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DepthwiseConv3d.cu
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DepthwiseConv3d.cu
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#define TORCH_ASSERT_ONLY_METHOD_OPERATORS
#include <ATen/core/Tensor.h>
#include <ATen/Dispatch.h>
#include <ATen/cuda/detail/KernelUtils.h>
#include <ATen/cuda/CUDAContext.h>
#include <ATen/AccumulateType.h>
#include <ATen/TensorUtils.h>
#include <ATen/native/ConvUtils.h>
#ifndef AT_PER_OPERATOR_HEADERS
#include <ATen/Functions.h>
#include <ATen/NativeFunctions.h>
#else
#include <ATen/ops/empty.h>
#include <ATen/ops/conv_depthwise3d_native.h>
#endif
#include <algorithm>
#include <tuple>
#include <limits>
namespace at::native {
namespace {
template <typename scalar_t, typename accscalar_t,
int kKnownKernelT, int kKnownKernelH, int kKnownKernelW,
int kKnownDilationT, int kKnownDilationH, int kKnownDilationW>
__global__ void conv_depthwise3d_cuda_kernel(
const PackedTensorAccessor32<scalar_t, 5> input,
PackedTensorAccessor32<scalar_t, 5> output,
const PackedTensorAccessor32<scalar_t, 5> kernel,
const scalar_t* bias,
int strideT, int strideH, int strideW,
int paddingT, int paddingH, int paddingW,
int dilationT_, int dilationH_, int dilationW_)
{
const int kT = kKnownKernelT > 0 ? kKnownKernelT : kernel.size(2);
const int kH = kKnownKernelH > 0 ? kKnownKernelH : kernel.size(3);
const int kW = kKnownKernelW > 0 ? kKnownKernelW : kernel.size(4);
const int oC = output.size(1);
const int oT = output.size(2);
const int oH = output.size(3);
const int oW = output.size(4);
const int iC = input.size(1);
const int iT = input.size(2);
const int iH = input.size(3);
const int iW = input.size(4);
const int channel_multiplier = oC / iC;
const int dilationT = kKnownDilationT > 0 ? kKnownDilationT : dilationT_;
const int dilationH = kKnownDilationH > 0 ? kKnownDilationH : dilationH_;
const int dilationW = kKnownDilationW > 0 ? kKnownDilationW : dilationW_;
const int num_output = output.size(0) * output.stride(0);
CUDA_KERNEL_LOOP(index, num_output) {
const int out_col = index % oW;
const int out_row = (index / oW) % oH;
const int out_frame = (index / oW / oH) % oT;
const int out_channel = (index / oW / oH / oT) % oC;
const int batch = index / oW / oH / oT / oC;
const int in_channel = out_channel / channel_multiplier;
const int in_col_start = out_col * strideW - paddingW;
const int in_row_start = out_row * strideH - paddingH;
const int in_frame_start = out_frame * strideT - paddingT;
accscalar_t sum = 0;
const scalar_t *kernel_ptr = kernel[out_channel].data();
const scalar_t *input_ptr =
&input[batch][in_channel][in_frame_start][in_row_start][in_col_start];
for (int k_frame = 0; k_frame < kT; ++k_frame) {
const int in_frame = in_frame_start + k_frame * dilationT;
for (int k_row = 0; k_row < kH; ++k_row) {
const int in_row = in_row_start + k_row * dilationH;
for (int k_col = 0; k_col < kW; ++k_col) {
const accscalar_t op1 = *(kernel_ptr++);
const int in_col = in_col_start + k_col * dilationW;
if (in_frame >= 0 && in_row >= 0 && in_col >= 0 &&
in_frame < iT && in_row < iH && in_col < iW) {
sum += op1 * *(input_ptr);
}
input_ptr += dilationW;
}
