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

 #pragma once

 #include "ATen/core/Scalar.h"
 #include "ATen/Tensor.h"
 #include "ATen/Type.h"

 #include <string>
 #include <stdexcept>

 namespace at {

 inline Tensor & Tensor::operator=(Tensor const & rhs) && {
   return copy_(rhs);
 }
 inline Tensor & Tensor::operator=(Tensor && rhs) && {
   return copy_(rhs);
 }
 inline Tensor & Tensor::operator=(Scalar v) && {
   return fill_(v);
 }
 inline Tensor Tensor::operator-() const {
   return neg();
 }
 inline Tensor& Tensor::operator+=(const Tensor & other) {
   return add_(other);
 }
 inline Tensor& Tensor::operator+=(Scalar other) {
   return add_(other);
 }
 inline Tensor& Tensor::operator-=(const Tensor & other) {
   return sub_(other);
 }
 inline Tensor& Tensor::operator-=(Scalar other) {
   return sub_(other);
 }
 inline Tensor& Tensor::operator*=(const Tensor & other) {
   return mul_(other);
 }
 inline Tensor& Tensor::operator*=(Scalar other) {
   return mul_(other);
 }
 inline Tensor& Tensor::operator/=(const Tensor & other) {
   return div_(other);
 }
 inline Tensor& Tensor::operator/=(Scalar other) {
   return div_(other);
 }
 inline Tensor Tensor::operator[](Scalar index) const {
   AT_CHECK(
       index.isIntegral(),
       "Can only index tensors with integral scalars");
   return select(0, index.toLong());
 }
 inline Tensor Tensor::operator[](Tensor index) const {
   // These properties are checked in the Scalar constructor, but we already
   // check them here to provide more useful diagnostics for the user.
   AT_CHECK(index.defined(), "Can only index with tensors that are defined");
   AT_CHECK(
       index.dim() == 0,
       "Can only index with tensors that are scalars (zero-dim)");
   // The Scalar(Tensor) constructor is explicit, so we need to call it.
   return this->operator[](index._local_scalar());
 }
 inline Tensor Tensor::operator[](int64_t index) const {
   return select(0, index);
 }

 #define AT_FORALL_BINARY_OPS(_) \
 _(+,x.add(y), y.add(x)) \
 _(*,x.mul(y), y.mul(x)) \
 _(-,x.sub(y), ::at::empty(y.sizes(), y.options()).fill_(x).sub_(y)) \
 _(/,x.div(y), ::at::empty(y.sizes(), y.options()).fill_(x).div_(y)) \
 _(%,x.remainder(y), ::at::empty(y.sizes(), y.options()).fill_(x).remainder_(y)) \
 _(<,x.lt(y), y.gt(x)) \
 _(<=,x.le(y), y.ge(x)) \
 _(>,x.gt(y),y.lt(x)) \
 _(>=,x.ge(y), y.le(x)) \
 _(==,x.eq(y), y.eq(x)) \
 _(!=,x.ne(y), y.ne(x))

 #define DEFINE_OPERATOR(op,body,reverse_scalar_body) \
 static inline Tensor operator op(const Tensor & x, const Tensor & y) { \
   return body; \
 } \
 static inline Tensor operator op(const Tensor & x, Scalar y) { \
   return body; \
 } \
 static inline Tensor operator op(Scalar x, const Tensor & y) { \
   return reverse_scalar_body; \
 }


 AT_FORALL_BINARY_OPS(DEFINE_OPERATOR)
 #undef DEFINE_OPERATOR
 #undef AT_FORALL_BINARY_OPS

 }
	#pragma once

	#include "ATen/core/Scalar.h"
	#include "ATen/Tensor.h"
	#include "ATen/Type.h"

	#include <string>
	#include <stdexcept>

	namespace at {

	inline Tensor & Tensor::operator=(Tensor const & rhs) && {
	return copy_(rhs);
	}
	inline Tensor & Tensor::operator=(Tensor && rhs) && {
	return copy_(rhs);
	}
	inline Tensor & Tensor::operator=(Scalar v) && {
	return fill_(v);
	}
	inline Tensor Tensor::operator-() const {
	return neg();
	}
	inline Tensor& Tensor::operator+=(const Tensor & other) {
	return add_(other);
	}
	inline Tensor& Tensor::operator+=(Scalar other) {
	return add_(other);
	}
	inline Tensor& Tensor::operator-=(const Tensor & other) {
	return sub_(other);
	}
	inline Tensor& Tensor::operator-=(Scalar other) {
	return sub_(other);
	}
	inline Tensor& Tensor::operator*=(const Tensor & other) {
	return mul_(other);
	}
	inline Tensor& Tensor::operator*=(Scalar other) {
	return mul_(other);
	}
	inline Tensor& Tensor::operator/=(const Tensor & other) {
	return div_(other);
	}
	inline Tensor& Tensor::operator/=(Scalar other) {
	return div_(other);
	}
	inline Tensor Tensor::operator[](Scalar index) const {
	AT_CHECK(
	index.isIntegral(),
	"Can only index tensors with integral scalars");
	return select(0, index.toLong());
	}
	inline Tensor Tensor::operator[](Tensor index) const {
	// These properties are checked in the Scalar constructor, but we already
	// check them here to provide more useful diagnostics for the user.
	AT_CHECK(index.defined(), "Can only index with tensors that are defined");
	AT_CHECK(
	index.dim() == 0,
	"Can only index with tensors that are scalars (zero-dim)");
	// The Scalar(Tensor) constructor is explicit, so we need to call it.
	return this->operator[](index._local_scalar());
	}
	inline Tensor Tensor::operator[](int64_t index) const {
	return select(0, index);
	}

	#define AT_FORALL_BINARY_OPS(_) \
	_(+,x.add(y), y.add(x)) \
	_(*,x.mul(y), y.mul(x)) \
	_(-,x.sub(y), ::at::empty(y.sizes(), y.options()).fill_(x).sub_(y)) \
	_(/,x.div(y), ::at::empty(y.sizes(), y.options()).fill_(x).div_(y)) \
	_(%,x.remainder(y), ::at::empty(y.sizes(), y.options()).fill_(x).remainder_(y)) \
	_(<,x.lt(y), y.gt(x)) \
	_(<=,x.le(y), y.ge(x)) \
	_(>,x.gt(y),y.lt(x)) \
	_(>=,x.ge(y), y.le(x)) \
	_(==,x.eq(y), y.eq(x)) \
	_(!=,x.ne(y), y.ne(x))

	#define DEFINE_OPERATOR(op,body,reverse_scalar_body) \
	static inline Tensor operator op(const Tensor & x, const Tensor & y) { \
	return body; \
	} \
	static inline Tensor operator op(const Tensor & x, Scalar y) { \
	return body; \
	} \
	static inline Tensor operator op(Scalar x, const Tensor & y) { \
	return reverse_scalar_body; \
	}


	AT_FORALL_BINARY_OPS(DEFINE_OPERATOR)
	#undef DEFINE_OPERATOR
	#undef AT_FORALL_BINARY_OPS

	}