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ConvolutionMM3d.cpp
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ConvolutionMM3d.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/TensorUtils.h>
#include <ATen/div_rtn.h>
#include <ATen/native/ConvolutionMM3d.h>
#include <ATen/native/CPUBlas.h>
#include <ATen/native/TransposeType.h>
#include <ATen/native/Unfold3d.h>
#include <c10/util/irange.h>
#ifndef AT_PER_OPERATOR_HEADERS
#include <ATen/Functions.h>
#include <ATen/NativeFunctions.h>
#else
#include <ATen/ops/empty.h>
#include <ATen/ops/slow_conv3d_forward.h>
#include <ATen/ops/slow_conv3d_forward_native.h>
#include <ATen/ops/slow_conv3d_native.h>
#include <ATen/ops/sum.h>
#endif
constexpr int64_t CONV3D_GRAIN_SALT = 20;
namespace at {
namespace native {
namespace {
static Tensor compute_columns3d(
const Tensor& input_,
IntArrayRef stride,
IntArrayRef padding,
IntArrayRef kernel_size,
const int64_t groups) {
const Tensor input = input_.contiguous();
const int64_t kernel_depth = kernel_size[0];
const int64_t kernel_height = kernel_size[1];
const int64_t kernel_width = kernel_size[2];
const int64_t pad_depth = padding[0];
const int64_t pad_height = padding[1];
const int64_t pad_width = padding[2];
const int64_t stride_depth = stride[0];
const int64_t stride_height = stride[1];
const int64_t stride_width = stride[2];
const int64_t dim_planes = 1;
const int64_t dim_depth = 2;
const int64_t dim_height = 3;
const int64_t dim_width = 4;
const int64_t n_input_plane = input.size(dim_planes);
const int64_t input_depth = input.size(dim_depth);
const int64_t input_height = input.size(dim_height);
const int64_t input_width = input.size(dim_width);
const int64_t output_depth =
(input_depth + 2 * pad_depth - kernel_depth) / stride_depth + 1;
const int64_t output_height =
(input_height + 2 * pad_height - kernel_height) / stride_height + 1;
const int64_t output_width =
(input_width + 2 * pad_width - kernel_width) / stride_width + 1;
const int64_t batch_size = input.size(0);
Tensor columns;
if ((kernel_depth == 1) && (kernel_height == 1) && (kernel_width == 1) &&
(pad_depth == 0) && (pad_height == 0) && (pad_width == 0) &&
(stride_depth == 1) && (stride_height == 1) && (stride_width == 1) && (groups == 1)) {
// Columns are just a view on the input for this special case.
columns = input.view({batch_size, n_input_plane, output_height * output_width * output_depth}).detach();
} else {
columns = at::empty({batch_size,
n_input_plane * kernel_depth * kernel_height * kernel_width,
output_depth * output_height * output_width},
input.options());
AT_DISPATCH_ALL_TYPES_AND(kBFloat16, input.scalar_type(), "compute_columns3d", [&] {
auto input_a = input.accessor<scalar_t, 5>();
auto columns_a = columns.accessor<scalar_t, 3>();
at::parallel_for(0, batch_size, CONV3D_GRAIN_SALT, [&](int64_t start, int64_t end) {
for (const auto t : c10::irange(start, end)) {
auto input_t = input_a[t];
auto columns_t = columns_a[t];
Unfold3dCopyCPU(
c10::CppTypeToScalarType<scalar_t>::value,
input_t.data(),
n_input_plane,
input_depth,
input_height,
input_width,
output_depth,
output_height,
output_width,
kernel_depth,
kernel_height,
kernel_width,
stride_depth,
stride_height,
stride_width,
pad_depth,
pad_height,
pad_width,
columns_t.data());
}
});
});
}
return columns;
}
static inline void slow_conv3d_shape_check(
const Tensor& input,
const Tensor& grad_output,
const Tensor& weight,
const Tensor& bias,
int64_t kernel_depth,
int64_t kernel_height,
int64_t kernel_width,
int64_t stride_depth,
int64_t stride_height,
int64_t stride_width,
int64_t pad_depth,
int64_t pad_height,
int64_t pad_width,
int64_t groups,
bool weight_optional) {
TORCH_CHECK(
kernel_width > 0 && kernel_height > 0 && kernel_depth > 0,
"kernel size should be greater than zero, but got: ",
kernel_depth,
" x ",
kernel_height,
" x ",
kernel_width,
" (TxHxW)");
TORCH_CHECK(
stride_width > 0 && stride_height > 0 && stride_depth > 0,
"stride should be greater than zero, but got: ",
stride_depth,
" x ",
stride_height,
" x ",
stride_width,
" (TxHxW)");
if (weight.defined()) {
TORCH_CHECK(
weight.numel() > 0 && (weight.dim() == 2 || weight.dim() == 5),
