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Convolution.cpp
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Convolution.cpp
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#define TORCH_ASSERT_ONLY_METHOD_OPERATORS
#include <ATen/core/Tensor.h>
#include <ATen/Config.h>
#include <ATen/Parallel.h>
#include <ATen/TensorOperators.h>
#include <ATen/native/ConvolutionMM3d.h>
#include <ATen/native/ConvUtils.h>
#include <ATen/native/Pool.h>
#include <ATen/native/cpu/DepthwiseConvKernel.h>
#include <ATen/native/utils/ParamUtils.h>
#include <ATen/native/xnnpack/Engine.h>
#include <c10/core/GradMode.h>
#include <c10/util/accumulate.h>
#include <c10/util/irange.h>
#include <c10/macros/Macros.h>
#include <limits>
#include <utility>
#ifndef AT_PER_OPERATOR_HEADERS
#include <ATen/Functions.h>
#else
#include <ATen/ops/permute.h>
#endif
#if AT_NNPACK_ENABLED()
#include <nnpack.h>
#endif
#if AT_MKLDNN_ENABLED()
#include <ATen/native/mkldnn/Utils.h>
#endif
#ifndef AT_PER_OPERATOR_HEADERS
#include <ATen/Functions.h>
#include <ATen/NativeFunctions.h>
#else
#include <ATen/ops/_conv_depthwise2d.h>
#include <ATen/ops/_convolution.h>
#include <ATen/ops/_convolution_double_backward_native.h>
#include <ATen/ops/_convolution_mode.h>
#include <ATen/ops/_convolution_mode_native.h>
#include <ATen/ops/_convolution_native.h>
#include <ATen/ops/_mps_convolution.h>
#include <ATen/ops/_mps_convolution_transpose.h>
#include <ATen/ops/_nnpack_available.h>
#include <ATen/ops/_nnpack_spatial_convolution.h>
#include <ATen/ops/_slow_conv2d_backward.h>
#include <ATen/ops/_unsafe_view.h>
#include <ATen/ops/cat.h>
#include <ATen/ops/constant_pad_nd.h>
#include <ATen/ops/conv1d_native.h>
#include <ATen/ops/conv2d_native.h>
#include <ATen/ops/conv3d_native.h>
#include <ATen/ops/conv_depthwise3d.h>
#include <ATen/ops/conv_transpose1d_native.h>
#include <ATen/ops/conv_transpose2d_native.h>
#include <ATen/ops/conv_transpose3d_native.h>
#include <ATen/ops/convolution.h>
#include <ATen/ops/convolution_backward_native.h>
#include <ATen/ops/convolution_backward_overrideable.h>
#include <ATen/ops/convolution_backward_overrideable_native.h>
#include <ATen/ops/convolution_native.h>
#include <ATen/ops/convolution_overrideable.h>
#include <ATen/ops/convolution_overrideable_native.h>
#include <ATen/ops/cudnn_convolution.h>
#include <ATen/ops/cudnn_convolution_transpose.h>
#include <ATen/ops/empty.h>
#include <ATen/ops/empty_like.h>
#include <ATen/ops/empty_native.h>
#include <ATen/ops/miopen_convolution.h>
#include <ATen/ops/miopen_convolution_transpose.h>
#include <ATen/ops/miopen_depthwise_convolution.h>
#include <ATen/ops/mkldnn_convolution.h>
#include <ATen/ops/mps_convolution_backward.h>
#include <ATen/ops/mps_convolution_transpose_backward.h>
#include <ATen/ops/slow_conv3d.h>
#include <ATen/ops/slow_conv_dilated2d.h>
#include <ATen/ops/slow_conv_dilated3d.h>
#include <ATen/ops/slow_conv_transpose2d.h>
#include <ATen/ops/slow_conv_transpose3d.h>
#include <ATen/ops/thnn_conv2d.h>
#include <ATen/ops/view_as_real.h>
#include <ATen/ops/zeros.h>
#include <ATen/ops/zeros_like.h>
#endif
constexpr int MIOPEN_DIM_MAX = 5;
namespace at::native {
static bool conv_benchmark_empty_cache = true;
// Check workload to activate fast depthwise FP16 cudnn conv kernels
template <typename T>
bool check_cudnn_depthwise_workload(const at::Tensor& input, T stride) {
auto w = at::symint::size<T>(input, 3); // same as h
auto ch = at::symint::size<T>(input, 1);
auto bs = at::symint::size<T>(input, 0);
if (stride==1) {
if (w >= 7) {
// All batch sizes and nb_channels
if (w >= 112) {
return true;
}
// large nb_channels
if (ch >= 1024) {
// NOLINTNEXTLINE(bugprone-branch-clone,cppcoreguidelines-avoid-magic-numbers)
if (w >= 56) {
return true;
} else if (bs >= 32) {
return true;
}
}
// batch_size specific
if (bs >= 128) {
// NOLINTNEXTLINE(bugprone-branch-clone,cppcoreguidelines-avoid-magic-numbers)
if (ch >= 512) {
return true;
} else if (ch >= 64) {
if (w >= 14) {
return true;
}
} else if ((ch >= 32) && (w >=28)) {
return true;
}
} else if (bs >= 64) {
// NOLINTNEXTLINE(bugprone-branch-clone,cppcoreguidelines-avoid-magic-numbers)
if ((ch >= 256) && (w >= 14)) {
return true;
} else if ((ch >= 32) && (w >= 28)) {
return true;
}
} else if (bs >= 32) {
