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im2col.cuh
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im2col.cuh
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#pragma once
#include <THC/THCGeneral.h>
#include <THC/THCDeviceUtils.cuh>
#include <ATen/ATen.h>
#include <ATen/TensorUtils.h>
#include <ATen/Utils.h>
#include <ATen/cuda/CUDAContext.h>
#include <ATen/cuda/detail/KernelUtils.h>
#include <ATen/cuda/CUDAApplyUtils.cuh>
#include <ATen/cuda/detail/IndexUtils.cuh>
#include <ATen/cuda/detail/TensorInfo.cuh>
#include <c10/macros/Macros.h>
namespace at {
namespace native {
using namespace at::cuda::detail;
// Kernel for fast unfold+copy
// (borrowed from Caffe:
// https://github.com/BVLC/caffe/blob/master/src/caffe/layers/conv_layer.cu)
// CUDA_NUM_THREADS = 1024
template <typename dt>
C10_LAUNCH_BOUNDS_1(1024)
__global__ void im2col_kernel(
const int64_t n,
const dt* data_im,
const int64_t height,
const int64_t width,
const int64_t kernel_height,
const int64_t kernel_width,
const int64_t pad_height,
const int64_t pad_width,
const int64_t stride_height,
const int64_t stride_width,
const int64_t dilation_height,
const int64_t dilation_width,
const int64_t height_col,
const int64_t width_col,
dt* data_col) {
CUDA_KERNEL_LOOP(index, n) {
int64_t w_out = index % width_col;
index /= width_col;
int64_t h_out = index % height_col;
int64_t channel_in = index / height_col;
int64_t channel_out = channel_in * kernel_height * kernel_width;
int64_t h_in = h_out * stride_height - pad_height;
int64_t w_in = w_out * stride_width - pad_width;
data_col += (channel_out * height_col + h_out) * width_col + w_out;
data_im += (channel_in * height + h_in) * width + w_in;
for (int64_t i = 0; i < kernel_height; ++i) {
for (int64_t j = 0; j < kernel_width; ++j) {
int64_t h = h_in + i * dilation_height;
int64_t w = w_in + j * dilation_width;
*data_col = (h >= 0 && w >= 0 && h < height && w < width)
? data_im[i * dilation_height * width + j * dilation_width]
: ScalarConvert<int, dt>::to(0);
data_col += height_col * width_col;
}
}
}
}
template <typename dt>
void im2col(
cudaStream_t stream,
const dt* data_im,
const int64_t channels,
const int64_t height,
const int64_t width,
const int64_t height_col,
const int64_t width_col,
const int64_t kernel_height,
const int64_t kernel_width,
const int64_t pad_height,
const int64_t pad_width,
const int64_t stride_height,
const int64_t stride_width,
const int64_t dilation_height,
const int64_t dilation_width,
dt* data_col) {
// We are going to launch channels * height_col * width_col kernels, each
// kernel responsible for copying a single-channel grid.
int64_t num_kernels = channels * height_col * width_col;
// Launch CUDA_NUM_THREADS = 1024
im2col_kernel<<<GET_BLOCKS(num_kernels), 1024, 0, stream>>>(
num_kernels,
data_im,
height,
width,
kernel_height,
kernel_width,
pad_height,
pad_width,
stride_height,
stride_width,
dilation_height,
dilation_width,
height_col,
width_col,
data_col);
AT_CUDA_CHECK(cudaGetLastError());
}
template <typename dt, typename accT>
C10_LAUNCH_BOUNDS_1(1024)
__global__ void col2im_kernel(
const int64_t n,
const dt* data_col,
const int64_t height,
const int64_t width,
const int64_t channels,
const int64_t kernel_h,
const int64_t kernel_w,
const int64_t pad_height,
const int64_t pad_width,
const int64_t stride_height,
const int64_t stride_width,
const int64_t dilation_height,
const int64_t dilation_width,
const int64_t height_col,
const int64_t width_col,
dt* data_im) {
CUDA_KERNEL_LOOP(index, n) {
accT val = static_cast<accT>(0);
const int64_t w_im = index % width + pad_width;
const int64_t h_im = (index / width) % height + pad_height;
const int64_t c_im = index / (width * height);
int64_t kernel_extent_w = (kernel_w - 1) * dilation_width + 1;
int64_t kernel_extent_h = (kernel_h - 1) * dilation_height + 1;
// compute the start and end of the output
const int64_t w_col_start = (w_im < kernel_extent_w)
? 0
: (w_im - kernel_extent_w) / stride_width + 1;
const int64_t w_col_end = ::min(w_im / stride_width + 1, width_col);
const int64_t h_col_start = (h_im < kernel_extent_h)
? 0
: (h_im - kernel_extent_h) / stride_height + 1;
const int64_t h_col_end = ::min(h_im / stride_height + 1, height_col);
// TODO: use LCM of stride and dilation to avoid unnecessary loops
for (int64_t h_col = h_col_start; h_col < h_col_end; h_col += 1) {
for (int64_t w_col = w_col_start; w_col < w_col_end; w_col += 1) {
int64_t h_k = (h_im - h_col * stride_height);
int64_t w_k = (w_im - w_col * stride_width);
if (h_k % dilation_height == 0 && w_k % dilation_width == 0) {
h_k /= dilation_height;
w_k /= dilation_width;
int64_t data_col_index =
(((c_im * kernel_h + h_k) * kernel_w + w_k) * height_col +
h_col) *
width_col +
w_col;
val += data_col[data_col_index];
}
}
}
data_im[index] = static_cast<dt>(val);
}
}
template <typename dt, typename accT>
void col2im(
cudaStream_t stream,
const dt* data_col,
const int64_t channels,
const int64_t height,
const int64_t width,
const int64_t output_height,
const int64_t output_width,
const int64_t patch_height,
const int64_t patch_width,
const int64_t pad_height,
const int64_t pad_width,
const int64_t stride_height,
const int64_t stride_width,
const int64_t dilation_height,
const int64_t dilation_width,
dt* data_im) {
int64_t num_kernels = channels * height * width;
// To avoid involving atomic operations, we will launch one kernel per
// bottom dimension, and then in the kernel add up the top dimensions.
// CUDA_NUM_THREADS = 1024
col2im_kernel<dt, accT>
<<<GET_BLOCKS(num_kernels), CUDA_NUM_THREADS, 0, stream>>>(
num_kernels,
data_col,
height,
width,
channels,
patch_height,
patch_width,
pad_height,
pad_width,
stride_height,
stride_width,
dilation_height,
dilation_width,
output_height,
output_width,
data_im);
AT_CUDA_CHECK(cudaGetLastError());
}
} // namespace native
} // namespace at