"non-empty 2D or 5D weight tensor expected, but got: ",
weight.sizes());
if (bias.defined()) {
check_dim_size(bias, 1, 0, weight.size(0));
}
} else {
TORCH_CHECK(weight_optional, "weight tensor is undefined");
}
const int64_t ndim = input.dim();
const int64_t dim_batch = 0;
const int64_t dim_planes = 1;
const int64_t dim_depth = 2;
const int64_t dim_height = 3;
const int64_t dim_width = 4;
// Allow for empty batch size but not other dimensions
bool valid_empty = ndim == 5 && input.size(dim_batch) == 0 &&
input.size(dim_planes) != 0 && input.size(dim_depth) != 0 &&
input.size(dim_height) != 0 && input.size(dim_width) != 0;
TORCH_CHECK(
(input.numel() > 0 || valid_empty) && ndim == 5,
"non-empty 5D input tensor expected but got: ",
input.sizes());
const int64_t input_depth = input.size(dim_depth);
const int64_t input_height = input.size(dim_height);
const int64_t input_width = input.size(dim_width);
const int64_t exact_input_depth = input_depth + 2 * pad_depth;
const int64_t exact_input_height = input_height + 2 * pad_height;
const int64_t exact_input_width = input_width + 2 * pad_width;
TORCH_CHECK(
exact_input_depth >= kernel_depth &&
exact_input_height >= kernel_height &&
exact_input_width >= kernel_width,
"Calculated padded input size per channel: (",
exact_input_depth,
" x ",
exact_input_height,
" x ",
exact_input_width,
"). ",
"Kernel size: (",
kernel_depth,
" x ",
kernel_height,
" x ",
kernel_width,
"). Kernel size can't be greater than actual input size");
const int64_t output_depth =
div_rtn<int64_t>(exact_input_depth - kernel_depth, stride_depth) + 1;
const int64_t output_height =
div_rtn<int64_t>(exact_input_height - kernel_height, stride_height) + 1;
const int64_t output_width =
div_rtn<int64_t>(exact_input_width - kernel_width, stride_width) + 1;
TORCH_CHECK(
output_depth >= 1 && output_width >= 1 && output_height >= 1,
"Given input size per channel: (",
input_depth,
" x ",
input_height,
" x ",
input_width,
"). "
"Calculated output size per channel: (",
output_depth,
" x ",
output_height,
" x ",
output_width,
"). Output size is too small");
if (weight.defined()) {
int64_t n_input_plane = weight.size(1);
if (weight.dim() == 2) {
n_input_plane /= (kernel_height * kernel_width);
}
// to support grouped conv we need to check if input.size(dim_planes)
// is multiple of weight.size(dim_planes)
TORCH_CHECK(groups > 0, "none zero group size expected");
check_dim_size(input, ndim, dim_planes, n_input_plane * groups);
}
if (grad_output.defined()) {
if (weight.defined()) {
int64_t n_output_plane = weight.size(0);
check_dim_size(grad_output, ndim, dim_planes, n_output_plane);
} else if (bias.defined()) {
TORCH_CHECK(bias.numel() > 0, "non-empty bias tensor expected");
const int64_t n_output_plane = bias.dim() == 0 ? 1 : bias.size(0);
check_dim_size(grad_output, ndim, dim_planes, n_output_plane);
}
check_dim_size(grad_output, ndim, dim_depth, output_depth);
check_dim_size(grad_output, ndim, dim_height, output_height);
check_dim_size(grad_output, ndim, dim_width, output_width);
}
}
static Tensor view_weight_2d(const Tensor& weight_) {
Tensor weight = weight_.contiguous();
if (weight.dim() == 5) {
const int64_t s1 = weight.size(0);
const int64_t s2 =
weight.size(1) * weight.size(2) * weight.size(3) * weight.size(4);
return weight.view({s1, s2});
} else {
return weight;
}
}
template <typename scalar_t>
static void slow_conv3d_update_output_frame(
TensorAccessor<scalar_t, 4> input,
TensorAccessor<scalar_t, 4> output,
TensorAccessor<scalar_t, 2> weight,
bool has_bias,
TensorAccessor<scalar_t, 2> finput,
int64_t kernel_depth,
int64_t kernel_height,
int64_t kernel_width,
int64_t stride_depth,
int64_t stride_height,
int64_t stride_width,
int64_t pad_depth,
int64_t pad_height,
int64_t pad_width,
int64_t n_input_plane,
int64_t groups,
int64_t input_depth,
int64_t input_height,
int64_t input_width,
int64_t n_output_plane,
int64_t output_depth,
int64_t output_height,
int64_t output_width) {
const int beta = has_bias ? 1 : 0;
// Compute out = weight * input
// Note gemm expects fortran order, so all 3 matrices are transposed.
