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GridSamplerKernel.cpp
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GridSamplerKernel.cpp
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#define TORCH_ASSERT_NO_OPERATORS
#include <ATen/native/GridSampler.h>
#include <ATen/native/cpu/GridSamplerKernel.h>
#include <ATen/core/TensorBase.h>
#include <ATen/Dispatch.h>
#include <ATen/Parallel.h>
#include <ATen/TensorGeometry.h>
#include <ATen/TensorIterator.h>
#include <ATen/cpu/vec/vec.h>
#include <c10/util/C++17.h>
#include <c10/util/irange.h>
#include <algorithm>
#include <cstring>
#include <type_traits>
namespace at::native { namespace {
/** NOTE [ Grid Sample CPU Kernels ]
*
* Implementation of vectorized grid sample CPU kernels is divided into three
* parts. More detailed description exist after this paragraph, but on a high
* level, they are
* 1. `ComputeLocation` struct
* + Computes the interpolation location basing on padding mode.
* 2. `ApplyGridSample` struct
* + Owns N (# spatial dims) `ComputeLocation` structs, and uses them to
* compute the interpolation locations.
* + Interpolates the values and writes to output.
* 3. `grid_sample_2d_grid_slice_iterator` function
* + Iterates over a slice of the grid tensor based on the geometry by the
* spatial ordering, i.e., the first iteration will process grid values
* grid[n, 0, 0, :], grid[n, 0, 1, :], grid[n, 0, 2, :], ...
* (Recall that, e.g., 2D grid has shape [N x H x W x 2], so grid[n, ...]
* is a slice, and grid[n, h, w, :] contains the values for a single
* output spatial location.)
* + Applies a given operator at each iteration, so we can use the same
* pattern for forward and backward.
*
* Putting everything together, we have, e.g., the forward kernel implemented
* as
*
* // `ApplyGridSample` struct that processes grid values, extracts and
* // interpolates input values, and write to output.
* ApplyGridSample<scalar_t, 2, interp, padding> grid_sample(input_accessor);
*
* // For each slice, we call `grid_sample_2d_grid_slice_iterator` with
* // 1. the grid slice, and
* // 2. a lambda that takes in
* // i. location vectors (x and y for 2D) extracted from grid
* // ii. `spatial_offset` as the spatial offset of these vectors
* // from the beginning of this slice.
* // iii. `len` as the number of valid locations in the vectors.
* // (There might not be enough near boundary.)
* for (const auto n : c10::irange(input_accessor.size(0))) {
* grid_sample_2d_grid_slice_iterator(
* grid_accessor[n],
* [&](const Vectorized<scalar_t>& grid_x,
* const Vectorized<scalar_t>& grid_y,
* int64_t spatial_offset, int64_t len) {
* grid_sample.forward(out_accessor[n], input_accessor[n],
* spatial_offset, grid_x, grid_y, len);
* });
* }
*
* Now we talk about details of each of these three parts:
*
* 1. `ComputeLocation` struct
* Transforms grid values into interpolation locations of the input tensor
* for a particular spatial dimension, based on the size of that dimension
* in input tensor, and the padding mode.
*
* template<typename scalar_t, GridSamplerPadding padding>
* struct ComputeLocation {
* using Vec = Vectorized<scalar_t>;
*
* // ctor
* ComputeLocation(int64_t size);
*
* // Given grid values `in`, return the interpolation locations after
* // un-normalization and padding mechanism (elementwise).
* Vec apply(const Vec &in) const;
*
* // Similar to `apply`, but also returns `d apply(in) / d in`
* // (elementwise).
* // this is often used in gradient computation.
* std::pair<Vec, Vec> apply_get_grad(const Vec &in) const;
* };
*
* 2. `ApplyGridSample` struct
* Owns N `ComputeLocation` structs, where N is the number of spatial
* dimensions. Given N input grid vectors (one for each spatial dimension)
* and spatial offset, it gets the interpolation locations from
* `ComputeLocation`s, applies interpolation procedure, and then writes to
* the output (or grad_input & grad_grid in backward).
*
* template<typename scalar_t, int spatial_dim,
* GridSamplerInterpolation interp,
* GridSamplerPadding padding>
* struct ApplyGridSample {
*
* // ctor
* ApplyGridSample(const TensorAccessor<scalar_t, 4>& input);
*
* // Applies grid sampling (forward) procedure:
* // 1. computes interpolation locations from grid values `grid_x`
* // and `grid_y`,
* // 2. interpolates output values using the locations and input
* // data in `inp_slice`, and
* // 3. writes the first `len` values in the interpolated vector to
* // `out_slice` with spatial offset being `offset`.
* //
* // This assimes that `grid_x` and `grid_y` all contain valid grid
* // values \in [-1, 1], even at indices greater than `len`.
* //
* // The `*_slice` argument names mean samples within a batch (i.e.,
* // with the batch dimension sliced out).
* void forward(TensorAccessor<scalar_t, 3>& out_slice,
* const TensorAccessor<scalar_t, 3>& inp_slice,
* int64_t offset, const Vec& grid_x, const Vec& grid_y,
* int64_t len) const;
*
* // Applies grid sampling (backward) procedure. Arguments semantics
* // and strategy are similar to those of `forward`, with the
* // exception that `backward` has branches based on whether `input`
* // requires gradient (passed in as a template parameter). The
* // TensorAccessor for the input gradient is also given as a
* // pointer instead of reference, so that it can be null if the
* // gradient is not calculated.
* template <bool input_requires_grad>
* void backward(TensorAccessor<scalar_t, 3>* gInp_slice_ptr,
* TensorAccessor<scalar_t, 3>& gGrid_slice,
* const TensorAccessor<scalar_t, 3>& gOut_slice,
* const TensorAccessor<scalar_t, 3>& inp_slice,
* int64_t offset, const Vec& grid_x, const Vec& grid_y,
* int64_t len) const;
* };
*
* 3. `grid_sample_2d_grid_slice_iterator` function
* Among the tensors we work with, we know that the output tensors are
* contiguous (i.e., `output` in forward, and `grad_input` & `grad_grid` in
* backward), we need to randomly read `input` anyways, and `grad_output`
* usually comes from autograd and is often contiguous. So we base our
* iterating strategy on the geometry of grid.
