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ReduceOpsKernel.cpp
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ReduceOpsKernel.cpp
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#define TORCH_ASSERT_ONLY_METHOD_OPERATORS
#include <algorithm>
#include <ATen/core/Tensor.h>
#include <ATen/Dispatch.h>
#include <ATen/OpMathType.h>
#include <ATen/cpu/vec/vec.h>
#include <ATen/cpu/vec/functional.h>
#include <ATen/native/ReduceOps.h>
#include <ATen/native/Resize.h>
#include <ATen/native/TensorIterator.h>
#include <ATen/native/SharedReduceOps.h>
#include <ATen/native/ReduceOpsUtils.h>
#include <ATen/native/cpu/Reduce.h>
#include <ATen/native/cpu/LogAddExp.h>
#ifndef AT_PER_OPERATOR_HEADERS
#include <ATen/Functions.h>
#else
#include <ATen/ops/imag.h>
#endif
#include <c10/util/irange.h>
#include <ATen/AccumulateType.h>
namespace at::native { namespace {
using namespace vec;
template <typename scalar_t, typename func_t>
static inline void cpu_cum_base_kernel(const Tensor& result,
const Tensor& self,
int64_t dim,
const func_t& f,
scalar_t init_val) {
if (result.sizes() != self.sizes()) {
at::native::resize_output(result, self.sizes());
}
if (self.numel() == 0) {
return;
}
const auto input_ndim = self.dim();
if (input_ndim == 0) {
result.fill_(self);
return;
}
// TODO This probably should be using at::native::make_reduction
auto iter = TensorIteratorConfig()
.check_all_same_dtype(false)
.resize_outputs(false)
// NOLINTNEXTLINE(bugprone-argument-comment)
.declare_static_shape(self.sizes(), /*squash_dim=*/dim)
.add_output(result)
.add_const_input(self)
.build();
auto result_dim_stride = ensure_nonempty_stride(result, dim);
auto self_dim_stride = ensure_nonempty_stride(self, dim);
auto loop = [&](char** data, const int64_t* strides, int64_t n) {
auto* result_data_bytes = data[0];
const auto* self_data_bytes = data[1];
for (const auto i C10_UNUSED : c10::irange(n)) {
f(
(scalar_t*)result_data_bytes, result_dim_stride,
(scalar_t*)self_data_bytes, self_dim_stride, init_val
);
result_data_bytes += strides[0];
self_data_bytes += strides[1];
}
};
int64_t grain_size = internal::GRAIN_SIZE / std::max(int64_t{1}, self.size(dim));
iter.for_each(loop, grain_size);
}
static void cumsum_cpu_kernel(const Tensor& result, const Tensor& self, int64_t dim) {
auto wrap_dim = maybe_wrap_dim(dim, self.dim());
int64_t self_dim_size = ensure_nonempty_size(self, wrap_dim);
AT_DISPATCH_ALL_TYPES_AND_COMPLEX_AND2(kBFloat16, kHalf, self.scalar_type(), "cumsum_out_cpu", [&] {
cpu_cum_base_kernel<scalar_t>(result, self, wrap_dim, [&] (
scalar_t* result_data, auto result_dim_stride,
const scalar_t* self_data, auto self_dim_stride, scalar_t init_val) {
// NOLINTNEXTLINE(bugprone-signed-char-misuse)
auto cum_number = (at::acc_type<scalar_t, false>)init_val;
for (const auto i : c10::irange(self_dim_size)) {
cum_number += self_data[i * self_dim_stride];
result_data[i * result_dim_stride] = (scalar_t)cum_number;
}
}, /*init_val=*/ 0
);
});
}
static void cumprod_cpu_kernel(const Tensor& result, const Tensor& self, int64_t dim) {
auto wrap_dim = maybe_wrap_dim(dim, self.dim());
int64_t self_dim_size = ensure_nonempty_size(self, wrap_dim);
