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ConvolutionMM2d.cu
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ConvolutionMM2d.cu
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#define TORCH_ASSERT_ONLY_METHOD_OPERATORS
#include <ATen/core/Tensor.h>
#include <ATen/AccumulateType.h>
#include <ATen/Dispatch.h>
#include <ATen/div_rtn.h>
#include <ATen/cuda/CUDABlas.h>
#include <ATen/native/ConvUtils.h>
#include <ATen/native/Resize.h>
#include <ATen/native/cuda/im2col.cuh>
#ifndef AT_PER_OPERATOR_HEADERS
#include <ATen/Functions.h>
#include <ATen/NativeFunctions.h>
#else
#include <ATen/ops/_slow_conv2d_forward_native.h>
#include <ATen/ops/_slow_conv2d_backward_native.h>
#include <ATen/ops/empty.h>
#include <ATen/ops/sum.h>
#endif
namespace at::native {
namespace {
void slow_conv2d_shape_check(
const Tensor& input, const Tensor& grad_output,
const Tensor& weight, const Tensor& bias,
int64_t kH, int64_t kW,
int64_t dH, int64_t dW,
int64_t padH, int64_t padW,
bool weight_nullable) {
TORCH_CHECK(kW > 0 && kH > 0,
"kernel size should be greater than zero, but got kH: ", kH, " kW: ", kW);
TORCH_CHECK(dW > 0 && dH > 0,
"stride should be greater than zero, but got dH: ", dH, " dW: ", dW);
TORCH_CHECK(weight_nullable || weight.defined(),
"weight tensor is expected to be non-nullable");
TORCH_CHECK(!weight.defined() ||
((weight.numel() > 0) && (weight.dim() == 2)),
"non-empty 2D weight tensor expected, but got: ", weight.sizes());
TORCH_CHECK(!bias.defined() || (bias.dim() == 1 && bias.sizes()[0] == weight.sizes()[0]),
"Expected bias to have shape [", weight.sizes()[0], "] but got ", bias.sizes());
const auto in_sizes = input.sizes();
constexpr int ndim = 4;
constexpr int dimf = 1;
constexpr int dimh = 2;
constexpr int dimw = 3;
TORCH_CHECK(in_sizes.size() == ndim, "Expected 4D input tensor, but got ", in_sizes);
// Allow for empty batch size but not other dimensions
const bool valid_empty = c10::multiply_integers(in_sizes.slice(1)) != 0;
TORCH_CHECK(valid_empty, "non-empty input tensor expected but got: ", in_sizes);
int64_t inputHeight = in_sizes[dimh];
int64_t inputWidth = in_sizes[dimw];
int64_t exactInputHeight = inputHeight + 2 * padH;
int64_t exactInputWidth = inputWidth + 2 * padW;
TORCH_CHECK(exactInputHeight >= kH && exactInputWidth >= kW,
"Calculated padded input size per channel: ",
IntArrayRef{exactInputHeight, exactInputWidth},
". Kernel size: ", IntArrayRef{kH, kW},
". Kernel size can't be greater than actual input size");
// NOTE: can't use conv_output_size if the weight isn't defined
auto outputHeight = div_rtn<int64_t>(exactInputHeight - kH, dH) + 1;
auto outputWidth = div_rtn<int64_t>(exactInputWidth - kW, dW) + 1;
TORCH_CHECK(outputWidth >= 1 && outputHeight >= 1,
"Given input size per channel: ",
IntArrayRef{inputHeight, inputWidth},
". Calculated output size per channel: ",
IntArrayRef{outputHeight, outputWidth},
". Output size is too small");
if (weight.defined()) {
const auto w_sizes = weight.sizes();
int64_t nInputPlane = w_sizes[1];
if (w_sizes.size() == 2) {
nInputPlane /= (kH * kW);
}
TORCH_CHECK(in_sizes[dimf] == nInputPlane,
"Expected input dim ", dimf, " to have size ", nInputPlane,
" but got ", in_sizes[dimf]);
}
if (grad_output.defined()) {
const auto gO_sizes = grad_output.sizes();
TORCH_CHECK(gO_sizes.size() == ndim,