* `grid_sample_2d_grid_slice_iterator` function provides an abstraction to
* efficiently iterates through a `grid` slice (without batch dimension).
* See comments of that function on the specific cases and strategies used.
*
* template<typename scalar_t, typename ApplyFn>
* void grid_sample_2d_grid_slice_iterator(
* const TensorAccessor<scalar_t, 3>& grid_slice,
* const ApplyFn &apply_fn);
*
* `apply_fn` is a function/lambda that takes in
* i. location vectors (x and y for 2D) extracted from grid
* ii. `spatial_offset` as the spatial offset of these vectors
* from the beginning of this slice.
* iii. `len` as the number of valid locations in the vectors.
* (There might not be enough near boundary.)
* It should be callable as if it has declaration:
* void apply_fn(const Vectorized<scalar_t>& grid_x,
* const Vectorized<scalar_t>& grid_y,
* int64_t spatial_offset, int64_t len);
*
* `apply_fn` will be called multiple times, and together cover the entire
* output spatial space.
*
* Now you should be able to understand everything about the implementation of
* 2D forward kernel shown at the beginning of this note.
*
**/
using at::native::detail::GridSamplerInterpolation;
using at::native::detail::GridSamplerPadding;
using namespace at::vec;
// ~~~~~~~~~~~~~~~~~~~~~~~~~~~~ ComputeLocation ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
// Struct to compute interpolation location from grid values, and to apply
// padding mechanism (e.g., reflection).
// See NOTE [ Grid Sample CPU Kernels ] for details.
template<typename scalar_t, bool align_corners>
struct ComputeLocationBase;
template<typename scalar_t>
struct ComputeLocationBase<scalar_t, /*align_corners=*/true> {
using Vec = Vectorized<scalar_t>;
// values are clipped to between 0 and max_val
const scalar_t max_val;
// unnormalization scaling factor
const scalar_t scaling_factor;
// reflection parameters: reflected coordinates land in [low, low+span] inclusive
const scalar_t low; // only used when align_corners=False
const scalar_t twice_span;
// if the reflecting span is empty, all reflected coords are set to 0
const bool empty;
ComputeLocationBase(int64_t size)
: max_val(static_cast<scalar_t>(size - 1))
, scaling_factor(static_cast<scalar_t>(size - 1) / 2)
, low(static_cast<scalar_t>(0))
, twice_span(static_cast<scalar_t>(size - 1) * 2)
, empty(size <= 1) {}
inline Vec unnormalize(const Vec &in) const {
return (in + Vec(1)) * Vec(scaling_factor);
}
inline Vec clip_coordinates(const Vec &in) const {
// Invert order of clamp_min operands in order to clamp Nans to zero
return clamp_max(Vec(max_val), clamp_min(Vec(0), in));
}
// same as clip_coordinates but also returns the gradient multiplier
inline std::pair<Vec, Vec> clip_coordinates_get_grad(const Vec &in) const {
using int_t = int_same_size_t<scalar_t>;
auto bounded_lo = maximum(in, Vec(0));
// Integral type equality comparison is very very fast because it just looks
// at the bits. Casting is free too. So we use the following pattern instead
// of comparison + blendv.
// Note that it is important for the gradient calculation that borders
// are considered out of bounds.
auto in_bound_lo = cast<scalar_t>(cast<int_t>(bounded_lo) != cast<int_t>(Vec(0)));
auto res = minimum(bounded_lo, Vec(max_val));
auto in_bound_hi = cast<scalar_t>(cast<int_t>(res) != cast<int_t>(Vec(max_val)));
return std::make_pair(res, in_bound_lo & in_bound_hi);
}
inline Vec reflect_coordinates(const Vec &in) const {
if (empty) {
return Vec(0);
}
Vec twice_span_vec(twice_span);
auto abs_in = in.abs();
auto fdouble_flips = abs_in / twice_span_vec;
auto double_flips = fdouble_flips.trunc();
auto extra = abs_in - double_flips * twice_span_vec;
// Now we need to test if extra > max_val to find out if another flip is
// needed. The following comparison does that and returns the correct
// flipped value.
return minimum(extra, twice_span_vec - extra);
}
// same as reflect_coordinates but also returns the gradient multiplier
inline std::pair<Vec, Vec> reflect_coordinates_get_grad(const Vec &in) const {
if (empty) {
return std::make_pair(Vec(0), Vec(0));
}
Vec twice_span_vec(twice_span);
auto neg_in = in < Vec(0);
auto abs_in = in.abs();
auto fdouble_flips = abs_in / twice_span_vec;
auto double_flips = fdouble_flips.trunc();
auto extra = abs_in - double_flips * twice_span_vec;
auto reflected_extra = twice_span_vec - extra;
auto one_more_flip = extra > reflected_extra;
return std::make_pair(
Vec::blendv(extra, reflected_extra, one_more_flip),
Vec::blendv(Vec(1), Vec(-1), one_more_flip ^ neg_in)
);
}
};
template<typename scalar_t>
struct ComputeLocationBase<scalar_t, /*align_corners=*/false> {
using Vec = Vectorized<scalar_t>;
// values are clipped to between 0 and max_val
const scalar_t max_val;
// unnormalization scaling factor
const scalar_t scaling_factor;
// reflection parameters: reflected coordinates land in [low, low+span] inclusive
const scalar_t low;
const scalar_t twice_span;
// if the reflecting span is empty, all reflected coords are set to 0
const bool empty; // only used when align_corners=True
ComputeLocationBase(int64_t size)
: max_val(static_cast<scalar_t>(size - 1))
, scaling_factor(static_cast<scalar_t>(size) / 2)
, low(static_cast<scalar_t>(-0.5))
, twice_span(static_cast<scalar_t>(size) * 2)
, empty(size <= 0) {}
inline Vec unnormalize(const Vec &in) const {
return (in + Vec(1)) * Vec(scaling_factor) - Vec(0.5);
}
inline Vec clip_coordinates(const Vec &in) const {
// Invert order of clamp_min operands in order to clamp Nans to zero
return clamp_max(Vec(max_val), clamp_min(Vec(0), in));
}
// same as clip_coordinates but also returns the gradient multiplier
inline std::pair<Vec, Vec> clip_coordinates_get_grad(const Vec &in) const {
using int_t = int_same_size_t<scalar_t>;
auto bounded_lo = maximum(in, Vec(0));
// Integral type equality comparison is very very fast because it just looks
// at the bits. Casting is free too. So we use the following pattern instead
// of comparison + blendv.