// NOLINTNEXTLINE(bugprone-branch-clone,cppcoreguidelines-avoid-magic-numbers)
if ((ch >= 256) && (w >= 14)) {
return true;
} else if ((ch >= 128) && (w >= 28)) {
return true;
} else if ((ch >= 32) && (w >= 56)) {
return true;
}
} else if (bs >= 16) {
if ((ch >= 1024) && (w >= 14)) {
return true;
}
// NOLINTNEXTLINE(bugprone-branch-clone,cppcoreguidelines-avoid-magic-numbers)
if ((ch >= 256) && (w >= 28)) {
return true;
} else if ((ch >= 32) && (w >= 56)) {
return true;
}
} else if (bs >= 8) {
// NOLINTNEXTLINE(bugprone-branch-clone,cppcoreguidelines-avoid-magic-numbers)
if ((ch >= 512) && (w >= 28)) {
return true;
} else if ((ch >= 64) && (w >= 56)) {
return true;
}
}
}
} else if (stride==2) {
if (ch < 256) {
return false;
}
if (w >= 7) {
if (bs >= 128) {
// NOLINTNEXTLINE(bugprone-branch-clone,cppcoreguidelines-avoid-magic-numbers)
if (ch >= 1024) {
return true;
} else if ((ch >= 512) && (w >= 14)) {
return true;
} else if (w >= 28) {
return true;
}
} else if (bs >= 64) {
// NOLINTNEXTLINE(bugprone-branch-clone,cppcoreguidelines-avoid-magic-numbers)
if ((ch >= 512) && (w >= 14)) {
return true;
} else if (w >= 28) {
return true;
}
} else if (bs >= 32) {
// NOLINTNEXTLINE(bugprone-branch-clone,cppcoreguidelines-avoid-magic-numbers)
if ((ch >= 1024) && (w >= 14)) {
return true;
} else if (w >= 28) {
return true;
}
} else if (bs >= 16) {
// NOLINTNEXTLINE(bugprone-branch-clone,cppcoreguidelines-avoid-magic-numbers)
if ((ch >= 512) && (w >= 28)) {
return true;
} else if (w >= 56) {
return true;
}
} else if (bs >= 8) {
// NOLINTNEXTLINE(bugprone-branch-clone,cppcoreguidelines-avoid-magic-numbers)
if ((ch >= 1024) && (w >= 28)) {
return true;
} else if (w >= 56) {
return true;
}
} else if (bs >= 1) {
if ((ch >= 512) && (w >=112)) {
return true;
}
}
}
}
return false;
}
// simplified version for cudnn 8.2 and above
template <typename T>
bool check_cudnn_depthwise_workload_with_filter(const at::Tensor& input, T stride, const at::Tensor& weight) {
// 1D conv
if(at::symint::size<T>(input, 2) == 1 && stride == 1){
return true;
}
// 2d conv
// only square filters
if (at::symint::size<T>(weight, 2) != at::symint::size<T>(weight, 3)) return false;
auto filter = at::symint::size<T>(weight, 3);
// only 1/3/5 filter
if (filter != 1 && filter != 3 && filter != 5) return false;
// we don't enforce square input but only check width to reduce heuristic space
if (at::symint::size<T>(input, 3) < 7) return false; // min width 7
auto w = at::symint::size<T>(input, 3);
// only 1/2 stride, use cudnn for all stride 1
if (stride == 1) return true;
if (stride != 2) return false;
auto ch = at::symint::size<T>(input, 1);
auto bs = at::symint::size<T>(input, 0);
// special case since bs1 show good perf in lots of cases
if (bs == 1) {
if (filter == 1 && w <= 28) return true;
if (filter == 3 || filter == 5) return true;
} else {
if (filter == 1 && bs <= 16 && ch >= 128 && w <= 7) return true;
if (filter == 3 || filter == 5) {
if ((ch >= 512) || (ch >= 256 && w >= 28)) return true;
}
}
return false;
}
#if defined(C10_MOBILE)
static bool xnnpack_use_convolution2d(
const Tensor& input,
const Tensor& weight,
const at::OptionalIntArrayRef bias_sizes_opt,
const IntArrayRef padding,
const IntArrayRef stride,
const IntArrayRef dilation,
const int64_t groups,
const bool transposed) {
return xnnpack::use_convolution2d(input, weight, bias_sizes_opt, padding, stride, dilation, groups, transposed);
}
static bool xnnpack_use_convolution2d(
const Tensor& input,
const Tensor& weight,
const at::OptionalSymIntArrayRef bias_sizes_opt,
const SymIntArrayRef padding,
const SymIntArrayRef stride,
const SymIntArrayRef dilation,
const c10::SymInt groups,
const bool transposed) {
// Never use xnnpack for symbolic tracing
return false;
}
#endif
// NOLINTNEXTLINE(cppcoreguidelines-pro-type-member-init)
// This struct is templated so that we can run backend selection in a dynamic
// shapes context; all of the real kernel selection in eager mode runs with
// int64_t
template <typename T>
struct ConvParams {
std::vector<T> stride;
std::vector<T> padding;
std::vector<T> dilation;
bool transposed;
std::vector<T> output_padding;
T groups;
bool benchmark;
bool deterministic;
bool cudnn_enabled;
bool allow_tf32;
bool is_strided() const {
bool is_strided = false;