"Expected grad_output to have ", ndim,
" dimensions but got shape", gO_sizes);
if (weight.defined()) {
const auto w_sizes = weight.sizes();
TORCH_CHECK(gO_sizes[dimf] == w_sizes[0],
"Expected dim ", dimf, " to have size ", w_sizes[0],
" but got ", gO_sizes[dimf]);
} else if (bias.defined()) {
const auto b_sizes = bias.sizes();
int64_t nOutputPlane = b_sizes.size() == 0 ? 1 : b_sizes[0];
TORCH_CHECK(gO_sizes[dimf] == nOutputPlane,
"Expected grad_output dim ", dimf, " to have size ",
nOutputPlane, " but got ", gO_sizes[dimf]);
}
TORCH_CHECK(gO_sizes[dimh] == outputHeight,
"Expected grad_output dim ", dimh, " to have size ",
outputHeight, " but got ", gO_sizes[dimh]);
TORCH_CHECK(gO_sizes[dimw] == outputWidth,
"Expected grad_output dim ", dimw, " to have size ",
outputWidth, " but got ", gO_sizes[dimw]);
}
}
Tensor new_view_weight_MM2d(const Tensor& weight_) {
auto weight = weight_.expect_contiguous();
const auto w_sizes = weight->sizes();
TORCH_CHECK(w_sizes.size() == 4);
int64_t s1 = w_sizes[0];
int64_t s2 = c10::multiply_integers(w_sizes.slice(1));
return weight->view({s1, s2});
}
void slow_conv2d_forward(
const Tensor &input,
const Tensor &output,
const Tensor &weight_,
const Tensor &bias,
int64_t kH, int64_t kW,
int64_t dH, int64_t dW,
int64_t padH, int64_t padW) {
auto weight = new_view_weight_MM2d(weight_);
slow_conv2d_shape_check(
input, {}, weight, bias, kH, kW, dH, dW, padH, padW, /*weight_nullable*/false);
constexpr int dimf = 1;
constexpr int dimh = 2;
constexpr int dimw = 3;
auto in_sizes = input.sizes();
int64_t batchSize = in_sizes[0];
int64_t nInputPlane = in_sizes[dimf];
int64_t inputHeight = in_sizes[dimh];
int64_t inputWidth = in_sizes[dimw];
int64_t nOutputPlane = weight.sizes()[0];
int64_t outputHeight = (inputHeight + 2*padH - kH) / dH + 1;
int64_t outputWidth = (inputWidth + 2*padW - kW) / dW + 1;
// Resize output
resize_output(output, {batchSize, nOutputPlane, outputHeight, outputWidth});
// Create temporary columns
at::Tensor columns;
const bool requires_columns = (
kW != 1 || kH != 1 || dW != 1 || dH != 1 || padH != 0 || padW != 0);
if (requires_columns) {
columns = at::empty({nInputPlane * kW * kH, outputHeight * outputWidth}, input.options());
}
if (bias.defined()) {
TORCH_CHECK(bias.scalar_type() == input.scalar_type(),
"Expected bias to have type ", input.scalar_type(),
" but got ", bias.scalar_type());
output.copy_(bias.view({-1, 1, 1}));
} else {
output.zero_();
}
AT_DISPATCH_FLOATING_TYPES_AND2(kHalf, kBFloat16, input.scalar_type(),
"slow_conv2d_cuda", [&] {
// For each elt in batch, do:
for (int elt = 0; elt < batchSize; elt ++) {
// Matrix mulitply per output:
auto input_n = input.select(0, elt);
auto output_n = output.select(0, elt);
if (requires_columns) {
// Extract columns:
at::native::im2col(
c10::cuda::getCurrentCUDAStream(),
input_n.const_data_ptr<scalar_t>(),
nInputPlane, inputHeight, inputWidth,
outputHeight, outputWidth,
kH, kW, padH, padW, dH, dW,
1, 1,
columns.mutable_data_ptr<scalar_t>()
);
}
// M,N,K are dims of matrix A and B
// (see http://docs.nvidia.com/cuda/cublas/#cublas-lt-t-gt-gemm)
int64_t m = nOutputPlane;
int64_t n = outputHeight * outputWidth;
int64_t k = nInputPlane*kH*kW;
// Do GEMM (note: this is a bit confusing because gemm assumes column-major matrices)
auto gemm_in_ptr = requires_columns ?