// Note that it is important for the gradient calculation that borders
// are considered out of bounds.
auto in_bound_lo = cast<scalar_t>(cast<int_t>(bounded_lo) != cast<int_t>(Vec(0)));
auto res = minimum(bounded_lo, Vec(max_val));
auto in_bound_hi = cast<scalar_t>(cast<int_t>(res) != cast<int_t>(Vec(max_val)));
return std::make_pair(res, in_bound_lo & in_bound_hi);
}
inline Vec reflect_coordinates(const Vec &in) const {
Vec twice_span_vec(twice_span), low_vec(low);
// Since reflection is around low and low+span, subtract low before
// the reflection, and then add it back at the end.
auto abs_in = (in - low_vec).abs();
auto fdouble_flips = abs_in / twice_span_vec;
auto double_flips = fdouble_flips.trunc();
auto extra = abs_in - double_flips * twice_span_vec;
// Now we need to test if extra > max_val to find out if another flip is
// needed. The following comparison does that and returns the correct
// flipped value.
return minimum(extra, twice_span_vec - extra) + low_vec;
}
// same as reflect_coordinates but also returns the gradient multiplier
inline std::pair<Vec, Vec> reflect_coordinates_get_grad(const Vec &in) const {
Vec twice_span_vec(twice_span), low_vec(low);
Vec in_minus_low = in - low_vec;
auto neg_in = in_minus_low < Vec(0);
auto abs_in = in_minus_low.abs();
auto fdouble_flips = abs_in / twice_span_vec;
auto double_flips = fdouble_flips.trunc();
auto extra = abs_in - double_flips * twice_span_vec;
auto reflected_extra = twice_span_vec - extra;
auto one_more_flip = extra > reflected_extra;
return std::make_pair(
Vec::blendv(extra, reflected_extra, one_more_flip) + low_vec,
Vec::blendv(Vec(1), Vec(-1), one_more_flip ^ neg_in)
);
}
};
template<typename scalar_t, GridSamplerPadding padding, bool align_corners>
struct ComputeLocation;
template<typename scalar_t, bool align_corners>
struct ComputeLocation<scalar_t, GridSamplerPadding::Zeros, align_corners>
: ComputeLocationBase<scalar_t, align_corners> {
using Vec = Vectorized<scalar_t>;
using ComputeLocationBase<scalar_t, align_corners>::unnormalize;
using ComputeLocationBase<scalar_t, align_corners>::scaling_factor;
using ComputeLocationBase<scalar_t, align_corners>::ComputeLocationBase;
inline Vec apply(const Vec &in) const {
return unnormalize(in);
}
inline Vec compute_coordinates(const Vec &in) const {
return in;
}
inline std::pair<Vec, Vec> apply_get_grad(const Vec &in) const {
return std::make_pair(unnormalize(in), Vec(scaling_factor));
}
};
template<typename scalar_t, bool align_corners>
struct ComputeLocation<scalar_t, GridSamplerPadding::Border, align_corners>
: ComputeLocationBase<scalar_t, align_corners> {
using Vec = Vectorized<scalar_t>;
using ComputeLocationBase<scalar_t, align_corners>::unnormalize;
using ComputeLocationBase<scalar_t, align_corners>::clip_coordinates;
using ComputeLocationBase<scalar_t, align_corners>::clip_coordinates_get_grad;
using ComputeLocationBase<scalar_t, align_corners>::scaling_factor;
using ComputeLocationBase<scalar_t, align_corners>::ComputeLocationBase;
inline Vec apply(const Vec &in) const {
return clip_coordinates(unnormalize(in));
}
inline Vec compute_coordinates(const Vec &in) const {
return clip_coordinates(in);
}
inline std::pair<Vec, Vec> apply_get_grad(const Vec &in) const {
Vec res, grad_clip;
std::tie(res, grad_clip) = clip_coordinates_get_grad(unnormalize(in));
return std::make_pair(res, grad_clip & Vec(scaling_factor));
}
};
template<typename scalar_t, bool align_corners>
struct ComputeLocation<scalar_t, GridSamplerPadding::Reflection, align_corners>
: ComputeLocationBase<scalar_t, align_corners> {
using Vec = Vectorized<scalar_t>;
using ComputeLocationBase<scalar_t, align_corners>::unnormalize;
using ComputeLocationBase<scalar_t, align_corners>::clip_coordinates;
using ComputeLocationBase<scalar_t, align_corners>::clip_coordinates_get_grad;
using ComputeLocationBase<scalar_t, align_corners>::reflect_coordinates;
using ComputeLocationBase<scalar_t, align_corners>::reflect_coordinates_get_grad;
using ComputeLocationBase<scalar_t, align_corners>::scaling_factor;
using ComputeLocationBase<scalar_t, align_corners>::ComputeLocationBase;
inline Vec apply(const Vec &in) const {
auto res = reflect_coordinates(unnormalize(in));
res = clip_coordinates(res);
return res;
}
inline Vec compute_coordinates(const Vec &in) const {
auto res = reflect_coordinates(in);
res = clip_coordinates(res);
return res;
}
inline std::pair<Vec, Vec> apply_get_grad(const Vec &in) const {
Vec res, grad_refl, grad_clip, grad(scaling_factor);
std::tie(res, grad_refl) = reflect_coordinates_get_grad(unnormalize(in));
grad = grad_refl * grad;
std::tie(res, grad_clip) = clip_coordinates_get_grad(res);
grad = grad_clip & grad;
return std::make_pair(res, grad);
}
};
// ~~~~~~~~~~~~~~~~~~~~~~~~~~~~ ApplyGridSample ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
// Struct to apply grid sample (reading from input, interpolate, and write to
// output).
