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GridSampler.cu
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GridSampler.cu
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#include <ATen/ATen.h>
#include <ATen/native/cuda/GridSampler.cuh>
#include <ATen/cuda/CUDAContext.h>
#include <ATen/cuda/CUDAApplyUtils.cuh>
#include <ATen/cuda/detail/TensorInfo.cuh>
#include <ATen/cuda/detail/IndexUtils.cuh>
#include <ATen/cuda/detail/KernelUtils.h>
#include <c10/macros/Macros.h>
namespace at { namespace native {
using namespace at::cuda::detail;
using at::native::detail::GridSamplerInterpolation;
using at::native::detail::GridSamplerPadding;
namespace {
template <typename scalar_t>
C10_LAUNCH_BOUNDS_1(1024)
__global__ void grid_sampler_2d_kernel(
const int nthreads,
TensorInfo<scalar_t, int> input,
TensorInfo<scalar_t, int> grid,
TensorInfo<scalar_t, int> output,
const GridSamplerInterpolation interpolation_mode,
const GridSamplerPadding padding_mode,
bool align_corners) {
int C = input.sizes[1];
int inp_H = input.sizes[2];
int inp_W = input.sizes[3];
int out_H = grid.sizes[1];
int out_W = grid.sizes[2];
int inp_sN = input.strides[0];
int inp_sC = input.strides[1];
int inp_sH = input.strides[2];
int inp_sW = input.strides[3];
int grid_sN = grid.strides[0];
int grid_sH = grid.strides[1];
int grid_sW = grid.strides[2];
int grid_sCoor = grid.strides[3];
int out_sN = output.strides[0];
int out_sC = output.strides[1];
int out_sH = output.strides[2];
int out_sW = output.strides[3];
CUDA_KERNEL_LOOP(index, nthreads) {
const int w = index % out_W;
const int h = (index / out_W) % out_H;
const int n = index / (out_H * out_W);
const int grid_offset = n * grid_sN + h * grid_sH + w * grid_sW;
// get the corresponding input x, y co-ordinates from grid
scalar_t ix = grid.data[grid_offset];
scalar_t iy = grid.data[grid_offset + grid_sCoor];
ix = grid_sampler_compute_source_index(ix, inp_W, padding_mode, align_corners);
iy = grid_sampler_compute_source_index(iy, inp_H, padding_mode, align_corners);
if (interpolation_mode == GridSamplerInterpolation::Bilinear) {
// get NE, NW, SE, SW pixel values from (x, y)
int ix_nw = static_cast<int>(::floor(ix));
int iy_nw = static_cast<int>(::floor(iy));
int ix_ne = ix_nw + 1;
int iy_ne = iy_nw;
int ix_sw = ix_nw;
int iy_sw = iy_nw + 1;
int ix_se = ix_nw + 1;
int iy_se = iy_nw + 1;
// get surfaces to each neighbor:
scalar_t nw = (ix_se - ix) * (iy_se - iy);
scalar_t ne = (ix - ix_sw) * (iy_sw - iy);
scalar_t sw = (ix_ne - ix) * (iy - iy_ne);
scalar_t se = (ix - ix_nw) * (iy - iy_nw);
// calculate bilinear weighted pixel value and set output pixel
auto inp_ptr_NC = input.data + n * inp_sN;
auto out_ptr_NCHW = output.data + n * out_sN + h * out_sH + w * out_sW;
for (int c = 0; c < C; ++c, inp_ptr_NC += inp_sC, out_ptr_NCHW += out_sC) {
*out_ptr_NCHW = static_cast<scalar_t>(0);
if (within_bounds_2d(iy_nw, ix_nw, inp_H, inp_W)) {
*out_ptr_NCHW += inp_ptr_NC[iy_nw * inp_sH + ix_nw * inp_sW] * nw;
}
if (within_bounds_2d(iy_ne, ix_ne, inp_H, inp_W)) {
*out_ptr_NCHW += inp_ptr_NC[iy_ne * inp_sH + ix_ne * inp_sW] * ne;
}
if (within_bounds_2d(iy_sw, ix_sw, inp_H, inp_W)) {
*out_ptr_NCHW += inp_ptr_NC[iy_sw * inp_sH + ix_sw * inp_sW] * sw;
}
if (within_bounds_2d(iy_se, ix_se, inp_H, inp_W)) {
*out_ptr_NCHW += inp_ptr_NC[iy_se * inp_sH + ix_se * inp_sW] * se;
}
}
} else if (interpolation_mode == GridSamplerInterpolation::Nearest) {
