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SparseCsrTensorMath.cpp
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SparseCsrTensorMath.cpp
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#define TORCH_ASSERT_ONLY_METHOD_OPERATORS
#include <ATen/Dispatch.h>
#include <ATen/ExpandUtils.h>
#include <ATen/Parallel.h>
#include <ATen/SparseCsrTensorUtils.h>
#include <ATen/core/Tensor.h>
#include <ATen/mkl/Sparse.h>
#include <ATen/native/BinaryOps.h>
#include <ATen/native/CPUBlas.h>
#include <ATen/native/Resize.h>
#include <ATen/native/SparseTensorUtils.h>
#include <ATen/native/mkl/SparseBlasImpl.h>
#include <ATen/native/sparse/SparseBlasImpl.h>
#include <ATen/native/sparse/SparseCsrTensorMath.h>
#include <c10/util/irange.h>
#ifndef AT_PER_OPERATOR_HEADERS
#include <ATen/Functions.h>
#include <ATen/NativeFunctions.h>
#include <ATen/Operators.h>
#else
#include <ATen/ops/_conj_physical_native.h>
#include <ATen/ops/_convert_indices_from_coo_to_csr.h>
#include <ATen/ops/_convert_indices_from_coo_to_csr_native.h>
#include <ATen/ops/_convert_indices_from_csr_to_coo.h>
#include <ATen/ops/_convert_indices_from_csr_to_coo_native.h>
#include <ATen/ops/_sparse_bsr_tensor_unsafe_native.h>
#include <ATen/ops/_sparse_compressed_tensor_unsafe_native.h>
#include <ATen/ops/_sparse_csr_tensor_unsafe_native.h>
#include <ATen/ops/_unique.h>
#include <ATen/ops/abs.h>
#include <ATen/ops/abs_native.h>
#include <ATen/ops/add.h>
#include <ATen/ops/add_native.h>
#include <ATen/ops/addmm.h>
#include <ATen/ops/addmm_native.h>
#include <ATen/ops/angle.h>
#include <ATen/ops/angle_native.h>
#include <ATen/ops/asin.h>
#include <ATen/ops/asin_native.h>
#include <ATen/ops/asinh.h>
#include <ATen/ops/asinh_native.h>
#include <ATen/ops/atan.h>
#include <ATen/ops/atan_native.h>
#include <ATen/ops/atanh.h>
#include <ATen/ops/atanh_native.h>
#include <ATen/ops/ceil.h>
#include <ATen/ops/ceil_native.h>
#include <ATen/ops/conj_physical.h>
#include <ATen/ops/conj_physical_native.h>
#include <ATen/ops/copy_native.h>
#include <ATen/ops/deg2rad.h>
#include <ATen/ops/deg2rad_native.h>
#include <ATen/ops/empty.h>
#include <ATen/ops/empty_like.h>
#include <ATen/ops/erf.h>
#include <ATen/ops/erf_native.h>
#include <ATen/ops/erfinv.h>
#include <ATen/ops/erfinv_native.h>
#include <ATen/ops/expm1.h>
#include <ATen/ops/expm1_native.h>
#include <ATen/ops/fill_native.h>
#include <ATen/ops/floor.h>
#include <ATen/ops/floor_native.h>
#include <ATen/ops/frac.h>
#include <ATen/ops/frac_native.h>
#include <ATen/ops/isinf.h>
#include <ATen/ops/isinf_native.h>
#include <ATen/ops/isnan.h>
#include <ATen/ops/isnan_native.h>
#include <ATen/ops/isneginf.h>
#include <ATen/ops/isneginf_native.h>
#include <ATen/ops/isposinf.h>
#include <ATen/ops/isposinf_native.h>
#include <ATen/ops/log1p.h>
#include <ATen/ops/log1p_native.h>
#include <ATen/ops/mm_native.h>
#include <ATen/ops/mul.h>
#include <ATen/ops/mul_native.h>
#include <ATen/ops/neg.h>
#include <ATen/ops/neg_native.h>
#include <ATen/ops/normal_native.h>
#include <ATen/ops/ones_like.h>
#include <ATen/ops/rad2deg.h>
#include <ATen/ops/rad2deg_native.h>
#include <ATen/ops/relu.h>
#include <ATen/ops/relu_native.h>
#include <ATen/ops/resize_as_sparse_native.h>
#include <ATen/ops/result_type.h>
#include <ATen/ops/round.h>
#include <ATen/ops/round_native.h>
#include <ATen/ops/round_ops.h>
#include <ATen/ops/sgn.h>
#include <ATen/ops/sgn_native.h>
#include <ATen/ops/sign.h>
#include <ATen/ops/sign_native.h>
#include <ATen/ops/signbit.h>
#include <ATen/ops/signbit_native.h>
#include <ATen/ops/sin.h>
#include <ATen/ops/sin_native.h>
#include <ATen/ops/sinh.h>
#include <ATen/ops/sinh_native.h>
#include <ATen/ops/sparse_mask.h>
#include <ATen/ops/sparse_mask_native.h>