// See NOTE [ Grid Sample CPU Kernels ] for details.
template<typename scalar_t>
static inline void
mask_scatter_add(const scalar_t *src, scalar_t* base_addr,
const int_same_size_t<scalar_t> *offsets,
const int_same_size_t<scalar_t> *mask, int64_t len) {
#if !defined(_MSC_VER) && !defined(COMPILING_FOR_MIN_SIZE)
# pragma unroll
#endif
for (const auto i : c10::irange(len)) {
if (mask[i] & 0x01) {
base_addr[offsets[i]] += src[i];
}
}
}
template<typename scalar_t, int spatial_dim,
GridSamplerInterpolation interp,
GridSamplerPadding padding,
bool align_corners>
struct ApplyGridSample;
template<typename scalar_t, GridSamplerPadding padding, bool align_corners>
struct ApplyGridSample<scalar_t, 2, GridSamplerInterpolation::Bilinear,
padding, align_corners> {
using Vec = Vectorized<scalar_t>;
using integer_t = int_same_size_t<scalar_t>;
using iVec = Vectorized<integer_t>;
const int64_t inp_H;
const int64_t inp_W;
const int64_t inp_sH;
const int64_t inp_sW;
const int64_t C;
const int64_t inp_sC;
const ComputeLocation<scalar_t, padding, align_corners> compute_H;
const ComputeLocation<scalar_t, padding, align_corners> compute_W;
const bool must_in_bound = padding != GridSamplerPadding::Zeros;
ApplyGridSample(const TensorAccessor<scalar_t, 4>& input)
: inp_H(input.size(2))
, inp_W(input.size(3))
, inp_sH(input.stride(2))
, inp_sW(input.stride(3))
, C(input.size(1))
, inp_sC(input.stride(1))
, compute_H(input.size(2))
, compute_W(input.size(3)) {}
inline std::tuple<
Vec, Vec, Vec, Vec, // distances to 4 sides
Vec, Vec, Vec, Vec, // interpolation weights wrt 4 corners
Vec, Vec, Vec, Vec, // in_bound masks
iVec, iVec // y_n and x_w
>
compute_interp_params(const Vec& x, const Vec& y) const {
// get NE, NW, SE, SW pixel values from (x, y)
// assuming we get exact integer representation and just use scalar_t
// if we don't, the weights will be garbage anyways.
auto x_w = x.floor();
auto y_n = y.floor();
// get distances to each side
auto w = x - x_w;
auto e = Vec(1) - w;
auto n = y - y_n;
auto s = Vec(1) - n;
// get interpolation weights for each neighbor
// e.g., for the nw corner, the weight is `dist_to_south * dist_to_east`.
auto nw = s * e;
auto ne = s * w;
auto sw = n * e;
auto se = n * w;
auto i_x_w = convert_to_int_of_same_size(x_w);
auto i_y_n = convert_to_int_of_same_size(y_n);
auto i_x_e = i_x_w + iVec(1);
auto i_y_s = i_y_n + iVec(1);
// Use int comparison because it is much faster than float comp with AVX2
// (latency 1 cyc vs. 4 cyc on skylake)
// Avoid using the le and ge because those are not implemented in AVX2 and
// are actually simulated using multiple instructions.
auto w_mask = must_in_bound ? iVec(-1) // true = all ones
: (i_x_w > iVec(-1)) & (i_x_w < iVec(inp_W));
auto n_mask = must_in_bound ? iVec(-1) // true = all ones
: (i_y_n > iVec(-1)) & (i_y_n < iVec(inp_H));
auto e_mask = must_in_bound ? (i_x_e < iVec(inp_W))
: (i_x_e > iVec(-1)) & (i_x_e < iVec(inp_W));
auto s_mask = must_in_bound ? (i_y_s < iVec(inp_H))
: (i_y_s > iVec(-1)) & (i_y_s < iVec(inp_H));
auto nw_mask = cast<scalar_t>(must_in_bound ? iVec(-1) : (w_mask & n_mask));
auto ne_mask = cast<scalar_t>(e_mask & n_mask);
auto sw_mask = cast<scalar_t>(w_mask & s_mask);
auto se_mask = cast<scalar_t>(e_mask & s_mask);
return std::make_tuple(
n, s, w, e,
nw, ne, sw, se,
nw_mask, ne_mask, sw_mask, se_mask,
i_y_n, i_x_w);
}
inline void forward(TensorAccessor<scalar_t, 3>& out_slice,
const TensorAccessor<scalar_t, 3>& inp_slice,
int64_t offset, const Vec& grid_x, const Vec& grid_y,
int64_t len) const {