AT_DISPATCH_ALL_TYPES_AND_COMPLEX_AND2(kBFloat16, kHalf, self.scalar_type(), "cumprod_out_cpu", [&] {
cpu_cum_base_kernel<scalar_t>(result, self, wrap_dim, [&] (
scalar_t* result_data, auto result_dim_stride,
const scalar_t* self_data, auto self_dim_stride, scalar_t init_val) {
// NOLINTNEXTLINE(bugprone-signed-char-misuse)
auto cum_number = (at::acc_type<scalar_t, false>)init_val;
for (const auto i : c10::irange(self_dim_size)) {
cum_number *= self_data[i * self_dim_stride];
result_data[i * result_dim_stride] = (scalar_t)cum_number;
}
}, /*init_val=*/ 1
);
});
}
static void logcumsumexp_cpu_kernel(Tensor& result, const Tensor& self, int64_t dim) {
auto wrap_dim = maybe_wrap_dim(dim, self.dim());
int64_t self_dim_size = ensure_nonempty_size(self, wrap_dim);
AT_DISPATCH_FLOATING_AND_COMPLEX_TYPES_AND2(kBFloat16, kHalf, self.scalar_type(), "logcumsumexp_out_cpu", [&] {
cpu_cum_base_kernel<scalar_t>(result, self, wrap_dim, [&] (
scalar_t* result_data, auto result_dim_stride,
const scalar_t* self_data, auto self_dim_stride, scalar_t init_val) {
using accscalar_t = at::acc_type<scalar_t, false>;
auto cum_number = (accscalar_t)init_val;
for (const auto i : c10::irange(self_dim_size)) {
accscalar_t x = self_data[i * self_dim_stride];
cum_number = _log_add_exp_helper(x, cum_number);
result_data[i * result_dim_stride] = static_cast<scalar_t>(cum_number);
}
}, /*init_val=*/ -std::numeric_limits<scalar_t>::infinity()
);
});
}
static void std_var_kernel_impl(TensorIterator& iter, double correction, bool take_sqrt) {
AT_DISPATCH_FLOATING_TYPES_AND2(kHalf, kBFloat16, iter.dtype(), "std_cpu", [&] {
binary_kernel_reduce(
iter,
WelfordOps<
scalar_t,
double,
int64_t,
std::tuple<scalar_t, scalar_t>>{correction, take_sqrt},
WelfordData<double, int64_t>());
});
}
static void prod_kernel_impl(TensorIterator& iter) {
// Workaround for the error: '*' in boolean context, suggest '&&' instead
// [-Werror=int-in-bool-context]
if (iter.dtype() == ScalarType::Bool) {
using scalar_t = bool;
binary_kernel_reduce_vec(
iter,
[=](scalar_t a, scalar_t b)
__ubsan_ignore_undefined__ -> scalar_t { return a && b; },
[=](Vectorized<scalar_t> a, Vectorized<scalar_t> b)
__ubsan_ignore_undefined__ { return a && b; },
// NOLINTNEXTLINE(bugprone-argument-comment)
/*identity=*/1);
} else {
AT_DISPATCH_ALL_TYPES_AND_COMPLEX_AND2(kBFloat16, kHalf, iter.dtype(), "prod_out_cpu", [&] {
binary_kernel_reduce_vec(
iter,
[=](scalar_t a, scalar_t b)
__ubsan_ignore_undefined__ -> scalar_t { return a * b; },
[=](Vectorized<scalar_t> a, Vectorized<scalar_t> b)
__ubsan_ignore_undefined__ { return a * b; },
// NOLINTNEXTLINE(bugprone-argument-comment)
/*identity=*/1);
});
}
}
template <typename scalar_t, typename acc_t>
inline void norm_two_reduce_step(Vectorized<acc_t>& acc_vec, Vectorized<scalar_t>& data_vec) {
acc_vec += data_vec * data_vec;
}
template <>
inline void norm_two_reduce_step(Vectorized<float>& acc_fvec, Vectorized<BFloat16>& data_bvec) {
auto [data_fvec0, data_fvec1] = convert_bfloat16_float(data_bvec);
acc_fvec += data_fvec0 * data_fvec0;
acc_fvec += data_fvec1 * data_fvec1;
}
// This reduction accumulates results as the type `acc_t`. By default, when
// `scalar_t` is complex, `acc_t` is the downgraded real number type.