for (auto s : stride) {
is_strided |= (s != 1);
}
return is_strided;
}
bool is_dilated() const {
bool is_dilated = false;
for (auto d : dilation) {
is_dilated |= (d != 1);
}
return is_dilated;
}
bool is_padded() const {
bool is_padded = false;
for (auto p : padding) {
is_padded |= (p != 0);
}
return is_padded;
}
bool is_output_padding_neg() const {
bool is_non_neg = false;
for (const auto& p : output_padding) {
is_non_neg |= (p < 0);
}
return is_non_neg;
}
bool is_output_padding_big() const {
bool is_big = false;
for (auto i: c10::irange(output_padding.size())) {
is_big |= (output_padding[i] >= stride[i]);
}
return is_big;
}
bool is_padding_neg() const {
bool is_non_neg = false;
for (const auto& p : padding) {
is_non_neg |= (p < 0);
}
return is_non_neg;
}
bool is_dilation_neg() const {
bool is_non_neg = false;
for (const auto& p : dilation) {
is_non_neg |= (p < 0);
}
return is_non_neg;
}
bool is_stride_nonpos() const {
bool is_nonpos = false;
for (auto s : stride) {
is_nonpos |= (s <= 0);
}
return is_nonpos;
}
void view1d_as_2d() {
if (stride.size() == 1) {
stride.insert(stride.begin(), 1);
padding.insert(padding.begin(), 0);
dilation.insert(dilation.begin(), 1);
output_padding.insert(output_padding.begin(), 0);
}
}
bool use_cpu_depthwise3x3_winograd(const at::Tensor& input, const at::Tensor& weight, const c10::optional<at::Tensor>& bias) const {
#if defined(__ARM_NEON__)
// Currently only 3x3 depthwise convolutions on tensors of float are supported.
return (input.ndimension() == 4) &&
(at::symint::size<T>(input, 1) == groups) &&
(weight.ndimension() == 4 ) &&
(at::symint::size<T>(weight, 0) % at::symint::size<T>(input, 1) == 0) &&
(at::symint::size<T>(weight, 1) == 1) &&
(at::symint::size<T>(weight, 2) == 3) &&
(at::symint::size<T>(weight, 3) == 3) &&
(input.device().is_cpu()) &&
(input.scalar_type() == at::kFloat) &&
input.is_contiguous() &&
(weight.device().is_cpu()) &&
(weight.scalar_type() == at::kFloat) &&
weight.is_contiguous() &&
(!bias.has_value() || bias->is_contiguous()) &&
!is_strided() &&
!is_dilated() &&
!transposed;
#else
return false;
#endif
}
bool needs_64bit_indexing_no_split(const at::Tensor& input, const at::Tensor& weight) const {
constexpr int64_t int_max = std::numeric_limits<int>::max();
auto numel_input = at::symint::numel<T>(input);
// empty input
if (numel_input == 0) {
return false;
}
// input size can not be reduced to the range of int by splitting the batch dim
auto n = at::symint::size<T>(input, 0);
if (numel_input / n > int_max) {
return true;
}
// output size can not be reduced to the range of int by splitting the batch dim
T outsize = 1;
if (transposed) {
auto o = conv_input_size(at::symint::sizes<T>(input), at::symint::sizes<T>(weight), padding, output_padding, stride, dilation, groups);
outsize = c10::multiply_integers(o.begin() + 1, o.end());
} else {
auto o = conv_output_size(at::symint::sizes<T>(input), at::symint::sizes<T>(weight), padding, stride, dilation);
outsize = c10::multiply_integers(o.begin() + 1, o.end());
}
return outsize > int_max;
}
bool use_cudnn(const at::Tensor& input, const at::Tensor& weight) const {
// Note [Mobile check segfaults]
// cudnn and miopen are guaranteed not to be on mobile, and T102591915 / T110194934 suggest
// that maybe the compiledWithCuDNN() check sometimes segfaults (though I can't imagine how)
#if !defined(C10_MOBILE)
if (needs_64bit_indexing_no_split(input, weight)) {
return false;
}
if (!detail::getCUDAHooks().compiledWithCuDNN()) {
return false;
}
if (!input.is_cuda() || !cudnn_enabled) {
return false;
}
if (input.scalar_type() == at::kBFloat16 || weight.scalar_type() == at::kBFloat16) {
if (!(detail::getCUDAHooks().supportsBFloat16ConvolutionWithCuDNNv8() && at::native::cudnnv8_enabled_check_debug())) {
return false;
}
}
if (cudnn_conv_suggest_memory_format(input, weight) == at::MemoryFormat::Contiguous) {
// bypass dilation checks for channels_last convolution
if (deterministic && is_dilated()) {
// cudnn doesn't support deterministic dilated convolution fully yet
return false;
}
if (is_dilated()) {
return detail::getCUDAHooks().supportsDilatedConvolutionWithCuDNN() && !is_output_padding_big();
}
}
return !is_output_padding_big();
#else
return false;
#endif
}
// Use cudnn for FP16 depthwise convolutions