auto x = compute_W.apply(grid_x);
auto y = compute_H.apply(grid_y);
auto interp_params = compute_interp_params(x, y);
auto nw = std::get<4>(interp_params);
auto ne = std::get<5>(interp_params);
auto sw = std::get<6>(interp_params);
auto se = std::get<7>(interp_params);
auto nw_mask = std::get<8>(interp_params);
auto ne_mask = std::get<9>(interp_params);
auto sw_mask = std::get<10>(interp_params);
auto se_mask = std::get<11>(interp_params);
auto i_y_n = std::get<12>(interp_params);
auto i_x_w = std::get<13>(interp_params);
auto i_nw_offset = i_y_n * iVec(inp_sH) + i_x_w * iVec(inp_sW);
auto i_ne_offset = i_nw_offset + iVec(inp_sW);
auto i_sw_offset = i_nw_offset + iVec(inp_sH);
auto i_se_offset = i_sw_offset + iVec(inp_sW);
#if !defined(_MSC_VER) && !defined(COMPILING_FOR_MIN_SIZE)
# pragma unroll
#endif
for (const auto c : c10::irange(C)) {
auto inp_slice_C_ptr = inp_slice[c].data();
// mask_gather zeros out the mask, so we need to make copies
Vec nw_mask_copy = nw_mask;
Vec ne_mask_copy = ne_mask;
Vec sw_mask_copy = sw_mask;
Vec se_mask_copy = se_mask;
auto nw_val = mask_gather<sizeof(scalar_t)>(Vec(0), inp_slice_C_ptr, i_nw_offset, nw_mask_copy);
auto ne_val = mask_gather<sizeof(scalar_t)>(Vec(0), inp_slice_C_ptr, i_ne_offset, ne_mask_copy);
auto sw_val = mask_gather<sizeof(scalar_t)>(Vec(0), inp_slice_C_ptr, i_sw_offset, sw_mask_copy);
auto se_val = mask_gather<sizeof(scalar_t)>(Vec(0), inp_slice_C_ptr, i_se_offset, se_mask_copy);
auto interpolated = (nw_val * nw) + (ne_val * ne) + (sw_val * sw) + (se_val * se);
interpolated.store(out_slice[c].data() + offset, len);
}
}
template<bool input_requires_grad>
inline void backward(TensorAccessor<scalar_t, 3>* gInp_slice_ptr,
TensorAccessor<scalar_t, 3>& gGrid_slice,
const TensorAccessor<scalar_t, 3>& gOut_slice,
const TensorAccessor<scalar_t, 3>& inp_slice,
int64_t offset, const Vec& grid_x, const Vec& grid_y,
int64_t len) const {
Vec x, y, gx_mult, gy_mult;
std::tie(x, gx_mult) = compute_W.apply_get_grad(grid_x);
std::tie(y, gy_mult) = compute_H.apply_get_grad(grid_y);
Vec n, s, w, e, nw, ne, sw, se, nw_mask, ne_mask, sw_mask, se_mask;
iVec i_y_n, i_x_w;
std::tie(
n, s, w, e, nw, ne, sw, se, nw_mask, ne_mask, sw_mask, se_mask,
i_y_n, i_x_w) = compute_interp_params(x, y);
auto i_nw_offset = i_y_n * iVec(inp_sH) + i_x_w * iVec(inp_sW);
auto i_ne_offset = i_nw_offset + iVec(inp_sW);
auto i_sw_offset = i_nw_offset + iVec(inp_sH);
auto i_se_offset = i_sw_offset + iVec(inp_sW);
// NOLINTNEXTLINE(modernize-avoid-c-arrays,cppcoreguidelines-avoid-c-arrays)
integer_t i_nw_mask_arr[iVec::size()];
// NOLINTNEXTLINE(modernize-avoid-c-arrays,cppcoreguidelines-avoid-c-arrays)
integer_t i_ne_mask_arr[iVec::size()];
// NOLINTNEXTLINE(modernize-avoid-c-arrays,cppcoreguidelines-avoid-c-arrays)
integer_t i_sw_mask_arr[iVec::size()];
// NOLINTNEXTLINE(modernize-avoid-c-arrays,cppcoreguidelines-avoid-c-arrays)
integer_t i_se_mask_arr[iVec::size()];
nw_mask.store(i_nw_mask_arr);
ne_mask.store(i_ne_mask_arr);
sw_mask.store(i_sw_mask_arr);
se_mask.store(i_se_mask_arr);
// i_gInp_*_offset_arr and gInp_corner_arr variables below are unnecessary
// when input_requires_grad is false (they are only used within the
// if-blocks), but required to make the code well-formed.
// When reading input values, we used mask_gather. Unfortunately, there is
// no mask_scatter_add (the backward of mask_gather) in Intel intrinsics.
// So we store the necessary vectors to temporary arrays and use the helper
// mask_scatter_add defined above.