// Swapping argument order cancels this, since C == AB <=> T(C) == T(B)T(A)
const int64_t m = output_depth * output_height * output_width;
const int64_t n = (n_output_plane / groups);
const int64_t k = (n_input_plane / groups) * kernel_depth * kernel_height * kernel_width;
const int64_t lda = m;
const int64_t ldb = k;
const int64_t ldc = m;
at::native::cpublas::gemm_batched_with_stride(
TransposeType::NoTranspose,
TransposeType::NoTranspose,
groups, m, n, k,
static_cast<scalar_t>(1),
finput.data(), lda, finput.stride(0) * k,
weight.data(), ldb, weight.stride(0) * n,
static_cast<scalar_t>(beta),
output.data(), ldc, output.stride(0) * n);
}
template <typename scalar_t>
void slow_conv3d_backward_update_grad_input_frame(
TensorAccessor<scalar_t, 4> grad_input,
TensorAccessor<scalar_t, 4> grad_output,
TensorAccessor<scalar_t, 2> weight,
TensorAccessor<scalar_t, 2> fgrad_input,
int64_t kernel_depth,
int64_t kernel_height,
int64_t kernel_width,
int64_t stride_depth,
int64_t stride_height,
int64_t stride_width,
int64_t pad_depth,
int64_t pad_height,
int64_t pad_width,
int64_t groups) {
// Compute fgrad_input = weight.T * grad_output.reshape({grad_output.shape(0), -1})
// Note gemm expects fortran order, so all 3 matrices are transposed.
// Swapping argument order cancels this, since C == AB <=> T(C) == T(B)T(A)
const int64_t m = grad_output.size(1) * grad_output.size(2) * grad_output.size(3);
const int64_t n = weight.size(1);
const int64_t k = weight.size(0) / groups;
const int64_t lda = m;
const int64_t ldb = n;
const int64_t ldc = m;
at::native::cpublas::gemm_batched_with_stride(
TransposeType::NoTranspose,
TransposeType::Transpose,
groups, m, n, k,
static_cast<scalar_t>(1),
grad_output.data(), lda, grad_output.stride(0) * k,
weight.data(), ldb, weight.stride(0) * k,
static_cast<scalar_t>(0),
fgrad_input.data(), ldc, fgrad_input.stride(0) * n);
Unfold3dAccCPU(
c10::CppTypeToScalarType<scalar_t>::value,
fgrad_input.data(),
grad_input.size(0),
grad_input.size(1),
grad_input.size(2),
grad_input.size(3),
grad_output.size(1),
grad_output.size(2),
grad_output.size(3),
kernel_depth,
kernel_height,
kernel_width,
stride_depth,
stride_height,
stride_width,
pad_depth,
pad_height,
pad_width,
grad_input.data());
}
void slow_conv3d_backward_out_cpu_template(
Tensor& grad_input,
const Tensor& grad_output,
const Tensor& input,
const Tensor& weight,
IntArrayRef kernel_size,
IntArrayRef stride,
IntArrayRef padding,
int64_t groups) {
const int64_t kernel_depth = kernel_size[0];
const int64_t kernel_height = kernel_size[1];
const int64_t kernel_width = kernel_size[2];
const int64_t pad_depth = padding[0];
const int64_t pad_height = padding[1];
const int64_t pad_width = padding[2];
const int64_t stride_depth = stride[0];
const int64_t stride_height = stride[1];
const int64_t stride_width = stride[2];
slow_conv3d_shape_check(
input,
grad_output,
weight,
Tensor(),
kernel_depth,
kernel_height,
kernel_width,
stride_depth,
stride_height,
stride_width,
pad_depth,
pad_height,
pad_width,
groups,
false);
const Tensor weight2d = view_weight_2d(weight);
const Tensor grad_output_contiguous = grad_output.contiguous();
grad_input.resize_as_(input);
TORCH_CHECK(grad_input.is_contiguous(), "grad_input must be contiguous")
const int64_t dim_planes = 1;
const int64_t dim_depth = 2;
const int64_t dim_height = 3;
const int64_t dim_width = 4;
const int64_t n_input_plane = input.size(dim_planes);
