test/typeparam/absdiffimp.dir/a.go - go - Git at Google

 // Copyright 2021 The Go Authors. All rights reserved.
 // Use of this source code is governed by a BSD-style
 // license that can be found in the LICENSE file.

 package a

 type Numeric interface {
 	~int | ~int8 | ~int16 | ~int32 | ~int64 |
 		~uint | ~uint8 | ~uint16 | ~uint32 | ~uint64 | ~uintptr |
 		~float32 | ~float64 |
 		~complex64 | ~complex128
 }

 // numericAbs matches numeric types with an Abs method.
 type numericAbs[T any] interface {
 	Numeric
 	Abs() T
 }

 // AbsDifference computes the absolute value of the difference of
 // a and b, where the absolute value is determined by the Abs method.
 func absDifference[T numericAbs[T]](a, b T) T {
 	d := a - b
 	return d.Abs()
 }

 // orderedNumeric matches numeric types that support the < operator.
 type orderedNumeric interface {
 	~int | ~int8 | ~int16 | ~int32 | ~int64 |
 		~uint | ~uint8 | ~uint16 | ~uint32 | ~uint64 | ~uintptr |
 		~float32 | ~float64
 }

 // Complex matches the two complex types, which do not have a < operator.
 type Complex interface {
 	~complex64 | ~complex128
 }

 // For now, a lone type parameter is not permitted as RHS in a type declaration (issue #45639).
 // // orderedAbs is a helper type that defines an Abs method for
 // // ordered numeric types.
 // type orderedAbs[T orderedNumeric] T
 //
 // func (a orderedAbs[T]) Abs() orderedAbs[T] {
 // 	if a < 0 {
 // 		return -a
 // 	}
 // 	return a
 // }
 //
 // // complexAbs is a helper type that defines an Abs method for
 // // complex types.
 // type complexAbs[T Complex] T
 //
 // func (a complexAbs[T]) Abs() complexAbs[T] {
 // 	r := float64(real(a))
 // 	i := float64(imag(a))
 // 	d := math.Sqrt(r*r + i*i)
 // 	return complexAbs[T](complex(d, 0))
 // }
 //
 // // OrderedAbsDifference returns the absolute value of the difference
 // // between a and b, where a and b are of an ordered type.
 // func OrderedAbsDifference[T orderedNumeric](a, b T) T {
 // 	return T(absDifference(orderedAbs[T](a), orderedAbs[T](b)))
 // }
 //
 // // ComplexAbsDifference returns the absolute value of the difference
 // // between a and b, where a and b are of a complex type.
 // func ComplexAbsDifference[T Complex](a, b T) T {
 // 	return T(absDifference(complexAbs[T](a), complexAbs[T](b)))
 // }
	// Copyright 2021 The Go Authors. All rights reserved.
	// Use of this source code is governed by a BSD-style
	// license that can be found in the LICENSE file.

	package a

	type Numeric interface {
	~int \| ~int8 \| ~int16 \| ~int32 \| ~int64 \|
	~uint \| ~uint8 \| ~uint16 \| ~uint32 \| ~uint64 \| ~uintptr \|
	~float32 \| ~float64 \|
	~complex64 \| ~complex128
	}

	// numericAbs matches numeric types with an Abs method.
	type numericAbs[T any] interface {
	Numeric
	Abs() T
	}

	// AbsDifference computes the absolute value of the difference of
	// a and b, where the absolute value is determined by the Abs method.
	func absDifference[T numericAbs[T]](a, b T) T {
	d := a - b
	return d.Abs()
	}

	// orderedNumeric matches numeric types that support the < operator.
	type orderedNumeric interface {
	~int \| ~int8 \| ~int16 \| ~int32 \| ~int64 \|
	~uint \| ~uint8 \| ~uint16 \| ~uint32 \| ~uint64 \| ~uintptr \|
	~float32 \| ~float64
	}

	// Complex matches the two complex types, which do not have a < operator.
	type Complex interface {
	~complex64 \| ~complex128
	}

	// For now, a lone type parameter is not permitted as RHS in a type declaration (issue #45639).
	// // orderedAbs is a helper type that defines an Abs method for
	// // ordered numeric types.
	// type orderedAbs[T orderedNumeric] T
	//
	// func (a orderedAbs[T]) Abs() orderedAbs[T] {
	// if a < 0 {
	// return -a
	// }
	// return a
	// }
	//
	// // complexAbs is a helper type that defines an Abs method for
	// // complex types.
	// type complexAbs[T Complex] T
	//
	// func (a complexAbs[T]) Abs() complexAbs[T] {
	// r := float64(real(a))
	// i := float64(imag(a))
	// d := math.Sqrt(rr + ii)
	// return complexAbs[T](complex(d, 0))
	// }
	//
	// // OrderedAbsDifference returns the absolute value of the difference
	// // between a and b, where a and b are of an ordered type.
	// func OrderedAbsDifference[T orderedNumeric](a, b T) T {
	// return T(absDifference(orderedAbs[T](a), orderedAbs[T](b)))
	// }
	//
	// // ComplexAbsDifference returns the absolute value of the difference
	// // between a and b, where a and b are of a complex type.
	// func ComplexAbsDifference[T Complex](a, b T) T {
	// return T(absDifference(complexAbs[T](a), complexAbs[T](b)))
	// }