int ix_nearest = static_cast<int>(::round(ix));
int iy_nearest = static_cast<int>(::round(iy));
// assign nearest neighor pixel value to output pixel
auto inp_ptr_NC = input.data + n * inp_sN;
auto out_ptr_NCHW = output.data + n * out_sN + h * out_sH + w * out_sW;
for (int c = 0; c < C; ++c, inp_ptr_NC += inp_sC, out_ptr_NCHW += out_sC) {
if (within_bounds_2d(iy_nearest, ix_nearest, inp_H, inp_W)) {
*out_ptr_NCHW = inp_ptr_NC[iy_nearest * inp_sH + ix_nearest * inp_sW];
} else {
*out_ptr_NCHW = static_cast<scalar_t>(0);
}
}
}
}
}
template <typename scalar_t>
C10_LAUNCH_BOUNDS_1(1024)
__global__ void grid_sampler_3d_kernel(
const int nthreads,
TensorInfo<scalar_t, int> input,
TensorInfo<scalar_t, int> grid,
TensorInfo<scalar_t, int> output,
const GridSamplerInterpolation interpolation_mode,
const GridSamplerPadding padding_mode,
bool align_corners) {
int C = input.sizes[1];
int inp_D = input.sizes[2];
int inp_H = input.sizes[3];
int inp_W = input.sizes[4];
int out_D = grid.sizes[1];
int out_H = grid.sizes[2];
int out_W = grid.sizes[3];
int inp_sN = input.strides[0];
int inp_sC = input.strides[1];
int inp_sD = input.strides[2];
int inp_sH = input.strides[3];
int inp_sW = input.strides[4];
int grid_sN = grid.strides[0];
int grid_sD = grid.strides[1];
int grid_sH = grid.strides[2];
int grid_sW = grid.strides[3];
int grid_sCoor = grid.strides[4];
int out_sN = output.strides[0];
int out_sC = output.strides[1];
int out_sD = output.strides[2];
int out_sH = output.strides[3];
int out_sW = output.strides[4];
CUDA_KERNEL_LOOP(index, nthreads) {
const int w = index % out_W;
const int h = (index / out_W) % out_H;
const int d = (index / (out_H * out_W)) % out_D;
const int n = index / (out_D * out_H * out_W);
const int grid_offset = n * grid_sN + d * grid_sD + h * grid_sH + w * grid_sW;
// get the corresponding input x, y, z co-ordinates from grid
scalar_t ix = grid.data[grid_offset];
scalar_t iy = grid.data[grid_offset + grid_sCoor];
scalar_t iz = grid.data[grid_offset + 2 * grid_sCoor];
ix = grid_sampler_compute_source_index(ix, inp_W, padding_mode, align_corners);
iy = grid_sampler_compute_source_index(iy, inp_H, padding_mode, align_corners);
iz = grid_sampler_compute_source_index(iz, inp_D, padding_mode, align_corners);
if (interpolation_mode == GridSamplerInterpolation::Bilinear) {
// get corner pixel values from (x, y, z)
// for 4d, we used north-east-south-west
// for 5d, we add top-bottom
int ix_tnw = static_cast<int>(::floor(ix));
int iy_tnw = static_cast<int>(::floor(iy));
int iz_tnw = static_cast<int>(::floor(iz));
int ix_tne = ix_tnw + 1;
int iy_tne = iy_tnw;
int iz_tne = iz_tnw;
int ix_tsw = ix_tnw;
int iy_tsw = iy_tnw + 1;
int iz_tsw = iz_tnw;
int ix_tse = ix_tnw + 1;
int iy_tse = iy_tnw + 1;
int iz_tse = iz_tnw;
int ix_bnw = ix_tnw;
int iy_bnw = iy_tnw;
int iz_bnw = iz_tnw + 1;
int ix_bne = ix_tnw + 1;
int iy_bne = iy_tnw;
int iz_bne = iz_tnw + 1;
int ix_bsw = ix_tnw;
int iy_bsw = iy_tnw + 1;
int iz_bsw = iz_tnw + 1;
int ix_bse = ix_tnw + 1;
int iy_bse = iy_tnw + 1;
int iz_bse = iz_tnw + 1;
// get surfaces to each neighbor:
scalar_t tnw = (ix_bse - ix) * (iy_bse - iy) * (iz_bse - iz);
scalar_t tne = (ix - ix_bsw) * (iy_bsw - iy) * (iz_bsw - iz);
scalar_t tsw = (ix_bne - ix) * (iy - iy_bne) * (iz_bne - iz);
scalar_t tse = (ix - ix_bnw) * (iy - iy_bnw) * (iz_bnw - iz);
scalar_t bnw = (ix_tse - ix) * (iy_tse - iy) * (iz - iz_tse);