input_ptr += iW * dilationH - kW * dilationW;
}
input_ptr += iW * (iH * dilationT - kH * dilationH);
}
if (bias != NULL) {
sum += bias[out_channel];
}
output[batch][out_channel][out_frame][out_row][out_col] = sum;
}
}
template <typename scalar_t, typename accscalar_t,
int kKnownKernelT, int kKnownKernelH, int kKnownKernelW,
int kKnownDilationT, int kKnownDilationH, int kKnownDilationW,
int kKnownStrideT, int kKnownStrideH, int kKnownStrideW>
__global__ void
conv_depthwise3d_cuda_backward_input_kernel(
const PackedTensorAccessor32<scalar_t, 5> grad_output,
PackedTensorAccessor32<scalar_t, 5> grad_input,
const PackedTensorAccessor32<scalar_t, 5> kernel,
int strideT_, int strideH_, int strideW_,
int paddingT, int paddingH, int paddingW,
int dilationT_, int dilationH_, int dilationW_) {
const int kT = kKnownKernelT > 0 ? kKnownKernelT : kernel.size(2);
const int kH = kKnownKernelH > 0 ? kKnownKernelH : kernel.size(3);
const int kW = kKnownKernelW > 0 ? kKnownKernelW : kernel.size(4);
const int oC = grad_output.size(1);
const int oT = grad_output.size(2);
const int oH = grad_output.size(3);
const int oW = grad_output.size(4);
const int iC = grad_input.size(1);
const int iT = grad_input.size(2);
const int iH = grad_input.size(3);
const int iW = grad_input.size(4);
const int channel_multiplier = oC / iC;
const int dilationT = kKnownDilationT > 0 ? kKnownDilationT : dilationT_;
const int dilationH = kKnownDilationH > 0 ? kKnownDilationH : dilationH_;
const int dilationW = kKnownDilationW > 0 ? kKnownDilationW : dilationW_;
const int strideT = kKnownStrideT > 0 ? kKnownStrideT : strideT_;
const int strideH = kKnownStrideH > 0 ? kKnownStrideH : strideH_;
const int strideW = kKnownStrideW > 0 ? kKnownStrideW : strideW_;
const int num_input = grad_input.size(0) * grad_input.stride(0);
CUDA_KERNEL_LOOP(index, num_input) {
const int in_col = index % iW;
const int in_row = (index / iW) % iH;
const int in_frame = (index / iW / iH) % iT;
const int in_channel = (index / iW / iH / iT) % iC;
const int batch = index / iW / iH / iT / iC;
const int out_col_end = in_col + paddingW;
const int out_row_end = in_row + paddingH;
const int out_frame_end = in_frame + paddingT;
const scalar_t* kernel_ptr = kernel[in_channel * channel_multiplier].data();
accscalar_t sum = 0;
for (int k_chn = in_channel * channel_multiplier;
k_chn < (in_channel + 1) * channel_multiplier;
++k_chn) {
const scalar_t* gout_ptr = grad_output[batch][k_chn].data();
for (int k_frame = 0; k_frame < kT; ++k_frame) {
const int out_frame_raw = out_frame_end - k_frame * dilationT;
const int out_frame = out_frame_raw / strideT;
for (int k_row = 0; k_row < kH; ++k_row) {
const int out_row_raw = out_row_end - k_row * dilationH;
const int out_row = out_row_raw / strideH;
for (int k_col = 0; k_col < kW; ++k_col) {
const accscalar_t op1 = *(kernel_ptr++);
const int out_col_raw = out_col_end - k_col * dilationW;
const int out_col = out_col_raw / strideW;
const int out_offs = (out_frame * oH + out_row) * oW + out_col;
accscalar_t op2 = (accscalar_t)0;
if (out_col >= 0 && out_row >= 0 && out_frame >= 0 &&
out_col < oW && out_row < oH && out_frame < oT) {
op2 = *(gout_ptr + out_offs);
}
if (out_frame * strideT == out_frame_raw &&