// Otherwise, `acc_t` and `scalar_t` are the same type.
template <typename scalar_t, typename acc_t=typename scalar_value_type<scalar_t>::type, typename out_t=typename scalar_value_type<scalar_t>::type>
void norm_kernel_cpu_impl(TensorIterator& iter, const double& val) {
if (val == 0.0) {
binary_kernel_reduce(iter, NormZeroOps<scalar_t, acc_t, out_t>(), acc_t(0));
} else if (val == 1.0) {
binary_kernel_reduce(iter, NormOneOps<scalar_t, acc_t, out_t>(), acc_t(0));
} else if (val == 2.0) {
binary_kernel_reduce(iter, NormTwoOps<scalar_t, acc_t, out_t>(), acc_t(0));
} else if (val == INFINITY) {
binary_kernel_reduce(iter, AbsMaxOps<scalar_t, acc_t, out_t>(), acc_t(0));
} else if (val == -INFINITY) {
binary_kernel_reduce(iter, AbsMinOps<scalar_t, acc_t, out_t>(), std::numeric_limits<acc_t>::infinity());
} else {
binary_kernel_reduce(iter, NormOps<scalar_t, acc_t, out_t>{acc_t(val)}, acc_t(0));
}
}
static void norm_kernel_tensor_iterator_impl(
TensorIterator& iter,
const Scalar& p) {
double val;
if (p.isIntegral(false)) {
val = p.to<int64_t>();
} else if (p.isFloatingPoint()) {
val = p.to<double>();
} else {
TORCH_CHECK(false, "norm_kernel_cpu expects norm to be integer or float");
}
if (iter.numel() == 0) {
iter.output().fill_((val < 0) ? INFINITY : 0);
return;
}
if (val == 2.0 && is_reduce_lastdim(iter) &&
iter.dtype(0) == iter.input_dtype() &&
(iter.input_dtype() == kFloat || iter.input_dtype() == kDouble ||
iter.input_dtype() == kBFloat16)) {
// If we can vectorize over the last dimension and the dtype
// of the output is the same as that of the input,
// then we go through the vectorised path.
AT_DISPATCH_FLOATING_TYPES_AND(kBFloat16, iter.input_dtype(), "norm_cpu", [&] {
// use float as accumulate type for BFloat16
using acc_t = at::opmath_type<scalar_t>;
binary_kernel_reduce_lastdim(iter, [](char* result_data_bytes, char* self_data_bytes, int64_t size) {
scalar_t* result_data = (scalar_t*)result_data_bytes;
scalar_t* self_data = (scalar_t*)self_data_bytes;
using Vec = Vectorized<scalar_t>;
using fVec = Vectorized<acc_t>;
fVec acc_vec{acc_t(0)};
acc_t buffer[fVec::size()];
int64_t d = 0;
for (; d < size - (size % Vec::size()); d += Vec::size()) {
Vec data_vec = Vec::loadu(self_data + d);
norm_two_reduce_step(acc_vec, data_vec);
}
acc_vec.store(buffer);
for (int j = 1; j < fVec::size(); j++) {
buffer[0] = buffer[0] + buffer[j];
}
for (; d < size; d++) {
acc_t data_val = acc_t(self_data[d]);
buffer[0] += data_val * data_val;
}
result_data[0] = scalar_t(std::sqrt(buffer[0]));
});
});
} else {
if (iter.dtype(0) == kHalf) {
return norm_kernel_cpu_impl<at::Half, float>(iter, val);
} else if (iter.input_dtype() == kHalf && iter.dtype(0) == kFloat) {
// type promotion that does cast and reduction in a single kernel
return norm_kernel_cpu_impl<at::Half, float, float>(iter, val);
} else if(iter.dtype(0) == kBFloat16) {
return norm_kernel_cpu_impl<at::BFloat16, float>(iter, val);