scalar_t bne = (ix - ix_tsw) * (iy_tsw - iy) * (iz - iz_tsw);
scalar_t bsw = (ix_tne - ix) * (iy - iy_tne) * (iz - iz_tne);
scalar_t bse = (ix - ix_tnw) * (iy - iy_tnw) * (iz - iz_tnw);
auto inp_ptr_NC = input.data + n * inp_sN;
auto out_ptr_NCDHW = output.data + n * out_sN + d * out_sD + h * out_sH + w * out_sW;
for (int c = 0; c < C; ++c, inp_ptr_NC += inp_sC, out_ptr_NCDHW += out_sC) {
// (c, iz_tnw, iy_tnw, ix_tnw) * tnw + (c, iz_tne, iy_tne, ix_tne) * tne
// + (c, iz_tsw, iy_tsw, ix_tsw) * tsw + (c, iz_tse, iy_tse, ix_tse) * tse
// + (c, iz_bnw, iy_bnw, ix_bnw) * bnw + (c, iz_bne, iy_bne, ix_bne) * bne
// + (c, iz_bsw, iy_bsw, ix_bsw) * bsw + (c, iz_bse, iy_bse, ix_bse) * bse
*out_ptr_NCDHW = static_cast<scalar_t>(0);
if (within_bounds_3d(iz_tnw, iy_tnw, ix_tnw, inp_D, inp_H, inp_W)) {
*out_ptr_NCDHW += inp_ptr_NC[iz_tnw * inp_sD + iy_tnw * inp_sH + ix_tnw * inp_sW] * tnw;
}
if (within_bounds_3d(iz_tne, iy_tne, ix_tne, inp_D, inp_H, inp_W)) {
*out_ptr_NCDHW += inp_ptr_NC[iz_tne * inp_sD + iy_tne * inp_sH + ix_tne * inp_sW] * tne;
}
if (within_bounds_3d(iz_tsw, iy_tsw, ix_tsw, inp_D, inp_H, inp_W)) {
*out_ptr_NCDHW += inp_ptr_NC[iz_tsw * inp_sD + iy_tsw * inp_sH + ix_tsw * inp_sW] * tsw;
}
if (within_bounds_3d(iz_tse, iy_tse, ix_tse, inp_D, inp_H, inp_W)) {
*out_ptr_NCDHW += inp_ptr_NC[iz_tse * inp_sD + iy_tse * inp_sH + ix_tse * inp_sW] * tse;
}
if (within_bounds_3d(iz_bnw, iy_bnw, ix_bnw, inp_D, inp_H, inp_W)) {
*out_ptr_NCDHW += inp_ptr_NC[iz_bnw * inp_sD + iy_bnw * inp_sH + ix_bnw * inp_sW] * bnw;
}
if (within_bounds_3d(iz_bne, iy_bne, ix_bne, inp_D, inp_H, inp_W)) {
*out_ptr_NCDHW += inp_ptr_NC[iz_bne * inp_sD + iy_bne * inp_sH + ix_bne * inp_sW] * bne;
}
if (within_bounds_3d(iz_bsw, iy_bsw, ix_bsw, inp_D, inp_H, inp_W)) {
*out_ptr_NCDHW += inp_ptr_NC[iz_bsw * inp_sD + iy_bsw * inp_sH + ix_bsw * inp_sW] * bsw;
}
if (within_bounds_3d(iz_bse, iy_bse, ix_bse, inp_D, inp_H, inp_W)) {
*out_ptr_NCDHW += inp_ptr_NC[iz_bse * inp_sD + iy_bse * inp_sH + ix_bse * inp_sW] * bse;
}
}
} else if (interpolation_mode == GridSamplerInterpolation::Nearest) {
int ix_nearest = static_cast<int>(::round(ix));
int iy_nearest = static_cast<int>(::round(iy));
int iz_nearest = static_cast<int>(::round(iz));
// assign nearest neighor pixel value to output pixel
auto inp_ptr_NC = input.data + n * inp_sN;
auto out_ptr_NCDHW = output.data + n * out_sN + d * out_sD + h * out_sH + w * out_sW;
for (int c = 0; c < C; ++c, inp_ptr_NC += inp_sC, out_ptr_NCDHW += out_sC) {
if (within_bounds_3d(iz_nearest, iy_nearest, ix_nearest, inp_D, inp_H, inp_W)) {
*out_ptr_NCDHW = inp_ptr_NC[iz_nearest * inp_sD + iy_nearest * inp_sH + ix_nearest * inp_sW];
} else {
*out_ptr_NCDHW = static_cast<scalar_t>(0);
}
}
}
}
}
template <typename scalar_t>
C10_LAUNCH_BOUNDS_1(1024)
__global__ void grid_sampler_2d_backward_kernel(
const int nthreads,
TensorInfo<scalar_t, int> grad_output,
TensorInfo<scalar_t, int> input,
TensorInfo<scalar_t, int> grid,
TensorInfo<scalar_t, int> grad_input, // initialized to zeros
TensorInfo<scalar_t, int> grad_grid, // initialized to empty
const GridSamplerInterpolation interpolation_mode,
const GridSamplerPadding padding_mode,
bool align_corners) {
int C = input.sizes[1];
int inp_H = input.sizes[2];
int inp_W = input.sizes[3];
int out_H = grid.sizes[1];
int out_W = grid.sizes[2];
int inp_sN = input.strides[0];
int inp_sC = input.strides[1];