// NOLINTNEXTLINE(modernize-avoid-c-arrays,cppcoreguidelines-avoid-c-arrays)
integer_t i_gInp_nw_offset_arr[iVec::size()];
// NOLINTNEXTLINE(modernize-avoid-c-arrays,cppcoreguidelines-avoid-c-arrays)
integer_t i_gInp_ne_offset_arr[iVec::size()];
// NOLINTNEXTLINE(modernize-avoid-c-arrays,cppcoreguidelines-avoid-c-arrays)
integer_t i_gInp_sw_offset_arr[iVec::size()];
// NOLINTNEXTLINE(modernize-avoid-c-arrays,cppcoreguidelines-avoid-c-arrays)
integer_t i_gInp_se_offset_arr[iVec::size()];
if (input_requires_grad) {
auto i_gInp_nw_offset = i_y_n * iVec(inp_W) + i_x_w;
auto i_gInp_ne_offset = i_gInp_nw_offset + iVec(1);
auto i_gInp_sw_offset = i_gInp_nw_offset + iVec(inp_W);
auto i_gInp_se_offset = i_gInp_sw_offset + iVec(1);
i_gInp_nw_offset.store(i_gInp_nw_offset_arr);
i_gInp_ne_offset.store(i_gInp_ne_offset_arr);
i_gInp_sw_offset.store(i_gInp_sw_offset_arr);
i_gInp_se_offset.store(i_gInp_se_offset_arr);
}
// NOLINTNEXTLINE(modernize-avoid-c-arrays,cppcoreguidelines-avoid-c-arrays)
scalar_t gInp_corner_arr[Vec::size()];
auto gx = Vec(0), gy = Vec(0);
#if !defined(_MSC_VER) && !defined(COMPILING_FOR_MIN_SIZE)
# pragma unroll
#endif
for (const auto c : c10::irange(C)) {
auto inp_slice_C_ptr = inp_slice[c].data();
auto gOut = Vec::loadu(gOut_slice[c].data() + offset, len);
if (input_requires_grad) {
TORCH_INTERNAL_ASSERT(gInp_slice_ptr);
auto gInp_slice_C_ptr = (*gInp_slice_ptr)[c].data();
(nw * gOut).store(gInp_corner_arr);
mask_scatter_add(gInp_corner_arr, gInp_slice_C_ptr, i_gInp_nw_offset_arr, i_nw_mask_arr, len);
(ne * gOut).store(gInp_corner_arr);
mask_scatter_add(gInp_corner_arr, gInp_slice_C_ptr, i_gInp_ne_offset_arr, i_ne_mask_arr, len);
(sw * gOut).store(gInp_corner_arr);
mask_scatter_add(gInp_corner_arr, gInp_slice_C_ptr, i_gInp_sw_offset_arr, i_sw_mask_arr, len);
(se * gOut).store(gInp_corner_arr);
mask_scatter_add(gInp_corner_arr, gInp_slice_C_ptr, i_gInp_se_offset_arr, i_se_mask_arr, len);
}
// mask_gather zeros out the mask, so we need to make copies
Vec nw_mask_copy = nw_mask;
Vec ne_mask_copy = ne_mask;
Vec sw_mask_copy = sw_mask;
Vec se_mask_copy = se_mask;
auto nw_val = mask_gather<sizeof(scalar_t)>(Vec(0), inp_slice_C_ptr, i_nw_offset, nw_mask_copy);
auto ne_val = mask_gather<sizeof(scalar_t)>(Vec(0), inp_slice_C_ptr, i_ne_offset, ne_mask_copy);
auto sw_val = mask_gather<sizeof(scalar_t)>(Vec(0), inp_slice_C_ptr, i_sw_offset, sw_mask_copy);
auto se_val = mask_gather<sizeof(scalar_t)>(Vec(0), inp_slice_C_ptr, i_se_offset, se_mask_copy);
gx = gx + ((ne_val - nw_val) * s + (se_val - sw_val) * n) * gOut;
gy = gy + ((sw_val - nw_val) * e + (se_val - ne_val) * w) * gOut;
}
gx = gx * gx_mult;
gy = gy * gy_mult;
constexpr int64_t step = Vec::size();
auto interleaved_gGrid = interleave2(gx, gy);
auto gGrid_ptr = gGrid_slice.data() + offset * 2;
std::get<0>(interleaved_gGrid).store(gGrid_ptr,
std::min(len * 2, step));
std::get<1>(interleaved_gGrid).store(gGrid_ptr + step,
std::max(static_cast<int64_t>(0), len * 2 - step));
}
};
template<typename scalar_t, GridSamplerPadding padding, bool align_corners>
struct ApplyGridSample<scalar_t, 2, GridSamplerInterpolation::Nearest,
padding, align_corners> {
using Vec = Vectorized<scalar_t>;
using integer_t = int_same_size_t<scalar_t>;
using iVec = Vectorized<integer_t>;
const int64_t inp_H;
const int64_t inp_W;
const int64_t inp_sH;
const int64_t inp_sW;
const int64_t C;
const int64_t inp_sC;
const ComputeLocation<scalar_t, padding, align_corners> compute_H;
const ComputeLocation<scalar_t, padding, align_corners> compute_W;
const bool must_in_bound = padding != GridSamplerPadding::Zeros;
ApplyGridSample(const TensorAccessor<scalar_t, 4>& input)
: inp_H(input.size(2))
, inp_W(input.size(3))
, inp_sH(input.stride(2))
, inp_sW(input.stride(3))
, C(input.size(1))
, inp_sC(input.stride(1))
, compute_H(input.size(2))
, compute_W(input.size(3)) {}
inline void forward(TensorAccessor<scalar_t, 3>& out_slice,
const TensorAccessor<scalar_t, 3>& inp_slice,
int64_t offset, const Vec& grid_x, const Vec& grid_y,
int64_t len) const {
auto x = compute_W.apply(grid_x);
auto y = compute_H.apply(grid_y);
auto x_nearest = x.round();
auto y_nearest = y.round();
auto i_x_nearest = convert_to_int_of_same_size(x_nearest);
auto i_y_nearest = convert_to_int_of_same_size(y_nearest);
auto i_mask = must_in_bound ? iVec(-1)
: (i_x_nearest > iVec(-1)) & (i_x_nearest < iVec(inp_W)) &
(i_y_nearest > iVec(-1)) & (i_y_nearest < iVec(inp_H));
auto mask = cast<scalar_t>(i_mask);
auto i_offset = i_y_nearest * iVec(inp_sH) + i_x_nearest * iVec(inp_sW);