bool use_cudnn_depthwise(const at::Tensor& input, const at::Tensor& weight) const {
if (cudnn_conv_suggest_memory_format(input, weight) != at::MemoryFormat::Contiguous && use_cudnn(input, weight)) {
// always use cudnn_depthwise for channels_last format
return true;
}
if (detail::getCUDAHooks().supportsDepthwiseConvolutionWithCuDNN()) {
long cudnn_version = detail::getCUDAHooks().versionCuDNN();
if (cudnn_version >= 8200) {
bool kernel_cond = (use_cudnn(input, weight) &&
input.scalar_type() == kHalf && // only for FP16
weight.scalar_type() == kHalf &&
is_depthwise(input, weight) &&
input.ndimension() == 4 && // TODO: 5-D contiguous depthwise is not supported yet, need benchmarks
!is_dilated() && // no dilation supported
(stride[0] == stride[1] || at::symint::size<T>(input, 2) == 1) && // square or 1d
at::symint::size<T>(input, 1) >= 32); // min 32 channels supported)
if (kernel_cond) {
return check_cudnn_depthwise_workload_with_filter<T>(input, stride[1], weight);
}
}
// keep (7600 <= cudnn < 8200) code unchanged
bool kernel_cond = (cudnn_version >= 7600 &&
use_cudnn(input, weight) &&
input.scalar_type() == kHalf && // only for FP16
weight.scalar_type() == kHalf &&
is_depthwise(input, weight) &&
input.ndimension() == 4 && // TODO: 5-D contiguous depthwise is not supported yet, need benchmarks
at::symint::size<T>(weight, 2) == at::symint::size<T>(weight, 3) && // only square kernels
at::symint::size<T>(input, 2) >= 7 && // min width/height 7
!is_dilated() && // no dilation supported
stride[0] == stride[1] && // equal strides
((at::symint::size<T>(weight, 3) == 3) || (at::symint::size<T>(weight, 3) == 1)) &&
at::symint::size<T>(input, 1) >= 32); // min 32 channels supported)
if (kernel_cond) {
return check_cudnn_depthwise_workload<T>(input, stride[0]);
} else {
return false;
}
} else {
return false;
}
}
bool use_miopen(const at::Tensor& input, const at::Tensor& weight, bool bias_defined) const {
if (needs_64bit_indexing_no_split(input, weight)) {
return false;
}
return ((input.scalar_type() == at::kFloat) || (input.scalar_type() == at::kHalf) || (input.scalar_type() == at::kBFloat16))
&& detail::getCUDAHooks().compiledWithMIOpen()
&& input.is_cuda()
&& input.dim() <= MIOPEN_DIM_MAX
&& !(groups > 1 && is_dilated()) // MIOpen currently does not support dilation with groups of size > 1
&& cudnn_enabled
;
}
bool use_mkldnn(const at::Tensor& input, const at::Tensor& weight) const {
#if AT_MKLDNN_ENABLED()
if (!at::globalContext().userEnabledMkldnn()) {
return false;
}
if (transposed && is_output_padding_big()) {
return false;
}
if (input.device().is_cpu() &&
((input.scalar_type() == at::kBFloat16 && mkldnn_bf16_device_check()) ||
(input.scalar_type() == at::kHalf && mkldnn_fp16_device_check()))) {
return true;
}
return (input.is_mkldnn()) || // input is mkldnn Tensor
(input.device().is_cpu() &&
input.scalar_type() == kFloat && // only on CPU Float Tensors
// For 1x1 filters, MKLDNN is faster than THNN when multi-threaded,
// but THNN is faster when single-threaded.
(is_strided() || is_dilated() || at::symint::size<T>(input, 0) >= 16 ||
at::symint::size<T>(weight, -1) != 1 || at::symint::size<T>(weight, -2) != 1 || at::get_num_threads() > 1) &&
(groups > 1
|| (at::symint::size<T>(weight, -1) > 3 && at::symint::size<T>(weight, -2) > 3)
|| at::symint::size<T>(input, 0) > 1
|| at::symint::size<T>(input, 0)*at::symint::size<T>(input, 1)*at::symint::size<T>(input, 2)*at::symint::size<T>(input, 3) > 20480) // for some case, native is faster
);
#endif
return false;
}
bool use_nnpack(const at::Tensor& input, const at::Tensor& weight) const {
#if AT_NNPACK_ENABLED()
return at::globalContext().userEnabledNNPACK() &&
at::_nnpack_available() &&
input.device().is_cpu() &&
input.scalar_type() == kFloat && // only on CPU Float Tensors
!is_dilated() && // or dilation
!transposed && // or transposed tensors
input.ndimension() == 4 && // must be in NCHW format
weight.ndimension() == 4 &&
(at::symint::size<T>(weight, 2) < 17) && (at::symint::size<T>(weight, 3) < 17) && // NNPACK only supports kernels up to 16x16
(padding[0] < at::symint::size<T>(weight, 2)) && (padding[1] < at::symint::size<T>(weight, 3)) // NNPACK only supports padding < kernel_size. See https://github.com/pytorch/pytorch/issues/90142.