int inp_sH = input.strides[2];
int inp_sW = input.strides[3];
int grid_sN = grid.strides[0];
int grid_sH = grid.strides[1];
int grid_sW = grid.strides[2];
int grid_sCoor = grid.strides[3];
int gOut_sN = grad_output.strides[0];
int gOut_sC = grad_output.strides[1];
int gOut_sH = grad_output.strides[2];
int gOut_sW = grad_output.strides[3];
int gInp_sN = grad_input.strides[0];
int gInp_sC = grad_input.strides[1];
int gInp_sH = grad_input.strides[2];
int gInp_sW = grad_input.strides[3];
int gGrid_sW = grad_grid.strides[2];
CUDA_KERNEL_LOOP(index, nthreads) {
const int w = index % out_W;
const int h = (index / out_W) % out_H;
const int n = index / (out_H * out_W);
const int grid_offset = n * grid_sN + h * grid_sH + w * grid_sW;
// get the corresponding input x, y co-ordinates from grid
scalar_t ix = grid.data[grid_offset];
scalar_t iy = grid.data[grid_offset + grid_sCoor];
// multipliers for gradients on ix and iy
scalar_t gix_mult, giy_mult;
ix = grid_sampler_compute_source_index_set_grad(ix, inp_W, padding_mode, align_corners, &gix_mult);
iy = grid_sampler_compute_source_index_set_grad(iy, inp_H, padding_mode, align_corners, &giy_mult);
if (interpolation_mode == GridSamplerInterpolation::Bilinear) {
// get NE, NW, SE, SW pixel values from (x, y)
int ix_nw = static_cast<int>(::floor(ix));
int iy_nw = static_cast<int>(::floor(iy));
int ix_ne = ix_nw + 1;
int iy_ne = iy_nw;
int ix_sw = ix_nw;
int iy_sw = iy_nw + 1;
int ix_se = ix_nw + 1;
int iy_se = iy_nw + 1;
// get surfaces to each neighbor:
scalar_t nw = (ix_se - ix) * (iy_se - iy);
scalar_t ne = (ix - ix_sw) * (iy_sw - iy);
scalar_t sw = (ix_ne - ix) * (iy - iy_ne);
scalar_t se = (ix - ix_nw) * (iy - iy_nw);
scalar_t gix = static_cast<scalar_t>(0), giy = static_cast<scalar_t>(0);
scalar_t *gOut_ptr_NCHW = grad_output.data + n * gOut_sN + h * gOut_sH + w * gOut_sW;
scalar_t *gInp_ptr_NC = grad_input.data + n * gInp_sN;
scalar_t *inp_ptr_NC = input.data + n * inp_sN;
for (int c = 0; c < C; ++c, inp_ptr_NC += inp_sC, gInp_ptr_NC += gInp_sC, gOut_ptr_NCHW += gOut_sC) {
scalar_t gOut = *gOut_ptr_NCHW;
// calculate and set grad_input
safe_add_2d(gInp_ptr_NC, iy_nw, ix_nw, gInp_sH, gInp_sW, inp_H, inp_W, nw * gOut);
safe_add_2d(gInp_ptr_NC, iy_ne, ix_ne, gInp_sH, gInp_sW, inp_H, inp_W, ne * gOut);
safe_add_2d(gInp_ptr_NC, iy_sw, ix_sw, gInp_sH, gInp_sW, inp_H, inp_W, sw * gOut);
safe_add_2d(gInp_ptr_NC, iy_se, ix_se, gInp_sH, gInp_sW, inp_H, inp_W, se * gOut);
// calculate grad_grid
if (within_bounds_2d(iy_nw, ix_nw, inp_H, inp_W)) {
scalar_t nw_val = inp_ptr_NC[iy_nw * inp_sH + ix_nw * inp_sW];
gix -= nw_val * (iy_se - iy) * gOut;
giy -= nw_val * (ix_se - ix) * gOut;
}
if (within_bounds_2d(iy_ne, ix_ne, inp_H, inp_W)) {
scalar_t ne_val = inp_ptr_NC[iy_ne * inp_sH + ix_ne * inp_sW];
gix += ne_val * (iy_sw - iy) * gOut;
giy -= ne_val * (ix - ix_sw) * gOut;
}
if (within_bounds_2d(iy_sw, ix_sw, inp_H, inp_W)) {
scalar_t sw_val = inp_ptr_NC[iy_sw * inp_sH + ix_sw * inp_sW];
gix -= sw_val * (iy - iy_ne) * gOut;
giy += sw_val * (ix_ne - ix) * gOut;
}
if (within_bounds_2d(iy_se, ix_se, inp_H, inp_W)) {
scalar_t se_val = inp_ptr_NC[iy_se * inp_sH + ix_se * inp_sW];
gix += se_val * (iy - iy_nw) * gOut;
giy += se_val * (ix - ix_nw) * gOut;
}
}
// assuming grad_grid is contiguous
// thus we can
// 1. use index with gGrid_sW to directly compute gGrid_ptr_NHW
// 2. directly assign to gGrid_ptr_NHW[0], gGrid_ptr_NHW[1]
