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FractionalMaxPool2d.cpp
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FractionalMaxPool2d.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 <ATen/TensorMeta.h>
#include <ATen/native/FractionalMaxPooling.h>
#include <c10/util/irange.h>
#ifndef AT_PER_OPERATOR_HEADERS
#include <ATen/Functions.h>
#include <ATen/NativeFunctions.h>
#else
#include <ATen/ops/fractional_max_pool2d_backward_native.h>
#include <ATen/ops/fractional_max_pool2d_native.h>
#endif
namespace at {
namespace meta {
TORCH_META_FUNC(fractional_max_pool2d) (
const at::Tensor& input,
IntArrayRef pool_size,
IntArrayRef output_size,
const at::Tensor& randomSamples
) {
TORCH_CHECK(
pool_size.size() == 2,
"fractional_max_pool2d: kernel_size must either be a single Int or tuple of Ints")
TORCH_CHECK(
output_size.size() == 2,
"fractional_max_pool2d: output_size must either be a single Int or tuple of Ints")
int64_t numBatch = 1;
int64_t planeDim = 0;
int64_t heightDim = 1;
int64_t widthDim = 2;
int64_t outputH = output_size[0];
int64_t outputW = output_size[1];
int64_t poolSizeH = pool_size[0];
int64_t poolSizeW = pool_size[1];
int64_t ndims = input.ndimension();
TORCH_CHECK(ndims == 3 || ndims == 4,
"fractional_max_pool2d(): Expected 3D or 4D tensor, but got: ", input.sizes());
for (const auto i : c10::irange(1, ndims)) {
TORCH_CHECK(input.size(i) > 0,
"fractional_max_pool2d(): Expected input to have non-zero size for non-batch dimensions, but got",
input.sizes(), " with dimension ", i, " being empty.");
}
if (ndims == 4) {
numBatch = input.size(0);
planeDim++;
heightDim++;
widthDim++;
}
/* sizes */
int64_t numPlanes = input.size(planeDim);
int64_t inputH = input.size(heightDim);
auto inputW = input.size(widthDim);
TORCH_CHECK(outputH + poolSizeH - 1 <= inputH,
"fractional_max_pool2d(): pool height ", poolSizeH,
" too large relative to input height ", inputH);
TORCH_CHECK(outputW + poolSizeW - 1 <= inputW,
"fractional_max_pool2d(): pool width ", poolSizeW,
" too large relative to input width ", inputW);
if (ndims == 3) {
set_output_raw_strided(0, {numPlanes, outputH, outputW}, {}, input.options());
/* indices will contain the locations for each output point */
set_output_raw_strided(1, {numPlanes, outputH, outputW}, {}, input.options().dtype(kLong));
} else {
set_output_raw_strided(0, {numBatch, numPlanes, outputH, outputW}, {}, input.options());
/* indices will contain the locations for each output point */
set_output_raw_strided(1, {numBatch, numPlanes, outputH, outputW}, {}, input.options().dtype(kLong));
}
}
TORCH_META_FUNC(fractional_max_pool2d_backward)(
const at::Tensor& gradOutput_,
const at::Tensor& input,
IntArrayRef pool_size /* unused */,
IntArrayRef output_size,
const at::Tensor& indices) {
int64_t numBatch = 1;
int planeDim = 0;
int heightDim = 1;
int widthDim = 2;
auto outputH = output_size[0];
auto outputW = output_size[1];
auto ndims = input.ndimension();
if (ndims == 4) {
numBatch = input.size(0);
planeDim = 1;
heightDim++;
widthDim++;
}
/* sizes */
auto numPlanes = input.size(planeDim);
auto inputH = input.size(heightDim);
auto inputW = input.size(widthDim);
/* get contiguous gradOutput */
auto gradOutput = gradOutput_.contiguous();
TORCH_CHECK(outputW == gradOutput.size(widthDim),
"fractional_max_pool2d_backward(): gradOutput width unexpected");
TORCH_CHECK(outputH == gradOutput.size(heightDim),
"fractional_max_pool2d_backward(): gradOutput height unexpected");
/* resize */
if (ndims == 3) {
set_output_raw_strided(0, {numPlanes, inputH, inputW}, {}, input.options());
} else {
