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AdaptiveAveragePooling3d.cpp
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AdaptiveAveragePooling3d.cpp
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#define TORCH_ASSERT_ONLY_METHOD_OPERATORS
#include <ATen/core/Tensor.h>
#include <ATen/Dispatch.h>
#include <ATen/Parallel.h>
#include <c10/util/irange.h>
#include <ATen/native/AdaptivePooling.h>
#ifndef AT_PER_OPERATOR_HEADERS
#include <ATen/Functions.h>
#include <ATen/NativeFunctions.h>
#else
#include <ATen/ops/_adaptive_avg_pool3d.h>
#include <ATen/ops/_adaptive_avg_pool3d_backward_native.h>
#include <ATen/ops/_adaptive_avg_pool3d_native.h>
#include <ATen/ops/adaptive_avg_pool3d_backward_native.h>
#include <ATen/ops/adaptive_avg_pool3d_native.h>
#include <ATen/ops/empty.h>
#include <ATen/ops/zeros_like.h>
#endif
namespace at {
namespace native {
namespace {
inline int64_t start_index(int64_t a, int64_t b, int64_t c) {
// NOLINTNEXTLINE(cppcoreguidelines-narrowing-conversions,bugprone-narrowing-conversions)
return (a / b) * c + ((a % b) * c) / b;
}
inline int64_t end_index(int64_t a, int64_t b, int64_t c) {
// NOLINTNEXTLINE(cppcoreguidelines-narrowing-conversions,bugprone-narrowing-conversions)
return 1 + ((a + 1) * c - 1) / b;
}
template <typename scalar_t>
static void adaptive_avg_pool3d_out_frame(
scalar_t* input_p,
scalar_t* output_p,
int64_t sizeD,
int64_t isizeT,
int64_t isizeH,
int64_t isizeW,
int64_t osizeT,
int64_t osizeH,
int64_t osizeW,
int64_t istrideD,
int64_t istrideT,
int64_t istrideH,
int64_t istrideW) {
at::parallel_for(0, sizeD, 1, [&](int64_t start, int64_t end) {
for (const auto d : c10::irange(start, end)) {
/* loop over output */
for (const auto ot : c10::irange(osizeT)) {
int istartT = start_index(ot, osizeT, isizeT);
int iendT = end_index(ot, osizeT, isizeT);
int kT = iendT - istartT;
for (const auto oh : c10::irange(osizeH)) {
int istartH = start_index(oh, osizeH, isizeH);
int iendH = end_index(oh, osizeH, isizeH);
int kH = iendH - istartH;
for (const auto ow : c10::irange(osizeW)) {
int istartW = start_index(ow, osizeW, isizeW);
int iendW = end_index(ow, osizeW, isizeW);
int kW = iendW - istartW;
/* local pointers */
scalar_t* ip = input_p + d * istrideD + istartT * istrideT +
istartH * istrideH + istartW * istrideW;
scalar_t* op = output_p + d * osizeT * osizeH * osizeW +
ot * osizeH * osizeW + oh * osizeW + ow;
/* compute local average: */
scalar_t sum = 0;
for (const auto it : c10::irange(kT)) {
for (const auto ih : c10::irange(kH)) {
for (const auto iw : c10::irange(kW)) {
scalar_t val =
*(ip + it * istrideT + ih * istrideH + iw * istrideW);
sum += val;
}
}
}
/* set output to local average */
*op = sum / kT / kH / kW;
}
}
}
}
});
}
void adaptive_avg_pool3d_out_cpu_template(
Tensor& output,
Tensor const& input,
IntArrayRef output_size) {
TORCH_CHECK(output_size.size() == 3, "adaptive_avg_pool3d: output_size must be 3");
for (const auto i : c10::irange(1, input.ndimension())) {
TORCH_CHECK(
input.size(i) > 0,
"adaptive_avg_pool3d(): Expected input to have non-zero size for non-batch dimensions, "
"but input has sizes ",
input.sizes(),
" with dimension ",
i,
" being "
"empty");
}
TORCH_CHECK(