columns.const_data_ptr<scalar_t>() :
input_n.const_data_ptr<scalar_t>();
at::cuda::blas::gemm(
'n', 'n',
n, m, k,
scalar_t(1),
gemm_in_ptr, n,
weight.const_data_ptr<scalar_t>(), k,
scalar_t(1),
output_n.mutable_data_ptr<scalar_t>(), n
);
}
});
}
void slow_conv2d_backward(
const Tensor &input,
const Tensor &grad_output,
const Tensor &grad_input,
const Tensor &weight_,
const Tensor &grad_columns,
int kH, int kW,
int dH, int dW,
int padH, int padW) {
Tensor weight = new_view_weight_MM2d(weight_);
slow_conv2d_shape_check(input, grad_output, weight, {},
kH, kW, dH, dW, padH, padW, /*weight_nullable=*/false);
// Params
auto weight_sizes = weight.sizes();
int nInputPlane = weight_sizes[1]/(kW*kH);
int nOutputPlane = weight_sizes[0];
TORCH_INTERNAL_ASSERT(grad_output.is_contiguous());
auto input_sizes = input.sizes();
int64_t inputWidth = input_sizes[3];
int64_t inputHeight = input_sizes[2];
auto output_sizes = grad_output.sizes();
int64_t outputWidth = output_sizes[3];
int64_t outputHeight = output_sizes[2];
// Batch size + input planes
int64_t batchSize = input_sizes[0];
// Resize output
resize_output(grad_input, input_sizes);
TORCH_CHECK(grad_input.is_contiguous(), "grad_input must be contiguous");
// Resize temporary columns
resize_output(grad_columns, {nInputPlane*kW*kH, outputHeight*outputWidth});
TORCH_CHECK(grad_columns.is_contiguous(), "grad_columns must be contiguous");
AT_DISPATCH_FLOATING_TYPES_AND2(kHalf, kBFloat16, input.scalar_type(),
"slow_conv2d_backward_cuda", [&] {
// For each elt in batch, do:
for (int elt = 0; elt < batchSize; elt ++) {
// Matrix mulitply per sample:
auto grad_input_n = grad_input.select(0, elt);
auto grad_output_n = grad_output.select(0, elt);
// M,N,K are dims of matrix A and B
// (see http://docs.nvidia.com/cuda/cublas/#cublas-lt-t-gt-gemm)
int64_t m = nInputPlane*kW*kH;
int64_t n = grad_columns.sizes()[1];
int64_t k = nOutputPlane;
// Do GEMM (note: this is a bit confusing because gemm assumes column-major matrices)
at::cuda::blas::gemm<scalar_t>(
'n', 't',
n, m, k,
scalar_t(1),
grad_output_n.const_data_ptr<scalar_t>(), n,
weight.const_data_ptr<scalar_t>(), m,
scalar_t(0),
grad_columns.mutable_data_ptr<scalar_t>(), n
);
// Unpack columns back into input:
using acc_t = at::acc_type<scalar_t, true>;
at::native::col2im<scalar_t, acc_t>(
c10::cuda::getCurrentCUDAStream(),
grad_columns.const_data_ptr<scalar_t>(),
nInputPlane, inputHeight, inputWidth, outputHeight, outputWidth, kH, kW, padH, padW, dH, dW,
1, 1, grad_input_n.mutable_data_ptr<scalar_t>()
);
}
});
}
void slow_conv2d_grad_weight(
const Tensor &input,
const Tensor &grad_output,
const Tensor &grad_weight_,
const Tensor &columns,
int64_t kH, int64_t kW,
int64_t dH, int64_t dW,
int64_t padH, int64_t padW) {
TORCH_CHECK(grad_weight_.is_contiguous(), "grad_weight needs to be contiguous");
auto grad_weight = new_view_weight_MM2d(grad_weight_);
slow_conv2d_shape_check(input, grad_output, grad_weight, {},
kH, kW, dH, dW, padH, padW, /*weight_nullable=*/true);
// Params
TORCH_INTERNAL_ASSERT(input.is_contiguous());
TORCH_INTERNAL_ASSERT(grad_output.is_contiguous());
auto input_sizes = input.sizes();
int64_t nInputPlane = input_sizes[1];
int64_t nOutputPlane = grad_output.sizes()[1];
int64_t inputWidth = input_sizes[3];
int64_t inputHeight = input_sizes[2];
int64_t outputWidth = (inputWidth + 2*padW - kW) / dW + 1;
int64_t outputHeight = (inputHeight + 2*padH - kH) / dH + 1;
// Batch size + input planes
int64_t batchSize = input_sizes[0];
// Resize temporary columns
resize_output(columns, {nInputPlane * kH * kW, outputHeight * outputWidth});
const bool requires_columns = (
kW != 1 || kH != 1 || dW != 1 || dH != 1 || padH != 0 || padW != 0);
AT_DISPATCH_FLOATING_TYPES_AND2(kHalf, kBFloat16, input.scalar_type(),
"slow_conv2d_grad_weight_cuda", [&] {
// For each elt in batch, do:
for (int elt = 0; elt < batchSize; elt ++) {
// Matrix mulitply per output:
auto grad_output_n = grad_output.select(0, elt);
// Matrix mulitply per output:
auto input_n = input.select(0, elt);
if (requires_columns) {
// Extract columns:
at::native::im2col<scalar_t>(
c10::cuda::getCurrentCUDAStream(),
input_n.const_data_ptr<scalar_t>(),
nInputPlane, inputHeight, inputWidth,
outputHeight, outputWidth,
kH, kW, padH, padW, dH, dW,
1, 1,
columns.mutable_data_ptr<scalar_t>()
);
}
// M,N,K are dims of matrix A and B
// (see http://docs.nvidia.com/cuda/cublas/#cublas-lt-t-gt-gemm)
int64_t m = nOutputPlane;
int64_t n = nInputPlane*kW*kH;
int64_t k = columns.sizes()[1];
// Do GEMM (note: this is a bit confusing because gemm assumes column-major matrices)
auto gemm_in_ptr = requires_columns ?