#if !defined(C10_MOBILE)
&& at::symint::size<T>(input, 0) >= 16 // ensure large enough batch size to ensure perf, tuneable
#endif
;
#endif
return false;
}
bool use_xnnpack(const at::Tensor& input, const at::Tensor& weight,
const at::OptionalArrayRef<T> bias_sizes_opt) const {
#if defined(C10_MOBILE)
if (!transposed) {
// NB: for the call here, it MATTERS that we are templated. If you
// untemplate this to always use SymInt, the function
// xnnpack_use_convolution2d will always return false
return (at::symint::size<T>(input, 1) == groups) &&
xnnpack_use_convolution2d(
input,
weight,
bias_sizes_opt,
padding,
stride,
dilation,
groups,
transposed);
}
#endif
return false;
}
bool use_mps(const at::Tensor& input, const at::Tensor& weight) const {
// These checks need to be expanded. Currently we have very limited set of
// checks for MPS.
#ifdef USE_MPS
if (needs_64bit_indexing_no_split(input, weight)) {
return false;
}
if (!input.is_mps()) {
return false;
}
return true;
#else
return false;
#endif
}
// We currently only have depthwise support for the case where groups ==
// nInputPlane and nInputPlane == nOutputPlane (the latter due to the lack of
// a depthwise multiplier)
bool is_depthwise(const at::Tensor& input, const at::Tensor& weight) const {
return input.is_cuda() &&
!transposed &&
(input.ndimension() == 4 || input.ndimension() == 5) &&
at::symint::size<T>(input, 1) == groups &&
groups > 1 && // no point if there is only a single group
at::symint::size<T>(weight, 0) % at::symint::size<T>(input, 1) == 0; // output channels must be a multiple of input channels
}
};
DEFINE_DISPATCH(conv_depthwise2d_backward_stub);
DEFINE_DISPATCH(conv_depthwise3d_backward_stub);
DEFINE_DISPATCH(cudnn_convolution_backward_stub);
DEFINE_DISPATCH(cudnn_convolution_transpose_backward_stub);
DEFINE_DISPATCH(slow_conv_transpose3d_backward_stub);
DEFINE_DISPATCH(convolution_depthwise3x3_winograd_stub);
DEFINE_DISPATCH(miopen_convolution_backward_stub);
DEFINE_DISPATCH(miopen_convolution_transpose_backward_stub);
DEFINE_DISPATCH(miopen_depthwise_convolution_backward_stub);
DEFINE_DISPATCH(mkldnn_convolution_backward_stub);
DEFINE_DISPATCH(mkldnn_convolution_transpose_stub);
DEFINE_DISPATCH(mkldnn_convolution_transpose_backward_stub);
DEFINE_DISPATCH(slow_conv_dilated2d_backward_stub);
DEFINE_DISPATCH(slow_conv_dilated3d_backward_stub);
DEFINE_DISPATCH(slow_conv_transpose2d_backward_stub);
REGISTER_NO_CPU_DISPATCH(conv_depthwise2d_backward_stub);
REGISTER_NO_CPU_DISPATCH(conv_depthwise3d_backward_stub);
REGISTER_NO_CPU_DISPATCH(cudnn_convolution_backward_stub);
REGISTER_NO_CPU_DISPATCH(cudnn_convolution_transpose_backward_stub);
REGISTER_NO_CPU_DISPATCH(miopen_convolution_backward_stub);
REGISTER_NO_CPU_DISPATCH(miopen_convolution_transpose_backward_stub);
REGISTER_NO_CPU_DISPATCH(miopen_depthwise_convolution_backward_stub);
template <typename T>
std::ostream& operator<<(std::ostream & out, const ConvParams<T>& params) {
out << "ConvParams {"
<< " stride = " << IntArrayRef{params.stride}
<< " padding = " << ArrayRef<T>{params.padding}
<< " dilation = " << IntArrayRef{params.dilation}
<< " transposed = " << params.transposed
<< " output_padding = " << ArrayRef<T>{params.output_padding}
<< " groups = " << params.groups
<< " benchmark = " << params.benchmark
<< " deterministic = " << params.deterministic
<< " cudnn_enabled = " << params.cudnn_enabled
<< " allow_tf32 = " << params.allow_tf32
<< "}";
return out;
}
template <typename T>
static void check_shape_forward(const at::Tensor& input,
const c10::ArrayRef<T>& weight_sizes, const at::Tensor& bias,
const ConvParams<T>& params) {
int64_t k = input.ndimension();
int64_t weight_dim = weight_sizes.size();