#include <ATen/ops/sqrt.h>
#include <ATen/ops/sqrt_native.h>
#include <ATen/ops/tan.h>
#include <ATen/ops/tan_native.h>
#include <ATen/ops/tanh.h>
#include <ATen/ops/tanh_native.h>
#include <ATen/ops/tensor.h>
#include <ATen/ops/threshold_backward.h>
#include <ATen/ops/threshold_backward_native.h>
#include <ATen/ops/trunc.h>
#include <ATen/ops/trunc_native.h>
#include <ATen/ops/zero_native.h>
#include <ATen/ops/zeros.h>
#endif
#include <algorithm>
namespace at {
namespace meta {
TORCH_META_FUNC(_convert_indices_from_coo_to_csr)
(const Tensor& self, const int64_t size, const bool out_int32) {
TORCH_CHECK(self.dim() <= 1, "Input is supposed to be a vector, but got ",
self.dim(), " dimensional tensor.");
ScalarType scalar_type = out_int32 ? ScalarType::Int : ScalarType::Long;
c10::TensorOptions options =
TensorOptions().device(self.options().device()).dtype(scalar_type);
set_output_raw_strided(0, size + 1, {}, options);
}
TORCH_META_FUNC(_convert_indices_from_csr_to_coo)
(const Tensor& crow_indices,
const Tensor& col_indices,
const bool out_int32,
const bool transpose) {
TORCH_CHECK(
crow_indices.dim() == 1, "crow_indices is supposed to be a vector, but got ",
crow_indices.dim(), " dimensional tensor.");
TORCH_CHECK(col_indices.dim() == 1, "col_indices is supposed to be a vector, but got ",
col_indices.dim(), " dimensional tensor.");
ScalarType scalar_type = out_int32 ? ScalarType::Int : ScalarType::Long;
c10::TensorOptions options = crow_indices.options().dtype(scalar_type);
set_output_raw_strided(0, {2, col_indices.numel()}, {}, options, {});
}
} // namespace meta
namespace {
constexpr int64_t GRAIN_SIZE = at::internal::GRAIN_SIZE;
template <typename F>
Tensor& unary_op_out(F op_out, const Tensor& self, Tensor& result) {
TORCH_INTERNAL_ASSERT(self.is_sparse_csr());
TORCH_INTERNAL_ASSERT(result.is_sparse_csr());
if (!result.is_same(self)) {
// For the case of (0x0) result tensor, manually resize `result` tensor
// to the size of `self` tensor
if (result.numel() == 0) {
at::native::resize_as_sparse_compressed_(result, self);
}
// copy_sparse_compressed_ internally checks the sizes of result and self tensors
// Hence no external size check required
at::native::copy_sparse_compressed_(result, self);
}
auto self_values = self.values();
auto result_values = result.values();
op_out(self_values, result_values);
return result;
}
template <typename F, typename... Args>
Tensor& unary_op_inplace(Tensor& self, const F& op_inplace, Args&&... args) {
AT_DISPATCH_ALL_SPARSE_COMPRESSED_LAYOUTS(self.layout(), "unary_op_inplace", [](){});
auto self_values = self.values();
(self_values.*op_inplace)(std::forward<Args>(args)...);
return self;
}
template <typename input_t, typename output_t>
void convert_indices_from_csr_to_coo_cpu(
const Tensor& indices,
const Tensor& crow_indices,
const Tensor& col_indices,
const bool transpose = false) {
int64_t nrows = crow_indices.numel() - 1;
if (nrows == 0) {
indices.zero_();
return;
}
auto crow_indices_ = crow_indices.expect_contiguous();
const input_t* crow_indices_data_in = crow_indices_->data_ptr<input_t>();
TORCH_INTERNAL_ASSERT(indices.is_contiguous());
auto row0 = indices.select(0, transpose ? 1 : 0);
auto row1 = indices.select(0, transpose ? 0 : 1);
output_t* data_out = row0.data_ptr<output_t>();
row1.copy_(*col_indices.expect_contiguous());
at::parallel_for(0, nrows, GRAIN_SIZE, [&](int64_t start, int64_t end) {
for (const auto i : c10::irange(start, end)) {
std::fill(
&data_out[crow_indices_data_in[i]],
&data_out[crow_indices_data_in[i + 1]],
static_cast<output_t>(i));
}
});
}
} // end anonymous namespace
namespace native {
using namespace at::sparse_csr;
// certain utiliy functions are usable from sparse COO.