scalar_t *gGrid_ptr_NHW = grad_grid.data + index * gGrid_sW;
gGrid_ptr_NHW[0] = gix_mult * gix;
gGrid_ptr_NHW[1] = giy_mult * giy;
} else if (interpolation_mode == GridSamplerInterpolation::Nearest) {
int ix_nearest = static_cast<int>(::round(ix));
int iy_nearest = static_cast<int>(::round(iy));
// assign nearest neighor pixel value to output pixel
scalar_t *gOut_ptr_NCHW = grad_output.data + n * gOut_sN + h * gOut_sH + w * gOut_sW;
scalar_t *gInp_ptr_NC = grad_input.data + n * gInp_sN;
for (int c = 0; c < C; ++c, gInp_ptr_NC += gInp_sC, gOut_ptr_NCHW += gOut_sC) {
// calculate and set grad_input
safe_add_2d(gInp_ptr_NC, iy_nearest, ix_nearest, gInp_sH, gInp_sW, inp_H, inp_W, *gOut_ptr_NCHW);
}
// assuming grad_grid is contiguous
// thus we can
// 1. use index with gGrid_sW to directly compute gGrid_ptr_NHW
// 2. directly assign to gGrid_ptr_NHW[0], gGrid_ptr_NHW[1]
scalar_t *gGrid_ptr_NHW = grad_grid.data + index * gGrid_sW;
gGrid_ptr_NHW[0] = static_cast<scalar_t>(0);
gGrid_ptr_NHW[1] = static_cast<scalar_t>(0);
}
}
}
template <typename scalar_t>
C10_LAUNCH_BOUNDS_1(1024)
__global__ void grid_sampler_3d_backward_kernel(
const int nthreads,
TensorInfo<scalar_t, int> grad_output,
TensorInfo<scalar_t, int> input,
TensorInfo<scalar_t, int> grid,
TensorInfo<scalar_t, int> grad_input, // initialized to zeros
TensorInfo<scalar_t, int> grad_grid, // initialized to empty
const GridSamplerInterpolation interpolation_mode,
const GridSamplerPadding padding_mode,
bool align_corners) {
int C = input.sizes[1];
int inp_D = input.sizes[2];
int inp_H = input.sizes[3];
int inp_W = input.sizes[4];
int out_D = grid.sizes[1];
int out_H = grid.sizes[2];
int out_W = grid.sizes[3];
int inp_sN = input.strides[0];
int inp_sC = input.strides[1];
int inp_sD = input.strides[2];
int inp_sH = input.strides[3];
int inp_sW = input.strides[4];
int grid_sN = grid.strides[0];
int grid_sD = grid.strides[1];
int grid_sH = grid.strides[2];
int grid_sW = grid.strides[3];
int grid_sCoor = grid.strides[4];
int gOut_sN = grad_output.strides[0];
int gOut_sC = grad_output.strides[1];
int gOut_sD = grad_output.strides[2];
int gOut_sH = grad_output.strides[3];
int gOut_sW = grad_output.strides[4];
int gInp_sN = grad_input.strides[0];
int gInp_sC = grad_input.strides[1];
int gInp_sD = grad_input.strides[2];
int gInp_sH = grad_input.strides[3];
int gInp_sW = grad_input.strides[4];
int gGrid_sW = grad_grid.strides[3];
CUDA_KERNEL_LOOP(index, nthreads) {
const int w = index % out_W;
const int h = (index / out_W) % out_H;
const int d = (index / (out_H * out_W)) % out_D;
const int n = index / (out_D * out_H * out_W);
const int grid_offset = n * grid_sN + d * grid_sD + h * grid_sH + w * grid_sW;
// get the corresponding input x, y, z co-ordinates from grid
scalar_t ix = grid.data[grid_offset];
scalar_t iy = grid.data[grid_offset + grid_sCoor];
scalar_t iz = grid.data[grid_offset + 2 * grid_sCoor];
// multipliers for gradients on ix, iy, and iz
scalar_t gix_mult, giy_mult, giz_mult;
ix = grid_sampler_compute_source_index_set_grad(ix, inp_W, padding_mode, align_corners, &gix_mult);
iy = grid_sampler_compute_source_index_set_grad(iy, inp_H, padding_mode, align_corners, &giy_mult);
iz = grid_sampler_compute_source_index_set_grad(iz, inp_D, padding_mode, align_corners, &giz_mult);
if (interpolation_mode == GridSamplerInterpolation::Bilinear) {
