aten/src/ATen/native/BinaryOps.h - platform/external/pytorch - Git at Google

 #pragma once

 #include <ATen/ATen.h>
 #include <ATen/native/DispatchStub.h>

 namespace at { struct TensorIterator; }

 namespace at { namespace native {

 inline void alpha_check(const ScalarType dtype, const Scalar& alpha) {
   TORCH_CHECK(! alpha.isBoolean() || dtype == ScalarType::Bool,
               "Boolean alpha only supported for Boolean results.");
   TORCH_CHECK(isFloatingType(dtype) || isComplexType(dtype)
               || alpha.isIntegral(true),
               "For integral input tensors, argument alpha must not be a floating point number.");
   TORCH_CHECK(isComplexType(dtype) || !alpha.isComplex(),
               "For non-complex input tensors, argument alpha must not be a complex number.")
 }

 // Basic checking for all sub functions.
 inline void sub_check(const Tensor& self, const Tensor& other) {
   TORCH_CHECK(self.scalar_type() != kBool || other.scalar_type() != kBool,
               "Subtraction, the `-` operator, with two bool tensors is not supported. "
               "Use the `^` or `logical_xor()` operator instead.")
   TORCH_CHECK(self.scalar_type() != kBool && other.scalar_type() != kBool,
               "Subtraction, the `-` operator, with a bool tensor is not supported. "
               "If you are trying to invert a mask, use the `~` or `logical_not()` operator instead.");
 }

 inline void sub_check(const Tensor& self, const Scalar& scalar) {
   TORCH_CHECK(self.scalar_type() != kBool || !scalar.isBoolean(),
               "Subtraction, the `-` operator, with two bool tensors is not supported."
               "Use the `^` or `logical_xor()` operator instead.")
   TORCH_CHECK(self.scalar_type() != kBool && !scalar.isBoolean(),
               "Subtraction, the `-` operator, with a bool tensor is not supported. "
               "If you are trying to invert a mask, use the `~` or `logical_not()` operator instead.");
 }

 using structured_binary_fn_alpha = void(*)(TensorIteratorBase&, const Scalar& alpha);
 using structured_binary_fn = void(*)(TensorIteratorBase&);

 using binary_fn_alpha = void(*)(TensorIterator&, const Scalar& alpha);
 using binary_fn_double = void(*)(TensorIterator&, double);
 using binary_fn = void(*)(TensorIterator&);
 using binary_clamp_fn_alpha =
     void(*)(TensorIterator&, const Scalar& alpha, const Scalar& min_val, const Scalar& max_val);