using namespace at::sparse;
Tensor& mul_out_sparse_csr(const Tensor& t_, const Tensor& src_, Tensor& r) {
// // TODO: Use a specialized CSR kernel for performance if needed
if (t_.is_sparse_csr() && src_.layout() == kStrided) {
return mul_out_sparse_csr(t_, src_.sparse_mask(t_), r);
}
if (t_.layout() == kStrided && src_.is_sparse_csr()) {
return mul_out_sparse_csr(t_.sparse_mask(src_), src_, r);
}
TORCH_CHECK(r.is_sparse_csr(), "Expected result Tensor to be of format CSR");
Tensor t = t_.to_sparse();
Tensor src = src_.to_sparse();
Tensor tmp_result = t.mul(src);
auto r_sparse_csr = tmp_result.to_sparse_csr();
r.resize_as_sparse_(r_sparse_csr);
r.copy_(r_sparse_csr);
return r;
}
template <typename op_t>
Tensor intersection_binary_op_with_wrapped_scalar(const Tensor& sparse, const Tensor& scalar, const op_t& op) {
// NOTE: intersection_binary_op_with_wrapped_scalar assumes scalar.numel() == 1.
const auto result_values = op(sparse.values(), scalar.squeeze()).to(at::result_type(sparse, scalar));
const auto result_sizes = infer_size(sparse.sizes(), scalar.sizes());
Tensor compressed_indices, plain_indices;
std::tie(compressed_indices, plain_indices) = getCompressedPlainIndices(sparse);
return at::native::_sparse_compressed_tensor_unsafe(
compressed_indices.clone(),
plain_indices.clone(),
result_values,
result_sizes,
result_values.scalar_type(),
sparse.layout(),
result_values.device());
}
template <typename op_t>
Tensor& intersection_binary_op_with_wrapped_scalar_(Tensor& sparse, const Tensor& scalar, const string& op_name, const op_t& op) {
// NOTE: intersection_binary_op_with_wrapped_scalar_ assumes scalar.numel() == 1.
const auto broadcasted_shape = infer_size(sparse.sizes(), scalar.sizes());
if (sparse.sizes() != broadcasted_shape) {
TORCH_CHECK(false, op_name, "(): output with shape ", sparse.sizes(), " does not match ",
"the broadcast shape ", broadcasted_shape);
}
auto values = sparse.values();
// Safe to use squeeze here, we already know that scalar safely broadcasts.
op(values, scalar.squeeze());
return sparse;
}
Tensor mul_sparse_csr(const Tensor& self, const Tensor& other) {
// Check if either of the arguments is a wrapped Scalar
if (self.layout() == kStrided && self.dim() == 0) {
return intersection_binary_op_with_wrapped_scalar(other, self, [](const Tensor& a, const Tensor& b) -> Tensor {
return a.mul(b);
});
}
if (other.layout() == kStrided && other.dim() == 0) {
return intersection_binary_op_with_wrapped_scalar(self, other, [](const Tensor& a, const Tensor& b) -> Tensor {
return a.mul(b);
});
}
if (self.is_sparse_csr() && other.layout() == kStrided) {
return mul_sparse_csr(self, other.sparse_mask(self));
}
if (self.layout() == kStrided && other.is_sparse_csr()) {
return mul_sparse_csr(self.sparse_mask(other), other);
}
auto commonDtype = at::result_type(self, other);
auto result_options = self.options().dtype(commonDtype);
// CSR is 2d!
Tensor result = at::empty({0, 0}, result_options);
return at::mul_out(result, self, other); // redispatch!
}
Tensor& mul_sparse_csr_(Tensor& self, const Tensor& other) {
if (other.layout() == kStrided && other.dim() == 0) {
return intersection_binary_op_with_wrapped_scalar_(self, other, "mul_", [](Tensor& a, const Tensor& b) -> Tensor& {
return a.mul_(b);
});
}
return at::mul_out(self, self, other); // redispatch!