(input.ndimension() == 4 || input.ndimension() == 5),
"adaptive_avg_pool3d(): Expected 4D or 5D tensor, but got ",
input.sizes());
TORCH_CHECK(input.dtype() == output.dtype(),
"expected dtype ", input.dtype(), " for `output` but got dtype ", output.dtype());
/* sizes */
int64_t sizeD = input.size(-4);
int64_t isizeT = input.size(-3);
int64_t isizeH = input.size(-2);
int64_t isizeW = input.size(-1);
/* strides */
int64_t istrideD = input.stride(-4);
int64_t istrideT = input.stride(-3);
int64_t istrideH = input.stride(-2);
int64_t istrideW = input.stride(-1);
/* output sizes */
auto osizeT = output_size[0];
auto osizeH = output_size[1];
auto osizeW = output_size[2];
if (input.ndimension() == 4) {
output.resize_({sizeD, osizeT, osizeH, osizeW});
AT_DISPATCH_FLOATING_TYPES_AND_HALF(
input.scalar_type(), "adaptive_avg_pool3d_cpu", [&] {
auto input_data = input.data_ptr<scalar_t>();
auto output_data = output.data_ptr<scalar_t>();
adaptive_avg_pool3d_out_frame<scalar_t>(
input_data,
output_data,
sizeD,
isizeT,
isizeH,
isizeW,
osizeT,
osizeH,
osizeW,
istrideD,
istrideT,
istrideH,
istrideW);
});
} else {
output.resize_({input.size(-5), sizeD, osizeT, osizeH, osizeW});
int64_t n = input.size(0);
AT_DISPATCH_FLOATING_TYPES_AND_HALF(
input.scalar_type(), "adaptive_avg_pool3d_cpu", [&] {
auto input_data = input.data_ptr<scalar_t>();
auto output_data = output.data_ptr<scalar_t>();
at::parallel_for(0, n, 1, [&](int64_t start, int64_t end) {
for (const auto b : c10::irange(start, end)) {
adaptive_avg_pool3d_out_frame<scalar_t>(
input_data + b * input.stride(0),
output_data + b * sizeD * osizeT * osizeH * osizeW,
sizeD,
isizeT,
isizeH,
isizeW,
osizeT,
osizeH,
osizeW,
istrideD,
istrideT,
istrideH,
istrideW);
}
});
});
}
}
template <typename scalar_t>
static void adaptive_avg_pool3d_backward_out_frame(
scalar_t* gradInput_p,
scalar_t* gradOutput_p,
int64_t sizeD,
int64_t isizeT,
int64_t isizeH,
int64_t isizeW,
int64_t osizeT,
int64_t osizeH,
int64_t osizeW) {
at::parallel_for(0, sizeD, 1, [&](int64_t start, int64_t end) {
for (const auto d : c10::irange(start, end)) {
scalar_t* gradInput_p_d = gradInput_p + d * isizeT * isizeW * isizeH;
scalar_t* gradOutput_p_d = gradOutput_p + d * osizeT * osizeW * osizeH;
/* calculate average */
for (const auto ot : c10::irange(osizeT)) {
int istartT = start_index(ot, osizeT, isizeT);
int iendT = end_index(ot, osizeT, isizeT);
int kT = iendT - istartT;
for (const auto oh : c10::irange(osizeH)) {
int istartH = start_index(oh, osizeH, isizeH);
int iendH = end_index(oh, osizeH, isizeH);
int kH = iendH - istartH;
for (const auto ow : c10::irange(osizeW)) {
int istartW = start_index(ow, osizeW, isizeW);
int iendW = end_index(ow, osizeW, isizeW);
int kW = iendW - istartW;
scalar_t grad_delta =
gradOutput_p_d[ot * osizeH * osizeW + oh * osizeW + ow] / kT /
kH / kW;
for (const auto it : c10::irange(istartT, iendT)) {
for (const auto ih : c10::irange(istartH, iendH)) {
for (const auto iw : c10::irange(istartW, iendW)) {
/* update gradient */
gradInput_p_d[it * isizeH * isizeW + ih * isizeW + iw] +=
grad_delta;
}
}
}
}
}
}
}
});
}
Tensor& adaptive_avg_pool3d_backward_out_cpu_template(
Tensor& gradInput,
const Tensor& gradOutput_,
const Tensor& input) {