auto out_ptr = out_slice.data() + offset;
auto out_sC = out_slice.stride(0);
auto inp_slice_ptr = inp_slice.data();
#if !defined(_MSC_VER) && !defined(COMPILING_FOR_MIN_SIZE)
# pragma unroll
#endif
for (int64_t c = 0; c < C; ++c, out_ptr += out_sC, inp_slice_ptr += inp_sC) {
// mask_gather zeros out the mask, so we need to make a copy
auto mask_copy = mask;
auto inp_val = mask_gather<sizeof(scalar_t)>(Vec(0), inp_slice_ptr, i_offset, mask_copy);
inp_val.store(static_cast<void*>(out_ptr), len);
}
}
template<bool input_requires_grad>
inline void backward(TensorAccessor<scalar_t, 3>* gInp_slice_ptr,
TensorAccessor<scalar_t, 3>& gGrid_slice,
const TensorAccessor<scalar_t, 3>& gOut_slice,
const TensorAccessor<scalar_t, 3>& /*inp_slice*/,
int64_t offset, const Vec& grid_x, const Vec& grid_y,
int64_t len) const {
if (input_requires_grad) {
auto x = compute_W.apply(grid_x);
auto y = compute_H.apply(grid_y);
auto x_nearest = x.round();
auto y_nearest = y.round();
auto i_x_nearest = convert_to_int_of_same_size(x_nearest);
auto i_y_nearest = convert_to_int_of_same_size(y_nearest);
auto i_mask = must_in_bound ? iVec(-1)
: (i_x_nearest > iVec(-1)) & (i_x_nearest < iVec(inp_W)) &
(i_y_nearest > iVec(-1)) & (i_y_nearest < iVec(inp_H));
auto i_gInp_offset = i_y_nearest * iVec(inp_W) + i_x_nearest; // gInp is contiguous
// NOLINTNEXTLINE(modernize-avoid-c-arrays,cppcoreguidelines-avoid-c-arrays)
integer_t mask_arr[iVec::size()];
i_mask.store(mask_arr);
// NOLINTNEXTLINE(modernize-avoid-c-arrays,cppcoreguidelines-avoid-c-arrays)
integer_t gInp_offset_arr[iVec::size()];
i_gInp_offset.store(gInp_offset_arr);
#if !defined(_MSC_VER) && !defined(COMPILING_FOR_MIN_SIZE)
# pragma unroll
#endif
for (const auto c : c10::irange(C)) {
mask_scatter_add(gOut_slice[c].data() + offset, (*gInp_slice_ptr)[c].data(),
gInp_offset_arr, mask_arr, len);
}
}
// grid has zero 0 gradient in Nearest mode
auto gGrid_ptr = gGrid_slice.data() + offset * 2;
std::memset(gGrid_ptr, 0, sizeof(scalar_t) * len * 2);
}
};
// Use bicubic convolution algorithm. Based on
// https://en.wikipedia.org/wiki/Bicubic_interpolation#Bicubic_convolution_algorithm
template<typename scalar_t, GridSamplerPadding padding, bool align_corners>
struct ApplyGridSample<scalar_t, 2, GridSamplerInterpolation::Bicubic,
padding, align_corners> {
using Vec = Vectorized<scalar_t>;
using integer_t = int_same_size_t<scalar_t>;
using iVec = Vectorized<integer_t>;
const int64_t inp_H;
const int64_t inp_W;
const int64_t inp_sH;
const int64_t inp_sW;
const int64_t C;
const int64_t inp_sC;
const ComputeLocation<scalar_t, padding, align_corners> compute_H;
const ComputeLocation<scalar_t, padding, align_corners> compute_W;
const bool must_in_bound = padding != GridSamplerPadding::Zeros;
// constant used in cubic convolution
// could be -0.5 or -0.75, use the same value in UpSampleBicubic2d.h
const Vec A = Vec(-0.75);
ApplyGridSample(const TensorAccessor<scalar_t, 4>& input)
: inp_H(input.size(2))
, inp_W(input.size(3))
, inp_sH(input.stride(2))
, inp_sW(input.stride(3))
, C(input.size(1))
, inp_sC(input.stride(1))
, compute_H(input.size(2))
, compute_W(input.size(3)) {}
// Calculate the cubic convolution coefficient
// NOLINTNEXTLINE(modernize-avoid-c-arrays,cppcoreguidelines-avoid-c-arrays)
inline void get_cubic_coefficients(Vec (&coeffs)[4], const Vec& tx) const {
Vec x;
x = tx + Vec(1); // 1 < x = |-1 - tx| < 2
coeffs[0] = ((A * x - Vec(5) * A) * x + Vec(8) * A) * x - Vec(4) * A;
x = tx; // x = |0 - tx| <= 1
coeffs[1] = ((A + Vec(2)) * x - (A + Vec(3))) * x * x + Vec(1);
x = Vec(1) - tx; // x = |1 - tx| <= 1
coeffs[2] = ((A + Vec(2)) * x - (A + Vec(3))) * x * x + Vec(1);
x = Vec(2) - tx; // 1 < x = |2 - tx| < 2
coeffs[3] = ((A * x - Vec(5) * A) * x + Vec(8) * A) * x - Vec(4) * A;
}
// Calculate the differential of the cubic convolution, i.e. `d coeff / d x`
// NOLINTNEXTLINE(modernize-avoid-c-arrays,cppcoreguidelines-avoid-c-arrays)
inline void get_cubic_coefficients_grad(Vec (&coeffs)[4], const Vec& tx) const {
Vec x;
x = Vec(-1) - tx; // 1 < x = |-1 - tx| < 2
coeffs[0] = (Vec(-3) * A * x - Vec(10) * A ) * x - Vec(8) * A;
x = Vec(0) - tx; // x = |0 - tx| <= 1
coeffs[1] = (Vec(-3) * (A + Vec(2)) * x - Vec(2) * (A + Vec(3))) * x;
x = Vec(1) - tx; // x = |1 - tx| <= 1
coeffs[2] = (Vec(3) * (A + Vec(2)) * x - Vec(2) * (A + Vec(3))) * x;
x = Vec(2) - tx; // 1 < x = |2 - tx| < 2
coeffs[3] = (Vec(3) * A * x - Vec(10) * A) * x + Vec(8) * A;
}
inline Vec get_value_bounded(const scalar_t* data, const Vec& x, const Vec& y) const {