}
namespace {
template <typename F>
inline Tensor get_result_tensor_for_unary_op(F op, const Tensor& input) {
auto values = input.values();
// To handle type promotion for inputs to unary ops,
// we first get the result from the underlined op, and use the result
// to create a sparse compressed tensor, which is used as the input to the out=
// variant
auto result_values = op(values);
auto compressed_indices = AT_DISPATCH_ROW_SPARSE_COMPRESSED_LAYOUTS(input.layout(),
"get_result_tensor_for_unary_op",
[&]{ return input.crow_indices(); },
[&]{ return input.ccol_indices(); });
auto plain_indices = AT_DISPATCH_ROW_SPARSE_COMPRESSED_LAYOUTS(input.layout(),
"get_result_tensor_for_unary_op",
[&]{ return input.col_indices(); },
[&]{ return input.row_indices(); });
auto result = at::native::_sparse_compressed_tensor_unsafe(
compressed_indices.clone(),
plain_indices.clone(),
result_values,
input.sizes(),
result_values.scalar_type(),
input.layout(),
result_values.device());
return result;
}
} // namespace
static constexpr bool is_mkl_supported() {
#ifdef _MSC_VER
return false;
#elif __APPLE__ || __MACH__
return false;
#else
return true;
#endif
}
// Only accept squares sparse matrices or dense input as a vector
// TODO: Check what happens with MKL, the output error reported with non square
// matrices tends to be high See:
// https://github.com/pytorch/pytorch/issues/58770
bool is_square_or_vec(int64_t dim_i, int64_t dim_j, int64_t dim_k) {
return (dim_i == dim_k && dim_k == dim_j) || (dim_i == dim_j && dim_k == 1);
}
Tensor& normal_sparse_csr_(
Tensor& self,
double mean,
double std,
c10::optional<Generator> gen) {
return unary_op_inplace(self, &Tensor::normal_, mean, std, gen);
}
Tensor& fill_sparse_csr_(Tensor& self, const Scalar& value) {
return unary_op_inplace(self, &TensorBase::fill_, value);
}
Tensor sparse_mask_sparse_csr(
const Tensor& self,
const Tensor& sparse_mask) {
TORCH_CHECK(sparse_mask.is_sparse_csr(), "sparse_mask_sparse_csr expects mask to be sparse csr");
TORCH_CHECK(self.dim() == 2, "sparse_mask_sparse_csr expects self to be 2D");
TORCH_CHECK(sparse_mask.dim() == 2, "sparse_mask_sparse_csr expects mask to be 2D");
// We are computing self.mul(at::ones_like(sparse_mask))
// But mul(dense, sparse_csr) is not implemented yet
if (self.layout() == sparse_mask.layout()) {
// Both inputs are CSR
return self.mul(at::ones_like(sparse_mask));
} else {
return self.sparse_mask(sparse_mask.to_sparse()).to_sparse_csr();
}
}
Tensor mul_scalar_sparse_csr(const Tensor& self, const Scalar& other) {
auto result_values = self.values().mul(other);
return at::native::_sparse_csr_tensor_unsafe(
self.crow_indices().clone(),
self.col_indices().clone(),
result_values,
self.sizes(),
result_values.scalar_type(),
self.layout(),
result_values.device());
}
Tensor& zero_sparse_csr_(Tensor& self) {
/*
csr.zero_() resets nnz to 0.
If the original sparsity pattern needs to be preserved, use
`csr.values().zero_()` instead.
The above behavior also implies that torch.zeros_like(csr) returns
a new tensor with nnz == 0. If one needs a zeros_like semantics
where the result has the same sparsity pattern as input, then use
`result = csr.clone(); result.values.zero_();`
*/
AT_DISPATCH_ALL_SPARSE_COMPRESSED_LAYOUTS(self.layout(), "zero_sparse_csr_", [](){});
get_sparse_csr_impl(self)->resize_and_clear_(self.sparse_dim(), self.sizes());
return self;
}
/* Implementation of Unary Ufuncs, those supported for Sparse CSR Layout
* Only simple funcs, with 0->0 correspondence are currently supported. */
#define CREATE_UNARY_UFUNC_OUT(op_name) \
Tensor& op_name##_sparse_csr_out(const Tensor& self, Tensor& result) { \
return unary_op_out(&at::op_name##_outf, self, result); \
}
#define CREATE_UNARY_UFUNC_FUNCTIONAL(op_name) \
Tensor op_name##_sparse_csr(const Tensor& self) { \
return get_result_tensor_for_unary_op(&at::op_name, self); \
}
#define CREATE_UNARY_UFUNC_INPLACE(op_name) \
Tensor& op_name##_sparse_csr_(Tensor& self) { \
return unary_op_inplace(self, &Tensor::op_name##_); \
}
#define CREATE_UNARY_UFUNC(op_name) \
CREATE_UNARY_UFUNC_OUT(op_name); \
CREATE_UNARY_UFUNC_FUNCTIONAL(op_name); \
CREATE_UNARY_UFUNC_INPLACE(op_name);
#define CREATE_UNARY_UFUNC_NO_INPLACE(op_name) \
CREATE_UNARY_UFUNC_OUT(op_name); \
CREATE_UNARY_UFUNC_FUNCTIONAL(op_name);
// Exhaustive list of the unary ufuncs supported by sparse compressed
CREATE_UNARY_UFUNC(abs);
CREATE_UNARY_UFUNC(asin);
CREATE_UNARY_UFUNC(asinh);
CREATE_UNARY_UFUNC(atan);
CREATE_UNARY_UFUNC(atanh);
CREATE_UNARY_UFUNC(ceil);
CREATE_UNARY_UFUNC(deg2rad);
CREATE_UNARY_UFUNC(erf);
CREATE_UNARY_UFUNC(erfinv);
CREATE_UNARY_UFUNC(expm1);
CREATE_UNARY_UFUNC(floor);
CREATE_UNARY_UFUNC(frac);
CREATE_UNARY_UFUNC(log1p);
CREATE_UNARY_UFUNC(neg);
CREATE_UNARY_UFUNC(rad2deg);
CREATE_UNARY_UFUNC(sign);
CREATE_UNARY_UFUNC(sin);
CREATE_UNARY_UFUNC(sinh);
CREATE_UNARY_UFUNC(sgn);
CREATE_UNARY_UFUNC(sqrt);
CREATE_UNARY_UFUNC(tan);
CREATE_UNARY_UFUNC(tanh);
CREATE_UNARY_UFUNC(trunc);
CREATE_UNARY_UFUNC(conj_physical);
CREATE_UNARY_UFUNC(relu);
// With addition of `round.decimals` overload, using CREATE_UNARY_UFUNC leads
// to unresolved overload.