// get corner pixel values from (x, y, z)
// for 4d, we used north-east-south-west
// for 5d, we add top-bottom
int ix_tnw = static_cast<int>(::floor(ix));
int iy_tnw = static_cast<int>(::floor(iy));
int iz_tnw = static_cast<int>(::floor(iz));
int ix_tne = ix_tnw + 1;
int iy_tne = iy_tnw;
int iz_tne = iz_tnw;
int ix_tsw = ix_tnw;
int iy_tsw = iy_tnw + 1;
int iz_tsw = iz_tnw;
int ix_tse = ix_tnw + 1;
int iy_tse = iy_tnw + 1;
int iz_tse = iz_tnw;
int ix_bnw = ix_tnw;
int iy_bnw = iy_tnw;
int iz_bnw = iz_tnw + 1;
int ix_bne = ix_tnw + 1;
int iy_bne = iy_tnw;
int iz_bne = iz_tnw + 1;
int ix_bsw = ix_tnw;
int iy_bsw = iy_tnw + 1;
int iz_bsw = iz_tnw + 1;
int ix_bse = ix_tnw + 1;
int iy_bse = iy_tnw + 1;
int iz_bse = iz_tnw + 1;
// get surfaces to each neighbor:
scalar_t tnw = (ix_bse - ix) * (iy_bse - iy) * (iz_bse - iz);
scalar_t tne = (ix - ix_bsw) * (iy_bsw - iy) * (iz_bsw - iz);
scalar_t tsw = (ix_bne - ix) * (iy - iy_bne) * (iz_bne - iz);
scalar_t tse = (ix - ix_bnw) * (iy - iy_bnw) * (iz_bnw - iz);
scalar_t bnw = (ix_tse - ix) * (iy_tse - iy) * (iz - iz_tse);
scalar_t bne = (ix - ix_tsw) * (iy_tsw - iy) * (iz - iz_tsw);
scalar_t bsw = (ix_tne - ix) * (iy - iy_tne) * (iz - iz_tne);
scalar_t bse = (ix - ix_tnw) * (iy - iy_tnw) * (iz - iz_tnw);
scalar_t gix = static_cast<scalar_t>(0), giy = static_cast<scalar_t>(0), giz = static_cast<scalar_t>(0);
scalar_t *gOut_ptr_NCDHW = grad_output.data + n * gOut_sN + d * gOut_sD + h * gOut_sH + w * gOut_sW;
scalar_t *gInp_ptr_NC = grad_input.data + n * gInp_sN;
scalar_t *inp_ptr_NC = input.data + n * inp_sN;
// calculate bilinear weighted pixel value and set output pixel
for (int c = 0; c < C; ++c, gOut_ptr_NCDHW += gOut_sC, gInp_ptr_NC += gInp_sC, inp_ptr_NC += inp_sC) {
scalar_t gOut = *gOut_ptr_NCDHW;
// calculate and set grad_input
safe_add_3d(gInp_ptr_NC, iz_tnw, iy_tnw, ix_tnw, gInp_sD, gInp_sH, gInp_sW, inp_D, inp_H, inp_W, tnw * gOut);
safe_add_3d(gInp_ptr_NC, iz_tne, iy_tne, ix_tne, gInp_sD, gInp_sH, gInp_sW, inp_D, inp_H, inp_W, tne * gOut);
safe_add_3d(gInp_ptr_NC, iz_tsw, iy_tsw, ix_tsw, gInp_sD, gInp_sH, gInp_sW, inp_D, inp_H, inp_W, tsw * gOut);
safe_add_3d(gInp_ptr_NC, iz_tse, iy_tse, ix_tse, gInp_sD, gInp_sH, gInp_sW, inp_D, inp_H, inp_W, tse * gOut);
safe_add_3d(gInp_ptr_NC, iz_bnw, iy_bnw, ix_bnw, gInp_sD, gInp_sH, gInp_sW, inp_D, inp_H, inp_W, bnw * gOut);
safe_add_3d(gInp_ptr_NC, iz_bne, iy_bne, ix_bne, gInp_sD, gInp_sH, gInp_sW, inp_D, inp_H, inp_W, bne * gOut);
safe_add_3d(gInp_ptr_NC, iz_bsw, iy_bsw, ix_bsw, gInp_sD, gInp_sH, gInp_sW, inp_D, inp_H, inp_W, bsw * gOut);
safe_add_3d(gInp_ptr_NC, iz_bse, iy_bse, ix_bse, gInp_sD, gInp_sH, gInp_sW, inp_D, inp_H, inp_W, bse * gOut);
// calculate grad_grid
if (within_bounds_3d(iz_tnw, iy_tnw, ix_tnw, inp_D, inp_H, inp_W)) {
scalar_t tnw_val = inp_ptr_NC[iz_tnw * inp_sD + iy_tnw * inp_sH + ix_tnw * inp_sW];
gix -= tnw_val * (iy_bse - iy) * (iz_bse - iz) * gOut;
giy -= tnw_val * (ix_bse - ix) * (iz_bse - iz) * gOut;
giz -= tnw_val * (ix_bse - ix) * (iy_bse - iy) * gOut;
}
if (within_bounds_3d(iz_tne, iy_tne, ix_tne, inp_D, inp_H, inp_W)) {
scalar_t tne_val = inp_ptr_NC[iz_tne * inp_sD + iy_tne * inp_sH + ix_tne * inp_sW];
gix += tne_val * (iy_bsw - iy) * (iz_bsw - iz) * gOut;
giy -= tne_val * (ix - ix_bsw) * (iz_bsw - iz) * gOut;
giz -= tne_val * (ix - ix_bsw) * (iy_bsw - iy) * gOut;
}
if (within_bounds_3d(iz_tsw, iy_tsw, ix_tsw, inp_D, inp_H, inp_W)) {