/* get contiguous gradOutput */
auto gradOutput = gradOutput_.contiguous();
adaptive_pool_empty_output_check(gradOutput_, "adaptive_avg_pool3d_backward");
/* sizes */
int64_t sizeD = input.size(-4);
int64_t isizeT = input.size(-3);
int64_t isizeH = input.size(-2);
int64_t isizeW = input.size(-1);
int64_t osizeT = gradOutput.size(-3);
int64_t osizeH = gradOutput.size(-2);
int64_t osizeW = gradOutput.size(-1);
/* backprop */
if (input.ndimension() == 4) {
AT_DISPATCH_FLOATING_TYPES_AND_HALF(
input.scalar_type(), "adaptive_avg_pool3d_backward_cpu", [&] {
/* get raw pointers */
scalar_t* gradInput_data = gradInput.data_ptr<scalar_t>();
scalar_t* gradOutput_data = gradOutput.data_ptr<scalar_t>();
adaptive_avg_pool3d_backward_out_frame<scalar_t>(
gradInput_data,
gradOutput_data,
sizeD,
isizeT,
isizeH,
isizeW,
osizeT,
osizeH,
osizeW);
});
} else {
int64_t n = input.size(0);
AT_DISPATCH_FLOATING_TYPES_AND_HALF(
input.scalar_type(), "adaptive_avg_pool3d_backward_cpu", [&] {
/* get raw pointers */
scalar_t* gradInput_data = gradInput.data_ptr<scalar_t>();
scalar_t* gradOutput_data = gradOutput.data_ptr<scalar_t>();
at::parallel_for(0, n, 1, [&](int64_t start, int64_t end) {
for (const auto b : c10::irange(start, end)) {
adaptive_avg_pool3d_backward_out_frame<scalar_t>(
gradInput_data + b * sizeD * isizeT * isizeH * isizeW,
gradOutput_data + b * sizeD * osizeT * osizeH * osizeW,
sizeD,
isizeT,
isizeH,
isizeW,
osizeT,
osizeH,
osizeW);
}
});
});
}
return gradInput;
}
} // namespace
Tensor& adaptive_avg_pool3d_out_cpu(const Tensor& input,
IntArrayRef output_size,
Tensor& output) {
adaptive_avg_pool3d_out_cpu_template(output, input, output_size);
return output;
}
Tensor adaptive_avg_pool3d_cpu(Tensor const& input, IntArrayRef output_size) {
auto output = at::empty({0}, input.options());
adaptive_avg_pool3d_out_cpu_template(output, input, output_size);
return output;
}
Tensor adaptive_avg_pool3d_symint(Tensor const& input, SymIntArrayRef output_size) {
TORCH_CHECK(output_size.size() == 3, "adaptive_avg_pool3d: output_size must be 3");
TORCH_CHECK(
(output_size[0] >= 0 && output_size[1] >= 0 && output_size[2] >= 0),
"adaptive_avg_pool2d: elements of output_size must be greater than or equal to 0 ",
"but received {", output_size[0], ", ", output_size[1], ",", output_size[2], "}");
if (output_size[0] == 1 && output_size[1] == 1 && output_size[2] == 1 && !input.is_xpu()) {
// in this case, adaptive pooling is just computing mean over hw
// dimensions, which can be done more efficiently
Tensor out = input.mean({-1, -2, -3}, /* keepdim = */ true);
return out;
} else {
return _adaptive_avg_pool3d_symint(input, output_size);
}
}
Tensor& adaptive_avg_pool3d_backward_out_cpu(const Tensor& gradOutput_,
const Tensor& input,
Tensor& gradInput) {
gradInput.resize_as_(input).zero_();
adaptive_avg_pool3d_backward_out_cpu_template(gradInput, gradOutput_, input);
return gradInput;
}
Tensor adaptive_avg_pool3d_backward_cpu(const Tensor& gradOutput_,
const Tensor& input) {
auto gradInput = at::zeros_like(input, LEGACY_CONTIGUOUS_MEMORY_FORMAT);
adaptive_avg_pool3d_backward_out_cpu_template(gradInput, gradOutput_, input);
return gradInput;
}
} // namespace native
} // namespace at