Tensor& round_sparse_csr_out(const Tensor& self, Tensor& result) {
return unary_op_out(&at::_ops::round_out::call, self, result);
}
Tensor round_sparse_csr(const Tensor& self) {
return get_result_tensor_for_unary_op(&at::_ops::round::call, self);
}
Tensor& round_sparse_csr_(Tensor& self) {
TORCH_INTERNAL_ASSERT(self.is_sparse_csr());
self.values().round_();
return self;
}
Tensor threshold_backward_sparse_compressed(
const Tensor& grad_output,
const Tensor& self,
const Scalar& threshold) {
return get_result_tensor_for_unary_op(
[&](const Tensor& t) {
return at::threshold_backward(t, self.values(), threshold);
},
grad_output);
}
Tensor& threshold_backward_sparse_compressed_out(
const Tensor& grad_output,
const Tensor& self,
const Scalar& threshold,
Tensor& grad_input) {
return unary_op_out(
[&](const Tensor& t, Tensor& out) {
return at::threshold_backward_outf(t, self.values(), threshold, out);
},
grad_output,
grad_input);
}
// angle, isneginf, isposinf and signbit currently don't have an inplace variant
CREATE_UNARY_UFUNC_NO_INPLACE(angle);
CREATE_UNARY_UFUNC_NO_INPLACE(isneginf);
CREATE_UNARY_UFUNC_NO_INPLACE(isposinf);
CREATE_UNARY_UFUNC_NO_INPLACE(signbit);
// isnan and isinf don't have an out variant
CREATE_UNARY_UFUNC_FUNCTIONAL(isnan);
CREATE_UNARY_UFUNC_FUNCTIONAL(isinf);
template <typename scalar_t>
void addmm_out_sparse_csr_native_cpu(
const Tensor& sparse,
const Tensor& dense,
const Tensor& r,
Scalar alpha,
Scalar beta) {
auto dim_i = sparse.size(0);
auto dim_k = dense.size(1);
auto csr = sparse.crow_indices();
auto col_indices = sparse.col_indices();
auto values = sparse.values();
scalar_t cast_alpha = alpha.to<scalar_t>();
r.mul_(beta);
AT_DISPATCH_INDEX_TYPES(
col_indices.scalar_type(), "csr_mm_crow_indices", [&]() {
auto csr_accessor = csr.accessor<index_t, 1>();
auto col_indices_accessor = col_indices.accessor<index_t, 1>();
auto values_accessor = values.accessor<scalar_t, 1>();
scalar_t* dense_ptr = dense.data_ptr<scalar_t>();
scalar_t* r_ptr = r.data_ptr<scalar_t>();
int64_t dense_stride0 = dense.stride(0);
int64_t dense_stride1 = dense.stride(1);
int64_t r_stride0 = r.stride(0);
int64_t r_stride1 = r.stride(1);
at::parallel_for(
0,
dim_i,
internal::GRAIN_SIZE,
[&](int64_t irow_start, int64_t irow_end) {
for (index_t h = irow_start; h < irow_end; ++h) {
index_t i_start = csr_accessor[h];
index_t i_end = csr_accessor[h + 1];
for (index_t i = i_start; i < i_end; i++) {
scalar_t val = values_accessor[i];
index_t col = col_indices_accessor[i];
at::native::cpublas::axpy<scalar_t>(
dim_k,
cast_alpha * val,
dense_ptr + col * dense_stride0,
dense_stride1,
r_ptr + h * r_stride0,
r_stride1);
}
}
});
});
}
// Functions for matrix multiplication.
