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MaxUnpoolKernel.cpp
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MaxUnpoolKernel.cpp
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#define TORCH_ASSERT_ONLY_METHOD_OPERATORS
#include <ATen/native/cpu/MaxUnpoolKernel.h>
#include <ATen/core/Tensor.h>
#include <ATen/Dispatch.h>
#include <ATen/Parallel.h>
#include <ATen/native/cpu/utils.h>
#include <c10/util/irange.h>
#include <c10/util/Optional.h>
namespace at { namespace native {
namespace {
template <typename scalar_t, bool is_3d = false>
void cpu_max_unpool(
Tensor& output_,
const Tensor& input,
const Tensor& indices) {
auto output = output_.contiguous();
auto input_data = input.data_ptr<scalar_t>();
auto indices_data = indices.data_ptr<int64_t>();
auto output_data = output.data_ptr<scalar_t>();
// NB: input tensor dimensions:
// MaxUnpool2d:
// dim = 3: CHW
// dim = 4: NCHW
// MaxUnpool3d:
// dim = 4: CDHW
// dim = 5: NCDHW
int64_t numel = input.numel();
int64_t ndim = input.ndimension();
// treat batch size and channels as one dimension
// and the feature map as another dimension
int64_t channels, output_depth, output_height, output_width;
if (is_3d) {
TORCH_CHECK(ndim == 4 || ndim == 5, "MaxUnpool3d: expect input to be 4d or 5d tensor.");
channels = ndim == 4 ? input.size(0) : input.size(0) * input.size(1);
output_depth = output.size(-3);
output_height = output.size(-2);
output_width = output.size(-1);
} else {
TORCH_CHECK(ndim == 3 || ndim == 4, "MaxUnpool2d: expect input to be 3d or 4d tensor.");
channels = ndim == 3 ? input.size(0) : input.size(0) * input.size(1);
output_depth = 1;
output_height = output.size(-2);
output_width = output.size(-1);
}
int64_t input_image_size = numel / channels;
int64_t output_image_size = output.numel() / channels;
c10::optional<int64_t> optional_error_index;
// parallel on dim N, C, D, H, W: [channels, input_image_size]
at::parallel_for(0, numel, 0, [&](int64_t begin, int64_t end) {
int64_t c = 0;
int64_t ip = 0;
data_index_init(begin, c, channels, ip, input_image_size);
for (const auto i : c10::irange(begin, end)) {
scalar_t* output_ptr = output_data + c * output_image_size;
int64_t maxp = indices_data[i];
if (maxp < 0 || maxp >= output_image_size) {
optional_error_index = maxp;
std::atomic_thread_fence(std::memory_order_release);
} else {
output_ptr[maxp] = input_data[i];
}
// move on to next input index
data_index_step(c, channels, ip, input_image_size);
}
});
if (optional_error_index) {
if (is_3d) {
AT_ERROR("Found an invalid max index: ", optional_error_index.value(),
" (output volumes are of size ", output_depth,
"x", output_height, "x", output_width);
} else {
AT_ERROR("Found an invalid max index: ", optional_error_index.value(),
" (output volumes are of size ", output_height,
"x", output_width);
}
}
if (!output_.is_contiguous()) {
output_.copy_(output);
}
}
template <typename scalar_t>
void cpu_max_unpool_channels_last(
Tensor& output_,
const Tensor& input,
const Tensor& indices) {
TORCH_CHECK(input.ndimension() == 4,
"max_unpool2d with channels last format supports tensors with 4 dims");
auto memory_format = at::MemoryFormat::ChannelsLast;
auto output = output_.contiguous(memory_format);
auto input_data = input.data_ptr<scalar_t>();
auto indices_data = indices.data_ptr<int64_t>();
auto output_data = output.data_ptr<scalar_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(2);
int64_t output_width = output.size(3);
int64_t input_image_size = input_height * input_width;
int64_t output_image_size = output_height * output_width;
c10::optional<int64_t> optional_error_index;
// parallel on dim N, H, W
at::parallel_for(0, nbatch * input_image_size, 0, [&](int64_t begin, int64_t end) {
int64_t n = 0;
int64_t ip = 0;
data_index_init(begin, n, nbatch, ip, input_image_size);
for (const auto i : c10::irange(begin, end)) {
scalar_t* input_ptr = input_data + i * channels;
int64_t* indices_ptr = indices_data + i * channels;