} else if (iter.input_dtype() == kBFloat16 && iter.dtype(0) == kFloat) {
// type promotion that does cast and reduction in a single kernel
return norm_kernel_cpu_impl<at::BFloat16, float, float>(iter, val);
}
AT_DISPATCH_FLOATING_AND_COMPLEX_TYPES(iter.input_dtype(), "norm_cpu", [&] {
norm_kernel_cpu_impl<scalar_t>(iter, val);
});
// For complex outputs, the above kernels do not touch the imaginary values,
// so we must zero them out
if (isComplexType(iter.output().scalar_type())) {
at::imag(iter.output()).zero_();
}
}
}
static void and_kernel_impl(TensorIterator& iter) {
if (iter.dtype() == ScalarType::Byte) {
// Refer [all, any : uint8 compatibility]
binary_kernel_reduce_vec(
iter,
[=](uint8_t a, uint8_t b) -> uint8_t { return (a && b) ? 1 : 0; },
[=](Vectorized<uint8_t> a, Vectorized<uint8_t> b) {
// NB: != returns 0xFF rather than 0x01, so we must negate to get
// the desired result
return (a != Vectorized<uint8_t>(0)).neg() & (b != Vectorized<uint8_t>(0)).neg();
},
/*ident=*/true);
} else {
binary_kernel_reduce_vec(
iter,
[=](bool a, bool b) -> bool { return a && b; },
[=](Vectorized<bool> a, Vectorized<bool> b) {
// Adding the implementation here instead of in vec256_base to avoid
// return value inconsistency. Other comparison operators in
// vec256_base return -1/0 (all bit 1 / all bit 0) as true/false to
// follow the AVX2 convention. This would be convenient when combined
// with other vectorized operations. For example, one can use the
// logical operation results as a mask for a bit operation to
// retrieve/reset multiple elements in a vector.
//
// In this method, users would expect, e.g., all(), to return 1/0 as
// true/false.
Vectorized<bool> c = Vectorized<bool>();
for (decltype(c.size()) i = 0; i != Vectorized<bool>::size(); i++) {
c[i] = a[i] && b[i];
}
return c;
},
/*ident=*/true);
}
}
static void or_kernel_impl(TensorIterator& iter) {
if (iter.dtype() == ScalarType::Byte) {
// Refer [all, any : uint8 compatibility]
binary_kernel_reduce_vec(
iter,
[=](uint8_t a, uint8_t b) -> uint8_t { return (a || b) ? 1 : 0; },
[=](Vectorized<uint8_t> a, Vectorized<uint8_t> b) {
return (a != Vectorized<uint8_t>(0)).neg() | (b != Vectorized<uint8_t>(0)).neg();
},
/*ident=*/false);
} else {
binary_kernel_reduce_vec(
iter,
[=](bool a, bool b) -> bool { return a || b; },
[=](Vectorized<bool> a, Vectorized<bool> b) {
Vectorized<bool> c = Vectorized<bool>();
for (decltype(c.size()) i = 0; i != Vectorized<bool>::size(); i++) {
c[i] = a[i] || b[i];
}
return c;
},
/*ident=*/false);
}
}
template<typename scalar_t>
struct MinValuesOps: public at::native::MinOps<scalar_t> {
using arg_t = typename MinOps<scalar_t>::arg_t;
static scalar_t project(arg_t arg) {
return arg.first;
}
};
static void min_values_kernel_impl(TensorIterator& iter) {
if (iter.dtype() == kLong) {
// This case is special because of Vectorized<int64_t> does not
// handle upper_bound<int64_t>().