out_row * strideH == out_row_raw &&
out_col * strideW == out_col_raw) {
sum += op1 * op2;
}
}
}
}
}
grad_input[batch][in_channel][in_frame][in_row][in_col] = sum;
}
}
template <typename scalar_t, typename accscalar_t,
int kKnownStrideH, int kKnownStrideW>
__global__ void
conv_depthwise3d_cuda_backward_weight_kernel(
const PackedTensorAccessor32<scalar_t, 5> grad_output,
const PackedTensorAccessor32<scalar_t, 5> input,
PackedTensorAccessor32<scalar_t, 5> grad_kernel,
int strideT, int strideH_, int strideW_,
int paddingT, int paddingH, int paddingW,
int dilationT, int dilationH, int dilationW) {
const int kC = grad_kernel.size(0);
const int kT = grad_kernel.size(2);
const int kH = grad_kernel.size(3);
const int kW = grad_kernel.size(4);
const int strideH = kKnownStrideH > 0 ? kKnownStrideH : strideH_;
const int strideW = kKnownStrideW > 0 ? kKnownStrideW : strideW_;
const int k_col = blockIdx.x % kW;
const int k_row = (blockIdx.x / kW) % kH;
const int k_frame = (blockIdx.x / kW / kH) % kT;
const int k_channel = blockIdx.x / kW / kH / kT;
scalar_t *result = &grad_kernel[k_channel][0][k_frame][k_row][k_col];
const int oT = grad_output.size(2);
const int oH = grad_output.size(3);
const int oW = grad_output.size(4);
const int iT = input.size(2);
const int iH = input.size(3);
const int iW = input.size(4);
const int channel_multiplier = grad_output.size(1) / input.size(1);
const int in_channel = k_channel / channel_multiplier;
extern __shared__ int sdata_raw[];
scalar_t* sdata = reinterpret_cast<scalar_t*>(sdata_raw);
if (k_channel >= kC) {
return;
}
const int laneid = threadIdx.x % C10_WARP_SIZE;
const int warpid = threadIdx.x / C10_WARP_SIZE;
const int nwarps = blockDim.x / C10_WARP_SIZE;
accscalar_t grad = 0;
int batch = warpid / oT;
int gout_frame = warpid - batch * oT;
for (int outer_pos = warpid; outer_pos < input.size(0) * oT;
outer_pos += nwarps, gout_frame += nwarps) {
while (gout_frame >= oT) { gout_frame -= oT; batch ++; }
const int in_frame = (gout_frame * strideT) + (k_frame * dilationT) - paddingT;
if (in_frame < 0 || in_frame >= iT) {
continue;
}
const scalar_t* gout_ptr = grad_output[batch][k_channel][gout_frame].data() + laneid;
const scalar_t* input_ptr = input[batch][in_channel][in_frame].data();
int gout_row = laneid / oW;
int gout_col = laneid - gout_row * oW;
for (; gout_row < oH; ) {
const accscalar_t op1 = *(gout_ptr);
gout_ptr += C10_WARP_SIZE;
const int in_col = (gout_col * strideW) + (k_col * dilationW) - paddingW;
const int in_row = (gout_row * strideH) + (k_row * dilationH) - paddingH;
const int in_pos = in_row * iW + in_col;
accscalar_t op2 = (accscalar_t)0;
if (in_col >= 0 && in_col < iW && in_row >= 0 && in_row < iH) {
op2 = *(input_ptr + in_pos);
}
gout_col += C10_WARP_SIZE;
while (gout_col >= oW) {
gout_col -= oW; gout_row ++;
}
grad += op1 * op2;
}
}
sdata[threadIdx.x] = grad;
__syncthreads();
CUDA_KERNEL_ASSERT(__popc(blockDim.x) == 1);
#pragma unroll
for (int i = blockDim.x / 2; i >= 1; i >>= 1) {
if (threadIdx.x < i) {
sdata[threadIdx.x] += sdata[threadIdx.x + i];
}
__syncthreads();
}
if (threadIdx.x == 0) {
*result = sdata[0];
}
}
template <int dim>
void conv_depthwise_shape_check(
const Tensor& input,