columns.const_data_ptr<scalar_t>() :
input_n.const_data_ptr<scalar_t>();
at::cuda::blas::gemm(
't', 'n',
n, m, k,
scalar_t(1),
gemm_in_ptr, k,
grad_output_n.const_data_ptr<scalar_t>(), k,
scalar_t(1),
grad_weight.mutable_data_ptr<scalar_t>(), n
);
}
});
}
} // namespace (anonymous)
Tensor& slow_conv2d_forward_out_cuda(
const Tensor &self_,
const Tensor &weight_,
IntArrayRef kernel_size,
const c10::optional<Tensor> &bias_,
IntArrayRef stride,
IntArrayRef padding,
Tensor &output) {
TORCH_CHECK(kernel_size.size() == 2);
TORCH_CHECK(stride.size() == 2);
TORCH_CHECK(padding.size() == 2);
auto self = self_.expect_contiguous();
auto weight = weight_.expect_contiguous();
auto bias = [&] {
if (bias_.has_value() && bias_->defined()) {
return bias_->expect_contiguous();
}
return MaybeOwned<Tensor>::owned(c10::in_place);
}();
slow_conv2d_forward(
*self,
output,
*weight,
*bias,
kernel_size[0], kernel_size[1],
stride[0], stride[1],
padding[0], padding[1]
);
return output;
}
Tensor slow_conv2d_forward_cuda(
const Tensor &self,
const Tensor &weight,
IntArrayRef kernel_size,
const c10::optional<Tensor> &bias,
IntArrayRef stride,
IntArrayRef padding) {
auto output = at::empty({0}, self.options());
return slow_conv2d_forward_out_cuda(
self, weight, kernel_size, bias, stride, padding, output);
}
std::tuple<Tensor&, Tensor&, Tensor&> slow_conv2d_backward_out_cuda(
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) {
auto grad_output = grad_output_.expect_contiguous();
Tensor columns = at::empty({0}, self_.options());
if (grad_input.defined()) {
resize_output(grad_input, self_.sizes());
auto weight = weight_.expect_contiguous();
slow_conv2d_backward(
self_, *grad_output,
grad_input, *weight,
columns,
kernel_size[0], kernel_size[1],
stride[0], stride[1],
padding[0], padding[1]);
}
if (grad_bias.defined()) {
at::sum_out(grad_bias, *grad_output, IntArrayRef{0, 2, 3});
}
if (grad_weight.defined()) {
resize_output(grad_weight, weight_.sizes());
grad_weight.zero_();
auto self = self_.expect_contiguous();
slow_conv2d_grad_weight(
*self,
*grad_output,
grad_weight,
columns,
kernel_size[0], kernel_size[1],
stride[0], stride[1],
padding[0], padding[1]
);
}
return std::tuple<Tensor&, Tensor&, Tensor&>{
grad_input, grad_weight, grad_bias};
}
std::tuple<Tensor, Tensor, Tensor> slow_conv2d_backward_cuda(
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());
}
return native::slow_conv2d_backward_out_cuda(
grad_output,
self,
weight,
kernel_size,
stride,
padding,
grad_input,
grad_weight,
grad_bias);
}
} // namespace at::native