scalar_t tsw_val = inp_ptr_NC[iz_tsw * inp_sD + iy_tsw * inp_sH + ix_tsw * inp_sW];
gix -= tsw_val * (iy - iy_bne) * (iz_bne - iz) * gOut;
giy += tsw_val * (ix_bne - ix) * (iz_bne - iz) * gOut;
giz -= tsw_val * (ix_bne - ix) * (iy - iy_bne) * gOut;
}
if (within_bounds_3d(iz_tse, iy_tse, ix_tse, inp_D, inp_H, inp_W)) {
scalar_t tse_val = inp_ptr_NC[iz_tse * inp_sD + iy_tse * inp_sH + ix_tse * inp_sW];
gix += tse_val * (iy - iy_bnw) * (iz_bnw - iz) * gOut;
giy += tse_val * (ix - ix_bnw) * (iz_bnw - iz) * gOut;
giz -= tse_val * (ix - ix_bnw) * (iy - iy_bnw) * gOut;
}
if (within_bounds_3d(iz_bnw, iy_bnw, ix_bnw, inp_D, inp_H, inp_W)) {
scalar_t bnw_val = inp_ptr_NC[iz_bnw * inp_sD + iy_bnw * inp_sH + ix_bnw * inp_sW];
gix -= bnw_val * (iy_tse - iy) * (iz - iz_tse) * gOut;
giy -= bnw_val * (ix_tse - ix) * (iz - iz_tse) * gOut;
giz += bnw_val * (ix_tse - ix) * (iy_tse - iy) * gOut;
}
if (within_bounds_3d(iz_bne, iy_bne, ix_bne, inp_D, inp_H, inp_W)) {
scalar_t bne_val = inp_ptr_NC[iz_bne * inp_sD + iy_bne * inp_sH + ix_bne * inp_sW];
gix += bne_val * (iy_tsw - iy) * (iz - iz_tsw) * gOut;
giy -= bne_val * (ix - ix_tsw) * (iz - iz_tsw) * gOut;
giz += bne_val * (ix - ix_tsw) * (iy_tsw - iy) * gOut;
}
if (within_bounds_3d(iz_bsw, iy_bsw, ix_bsw, inp_D, inp_H, inp_W)) {
scalar_t bsw_val = inp_ptr_NC[iz_bsw * inp_sD + iy_bsw * inp_sH + ix_bsw * inp_sW];
gix -= bsw_val * (iy - iy_tne) * (iz - iz_tne) * gOut;
giy += bsw_val * (ix_tne - ix) * (iz - iz_tne) * gOut;
giz += bsw_val * (ix_tne - ix) * (iy - iy_tne) * gOut;
}
if (within_bounds_3d(iz_bse, iy_bse, ix_bse, inp_D, inp_H, inp_W)) {
scalar_t bse_val = inp_ptr_NC[iz_bse * inp_sD + iy_bse * inp_sH + ix_bse * inp_sW];
gix += bse_val * (iy - iy_tnw) * (iz - iz_tnw) * gOut;
giy += bse_val * (ix - ix_tnw) * (iz - iz_tnw) * gOut;
giz += bse_val * (ix - ix_tnw) * (iy - iy_tnw) * gOut;
}
}
// assuming grad_grid is contiguous
// thus we can
// 1. use index with gGrid_sW to directly compute gGrid_ptr_NDHW
// 2. directly assign to gGrid_ptr_NDHW[0], gGrid_ptr_NDHW[1], gGrid_ptr_NDHW[2]
scalar_t *gGrid_ptr_NDHW = grad_grid.data + index * gGrid_sW;
gGrid_ptr_NDHW[0] = gix_mult * gix;
gGrid_ptr_NDHW[1] = giy_mult * giy;
gGrid_ptr_NDHW[2] = giz_mult * giz;
} else if (interpolation_mode == GridSamplerInterpolation::Nearest) {
int ix_nearest = static_cast<int>(::round(ix));
int iy_nearest = static_cast<int>(::round(iy));
int iz_nearest = static_cast<int>(::round(iz));
// assign nearest neighor pixel value to output pixel
scalar_t *gOut_ptr_NCDHW = grad_output.data + n * gOut_sN + d * gOut_sD + h * gOut_sH + w * gOut_sW;
scalar_t *gInp_ptr_NC = grad_input.data + n * gInp_sN;
for (int c = 0; c < C; ++c, gOut_ptr_NCDHW += gOut_sC, gInp_ptr_NC += gInp_sC) {
// calculate and set grad_input
safe_add_3d(gInp_ptr_NC, iz_nearest, iy_nearest, ix_nearest,
gInp_sD, gInp_sH, gInp_sW, inp_D, inp_H, inp_W, *gOut_ptr_NCDHW);
}
// assuming grad_grid is contiguous
// thus we can
// 1. use index with gGrid_sW to directly compute gGrid_ptr_NDHW
// 2. directly assign to gGrid_ptr_NDHW[0], gGrid_ptr_NDHW[1], gGrid_ptr_NDHW[2]
scalar_t *gGrid_ptr_NDHW = grad_grid.data + index * gGrid_sW;
gGrid_ptr_NDHW[0] = static_cast<scalar_t>(0);
gGrid_ptr_NDHW[1] = static_cast<scalar_t>(0);
gGrid_ptr_NDHW[2] = static_cast<scalar_t>(0);
}
}
}
} // namespace
// No shape checking needed here. See # NOTE [ grid_sampler Native Functions ].