 DECLARE_DISPATCH(structured_binary_fn_alpha, add_stub);
 DECLARE_DISPATCH(binary_clamp_fn_alpha, add_clamp_stub);
 DECLARE_DISPATCH(structured_binary_fn_alpha, sub_stub);
 DECLARE_DISPATCH(structured_binary_fn, mul_stub);
 DECLARE_DISPATCH(structured_binary_fn, div_true_stub);
 DECLARE_DISPATCH(structured_binary_fn, div_floor_stub);
 DECLARE_DISPATCH(structured_binary_fn, div_trunc_stub);
 DECLARE_DISPATCH(structured_binary_fn, atan2_stub);
 DECLARE_DISPATCH(binary_fn, remainder_stub);
 DECLARE_DISPATCH(binary_fn, bitwise_and_stub);
 DECLARE_DISPATCH(binary_fn, bitwise_or_stub);
 DECLARE_DISPATCH(binary_fn, bitwise_xor_stub);
 DECLARE_DISPATCH(binary_fn, lshift_stub);
 DECLARE_DISPATCH(binary_fn, rshift_stub);
 DECLARE_DISPATCH(binary_fn, logical_xor_stub);
 DECLARE_DISPATCH(binary_fn, logical_and_stub);
 DECLARE_DISPATCH(binary_fn, logical_or_stub);
 DECLARE_DISPATCH(binary_fn, lt_stub);
 DECLARE_DISPATCH(binary_fn, le_stub);
 DECLARE_DISPATCH(binary_fn, gt_stub);
 DECLARE_DISPATCH(binary_fn, ge_stub);
 DECLARE_DISPATCH(binary_fn, eq_stub);
 DECLARE_DISPATCH(binary_fn, ne_stub);
 DECLARE_DISPATCH(binary_fn, max_elementwise_stub);
 DECLARE_DISPATCH(binary_fn, min_elementwise_stub);
 DECLARE_DISPATCH(binary_fn, maximum_stub);
 DECLARE_DISPATCH(binary_fn, minimum_stub);
 DECLARE_DISPATCH(binary_fn, fmax_stub);
 DECLARE_DISPATCH(binary_fn, fmin_stub);
 DECLARE_DISPATCH(binary_fn_double, smooth_l1_stub);
 DECLARE_DISPATCH(binary_fn_double, huber_stub);
 DECLARE_DISPATCH(binary_fn, sigmoid_backward_stub);
 DECLARE_DISPATCH(binary_fn_alpha, logit_backward_stub);
 DECLARE_DISPATCH(binary_fn, tanh_backward_stub);
 DECLARE_DISPATCH(binary_fn, mse_stub);
 DECLARE_DISPATCH(binary_fn, fmod_stub);
 DECLARE_DISPATCH(binary_fn, logaddexp_stub);
 DECLARE_DISPATCH(binary_fn, logaddexp2_stub);
 DECLARE_DISPATCH(binary_fn, gcd_stub);
 DECLARE_DISPATCH(binary_fn, lcm_stub);
 DECLARE_DISPATCH(binary_fn, hypot_stub);
 DECLARE_DISPATCH(binary_fn, igamma_stub);
 DECLARE_DISPATCH(binary_fn, igammac_stub);
 DECLARE_DISPATCH(binary_fn, nextafter_stub);
 DECLARE_DISPATCH(binary_fn, heaviside_stub);
 DECLARE_DISPATCH(structured_binary_fn, copysign_stub);
 DECLARE_DISPATCH(binary_fn, xlogy_stub);

 }} // namespace at::native
	#pragma once

	#include <ATen/ATen.h>
	#include <ATen/native/DispatchStub.h>

	namespace at { struct TensorIterator; }

	namespace at { namespace native {

	inline void alpha_check(const ScalarType dtype, const Scalar& alpha) {
	TORCH_CHECK(! alpha.isBoolean() \|\| dtype == ScalarType::Bool,
	"Boolean alpha only supported for Boolean results.");
	TORCH_CHECK(isFloatingType(dtype) \|\| isComplexType(dtype)
	\|\| alpha.isIntegral(true),
	"For integral input tensors, argument alpha must not be a floating point number.");
	TORCH_CHECK(isComplexType(dtype) \|\| !alpha.isComplex(),
	"For non-complex input tensors, argument alpha must not be a complex number.")
	}

	// Basic checking for all sub functions.
	inline void sub_check(const Tensor& self, const Tensor& other) {
	TORCH_CHECK(self.scalar_type() != kBool \|\| other.scalar_type() != kBool,
	"Subtraction, the `-` operator, with two bool tensors is not supported. "
	"Use the `^` or `logical_xor()` operator instead.")
	TORCH_CHECK(self.scalar_type() != kBool && other.scalar_type() != kBool,
	"Subtraction, the `-` operator, with a bool tensor is not supported. "
	"If you are trying to invert a mask, use the `~` or `logical_not()` operator instead.");
	}

	inline void sub_check(const Tensor& self, const Scalar& scalar) {
	TORCH_CHECK(self.scalar_type() != kBool \|\| !scalar.isBoolean(),
	"Subtraction, the `-` operator, with two bool tensors is not supported."
	"Use the `^` or `logical_xor()` operator instead.")
	TORCH_CHECK(self.scalar_type() != kBool && !scalar.isBoolean(),
	"Subtraction, the `-` operator, with a bool tensor is not supported. "
	"If you are trying to invert a mask, use the `~` or `logical_not()` operator instead.");
	}

	using structured_binary_fn_alpha = void(*)(TensorIteratorBase&, const Scalar& alpha);
	using structured_binary_fn = void(*)(TensorIteratorBase&);

	using binary_fn_alpha = void(*)(TensorIterator&, const Scalar& alpha);
	using binary_fn_double = void(*)(TensorIterator&, double);
	using binary_fn = void(*)(TensorIterator&);
	using binary_clamp_fn_alpha =
	void(*)(TensorIterator&, const Scalar& alpha, const Scalar& min_val, const Scalar& max_val);