auto groups = params.groups;
const auto& padding = params.padding;
const auto& dilation = params.dilation;
bool transposed = params.transposed;
TORCH_CHECK(!params.is_padding_neg(), "negative padding is not supported");
TORCH_CHECK(!params.is_output_padding_neg(), "negative output_padding is not supported");
TORCH_CHECK(!params.is_stride_nonpos(), "non-positive stride is not supported");
TORCH_CHECK(!params.is_dilation_neg(), "dilation should be greater than zero");
TORCH_CHECK(weight_dim == k,
"Expected ", weight_dim, "-dimensional input for ", weight_dim,
"-dimensional weight ", weight_sizes, ", but got ", k, "-dimensional input of size ",
at::symint::sizes<T>(input), " instead");
TORCH_CHECK(weight_sizes[0] >= groups,
"Given groups=", groups, ", expected weight to be at least ", groups,
" at dimension 0, but got weight of size ", weight_sizes, " instead");
TORCH_CHECK(weight_sizes[0] % groups == 0,
"Given groups=", groups, ", expected weight to be divisible by ",
groups, " at dimension 0, but got weight of size [", weight_sizes,
"] instead");
if (!transposed) {
std::vector<T> input_shape;
std::vector<T> kernel_shape;
bool kernel_size_correct = true;
TORCH_CHECK(at::symint::size<T>(input, 1) == (weight_sizes[1] * groups),
"Given groups=", groups, ", weight of size ", weight_sizes,
", expected input", at::symint::sizes<T>(input), " to have ",
(weight_sizes[1] * groups), " channels, but got ", at::symint::size<T>(input, 1),
" channels instead");
TORCH_CHECK(!bias.defined() || (bias.ndimension() == 1 && at::symint::size<T>(bias, 0) == weight_sizes[0]),
"Given weight of size ", weight_sizes,
", expected bias to be 1-dimensional with ", weight_sizes[0], " elements",
", but got bias of size ", at::symint::sizes<T>(bias), " instead");
for (const auto i : c10::irange(2, k)) {
input_shape.push_back(at::symint::size<T>(input, i) + 2 * padding[i-2]);
// log new kernel size considering dilation
kernel_shape.push_back(dilation[i-2] * (weight_sizes[i]-1) + 1);
if (input_shape.back() < kernel_shape.back()) {
kernel_size_correct = false;
}
}
TORCH_CHECK(input_shape.size() == kernel_shape.size(), "Inconsistent shape between Input and Kernel");
if (!kernel_size_correct) {
// If kernel size is incorrect
std::ostringstream input_ss;
std::ostringstream kernel_ss;
std::string separator = "";
for (int i = 0, len = input_shape.size(); i < len; ++i) {
input_ss << separator << input_shape[i];
kernel_ss << separator << kernel_shape[i];
separator = " x ";
}
AT_ERROR("Calculated padded input size per channel: (", input_ss.str(), "). "
"Kernel size: (", kernel_ss.str(), "). Kernel size can't be greater than actual input size");
}
} else { // transposed
TORCH_CHECK(at::symint::size<T>(input, 1) == weight_sizes[0],
"Given transposed=", transposed, ", weight of size ", weight_sizes,
", expected input", at::symint::sizes<T>(input), " to have ", weight_sizes[0],
" channels, but got ", at::symint::size<T>(input, 1), " channels instead");
TORCH_CHECK(!bias.defined() || (bias.ndimension() == 1 && at::symint::size<T>(bias, 0) == weight_sizes[1] * groups),
"Given transposed=", transposed, ", weight of size ", weight_sizes,
", expected bias to be 1-dimensional with ", weight_sizes[1] * groups, " elements",
", but got bias of size ", at::symint::sizes<T>(bias), " instead");
}
}
template <typename T>
static void check_shape_backward(
const at::Tensor& input,
const c10::ArrayRef<T>& weight_sizes,
const ConvParams<T>& params) {
check_shape_forward<T>(input, weight_sizes, /*bias=*/ Tensor(), params);
}
// Given an input tensor and an expected number of spatial dimensions, checks that the
// input is a valid shape and returns the batched form of the input.