Tensor grid_sampler_2d_cuda(const Tensor& input, const Tensor& grid,
int64_t interpolation_mode, int64_t padding_mode,
bool align_corners) {
auto N = input.size(0);
auto H = grid.size(1);
auto W = grid.size(2);
auto output = at::empty({N, input.size(1), H, W}, input.options());
int count = static_cast<int>(N * H * W);
if (count > 0) {
AT_DISPATCH_FLOATING_TYPES_AND_HALF(input.scalar_type(), "grid_sampler_2d_cuda", [&] {
grid_sampler_2d_kernel<scalar_t>
<<<GET_BLOCKS(count), CUDA_NUM_THREADS, 0, at::cuda::getCurrentCUDAStream()>>>(
count,
getTensorInfo<scalar_t, int>(input),
getTensorInfo<scalar_t, int>(grid),
getTensorInfo<scalar_t, int>(output),
static_cast<GridSamplerInterpolation>(interpolation_mode),
static_cast<GridSamplerPadding>(padding_mode),
align_corners);
});
}
return output;
}
// No shape checking needed here. See # NOTE [ grid_sampler Native Functions ].
Tensor grid_sampler_3d_cuda(const Tensor& input, const Tensor& grid,
int64_t interpolation_mode, int64_t padding_mode,
bool align_corners) {
auto N = input.size(0);
auto D = grid.size(1);
auto H = grid.size(2);
auto W = grid.size(3);
auto output = at::empty({N, input.size(1), D, H, W}, input.options());
int count = static_cast<int>(N * D * H * W);
if (count > 0) {
AT_DISPATCH_FLOATING_TYPES_AND_HALF(input.scalar_type(), "grid_sampler_2d_cuda", [&] {
grid_sampler_3d_kernel<scalar_t>
<<<GET_BLOCKS(count), CUDA_NUM_THREADS, 0, at::cuda::getCurrentCUDAStream()>>>(
count,
getTensorInfo<scalar_t, int>(input),
getTensorInfo<scalar_t, int>(grid),
getTensorInfo<scalar_t, int>(output),
static_cast<GridSamplerInterpolation>(interpolation_mode),
static_cast<GridSamplerPadding>(padding_mode),
align_corners);
});
}
return output;
}
// No shape checking needed here. See # NOTE [ grid_sampler Native Functions ].
std::tuple<Tensor, Tensor>
grid_sampler_2d_backward_cuda(const Tensor& grad_output, const Tensor& input,
const Tensor& grid, int64_t interpolation_mode,
int64_t padding_mode, bool align_corners) {
auto N = input.size(0);
auto H = grid.size(1);
auto W = grid.size(2);
auto grad_input = at::zeros_like(input, LEGACY_CONTIGUOUS_MEMORY_FORMAT);
auto grad_grid = at::empty_like(grid, LEGACY_CONTIGUOUS_MEMORY_FORMAT);
int count = static_cast<int>(N * H * W);
if (count > 0) {
AT_DISPATCH_FLOATING_TYPES_AND_HALF(input.scalar_type(), "grid_sampler_2d_backward_cuda", [&] {
grid_sampler_2d_backward_kernel<scalar_t>
<<<GET_BLOCKS(count), CUDA_NUM_THREADS, 0, at::cuda::getCurrentCUDAStream()>>>(
count,
getTensorInfo<scalar_t, int>(grad_output),
getTensorInfo<scalar_t, int>(input),
getTensorInfo<scalar_t, int>(grid),
getTensorInfo<scalar_t, int>(grad_input),
getTensorInfo<scalar_t, int>(grad_grid),
static_cast<GridSamplerInterpolation>(interpolation_mode),
static_cast<GridSamplerPadding>(padding_mode),
align_corners);
});
}
return std::make_tuple(grad_input, grad_grid);
}
// No shape checking needed here. See # NOTE [ grid_sampler Native Functions ].
std::tuple<Tensor, Tensor>
grid_sampler_3d_backward_cuda(const Tensor& grad_output, const Tensor& input,
const Tensor& grid, int64_t interpolation_mode, int64_t padding_mode,
bool align_corners) {
auto N = input.size(0);
auto D = grid.size(1);
auto H = grid.size(2);
auto W = grid.size(3);
auto grad_input = at::zeros_like(input, LEGACY_CONTIGUOUS_MEMORY_FORMAT);
auto grad_grid = at::empty_like(grid, LEGACY_CONTIGUOUS_MEMORY_FORMAT);
int count = static_cast<int>(N * D * H * W);
if (count > 0) {
AT_DISPATCH_FLOATING_TYPES_AND_HALF(input.scalar_type(), "grid_sampler_3d_backward_cuda", [&] {
grid_sampler_3d_backward_kernel<scalar_t>
<<<GET_BLOCKS(count), CUDA_NUM_THREADS, 0, at::cuda::getCurrentCUDAStream()>>>(
count,
getTensorInfo<scalar_t, int>(grad_output),
getTensorInfo<scalar_t, int>(input),
getTensorInfo<scalar_t, int>(grid),
getTensorInfo<scalar_t, int>(grad_input),
getTensorInfo<scalar_t, int>(grad_grid),
static_cast<GridSamplerInterpolation>(interpolation_mode),
static_cast<GridSamplerPadding>(padding_mode),
align_corners);
});
}
return std::make_tuple(grad_input, grad_grid);
}
}} // namespace at::native