const Tensor& weight,
const Tensor& bias,
const Tensor& grad_output,
IntArrayRef kernel_size,
IntArrayRef stride,
IntArrayRef padding,
IntArrayRef dilation) {
TORCH_CHECK(kernel_size.size() == dim,
"kernel size length should be ", dim, ", but got ", kernel_size.size());
TORCH_CHECK(stride.size() == dim,
"stride length should be ", dim, ", but got ", stride.size());
TORCH_CHECK(padding.size() == dim,
"padding length should be ", dim, ", but got ", padding.size());
TORCH_CHECK(dilation.size() == dim,
"dilation length should be ", dim, ", but got ", dilation.size());
TORCH_CHECK(weight.defined(),
"Weight must be defined.");
TORCH_CHECK(input.dim() == dim + 1 || input.dim() == dim + 2,
"Input dimension should be ",
dim + 1, "D or ", dim + 2, "D, got ",
input.dim(), "D");
TORCH_CHECK(weight.dim() == dim + 2,
"Weight dimension should be ", dim + 2, "D, got ", weight.dim(), "D");
TORCH_CHECK(weight.size(1) == 1,
"Depthwise weight should have in_channels=1, got ", weight.size(1));
TORCH_CHECK(weight.size(0) % input.size(-dim - 1) == 0,
"Depthwise out channels should be a multiple of in channels, got ",
weight.size(0), " and ", input.size(-dim - 1));
for (int i = 0; i < dim; ++i) {
TORCH_CHECK(weight.size(i + 2) == kernel_size[i],
"kernel size and weight size mismatch, got ",
kernel_size, " and ", weight.sizes());
TORCH_CHECK(stride[i] >= 1,
"stride should be at least 1, got ", stride);
TORCH_CHECK(padding[i] >= 0,
"padding should be non-negative, got ", padding);
TORCH_CHECK(dilation[i] >= 1,
"dilation should be at least 1, got ", dilation);
}
if (bias.defined()) {
TORCH_CHECK(bias.dim() == 1,
"Bias should be 1D tensor, got ", bias.dim(), "D");
TORCH_CHECK(bias.size(0) == weight.size(0),
"Bias length should be equal to out_channels, got ",
bias.size(0), " and ", weight.size(0));
}
if (grad_output.defined()) {
auto expected_output_size = conv_output_size(input.sizes(), weight.sizes(),
padding, stride, dilation);
TORCH_CHECK(static_cast<size_t>(grad_output.dim()) == expected_output_size.size(),
"Expect grad_output to be ",
expected_output_size.size(), "D, got ",
grad_output.dim(), "D.");
for (int i = 0; i < grad_output.dim(); ++i) {
TORCH_CHECK(grad_output.size(i) == expected_output_size[i],
"Expect grad_output to be of same shape as output, got ",
grad_output.size(i), " and ", expected_output_size[i],
" at dimension ", i);
}
}
}
}
#define NODEF_OR_EQUAL(x, y) ((y) < 0 || (x) == (y))
#define NODEF_OR_EQUAL_3(x, y1, y2, y3) \
(NODEF_OR_EQUAL(x[0], y1) && \
NODEF_OR_EQUAL(x[1], y2) && \
NODEF_OR_EQUAL(x[2], y3))
#define DWCONV3D_FORWARD_DISPATCH_SPECIALIZATION(kt, kh, kw, dilt, dilh, dilw) \
if (NODEF_OR_EQUAL_3(kernel_size, (kt), (kh), (kw)) && \
NODEF_OR_EQUAL_3(dilation, (dilt), (dilh), (dilw))) { \
using accscalar_t = acc_type<scalar_t, true>; \
conv_depthwise3d_cuda_kernel \
<scalar_t, accscalar_t, (kt), (kh), (kw), (dilt), (dilh), (dilw)> \
<<<grid, block, (smem), at::cuda::getCurrentCUDAStream()>>>( \
input_.packed_accessor32<scalar_t, 5>(), \
output_.packed_accessor32<scalar_t, 5>(), \
weight_.packed_accessor32<scalar_t, 5>(), \
bias_ptr, \
stride[0], stride[1], stride[2], \
padding[0], padding[1], padding[2], \
dilation[0], dilation[1], dilation[2]); \