//
// Args:
// input (Tensor): Input tensor
// num_spatial_dims (int): Number of spatial dimensions expected for the input
// func_name (string): Function name to produce a nice error message for invalid input
//
// Returns a std::tuple containing:
// batched_input (Tensor): Input with a batch dimension
// is_batched (bool): Indicates whether the original input was already batched
static std::tuple<Tensor, bool> batchify(
const Tensor& input,
const int64_t num_spatial_dims,
const std::string& func_name) {
// assume NTs are always batched
if (input.is_nested()) {
return std::make_tuple(input, true);
}
const auto dim_count_no_batch = num_spatial_dims + 1;
const auto dim_count_batch = dim_count_no_batch + 1;
const auto is_batched = (input.dim() == dim_count_batch);
TORCH_CHECK(input.dim() == dim_count_no_batch || is_batched,
"Expected ", dim_count_no_batch, "D (unbatched) or ", dim_count_batch,
"D (batched) input to ", func_name, ", but got input of size: ", input.sizes());
return std::make_tuple(is_batched ? input : input.unsqueeze(0), is_batched);
}
static void check_input_same_type_as_parameters(
const Tensor& input,
const Tensor& weight,
const Tensor& bias) {
TORCH_CHECK(input.options().type_equal(weight.options()),
"Input type (", input.toString(), ") and weight type (", weight.toString(),
") should be the same");
TORCH_CHECK(!bias.defined() || (input.options().type_equal(bias.options())),
"Input type (", input.toString(), ") and bias type (", bias.toString(),
") should be the same");
}
static void check_input_same_type_as_parameters(
const Tensor& input,
const Tensor& weight) {
check_input_same_type_as_parameters(input, weight, /*bias=*/ Tensor());
}
#if AT_MKLDNN_ENABLED()
static void check_input_same_type_as_parameters(
const Tensor& input,
const Tensor& weight,
const Tensor& bias,
const ConvBackend backend) {
if (backend == ConvBackend::Mkldnn || backend == ConvBackend::MkldnnTranspose) {
TORCH_CHECK(input.options().type_equal(weight.options())
|| (input.is_mkldnn() && weight.device().is_cpu() && weight.scalar_type() == kFloat),
"Input type (", input.toString(), ") and weight type (", weight.toString(),
") should be the same or input should be a MKLDNN tensor and weight is a dense tensor");
TORCH_CHECK(!bias.defined() || (input.options().type_equal(bias.options()))
|| (input.is_mkldnn() && bias.device().is_cpu() && bias.scalar_type() == kFloat),
"Input type (", input.toString(), ") and bias type (", bias.toString(),
") should be the same or input should be a MKLDNN tensor and bias is a dense tensor");
} else {
check_input_same_type_as_parameters(input, weight, bias);
}
}
#endif
static auto view4d(const at::Tensor& tensor) -> at::Tensor {
TORCH_CHECK(tensor.ndimension() == 3,
"expected 3D tensor, got tensor with ", tensor.ndimension(),
" dimensions instead");
return tensor.unsqueeze(2);
}
static auto view3d(const at::Tensor& tensor) -> at::Tensor {
TORCH_CHECK(tensor.ndimension() == 4,
"expected 4D tensor, got tensor with ", tensor.ndimension(),
" dimensions instead");
return tensor.squeeze(2);
}
static at::Tensor subtensor(at::Tensor& tensor, int dim, int groups, int g) {
if (!tensor.defined()) {
return at::Tensor();
}
const auto memory_format = tensor.suggest_memory_format();
int64_t n = tensor.sizes()[dim] / groups;
return tensor.narrow(dim, n * g, n).contiguous(memory_format);
}
namespace {
std::pair<Tensor, Tensor> complex_to_real(const Tensor& inp) {
auto inp_view_as_complex = at::view_as_real(inp);
auto dim_i = inp_view_as_complex.dim() - 1;
auto i_r = inp_view_as_complex.select(dim_i, 0);
auto i_i = inp_view_as_complex.select(dim_i, 1);
return std::make_pair(i_r, i_i);
}
at::Tensor complex_convolution(
const Tensor& input,
const Tensor& weight,
const Tensor& bias,
SymIntArrayRef stride,
SymIntArrayRef padding,
SymIntArrayRef dilation,
bool transposed,
SymIntArrayRef output_padding,
c10::SymInt groups) {
check_input_same_type_as_parameters(input, weight, bias);
auto [i_r, i_i] = complex_to_real(input.resolve_conj());
auto [w_r, w_i] = complex_to_real(weight.resolve_conj());
// [NOTE] Complex Convolution
// conv(W, x, b) = conv(Wr, xr, br) - conv(Wi, xi, 0) + i(conv(Wi, xr, bi) + conv(Wr, xi, 0))
// where W, x and b are all complex inputs.