const int64_t input_depth = input.size(dim_depth);
const int64_t input_height = input.size(dim_height);
const int64_t input_width = input.size(dim_width);
const int64_t output_depth =
(input_depth + 2 * pad_depth - kernel_depth) / stride_depth + 1;
const int64_t output_height =
(input_height + 2 * pad_height - kernel_height) / stride_height + 1;
const int64_t output_width =
(input_width + 2 * pad_width - kernel_width) / stride_width + 1;
const int64_t batch_size = input.size(0);
Tensor fgrad_input = at::empty({batch_size,
n_input_plane * kernel_depth * kernel_height * kernel_width,
output_depth * output_height * output_width}, input.options());
AT_DISPATCH_FLOATING_TYPES_AND(
kBFloat16, input.scalar_type(), "slow_conv3d_cpu_grad_input", [&] {
at::parallel_for(0, batch_size, CONV3D_GRAIN_SALT,
[&](int64_t start, int64_t end) {
auto grad_input_a = grad_input.accessor<scalar_t, 5>();
auto grad_output_a = grad_output_contiguous.accessor<scalar_t, 5>();
auto fgrad_input_a = fgrad_input.accessor<scalar_t, 3>();
auto weight_2d_a = weight2d.accessor<scalar_t, 2>();
for (const auto t : c10::irange(start, end)) {
auto grad_input_t = grad_input_a[t];
auto grad_output_t = grad_output_a[t];
auto fgrad_input_t = fgrad_input_a[t];
slow_conv3d_backward_update_grad_input_frame(
grad_input_t,
grad_output_t,
weight_2d_a,
fgrad_input_t,
kernel_depth,
kernel_height,
kernel_width,
stride_depth,
stride_height,
stride_width,
pad_depth,
pad_height,
pad_width,
groups);
}
});
});
}
template <typename scalar_t>
void slow_conv3d_backward_weight_frame(
TensorAccessor<scalar_t, 2> grad_weight,
TensorAccessor<scalar_t, 4> grad_output,
TensorAccessor<scalar_t, 2> finput,
int64_t groups) {
// Compute grad_weight += grad_output.reshape({grad_output.shape(0), -1}) * finput.T
// Note gemm expects fortran order, so all 3 matrices are transposed.
// Swapping argument order cancels this, since C == AB <=> T(C) == T(B)T(A)
const int64_t m = grad_weight.size(1);
const int64_t n = grad_weight.size(0) / groups;
const int64_t k = grad_output.size(1) * grad_output.size(2) * grad_output.size(3);
const int64_t lda = k;
const int64_t ldb = k;
const int64_t ldc = m;
at::native::cpublas::gemm_batched_with_stride(
TransposeType::Transpose,
TransposeType::NoTranspose,
groups, m, n, k,
static_cast<scalar_t>(1),
finput.data(), lda, finput.stride(0) * m,
grad_output.data(), ldb, grad_output.stride(0) * n,
static_cast<scalar_t>(1),
grad_weight.data(), ldc, grad_weight.stride(0) * n);
}
static void slow_conv3d_backward_parameters_out_cpu_template(
Tensor& grad_weight,
const Tensor& input,
const Tensor& grad_output,
IntArrayRef kernel_size,
IntArrayRef stride,
IntArrayRef padding,
int64_t groups) {
CheckedFrom c = "slow_conv3d_backward_parameters_cpu";
auto grad_weight_arg = TensorArg(grad_weight, "grad_weight_arg", 0);
const int64_t kernel_depth = kernel_size[0];
const int64_t kernel_height = kernel_size[1];
const int64_t kernel_width = kernel_size[2];
const int64_t pad_depth = padding[0];
const int64_t pad_height = padding[1];
const int64_t pad_width = padding[2];
const int64_t stride_depth = stride[0];
const int64_t stride_height = stride[1];
const int64_t stride_width = stride[2];
slow_conv3d_shape_check(
input,
grad_output,
grad_weight,
{},
kernel_depth,
kernel_height,
kernel_width,
stride_depth,
stride_height,
stride_width,
pad_depth,
pad_height,
pad_width,
groups,
true);
Tensor grad_weight_2d = view_weight_2d(grad_weight);
checkContiguous(c, grad_weight_arg);