C10_CUDA_KERNEL_LAUNCH_CHECK(); \
} else
#define DWCONV3D_FORWARD_DISPATCH_OTHERS \
{ \
using accscalar_t = acc_type<scalar_t, true>; \
conv_depthwise3d_cuda_kernel \
<scalar_t,accscalar_t, -1, -1, -1, -1, -1, -1> \
<<<grid, block, (smem), at::cuda::getCurrentCUDAStream()>>>( \
input_.packed_accessor32<scalar_t, 5>(), \
output_.packed_accessor32<scalar_t, 5>(), \
weight_.packed_accessor32<scalar_t, 5>(), \
bias_ptr, \
stride[0], stride[1], stride[2], \
padding[0], padding[1], padding[2], \
dilation[0], dilation[1], dilation[2]); \
C10_CUDA_KERNEL_LAUNCH_CHECK(); \
}
Tensor conv_depthwise3d_cuda(
const Tensor& input,
const Tensor& weight,
IntArrayRef kernel_size, const c10::optional<Tensor>& bias_opt,
IntArrayRef stride,
IntArrayRef padding,
IntArrayRef dilation) {
// 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;
TORCH_CHECK(input.device() == weight.device(), "expects input and weight tensors to be on the same device.");
if (bias.defined()) {
TORCH_CHECK(input.device() == bias.device(), "expects input and bias tensors to be on the same device.");
}
conv_depthwise_shape_check<3>(input, weight, bias, Tensor() /* undefined */,
kernel_size, stride, padding, dilation);
Tensor input_ = input.contiguous();
if (input.dim() == 4 /* no batch */) {
input_ = input.unsqueeze(0);
}
auto output_size = conv_output_size(input_.sizes(), weight.sizes(),
padding, stride, dilation);
for (size_t i = 0; i < output_size.size(); ++i) {
TORCH_CHECK(output_size[i] > 0,
"Output size should be positive, got ", output_size[i], " at dim ", i);
}
Tensor output = at::empty(output_size, input.options());
Tensor output_ = output;
Tensor weight_ = weight.contiguous();
Tensor bias_ = bias.defined() ? bias.contiguous() : bias;
AT_DISPATCH_FLOATING_TYPES_AND_HALF(
input.scalar_type(),
"conv_depthwise3d",
[&]{
int64_t num_outputs = output_.numel();
int64_t block = 256;
int64_t grid = std::min((num_outputs - 1) / block + 1, (int64_t)65536);
int64_t smem = 0;
const scalar_t* bias_ptr =
bias_.defined() ? bias_.data_ptr<scalar_t>() : NULL;
// Range check to avoid overflow in CUDA kernels.
TORCH_CHECK(input_.numel() <= std::numeric_limits<int32_t>::max(),
"Input tensor is too large.");
TORCH_CHECK(output_.numel() <= std::numeric_limits<int32_t>::max(),
"Output tensor is too large.");
TORCH_CHECK(weight_.numel() <= std::numeric_limits<int32_t>::max(),
"Weight tensor is too large.");
for (int i = 0; i < 3; ++i) {
TORCH_CHECK(padding[i] * 2 + input.size(i + 2) <= std::numeric_limits<int32_t>::max(),
"Padded input tensor is too large.");
}
DWCONV3D_FORWARD_DISPATCH_SPECIALIZATION(3, 3, 3, 1, 1, 1)
DWCONV3D_FORWARD_DISPATCH_SPECIALIZATION(-1, -1, -1, 1, 1, 1)
DWCONV3D_FORWARD_DISPATCH_OTHERS
}
);
return output;
}
#undef DWCONV3D_FORWARD_DISPATCH_SPECIALIZATION
#undef DWCONV3D_FORWARD_DISPATCH_OTHERS
#define DWCONV3D_BACKWARD_INPUT_DISPATCH_SPECIALIZATION( \
kt, kh, kw, dilt, dilh, dilw, dt, dh, dw) \
if (NODEF_OR_EQUAL_3(kernel_size, (kt), (kh), (kw)) && \
NODEF_OR_EQUAL_3(dilation, (dilt), (dilh), (dilw)) && \
NODEF_OR_EQUAL_3(stride, (dt), (dh), (dw))) { \
using accscalar_t = acc_type<scalar_t, true>; \
conv_depthwise3d_cuda_backward_input_kernel \