set_output_raw_strided(0, {numBatch, numPlanes, inputH, inputW}, {}, input.options());
}
}
} // namespace meta
namespace native {
namespace {
template <typename scalar_t>
static void fractional_max_pool2d_out_single_batch_frame(
const scalar_t* input,
scalar_t* output,
int64_t* indices,
const scalar_t* randomSamples,
int numPlanes,
int inputW, int inputH,
int outputW, int outputH,
int poolSizeW, int poolSizeH) {
at::parallel_for(0, numPlanes, 0, [&](int64_t start, int64_t end) {
for (const auto plane : c10::irange(start, end)) {
/* each plane contains 2 random samples, one for W and one for H */
const scalar_t* randomSamplesForPlane = randomSamples + plane * 2;
/* Generate interval sequence */
auto sequenceW = generate_intervals<scalar_t>(
randomSamplesForPlane[0], inputW, outputW, poolSizeW);
auto sequenceH = generate_intervals<scalar_t>(
randomSamplesForPlane[1], inputH, outputH, poolSizeH);
/* loop over output */
// NOLINTNEXTLINE(cppcoreguidelines-init-variables)
int h, w;
const scalar_t* inputForPlane = input + plane * inputW * inputH;
scalar_t* outputForPlane = output + plane * outputW * outputH;
int64_t* indicesForPlane = indices + plane * outputW * outputH;
for (h = 0; h < outputH; ++h) {
int inputHStart = sequenceH[h];
for (w = 0; w < outputW; ++w) {
int inputWStart = sequenceW[w];
int h2 = inputHStart, w2 = inputWStart;
scalar_t maxVal = -std::numeric_limits<scalar_t>::infinity();
int64_t maxIndex = h2 * inputW + w2;
for (h2 = inputHStart; h2 < inputHStart + poolSizeH; ++h2) {
for (w2 = inputWStart; w2 < inputWStart + poolSizeW; ++w2) {
AT_ASSERT(h2 >= 0 && h2 < inputH);
AT_ASSERT(w2 >= 0 && w2 < inputW);
int planeIndex = h2 * inputW + w2;
scalar_t val = inputForPlane[planeIndex];
if (val > maxVal || std::isnan(val)) {
maxVal = val;
maxIndex = planeIndex;
}
}
}
outputForPlane[h * outputW + w] = maxVal;
indicesForPlane[h * outputW + w] = maxIndex;
}
}
}
});
}
template <typename scalar_t>
static void fractional_max_pool2d_out_frame(
const scalar_t* input,
scalar_t* output,
int64_t* indices,
const scalar_t* randomSamples,
int numBatch, int numPlanes,
int inputW, int inputH,
int outputW, int outputH,
int poolSizeW, int poolSizeH) {
if(numBatch == 1) {
fractional_max_pool2d_out_single_batch_frame<scalar_t>(
input,
output,
indices,
randomSamples,
numPlanes, inputW, inputH, outputW, outputH, poolSizeW, poolSizeH
);
return;
}
at::parallel_for(0, numBatch, 0, [&](int64_t start, int64_t end) {
for (const auto batch : c10::irange(start, end)) {
fractional_max_pool2d_out_single_batch_frame<scalar_t>(
input + batch * numPlanes * inputH * inputW,
output + batch * numPlanes * outputH * outputW,
indices + batch * numPlanes * outputH * outputW,
randomSamples + batch * numPlanes * 2,
numPlanes, inputW, inputH, outputW, outputH, poolSizeW, poolSizeH);
}
});
}
template <typename scalar_t>
static void fractional_max_pool2d_backward_out_single_batch_frame(
scalar_t* gradInput,
const scalar_t* gradOutput,
const int64_t* indices,
int numPlanes,
int inputW, int inputH,
int outputW, int outputH) {
at::parallel_for(0, numPlanes, 0, [&](int64_t start, int64_t end) {
for (const auto plane : c10::irange(start, end)) {
scalar_t* gradInputForPlane = gradInput + plane * inputW * inputH;
const scalar_t* gradOutputForPlane = gradOutput + plane * outputW * outputH;
const int64_t* indicesForPlane = indices + plane * outputW * outputH;
for (int h = 0; h < outputH; ++h) {
for (int w = 0; w < outputW; ++w) {
int outputIndex = h * outputW + w;
int64_t index = indicesForPlane[outputIndex];
AT_ASSERT(index >= 0 && index < static_cast<int64_t>(inputW) * inputH);