// See: https://github.com/pytorch/pytorch/issues/43254
using scalar_t = int64_t;
binary_kernel_reduce(
iter,
MinValuesOps<scalar_t>{},
std::pair<scalar_t, int64_t>(upper_bound<scalar_t>(), -1));
return;
}
AT_DISPATCH_ALL_TYPES_AND3(kBFloat16, kHalf, kBool, iter.dtype(), "min_values_cpu", [&iter] {
binary_kernel_reduce_vec(
iter,
[](scalar_t a, scalar_t b) -> scalar_t { return min_impl(a, b); },
[](Vectorized<scalar_t> a, Vectorized<scalar_t> b) { return minimum(a, b); },
static_cast<double>(upper_bound<scalar_t>()));
});
}
static void max_values_kernel_impl(TensorIterator& iter) {
AT_DISPATCH_ALL_TYPES_AND3(kBFloat16, kHalf, kBool, iter.dtype(), "max_values_cpu", [&iter] {
binary_kernel_reduce_vec(
iter,
[](scalar_t a, scalar_t b) -> scalar_t { return max_impl(a, b); },
[](Vectorized<scalar_t> a, Vectorized<scalar_t> b) { return maximum(a, b); },
lower_bound<scalar_t>());
});
}
static void argmax_kernel_impl(TensorIterator &iter) {
AT_DISPATCH_ALL_TYPES_AND2(kHalf, kBFloat16, iter.dtype(1), "argmax_cpu", [&] {
if (is_reduce_lastdim(iter)) {
using arg_t = std::pair<scalar_t, int64_t>;
auto op = ArgMaxOps<scalar_t>{};
binary_kernel_reduce_lastdim(iter, [&](char* result_data_bytes, char* self_data_bytes, int64_t size) {
int64_t* result_data = (int64_t*)result_data_bytes;
scalar_t* self_data = (scalar_t*)self_data_bytes;
arg_t acc = arg_t(lower_bound<scalar_t>(), 0);
for (int64_t i = 0; i < size; i++) {
acc = op.reduce(acc, self_data[i], i);
}
result_data[0] = acc.second;
});
return;
}
binary_kernel_reduce(
iter,
ArgMaxOps<scalar_t>{},
std::pair<scalar_t, int64_t>(lower_bound<scalar_t>(), 0));
});
}
static void argmin_kernel_impl(TensorIterator &iter) {
AT_DISPATCH_ALL_TYPES_AND2(kHalf, kBFloat16, iter.dtype(1), "argmin_cpu", [&] {
if (is_reduce_lastdim(iter)) {
using arg_t = std::pair<scalar_t, int64_t>;
auto op = ArgMinOps<scalar_t>{};
binary_kernel_reduce_lastdim(iter, [&](char* result_data_bytes, char* self_data_bytes, int64_t size) {
int64_t* result_data = (int64_t*)result_data_bytes;
scalar_t* self_data = (scalar_t*)self_data_bytes;
arg_t acc = arg_t(upper_bound<scalar_t>(), 0);
for (int64_t i = 0; i < size; i++) {
acc = op.reduce(acc, self_data[i], i);
}
result_data[0] = acc.second;
});
return;
}
binary_kernel_reduce(
iter,
ArgMinOps<scalar_t>{},
std::pair<scalar_t, int64_t>(upper_bound<scalar_t>(), 0));
});
}
} // anonymous namespace
REGISTER_DISPATCH(std_var_stub, &std_var_kernel_impl);
REGISTER_DISPATCH(prod_stub, &prod_kernel_impl);
// mean implementation for CPU is in aten/src/ATen/native/ReduceOps.cpp
// but mean_stub must be defined for CPU as well
REGISTER_DISPATCH(mean_stub, nullptr);
REGISTER_DISPATCH(norm_stub, &norm_kernel_tensor_iterator_impl);
REGISTER_DISPATCH(and_stub, &and_kernel_impl);
REGISTER_DISPATCH(or_stub, &or_kernel_impl);
REGISTER_DISPATCH(min_values_stub, &min_values_kernel_impl);
REGISTER_DISPATCH(max_values_stub, &max_values_kernel_impl);
REGISTER_DISPATCH(argmax_stub, &argmax_kernel_impl);
REGISTER_DISPATCH(argmin_stub, &argmin_kernel_impl);
REGISTER_DISPATCH(cumprod_stub, &cumprod_cpu_kernel);
REGISTER_DISPATCH(cumsum_stub, &cumsum_cpu_kernel);
REGISTER_DISPATCH(logcumsumexp_stub, &logcumsumexp_cpu_kernel);
} // namespace at::native