auto ix = convert_to_int_of_same_size(compute_W.compute_coordinates(x));
auto iy = convert_to_int_of_same_size(compute_H.compute_coordinates(y));
auto mask_x = must_in_bound ? iVec(-1) : (ix > iVec(-1)) & (ix < iVec(inp_W));
auto mask_y = must_in_bound ? iVec(-1) : (iy > iVec(-1)) & (iy < iVec(inp_H));
auto mask = cast<scalar_t>(mask_x & mask_y);
auto offset = iy * iVec(inp_sH) + ix * iVec(inp_sW);
auto val = mask_gather<sizeof(scalar_t)>(Vec(0), data, offset, mask);
return val;
}
inline void add_value_bounded(scalar_t* data, int64_t len, const Vec& x, const Vec&y,
const Vec& delta) const {
auto ix = convert_to_int_of_same_size(compute_W.compute_coordinates(x));
auto iy = convert_to_int_of_same_size(compute_H.compute_coordinates(y));
auto mask_x = must_in_bound ? iVec(-1) : (ix > iVec(-1)) & (ix < iVec(inp_W));
auto mask_y = must_in_bound ? iVec(-1) : (iy > iVec(-1)) & (iy < iVec(inp_H));
auto mask = cast<scalar_t>(mask_x & mask_y);
auto i_gInp_offset = iy * iVec(inp_W) + ix;
// NOLINTNEXTLINE(modernize-avoid-c-arrays,cppcoreguidelines-avoid-c-arrays)
integer_t i_gInp_offset_arr[iVec::size()];
i_gInp_offset.store(i_gInp_offset_arr);
// NOLINTNEXTLINE(modernize-avoid-c-arrays,cppcoreguidelines-avoid-c-arrays)
integer_t mask_arr[iVec::size()];
mask.store(mask_arr);
// NOLINTNEXTLINE(modernize-avoid-c-arrays,cppcoreguidelines-avoid-c-arrays)
scalar_t gInp_corner_arr[Vec::size()];
delta.store(gInp_corner_arr);
mask_scatter_add(gInp_corner_arr, data, i_gInp_offset_arr, mask_arr, len);
}
inline void forward(TensorAccessor<scalar_t, 3>& out_slice,
const TensorAccessor<scalar_t, 3>& inp_slice,
int64_t offset, const Vec& grid_x, const Vec& grid_y,
int64_t len) const {
auto x = compute_W.unnormalize(grid_x);
auto y = compute_H.unnormalize(grid_y);
auto ix = x.floor();
auto iy = y.floor();
// NOLINTNEXTLINE(modernize-avoid-c-arrays,cppcoreguidelines-avoid-c-arrays)
Vec coeff_x[4];
// NOLINTNEXTLINE(modernize-avoid-c-arrays,cppcoreguidelines-avoid-c-arrays)
Vec coeff_y[4];
get_cubic_coefficients(coeff_x, x - ix);
get_cubic_coefficients(coeff_y, y - iy);
#if !defined(_MSC_VER) && !defined(COMPILING_FOR_MIN_SIZE)
# pragma unroll
#endif
for (const auto c : c10::irange(C)) {
auto inp_slice_C_ptr = inp_slice[c].data();
// Interpolate the 4 values in the x direction
// NOLINTNEXTLINE(modernize-avoid-c-arrays,cppcoreguidelines-avoid-c-arrays)
Vec interp_x[4];
for (const auto i : c10::irange(4)) {
interp_x[i] =
coeff_x[0] * get_value_bounded(inp_slice_C_ptr, ix - Vec(1), iy + Vec(-1 + i)) +
coeff_x[1] * get_value_bounded(inp_slice_C_ptr, ix + Vec(0), iy + Vec(-1 + i)) +
coeff_x[2] * get_value_bounded(inp_slice_C_ptr, ix + Vec(1), iy + Vec(-1 + i)) +
coeff_x[3] * get_value_bounded(inp_slice_C_ptr, ix + Vec(2), iy + Vec(-1 + i));
}
// Interpolate the 4 values in the y direction
auto interpolated = coeff_y[0] * interp_x[0] + coeff_y[1] * interp_x[1] +
coeff_y[2] * interp_x[2] + coeff_y[3] * interp_x[3];
interpolated.store(out_slice[c].data() + offset, len);
}
}
template<bool input_requires_grad>
inline void backward(TensorAccessor<scalar_t, 3>* gInp_slice_ptr,
TensorAccessor<scalar_t, 3>& gGrid_slice,
const TensorAccessor<scalar_t, 3>& gOut_slice,
const TensorAccessor<scalar_t, 3>& inp_slice,
int64_t offset, const Vec& grid_x, const Vec& grid_y,
int64_t len) const {
Vec x = compute_W.unnormalize(grid_x);
Vec y = compute_H.unnormalize(grid_y);
Vec gx_mult = Vec(compute_W.scaling_factor);
Vec gy_mult = Vec(compute_H.scaling_factor);
auto ix = x.floor();
auto iy = y.floor();
// NOLINTNEXTLINE(modernize-avoid-c-arrays,cppcoreguidelines-avoid-c-arrays)
Vec coeff_x[4];
// NOLINTNEXTLINE(modernize-avoid-c-arrays,cppcoreguidelines-avoid-c-arrays)
Vec coeff_y[4];
get_cubic_coefficients(coeff_x, x - ix);
get_cubic_coefficients(coeff_y, y - iy);
// NOLINTNEXTLINE(modernize-avoid-c-arrays,cppcoreguidelines-avoid-c-arrays)
Vec coeff_x_grad[4];
// NOLINTNEXTLINE(modernize-avoid-c-arrays,cppcoreguidelines-avoid-c-arrays)
Vec coeff_y_grad[4];
get_cubic_coefficients_grad(coeff_x_grad, x - ix);
get_cubic_coefficients_grad(coeff_y_grad, y - iy);
auto gx = Vec(0), gy = Vec(0);
#if !defined(_MSC_VER) && !defined(COMPILING_FOR_MIN_SIZE)
# pragma unroll
#endif
for (const auto c : c10::irange(C)) {
auto inp_slice_C_ptr = inp_slice[c].data();
auto gOut = Vec::loadu(gOut_slice[c].data() + offset, len);
for (const auto i : c10::irange(4)) {
for (const auto j : c10::irange(4)) {
auto xx = ix + Vec(-1 + i);
auto yy = iy + Vec(-1 + j);
if (input_requires_grad) {
auto gInp_slice_C_ptr = (*gInp_slice_ptr)[c].data();