// result = beta * self + alpha (mat1 @ mat2)
Tensor& addmm_out_sparse_compressed_cpu(
const Tensor& self,
const Tensor& mat1,
const Tensor& mat2,
const Scalar& beta,
const Scalar& alpha,
Tensor& result) {
// TODO: remove this, there are no codegenerated checks for devices yet
sparse::impl::_check_is_cpu(self, "self");
sparse::impl::_check_is_cpu(mat1, "mat1");
sparse::impl::_check_is_cpu(mat2, "mat2");
sparse::impl::_check_is_cpu(result, "result");
// All the checks are from addmm_out_cuda_impl (ATen/native/cuda/Blas.cpp) and
// TORCH_META_FUNC(addmm) (ATen/native/LinearAlgebra.cpp)
// TODO: remove code duplication and unify code
sparse::impl::_check_dim(mat1, 2, "mat1");
sparse::impl::_check_dim(mat2, 2, "mat2");
TORCH_CHECK(
mat1.size(1) == mat2.size(0), "mat1 and mat2 shapes cannot be multiplied (",
mat1.size(0), "x", mat1.size(1), " and ", mat2.sizes()[0], "x", mat2.sizes()[1], ")");
c10::MaybeOwned<at::Tensor> self_;
// Don't expand self if this is an in-place operation
if (&result == &self) {
self_ = c10::MaybeOwned<Tensor>::borrowed(self);
} else {
self_ = expand_size(self, {mat1.size(0), mat2.size(1)}, "addmm");
}
TORCH_CHECK(((self_->dim() == 2) &&
(self_->size(0) == mat1.size(0)) &&
(self_->size(1) == mat2.size(1))),
"The input tensor must be a matrix with size ",
mat1.size(0),
"x",
mat2.size(1),
", but got a ",
self_->dim(),
"-D tensor with size ",
self_->size(0),
"x",
self_->size(1));
if (&result != &self) {
if (result.layout() == kStrided) {
at::native::resize_output(result, self_->sizes());
} else {
result.resize_as_sparse_(*self_);
}
result.copy_(*self_);
}
if (result.numel() == 0) {
// If result gets resized and is sparse compressed,
// it's compressed_indices tensor will contain junk values
// so the whole tensor is not a valid compressed tensor.
// To combat that, result needs to get zeroed out.
if (at::sparse_csr::is_sparse_compressed(result)) {
result.zero_();
}
return result;
}
if (sparse::impl::_is_sparse_and_zero(mat1) || sparse::impl::_is_sparse_and_zero(mat2)) {
// According to docs, when beta==0 values in self should be ignored.
// nans and infs should not propagate
if (beta.toComplexDouble() == 0.) {
result.zero_();
} else {
result.mul_(beta);
}
return result;
}
#if !AT_USE_MKL_SPARSE()
// The custom impl addmm_out_sparse_csr_native_cpu only supports CSR @
// strided -> strided
if (mat1.layout() == kStrided) {
if (mat2.layout() == kSparseCsr) {
if (result.layout() == kStrided) {
AT_DISPATCH_FLOATING_AND_COMPLEX_TYPES(
result.scalar_type(), "addmm_sparse_dense", [&] {
addmm_out_sparse_csr_native_cpu<scalar_t>(
mat2.transpose(-2, -1).to_sparse_csr(),
mat1.transpose(-2, -1),
result.transpose(-2, -1),
alpha,
beta);
});
return result;
}
}
if (mat2.layout() == kSparseCsc) {
if (result.layout() == kStrided) {
AT_DISPATCH_FLOATING_AND_COMPLEX_TYPES(
result.scalar_type(), "addmm_sparse_dense", [&] {
addmm_out_sparse_csr_native_cpu<scalar_t>(
mat2.transpose(-2, -1),
mat1.transpose(-2, -1),
result.transpose(-2, -1),
alpha,
beta);
});
return result;
}
}
} else if (mat1.layout() == kSparseCsr) {
if (mat2.layout() == kStrided) {
if (result.layout() == kStrided) {
AT_DISPATCH_FLOATING_AND_COMPLEX_TYPES(
result.scalar_type(), "addmm_sparse_dense", [&] {
addmm_out_sparse_csr_native_cpu<scalar_t>(
mat1, mat2, result, alpha, beta);
});
return result;
}
}
} else if (mat1.layout() == kSparseCsc) {
if (mat2.layout() == kStrided) {
if (result.layout() == kStrided) {
AT_DISPATCH_FLOATING_AND_COMPLEX_TYPES(
result.scalar_type(), "addmm_sparse_dense", [&] {
addmm_out_sparse_csr_native_cpu<scalar_t>(
mat1.to_sparse_csr(), mat2, result, alpha, beta);
});
return result;
}
}
}
TORCH_CHECK(
false,
"addmm: computation on CPU is not implemented for ",
result.layout(),
" + ",
mat1.layout(),
" @ ",
mat2.layout(),
" without MKL. PyTorch built with MKL has better support for addmm with sparse CPU tensors.");