	DECLARE_DISPATCH(structured_binary_fn_alpha, add_stub);
	DECLARE_DISPATCH(binary_clamp_fn_alpha, add_clamp_stub);
	DECLARE_DISPATCH(structured_binary_fn_alpha, sub_stub);
	DECLARE_DISPATCH(structured_binary_fn, mul_stub);
	DECLARE_DISPATCH(structured_binary_fn, div_true_stub);
	DECLARE_DISPATCH(structured_binary_fn, div_floor_stub);
	DECLARE_DISPATCH(structured_binary_fn, div_trunc_stub);
	DECLARE_DISPATCH(structured_binary_fn, atan2_stub);
	DECLARE_DISPATCH(binary_fn, remainder_stub);
	DECLARE_DISPATCH(binary_fn, bitwise_and_stub);
	DECLARE_DISPATCH(binary_fn, bitwise_or_stub);
	DECLARE_DISPATCH(binary_fn, bitwise_xor_stub);
	DECLARE_DISPATCH(binary_fn, lshift_stub);
	DECLARE_DISPATCH(binary_fn, rshift_stub);
	DECLARE_DISPATCH(binary_fn, logical_xor_stub);
	DECLARE_DISPATCH(binary_fn, logical_and_stub);
	DECLARE_DISPATCH(binary_fn, logical_or_stub);
	DECLARE_DISPATCH(binary_fn, lt_stub);
	DECLARE_DISPATCH(binary_fn, le_stub);
	DECLARE_DISPATCH(binary_fn, gt_stub);
	DECLARE_DISPATCH(binary_fn, ge_stub);
	DECLARE_DISPATCH(binary_fn, eq_stub);
	DECLARE_DISPATCH(binary_fn, ne_stub);
	DECLARE_DISPATCH(binary_fn, max_elementwise_stub);
	DECLARE_DISPATCH(binary_fn, min_elementwise_stub);
	DECLARE_DISPATCH(binary_fn, maximum_stub);
	DECLARE_DISPATCH(binary_fn, minimum_stub);
	DECLARE_DISPATCH(binary_fn, fmax_stub);
	DECLARE_DISPATCH(binary_fn, fmin_stub);
	DECLARE_DISPATCH(binary_fn_double, smooth_l1_stub);
	DECLARE_DISPATCH(binary_fn_double, huber_stub);
	DECLARE_DISPATCH(binary_fn, sigmoid_backward_stub);
	DECLARE_DISPATCH(binary_fn_alpha, logit_backward_stub);
	DECLARE_DISPATCH(binary_fn, tanh_backward_stub);
	DECLARE_DISPATCH(binary_fn, mse_stub);
	DECLARE_DISPATCH(binary_fn, fmod_stub);
	DECLARE_DISPATCH(binary_fn, logaddexp_stub);
	DECLARE_DISPATCH(binary_fn, logaddexp2_stub);
	DECLARE_DISPATCH(binary_fn, gcd_stub);
	DECLARE_DISPATCH(binary_fn, lcm_stub);
	DECLARE_DISPATCH(binary_fn, hypot_stub);
	DECLARE_DISPATCH(binary_fn, igamma_stub);
	DECLARE_DISPATCH(binary_fn, igammac_stub);
	DECLARE_DISPATCH(binary_fn, nextafter_stub);
	DECLARE_DISPATCH(binary_fn, heaviside_stub);
	DECLARE_DISPATCH(structured_binary_fn, copysign_stub);
	DECLARE_DISPATCH(binary_fn, xlogy_stub);

	}} // namespace at::native