auto grad_output_contiguous = grad_output.contiguous();
const int64_t batch_size = input.size(0);
Tensor finput = compute_columns3d(input, stride, padding, kernel_size, groups);
AT_DISPATCH_FLOATING_TYPES_AND(
kBFloat16, input.scalar_type(), "slow_conv3d_cpu_grad_weight", [&] {
auto grad_weight_2d_a = grad_weight_2d.accessor<scalar_t, 2>();
auto grad_output_a = grad_output_contiguous.accessor<scalar_t, 5>();
auto finput_a = finput.accessor<scalar_t, 3>();
for (const auto t : c10::irange(batch_size)) {
auto grad_output_t = grad_output_a[t];
auto finput_t = finput_a[t];
slow_conv3d_backward_weight_frame(
grad_weight_2d_a, grad_output_t, finput_t, groups);
}
});
}
} // namespace
Tensor& slow_conv3d_forward_out_cpu(const Tensor& self,
const Tensor& weight,
IntArrayRef kernel_size, const c10::optional<Tensor>& bias_opt,
IntArrayRef stride,
IntArrayRef padding,
Tensor& output) {
// See [Note: hacky wrapper removal for optional tensor]
c10::MaybeOwned<Tensor> bias_maybe_owned = at::borrow_from_optional_tensor(bias_opt);
const Tensor& bias = *bias_maybe_owned;
const int64_t kernel_depth = kernel_size[0];
const int64_t kernel_height = kernel_size[1];
const int64_t kernel_width = kernel_size[2];
const int64_t pad_depth = padding[0];
const int64_t pad_height = padding[1];
const int64_t pad_width = padding[2];
const int64_t stride_depth = stride[0];
const int64_t stride_height = stride[1];
const int64_t stride_width = stride[2];
// TODO: hacky way of deciding the groups
// Assuming the group size is checked in upstream functions
const int64_t groups = weight.size(1) > 0 ? self.size(1) / weight.size(1) : 0;
slow_conv3d_shape_check(
self,
Tensor(),
weight,
bias,
kernel_depth,
kernel_height,
kernel_width,
stride_depth,
stride_height,
stride_width,
pad_depth,
pad_height,
pad_width,
groups,
false);
const Tensor input = self.contiguous();
const Tensor weight_2d = view_weight_2d(weight);
const int64_t dim_planes = 1;
const int64_t dim_depth = 2;
const int64_t dim_height = 3;
const int64_t dim_width = 4;
const int64_t n_input_plane = input.size(dim_planes);
const int64_t input_depth = input.size(dim_depth);
const int64_t input_height = input.size(dim_height);
const int64_t input_width = input.size(dim_width);
const int64_t n_output_plane = weight_2d.size(0);
const int64_t output_depth =
(input_depth + 2 * pad_depth - kernel_depth) / stride_depth + 1;
const int64_t output_height =
(input_height + 2 * pad_height - kernel_height) / stride_height + 1;
const int64_t output_width =
(input_width + 2 * pad_width - kernel_width) / stride_width + 1;
Tensor finput = compute_columns3d(input, stride, padding, kernel_size, groups);
const int64_t batch_size = input.size(0);
output.resize_(
{batch_size, n_output_plane, output_depth, output_height, output_width});
if (bias.defined()) {
output.copy_(bias.reshape({-1, 1, 1, 1}));
}
TORCH_CHECK(output.is_contiguous(), "slow_conv3d output must be contiguous");
AT_DISPATCH_ALL_TYPES_AND(kBFloat16, input.scalar_type(), "slow_conv3d_cpu", [&] {
auto input_a = input.accessor<scalar_t, 5>();
auto output_a = output.accessor<scalar_t, 5>();
auto finput_a = finput.accessor<scalar_t, 3>();
auto weight_2d_a = weight_2d.accessor<scalar_t, 2>();
at::parallel_for(
0, batch_size, CONV3D_GRAIN_SALT, [&](int64_t start, int64_t end) {
for (const auto t : c10::irange(start, end)) {
auto input_t = input_a[t];
auto output_t = output_a[t];
auto finput_t = finput_a[t];