#else
sparse::impl::mkl::addmm_out_sparse_csr(mat1, mat2, beta, alpha, result);
#endif
return result;
}
Tensor addmm_sparse_compressed_dense(
const Tensor& self,
const SparseCsrTensor& sparse,
const Tensor& dense,
const Scalar& beta,
const Scalar& alpha) {
Tensor r = at::empty({0, 0}, self.options());
at::addmm_out(r, self, sparse, dense, beta, alpha);
return r;
}
Tensor& _sparse_csr_mm_out(
const Tensor& mat1,
const Tensor& mat2,
Tensor& result) {
auto zero = at::zeros({mat1.size(0), mat2.size(1)}, mat2.options());
return at::addmm_out(result, zero, mat1, mat2, 0.0, 1.0);
}
Tensor _sparse_csr_mm(const Tensor& mat1, const Tensor& mat2) {
if (mat1.is_sparse_csr() && mat2.is_sparse_csr()) {
// Return sparse
return at::addmm(
at::zeros({mat1.size(0), mat2.size(1)}, mat2.options()),
mat1,
mat2,
0.0,
1.0);
}
if ((mat1.layout() == kSparseCsc || mat1.layout() == kSparseCsr) &&
(mat2.layout() == kSparseCsc || mat2.layout() == kSparseCsr)) {
// TODO: Expensive conversion to CSR. Should add native support for CSC.
// Covers CSC @ CSR
// Covers CSR @ CSC
// Covers CSC @ CSC
return _sparse_csr_mm(mat1.to_sparse_csr(), mat2.to_sparse_csr());
}
if (mat1.layout() == kSparseCsc && mat2.layout() == c10::kStrided) {
// TODO: This is a costly conversion. We should have
// native support for CSC.
return _sparse_csr_mm(mat1.to_sparse_csr(), mat2);
}
// Default to taking options from mat1
auto result_options = mat1.options();
if (mat2.layout() == kStrided) {
// if either arg is strided we return strided, so update the options if
// mat2 is strided.
result_options = result_options.layout(kStrided);
}
return at::addmm(
at::zeros({mat1.size(0), mat2.size(1)}, result_options),
mat1,
mat2,
0.0,
1.0);
}
Tensor _sparse_csr_addmm(
const Tensor& t,
const SparseCsrTensor& sparse,
const Tensor& dense,
const Scalar& beta,
const Scalar& alpha) {
// _sparse_addmm forward is functionally equivalent to addmm; it's
// just the backward that is different. This technically does an
// unnecessary redispatch, I was too lazy to make it not do that
return at::addmm(t, sparse, dense, beta, alpha);
}
// Functions for element-wise addition.
Tensor add_sparse_csr(
const Tensor& self,
const Tensor& other,
const Scalar& alpha) {
auto commonDtype = at::result_type(self, other);
alpha_check(commonDtype, alpha);
Tensor result = at::empty_like(self, self.options().dtype(commonDtype).memory_format(at::MemoryFormat::Contiguous));
return at::add_out(result, self, other, alpha); // redispatch!
}
Tensor& add_sparse_csr_(
Tensor& self,
const Tensor& other,
const Scalar& alpha) {
return at::add_out(self, self, other, alpha); // redispatch!
}
void add_out_dense_sparse_csr_cpu(
const Tensor& out,
const Tensor& dense,
const SparseCsrTensor& src,
const Scalar& alpha) {
TORCH_INTERNAL_ASSERT(dense.layout() == kStrided);
TORCH_INTERNAL_ASSERT(src.is_sparse_csr());
TORCH_INTERNAL_ASSERT(dense.device() == kCPU);
TORCH_CHECK(
out.is_contiguous(),
"out argument must be contiguous, but got: ",
out.suggest_memory_format());
TORCH_CHECK(
out.device() == kCPU,
"add: expected 'out' to be CPU tensor, but got tensor on device: ",
out.device());
TORCH_CHECK(
src.device() == kCPU,
"add: expected 'other' to be a CPU tensor, but got tensor on device: ",
src.device());
TORCH_CHECK(
dense.sizes().equals(src.sizes()),
"add: expected 'self' and 'other' to have same size, but self has size ",
dense.sizes(),
" while other has size ",
src.sizes(),
" (FYI: op2-sparse addition does not currently support broadcasting)");
auto commonDtype = promoteTypes(dense.scalar_type(), src.scalar_type());
TORCH_CHECK(
canCast(commonDtype, out.scalar_type()),
"Can't convert result type ",
commonDtype,
" to output ",
out.scalar_type(),
" in add operation");
auto src_values = src.values();
resize_output(out, dense.sizes());
Tensor resultBuffer = out;
