "adaptive_max_pool2d_channels_last", [&]{
cpu_adaptive_max_pool_channels_last<scalar_t>(output, indices, input, output_size);
});
break;
}
default:
TORCH_CHECK(false, "Unsupported memory format. Supports only ChannelsLast, Contiguous");
}
}
void adaptive_max_pool2d_backward_kernel_impl(
const Tensor& grad_input,
const Tensor& grad_output,
const Tensor& indices) {
// can't use grad_output memory format to switch here since grad_output might be NC11
switch (grad_input.suggest_memory_format()) {
case at::MemoryFormat::Contiguous: {
AT_DISPATCH_FLOATING_TYPES_AND(ScalarType::BFloat16, grad_output.scalar_type(), "adaptive_max_pool2d_backward", [&] {
cpu_adaptive_max_pool_backward<scalar_t>(grad_input, grad_output, indices);
});
break;
}
case at::MemoryFormat::ChannelsLast: {
AT_DISPATCH_FLOATING_TYPES_AND(ScalarType::BFloat16, grad_output.scalar_type(), "adaptive_max_pool2d_backward_channels_last", [&]{
cpu_adaptive_max_pool_backward_channels_last<scalar_t>(grad_input, grad_output, indices);
});
break;
}
default:
TORCH_CHECK(false, "Unsupported memory format. Supports only ChannelsLast, Contiguous");
}
}
} // anonymous namespace
REGISTER_DISPATCH(adaptive_max_pool2d_kernel, &adaptive_max_pool2d_kernel_impl);
REGISTER_DISPATCH(adaptive_max_pool2d_backward_kernel, &adaptive_max_pool2d_backward_kernel_impl);
}} // at::native