scalar_t* output_ptr = output_data + n * output_image_size * channels;
// can't do scatter on avx2 (only available on avx512)
for (const auto c : c10::irange(channels)) {
int64_t maxp = indices_ptr[c];
if (maxp < 0 || maxp >= output_image_size) {
optional_error_index = maxp;
std::atomic_thread_fence(std::memory_order_release);
} else {
output_ptr[maxp * channels + c] = input_ptr[c];
}
}
// move on to next input index
data_index_step(n, nbatch, ip, input_image_size);
}
});
if (optional_error_index) {
AT_ERROR("Found an invalid max index: ", optional_error_index.value(),
" (output volumes are of size ", output_height,
"x", output_width, ")");
}
if (!output_.is_contiguous(memory_format)) {
output_.copy_(output);
}
}
template <typename scalar_t, bool is_3d = false>
void cpu_max_unpool_backward(
Tensor& grad_input_,
const Tensor& grad_output,
const Tensor& indices) {
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 numel = grad_input.numel();
int64_t ndim = grad_output.ndimension();
// treat batch size and channels as one dimension
// and the feature map as another dimension
int64_t channels, output_depth, output_height, output_width;
if (is_3d) {
TORCH_CHECK(ndim == 4 || ndim == 5, "MaxUnpool3d_backward: expect grad_output to be 4d or 5d tensor.");
channels = ndim == 4 ? grad_output.size(0) : grad_output.size(0) * grad_output.size(1);
output_depth = grad_output.size(-3);
output_height = grad_output.size(-2);
output_width = grad_output.size(-1);
} else {
TORCH_CHECK(ndim == 3 || ndim == 4, "MaxUnpool2d_backward: expect grad_output to be 3d or 4d tensor.");
channels = ndim == 3 ? grad_output.size(0) : grad_output.size(0) * grad_output.size(1);
output_depth = 1;
output_height = grad_output.size(-2);
output_width = grad_output.size(-1);
}
int64_t input_image_size = numel / channels;
int64_t output_image_size = grad_output.numel() / channels;
c10::optional<int64_t> optional_error_index;
// parallel on dim N, C, D, H, W
at::parallel_for(0, numel, 0, [&](int64_t begin, int64_t end) {
int64_t c = 0;
int64_t ip = 0;
data_index_init(begin, c, channels, ip, input_image_size);
for (const auto i : c10::irange(begin, end)) {
scalar_t* grad_output_ptr = grad_output_data + c * output_image_size;
int64_t maxp = indices_data[i];
if (maxp < 0 || maxp >= output_image_size) {
optional_error_index = maxp;
std::atomic_thread_fence(std::memory_order_release);
} else {
grad_input_data[i] = grad_output_ptr[maxp];
}
// move on to next input index
data_index_step(c, channels, ip, input_image_size);
}
});
if (optional_error_index) {
if (is_3d) {
AT_ERROR("invalid max index ", optional_error_index.value(),
", odepth= ", output_depth,
", owidth= ", output_width,
", oheight= ", output_height);
} else {
AT_ERROR("invalid max index ", optional_error_index.value(),
", owidth= ", output_width,
", oheight= ", output_height);
}
}
if (!grad_input_.is_contiguous()) {
grad_input_.copy_(grad_input);
}
}
void max_unpool2d_kernel_impl(
Tensor& output,
const Tensor& input,
const Tensor& indices) {
switch(input.suggest_memory_format()) {
case at::MemoryFormat::Contiguous: {
AT_DISPATCH_FLOATING_TYPES(input.scalar_type(), "max_unpool2d", [&] {
cpu_max_unpool<scalar_t, /*is_3d*/false>(output, input, indices);
});
break;
}
case at::MemoryFormat::ChannelsLast: {
AT_DISPATCH_FLOATING_TYPES(input.scalar_type(), "max_unpool2d_channels_last", [&] {
cpu_max_unpool_channels_last<scalar_t>(output, input, indices);
});
break;
}
default:
TORCH_CHECK(false, "Unsupported memory format. Supports only ChannelsLast, Contiguous");
}
}
void max_unpool3d_kernel_impl(
Tensor& output,
const Tensor& input,
const Tensor& indices) {
AT_DISPATCH_FLOATING_TYPES(input.scalar_type(), "max_unpool3d", [&] {
cpu_max_unpool<scalar_t, /*is_3d*/true>(output, input, indices);
});
}
} // anonymous namespace
REGISTER_DISPATCH(max_unpool2d_kernel, &max_unpool2d_kernel_impl);
REGISTER_DISPATCH(max_unpool3d_kernel, &max_unpool3d_kernel_impl);
}} // at::native