<scalar_t, accscalar_t, (kt), (kh), (kw), (dilt), (dilh), (dilw), (dt), (dh), (dw)> \
<<<grid, block, 0, at::cuda::getCurrentCUDAStream()>>>( \
grad_output_.packed_accessor32<scalar_t, 5>(), \
grad_input_.packed_accessor32<scalar_t, 5>(), \
weight_.packed_accessor32<scalar_t, 5>(), \
stride[0], stride[1], stride[2], \
padding[0], padding[1], padding[2], \
dilation[0], dilation[1], dilation[2]); \
C10_CUDA_KERNEL_LAUNCH_CHECK(); \
} else
#define DWCONV3D_BACKWARD_INPUT_DISPATCH_OTHERS \
{ \
using accscalar_t = acc_type<scalar_t, true>; \
conv_depthwise3d_cuda_backward_input_kernel \
<scalar_t, accscalar_t, -1, -1, -1, -1, -1, -1, -1, -1, -1> \
<<<grid, block, 0, at::cuda::getCurrentCUDAStream()>>>( \
grad_output_.packed_accessor32<scalar_t, 5>(), \
grad_input_.packed_accessor32<scalar_t, 5>(), \
weight_.packed_accessor32<scalar_t, 5>(), \
stride[0], stride[1], stride[2], \
padding[0], padding[1], padding[2], \
dilation[0], dilation[1], dilation[2]); \
C10_CUDA_KERNEL_LAUNCH_CHECK(); \
}
#define DWCONV3D_BACKWARD_WEIGHT_DISPATCH_SPECIALIZATION(dh, dw) \
if (NODEF_OR_EQUAL_3(stride, -1, (dh), (dw))) { \
using accscalar_t = acc_type<scalar_t, true>; \
conv_depthwise3d_cuda_backward_weight_kernel \
<scalar_t, accscalar_t, (dh), (dw)> \
<<<grid, block, smem, at::cuda::getCurrentCUDAStream()>>>( \
grad_output_.packed_accessor32<scalar_t, 5>(), \
input_.packed_accessor32<scalar_t, 5>(), \
grad_weight.packed_accessor32<scalar_t, 5>(), \
stride[0], stride[1], stride[2], \
padding[0], padding[1], padding[2], \
dilation[0], dilation[1], dilation[2]); \
C10_CUDA_KERNEL_LAUNCH_CHECK(); \
} else
#define DWCONV3D_BACKWARD_WEIGHT_DISPATCH_OTHERS \
{ \
using accscalar_t = acc_type<scalar_t, true>; \
conv_depthwise3d_cuda_backward_weight_kernel \
<scalar_t, accscalar_t, -1, -1> \
<<<grid, block, smem, at::cuda::getCurrentCUDAStream()>>>( \
grad_output_.packed_accessor32<scalar_t, 5>(), \
input_.packed_accessor32<scalar_t, 5>(), \
grad_weight.packed_accessor32<scalar_t, 5>(), \
stride[0], stride[1], stride[2], \
padding[0], padding[1], padding[2], \
dilation[0], dilation[1], dilation[2]); \
C10_CUDA_KERNEL_LAUNCH_CHECK(); \
}
std::tuple<Tensor&, Tensor&, Tensor&> _depthwise_3d_backward_cuda_out(
Tensor& grad_input,
Tensor& grad_weight,
Tensor& grad_bias,
const Tensor& grad_output,
const Tensor& input,
const Tensor& weight,
IntArrayRef kernel_size,
IntArrayRef stride,
IntArrayRef padding,
IntArrayRef dilation,
const std::array<bool, 3> output_mask)
{
TORCH_CHECK(grad_output.device() == input.device() &&
input.device() == weight.device(),
"expects input, weight and grad_output to be on the same device.");
conv_depthwise_shape_check<3>(
input, weight, Tensor() /* undefined */, grad_output,
kernel_size, stride, padding, dilation);
const Tensor grad_output_ = grad_output.contiguous();
Tensor grad_input_ =
(output_mask[0] ? grad_input
: Tensor());
if (output_mask[0]) {
const Tensor weight_ = weight.contiguous();
AT_DISPATCH_FLOATING_TYPES_AND_HALF(
grad_output.scalar_type(),
"conv_depthwise3d",
[&] {
int64_t num_inputs = grad_input_.numel();
int64_t block = 256;
int64_t grid = std::min((num_inputs - 1) / block + 1, (int64_t)65536);
// Range check to avoid overflow in CUDA kernels.