if (out.scalar_type() != commonDtype) {
resultBuffer = dense.to(commonDtype);
} else if (!is_same_tensor(out, dense)) {
resultBuffer.copy_(dense);
}
if (src._nnz() == 0) {
return;
}
auto valuesBuffer = src_values.to(commonDtype).reshape({-1, src_values.size(-1)});
resultBuffer = resultBuffer.view({-1, out.size(-2), out.size(-1)});
auto src_crow_indices = src.crow_indices().reshape({-1, src.crow_indices().size(-1)});
auto src_col_indices = src.col_indices().reshape({-1, src.col_indices().size(-1)});
AT_DISPATCH_ALL_TYPES_AND_COMPLEX_AND4(
kComplexHalf,
kHalf,
kBool,
kBFloat16,
commonDtype,
"add_out_op2_sparse_csr",
[&valuesBuffer,
&resultBuffer,
&alpha,
&src_crow_indices,
&src_col_indices]() {
AT_DISPATCH_INDEX_TYPES(
src_crow_indices.scalar_type(),
"csr_add_out_crow_indices",
[&valuesBuffer,
&resultBuffer,
&alpha,
&src_crow_indices,
&src_col_indices]() {
auto batch_count = resultBuffer.dim() > 2 ? resultBuffer.size(-3) : 1;
auto values_accessor = valuesBuffer.accessor<scalar_t, 2>();
scalar_t* out_ptr = resultBuffer.data_ptr<scalar_t>();
scalar_t cast_value = alpha.to<scalar_t>();
auto crow_indices_accessor =
src_crow_indices.accessor<index_t, 2>();
auto col_indices_accessor =
src_col_indices.accessor<index_t, 2>();
auto out_strides = resultBuffer.strides();
for (const auto batch_idx : c10::irange(batch_count)) {
for (const auto irow : c10::irange(src_crow_indices.size(-1) - 1)) {
index_t start_index = crow_indices_accessor[batch_idx][irow];
index_t end_index = crow_indices_accessor[batch_idx][irow + 1];
for (const auto i : c10::irange(start_index, end_index)) {
auto icol = col_indices_accessor[batch_idx][i];
auto index = batch_idx * out_strides[0] + irow * out_strides[1] + icol * out_strides[2];
out_ptr[index] += cast_value * values_accessor[batch_idx][i];
}
}
}
});
});
if (out.scalar_type() != commonDtype) {
out.copy_(resultBuffer);
}
}
Tensor& add_out_sparse_csr_cpu(
const Tensor& self,
const SparseCsrTensor& other,
const Scalar& alpha,
SparseCsrTensor& out) {
if (self.layout() == kStrided) {
add_out_dense_sparse_csr_cpu(out, self, other, alpha);
} else {
TORCH_CHECK(
self.sizes().equals(other.sizes()),
"torch.add: Expected input tensors to have the same shape, but got tensor `self` with shape ",
self.sizes(),
" and tensor `other` with shape ",
other.sizes());
if (only_sparse_compressed_add_trivial_cases(self, other, alpha, out)) {
return out;
}
at::native::resize_as_sparse_compressed_(out, self);
sparse::impl::cpu::add_out_sparse_csr(self, other, alpha, out);
}
return out;
}
/*
Reductions on sparse CSR tensors using masked semantics.
- A CSR tensor is a 2D tensor that is specified by a 3-tuple
(crow_indices, col_indices, values).
- To support a reduction operator on a CSR tensor, define:
template <typename scalar_t>
struct Reduction...Op {
inline scalar_t operator()(const scalar_t& a, const scalar_t& b) const {
return a ... b;
}
inline scalar_t identity() const { return ...; }
};
Tensor _sparse_csr_..._cpu(const Tensor& input, IntArrayRef dims_to_sum, bool keepdim, c10::optional<ScalarType> dtype) {
...
result = reduce_sparse_csr_cpu_template<scalar_t>(input_, dims_to_sum, keepdim, Reduction...Op<scalar_t>());
...
return result;
}
and add the following
- func: _sparse_csr_op.dim_dtype(Tensor self, int[1] dim, bool keepdim=False, *, ScalarType? dtype=None) -> Tensor
dispatch:
SparseCsrCUDA: _sparse_csr_..._cpu
to native_functions.yaml
Use ReductionAddOp and _sparse_csr_sum implementation as an example.
- Since a CSR tensor dimensionality is always 2, only reductions
with keepdim=True can be supported.
*/
namespace {
template <typename scalar_t, typename ReductionOp>
Tensor reduce_sparse_csr_dim0_cpu_template(const Tensor& sparse, ReductionOp rop) {
/*
Consider the following sparse tensor:
1 * * * *
* * * 2 *
* * 3 * *
* * * * *
4 * 5 * *
that has CSR representation