// With Gauss Trick:
// a = conv(Wr, xr, br),
// b = conv(Wi, xi, 0),
// c = conv(Wr + Wi, xr + xi, bi + br)
// conv(W, x, b) = a - b + i(c - a - b)
Tensor a, b, c;
if (!bias.defined()) {
a = at::convolution_symint(i_r, w_r, bias, stride, padding, dilation, transposed, output_padding, groups);
b = at::convolution_symint(i_i, w_i, bias, stride, padding, dilation, transposed, output_padding, groups);
c = at::convolution_symint(i_r + i_i, w_r + w_i, bias, stride, padding, dilation, transposed, output_padding, groups);
} else {
auto [b_r, b_i] = complex_to_real(bias.resolve_conj());
a = at::convolution_symint(i_r, w_r, b_r, stride, padding, dilation, transposed, output_padding, groups);
b = at::convolution_symint(i_i, w_i, Tensor(), stride, padding, dilation, transposed, output_padding, groups);
c = at::convolution_symint(i_r + i_i, w_r + w_i, b_r + b_i, stride, padding, dilation, transposed, output_padding, groups);
}
auto i = c10::Scalar(c10::complex<double>(0, 1));
return a - b + i * (c - a - b);
}
at::Tensor complex_convolution_mode(
const at::Tensor& input,
const at::Tensor& weight,
const c10::optional<at::Tensor>& bias_opt,
c10::SymIntArrayRef stride,
c10::string_view padding,
c10::SymIntArrayRef dilation,
c10::SymInt groups) {
auto bias = bias_opt.value_or(Tensor());
check_input_same_type_as_parameters(input, weight, bias);
auto [i_r, i_i] = complex_to_real(input.resolve_conj());
auto [w_r, w_i] = complex_to_real(weight.resolve_conj());
// See [NOTE] Complex Convolution
Tensor a, b, c;
if (!bias.defined()) {
a = at::_convolution_mode_symint(i_r, w_r, bias, stride, padding, dilation, groups);
b = at::_convolution_mode_symint(i_i, w_i, bias, stride, padding, dilation, groups);
c = at::_convolution_mode_symint(i_r + i_i, w_r + w_i, bias, stride, padding, dilation, groups);
} else {
auto [b_r, b_i] = complex_to_real(bias.resolve_conj());
a = at::_convolution_mode_symint(i_r, w_r, b_r, stride, padding, dilation, groups);
b = at::_convolution_mode_symint(i_i, w_i, Tensor(), stride, padding, dilation, groups);
c = at::_convolution_mode_symint(i_r + i_i, w_r + w_i, b_r + b_i, stride, padding, dilation, groups);
}
auto i = c10::Scalar(c10::complex<double>(0, 1));
return a - b + i * (c - a - b);
}
} // namespace
at::Tensor conv1d_symint(
const Tensor& input_, const Tensor& weight, const c10::optional<Tensor>& bias_opt,
SymIntArrayRef stride, SymIntArrayRef padding, SymIntArrayRef dilation, c10::SymInt groups) {
// 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(
!bias.defined() || bias.dtype() == input_.dtype(),
"Input type (",
input_.dtype().name(),
") and bias type (",
bias.dtype().name(),
") should be the same");
auto [input, is_batched] = batchify(input_, /*num_spatial_dims=*/ 1, "conv1d");
Tensor output;
if (at::isComplexType(input_.scalar_type())) {
output = complex_convolution(input, weight, bias, stride, padding, dilation, false, {0}, groups);
} else {
output = at::convolution_symint(input, weight, bias, stride, padding, dilation, false, {0}, groups);
}
return is_batched ? std::move(output) : output.squeeze(0);
}
at::Tensor conv2d_symint(
const Tensor& input_, const Tensor& weight, const c10::optional<Tensor>& bias_opt,
SymIntArrayRef stride, SymIntArrayRef padding, SymIntArrayRef dilation, c10::SymInt groups) {
// 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(
!bias.defined() || bias.dtype() == input_.dtype(),
"Input type (",
input_.dtype().name(),
") and bias type (",
bias.dtype().name(),
") should be the same");
auto [input, is_batched] = batchify(input_, /*num_spatial_dims=*/ 2, "conv2d");
Tensor output;
if (at::isComplexType(input_.scalar_type())) {
output = complex_convolution(input, weight, bias, stride, padding, dilation, false, {{0, 0}}, groups);
} else {
output = at::convolution_symint(input, weight, bias, stride, padding, dilation, false, {{0, 0}}, groups);
}
return is_batched ? std::move(output) : output.squeeze(0);
}
at::Tensor conv3d_symint(
const Tensor& input_, const Tensor& weight, const c10::optional<Tensor>& bias_opt,
SymIntArrayRef stride, SymIntArrayRef padding, SymIntArrayRef dilation, c10::SymInt groups) {
// 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(
!bias.defined() || bias.dtype() == input_.dtype(),
"Input type (",
input_.dtype().name(),
") and bias type (",
bias.dtype().name(),
") should be the same");
auto [input, is_batched] = batchify(input_, /*num_spatial_dims=*/ 3, "conv3d");
Tensor output;
if (at::isComplexType(input_.scalar_type())) {
output = complex_convolution(input, weight, bias, stride, padding, dilation, false, {{0, 0, 0}}, groups);
} else {
output = at::convolution_symint(input, weight, bias, stride, padding, dilation, false, {{0, 0, 0}}, groups);
}
return is_batched ? std::move(output) : output.squeeze(0);
}
static Tensor convolution_same(
const Tensor &input, const Tensor &weight, const Tensor &bias,
SymIntArrayRef stride, SymIntArrayRef dilation, c10::SymInt groups) {
auto k = weight.dim();
TORCH_CHECK(k > 2, "weight should have at least three dimensions");
TORCH_CHECK(groups > 0, "non-positive groups is not supported");
auto dim = static_cast<size_t>(k - 2);
auto weight_sizes = weight.sym_sizes();
auto input_sizes = input.sym_sizes();
TORCH_CHECK(k == input.dim(),
"Expected ", k, "-dimensional input for ",
k, "-dimensional weight", weight_sizes, ", but got ",
input.dim(), "-dimensional input of size ",
input.sizes(), " instead");