TORCH_CHECK(grad_input_.numel() <= std::numeric_limits<int32_t>::max(),
"Input tensor is too large.");
TORCH_CHECK(grad_output_.numel() <= std::numeric_limits<int32_t>::max(),
"Output tensor is too large.");
TORCH_CHECK(weight_.numel() <= std::numeric_limits<int32_t>::max(),
"Weight tensor is too large.");
for (int i = 0; i < 3; ++i) {
TORCH_CHECK(padding[i] * 2 + input.size(i + 2) <= std::numeric_limits<int32_t>::max(),
"Padded input tensor is too large.");
}
DWCONV3D_BACKWARD_INPUT_DISPATCH_SPECIALIZATION(
3, 3, 3, 1, 1, 1, 1, 1, 1)
DWCONV3D_BACKWARD_INPUT_DISPATCH_SPECIALIZATION(
3, 3, 3, 1, 1, 1, -1, -1, -1)
DWCONV3D_BACKWARD_INPUT_DISPATCH_SPECIALIZATION(
3, 3, 3, -1, -1, -1, 1, 1, 1)
DWCONV3D_BACKWARD_INPUT_DISPATCH_SPECIALIZATION(
3, 3, 3, -1, -1, -1, -1, -1, -1)
DWCONV3D_BACKWARD_INPUT_DISPATCH_OTHERS
}
);
}
if (output_mask[1]) {
const Tensor input_ = input.contiguous();
AT_DISPATCH_FLOATING_TYPES_AND_HALF(
grad_output.scalar_type(),
"conv_depthwise3d",
[&] {
int64_t grid = grad_weight.numel();
int64_t block = 256;
int64_t smem = sizeof(scalar_t) * block;
const int64_t int_max = std::numeric_limits<int32_t>::max();
TORCH_CHECK(grad_input_.numel() <= int_max,
"Input tensor is too large.");
TORCH_CHECK(grad_output_.numel() <= int_max,
"Output tensor is too large.");
TORCH_CHECK(weight.numel() <= int_max,
"Weight tensor is too large.");
for (int i = 0; i < 3; ++i) {
TORCH_CHECK(padding[i] * 2 + input.size(i + 2) <= int_max,
"Padded input tensor is too large.");
}
int64_t warp_size = at::cuda::warp_size();
TORCH_CHECK(grad_output_.size(0) * grad_output_.size(2) < int_max - block / warp_size &&
grad_output_.size(3) <= int_max - warp_size &&
grad_output_.size(4) <= int_max - warp_size,
"Output size is too large.");
DWCONV3D_BACKWARD_WEIGHT_DISPATCH_SPECIALIZATION(1, 1)
DWCONV3D_BACKWARD_WEIGHT_DISPATCH_SPECIALIZATION(2, 2)
DWCONV3D_BACKWARD_WEIGHT_DISPATCH_OTHERS
}
);
}
if (output_mask[2]) {
grad_bias = grad_output.sum({0, 2, 3, 4});
}
return std::tie(grad_input, grad_weight, grad_bias);
}
std::tuple<Tensor&, Tensor&, Tensor&> conv_depthwise3d_backward_cuda_out(const Tensor& grad_output,
const Tensor& input,
const Tensor& weight,
IntArrayRef kernel_size,
IntArrayRef stride,
IntArrayRef padding,
IntArrayRef dilation,
Tensor& grad_input,
Tensor& grad_weight,
Tensor& grad_bias) {
if (grad_weight.defined()) {
grad_weight.resize_(weight.sizes());
grad_weight.zero_();
}
return _depthwise_3d_backward_cuda_out(
grad_input,
grad_weight,
grad_bias,
grad_output,
input,
weight,
kernel_size,
stride,
padding,
dilation,
{true,true,true});
}
std::tuple<Tensor, Tensor, Tensor> conv_depthwise3d_backward_cuda(
const Tensor& grad_output,
const Tensor& input,
const Tensor& weight,
IntArrayRef kernel_size,
IntArrayRef stride,
IntArrayRef padding,
IntArrayRef dilation,
const std::array<bool, 3> output_mask) {
auto options = grad_output.options();
Tensor grad_input =
(output_mask[0] ? at::empty(input.sizes(), options) : Tensor());
Tensor grad_weight =
(output_mask[1] ? at::empty(weight.sizes(), options) : Tensor());
Tensor grad_bias; /* undefined temporarily */
return _depthwise_3d_backward_cuda_out(
grad_input,
grad_weight,
grad_bias,
grad_output,
input,
weight,
kernel_size,
stride,
padding,
dilation,
output_mask
);
}
REGISTER_CUDA_DISPATCH(conv_depthwise3d_backward_stub, &conv_depthwise3d_backward_cuda);
#undef DWCONV3D_BACKWARD_INPUT_DISPATCH_SPECIALIZATION
#undef DWCONV3D_BACKWARD_INPUT_DISPATCH_OTHERS
#undef NODEF_OR_EQUAL_3
#undef NODEF_OR_EQUAL
} // namespace at::native