gradInputForPlane[index] += gradOutputForPlane[outputIndex];
}
}
}
});
}
template <typename scalar_t>
static void fractional_max_pool2d_backward_out_frame(
scalar_t* gradInput,
const scalar_t* gradOutput,
const int64_t* indices,
int numBatch, int numPlanes,
int inputW, int inputH,
int outputW, int outputH) {
if(numBatch == 1) {
fractional_max_pool2d_backward_out_single_batch_frame<scalar_t>(
gradInput, gradOutput, indices,
numPlanes,
inputW, inputH, outputW, outputH
);
return;
}
at::parallel_for(0, numBatch, 0, [&](int64_t start, int64_t end) {
for (const auto batch : c10::irange(start, end)) {
fractional_max_pool2d_backward_out_single_batch_frame<scalar_t>(
gradInput + batch * numPlanes * inputH * inputW,
gradOutput + batch * numPlanes * outputH * outputW,
indices + batch * numPlanes * outputH * outputW,
numPlanes, inputW, inputH, outputW, outputH);
}
});
}
} // anonymous namespace
TORCH_IMPL_FUNC(fractional_max_pool2d_out_cpu) (
const at::Tensor& input_,
IntArrayRef pool_size,
IntArrayRef output_size,
const at::Tensor& randomSamples_,
const at::Tensor& output,
const at::Tensor& indices) {
fractional_max_pool_check_shape</*ndim*/ 2>(input_, randomSamples_);
if (output.numel() == 0) {
return;
}
int64_t numBatch = 1;
int64_t planeDim = 0;
int64_t heightDim = 1;
int64_t widthDim = 2;
int64_t outputH = output_size[0]; // output.size(heightDim)
int64_t outputW = output_size[1]; // output.size(widthDim)
int64_t poolSizeH = pool_size[0];
int64_t poolSizeW = pool_size[1];
/* get contiguous input and samples */
auto input = input_.contiguous();
auto randomSamples = randomSamples_.contiguous();
int64_t ndims = input.ndimension();
if (ndims == 4) {
numBatch = input.size(0);
planeDim++;
heightDim++;
widthDim++;
}
/* sizes */
int64_t numPlanes = input.size(planeDim);
int64_t inputH = input.size(heightDim);
int64_t inputW = input.size(widthDim);
AT_DISPATCH_FLOATING_TYPES_AND2(
kBFloat16,
kHalf,
input.scalar_type(),
"fractional_max_pool2d_out_frame", [&] {
auto input_data = input.const_data_ptr<scalar_t>();
auto output_data = output.data_ptr<scalar_t>();
auto indices_data = indices.data_ptr<int64_t>();
auto randomSamples_data = randomSamples.const_data_ptr<scalar_t>();
fractional_max_pool2d_out_frame<scalar_t>(
input_data,
output_data,
indices_data,
randomSamples_data,
numBatch, numPlanes,
inputW, inputH,
outputW, outputH,
poolSizeW, poolSizeH);
}
);
}
TORCH_IMPL_FUNC(fractional_max_pool2d_backward_cpu) (
const at::Tensor& gradOutput_,
const at::Tensor& input,
IntArrayRef pool_size,
IntArrayRef output_size,
const at::Tensor& indices,
const at::Tensor& gradInput) {
gradInput.zero_();
int64_t numBatch = 1;
int planeDim = 0;
int heightDim = 1;
int widthDim = 2;
auto outputH = output_size[0];
auto outputW = output_size[1];
auto ndims = input.ndimension();
if (ndims == 4) {
numBatch = input.size(0);
planeDim = 1;
heightDim++;
widthDim++;
}
/* sizes */
auto numPlanes = input.size(planeDim);
auto inputH = input.size(heightDim);
auto inputW = input.size(widthDim);
/* get contiguous gradOutput */
auto gradOutput = gradOutput_.contiguous();
/* backprop */
AT_DISPATCH_FLOATING_TYPES_AND2(
kBFloat16,
kHalf,
input.scalar_type(), "fractional_max_pool2d_backward_out_frame", [&] {
auto gradInput_data = gradInput.data_ptr<scalar_t>();
auto gradOutput_data = gradOutput.const_data_ptr<scalar_t>();
auto indices_data = indices.const_data_ptr<int64_t>();
fractional_max_pool2d_backward_out_frame<scalar_t>(
gradInput_data,
gradOutput_data,
indices_data,
numBatch, numPlanes,
inputW, inputH,
outputW, outputH
);
}
);
}
} // at::native
} // at