slow_conv3d_update_output_frame(
input_t,
output_t,
weight_2d_a,
bias.defined(),
finput_t,
kernel_depth,
kernel_height,
kernel_width,
stride_depth,
stride_height,
stride_width,
pad_depth,
pad_height,
pad_width,
n_input_plane,
groups,
input_depth,
input_height,
input_width,
n_output_plane,
output_depth,
output_height,
output_width);
}
});
});
return output;
}
Tensor slow_conv3d_forward_cpu(
const Tensor& self,
const Tensor& weight,
IntArrayRef kernel_size, const c10::optional<Tensor>& bias_opt,
IntArrayRef stride,
IntArrayRef padding) {
// See [Note: hacky wrapper removal for optional tensor]
c10::MaybeOwned<Tensor> bias_maybe_owned = at::borrow_from_optional_tensor(bias_opt);
const Tensor& bias = *bias_maybe_owned;
auto output = at::empty({0}, self.options());
at::native::slow_conv3d_forward_out_cpu(
self,
weight,
kernel_size,
bias,
stride,
padding,
output);
return output;
}
std::tuple<Tensor&, Tensor&, Tensor&> slow_conv3d_backward_out_cpu(const Tensor& grad_output,
const Tensor& self,
const Tensor& weight,
IntArrayRef kernel_size,
IntArrayRef stride,
IntArrayRef padding,
Tensor& grad_input,
Tensor& grad_weight,
Tensor& grad_bias) {
// TODO: hacky way of determine the group size
int64_t groups = self.size(1) / weight.size(1);
if (grad_input.defined()) {
slow_conv3d_backward_out_cpu_template(
grad_input,
grad_output,
self,
weight,
kernel_size,
stride,
padding,
groups);
}
if (grad_bias.defined()) {
at::sum_out(grad_bias, grad_output, IntArrayRef{0, 2, 3, 4});
}
if (grad_weight.defined()) {
grad_weight.resize_(weight.sizes());
grad_weight.zero_();
slow_conv3d_backward_parameters_out_cpu_template(
grad_weight,
self,
grad_output,
kernel_size,
stride,
padding,
groups);
}
return std::tuple<Tensor&, Tensor&, Tensor&>(
grad_input, grad_weight, grad_bias);
}
std::tuple<Tensor, Tensor, Tensor> slow_conv3d_backward_cpu(
const Tensor& grad_output,
const Tensor& self,
const Tensor& weight,
IntArrayRef kernel_size,
IntArrayRef stride,
IntArrayRef padding,
std::array<bool, 3> output_mask) {
Tensor grad_input;
Tensor grad_weight;
Tensor grad_bias;
if (output_mask[0]) {
grad_input = at::empty({0}, grad_output.options());
}
if (output_mask[1]) {
grad_weight = at::empty({0}, grad_output.options());
}
if (output_mask[2]) {
grad_bias = at::empty({0}, grad_output.options());
}
at::native::slow_conv3d_backward_out_cpu(
grad_output,
self,
weight,
kernel_size,
stride,
padding,
grad_input,
grad_weight,
grad_bias);
return std::make_tuple(grad_input, grad_weight, grad_bias);
}
Tensor& slow_conv3d_out(const Tensor& self,
const Tensor& weight,
IntArrayRef kernel_size, const c10::optional<Tensor>& bias_opt,
IntArrayRef stride,
IntArrayRef padding,
Tensor& output) {
// See [Note: hacky wrapper removal for optional tensor]
c10::MaybeOwned<Tensor> bias_maybe_owned = at::borrow_from_optional_tensor(bias_opt);
const Tensor& bias = *bias_maybe_owned;
return at::slow_conv3d_forward_out(
output,
self,
weight,
kernel_size,
bias,
stride,
padding);
}
Tensor slow_conv3d(
const Tensor& self,
const Tensor& weight,
IntArrayRef kernel_size, const c10::optional<Tensor>& bias_opt,
IntArrayRef stride,
IntArrayRef padding) {
// See [Note: hacky wrapper removal for optional tensor]
c10::MaybeOwned<Tensor> bias_maybe_owned = at::borrow_from_optional_tensor(bias_opt);
const Tensor& bias = *bias_maybe_owned;
return at::slow_conv3d_forward(self, weight, kernel_size, bias, stride, padding);
}
} // namespace native
} // namespace at