src/runtime/complex.go - go - Git at Google

 // Copyright 2010 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 runtime

 // inf2one returns a signed 1 if f is an infinity and a signed 0 otherwise.
 // The sign of the result is the sign of f.
 func inf2one(f float64) float64 {
 	g := 0.0
 	if isInf(f) {
 		g = 1.0
 	}
 	return copysign(g, f)
 }

 func complex128div(n complex128, m complex128) complex128 {
 	var e, f float64 // complex(e, f) = n/m

 	// Algorithm for robust complex division as described in
 	// Robert L. Smith: Algorithm 116: Complex division. Commun. ACM 5(8): 435 (1962).
 	if abs(real(m)) >= abs(imag(m)) {
 		ratio := imag(m) / real(m)
 		denom := real(m) + ratio*imag(m)
 		e = (real(n) + imag(n)*ratio) / denom
 		f = (imag(n) - real(n)*ratio) / denom
 	} else {
 		ratio := real(m) / imag(m)
 		denom := imag(m) + ratio*real(m)
 		e = (real(n)*ratio + imag(n)) / denom
 		f = (imag(n)*ratio - real(n)) / denom
 	}

 	if isNaN(e) && isNaN(f) {
 		// Correct final result to infinities and zeros if applicable.
 		// Matches C99: ISO/IEC 9899:1999 - G.5.1  Multiplicative operators.

 		a, b := real(n), imag(n)
 		c, d := real(m), imag(m)

 		switch {
 		case m == 0 && (!isNaN(a) || !isNaN(b)):
 			e = copysign(inf, c) * a
 			f = copysign(inf, c) * b

 		case (isInf(a) || isInf(b)) && isFinite(c) && isFinite(d):
 			a = inf2one(a)
 			b = inf2one(b)
 			e = inf * (a*c + b*d)
 			f = inf * (b*c - a*d)

 		case (isInf(c) || isInf(d)) && isFinite(a) && isFinite(b):
 			c = inf2one(c)
 			d = inf2one(d)
 			e = 0 * (a*c + b*d)
 			f = 0 * (b*c - a*d)
 		}
 	}

 	return complex(e, f)
 }
	// Copyright 2010 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 runtime

	// inf2one returns a signed 1 if f is an infinity and a signed 0 otherwise.
	// The sign of the result is the sign of f.
	func inf2one(f float64) float64 {
	g := 0.0
	if isInf(f) {
	g = 1.0
	}
	return copysign(g, f)
	}

	func complex128div(n complex128, m complex128) complex128 {
	var e, f float64 // complex(e, f) = n/m

	// Algorithm for robust complex division as described in
	// Robert L. Smith: Algorithm 116: Complex division. Commun. ACM 5(8): 435 (1962).
	if abs(real(m)) >= abs(imag(m)) {
	ratio := imag(m) / real(m)
	denom := real(m) + ratio*imag(m)
	e = (real(n) + imag(n)*ratio) / denom
	f = (imag(n) - real(n)*ratio) / denom
	} else {
	ratio := real(m) / imag(m)
	denom := imag(m) + ratio*real(m)
	e = (real(n)*ratio + imag(n)) / denom
	f = (imag(n)*ratio - real(n)) / denom
	}

	if isNaN(e) && isNaN(f) {
	// Correct final result to infinities and zeros if applicable.
	// Matches C99: ISO/IEC 9899:1999 - G.5.1 Multiplicative operators.

	a, b := real(n), imag(n)
	c, d := real(m), imag(m)

	switch {
	case m == 0 && (!isNaN(a) \|\| !isNaN(b)):
	e = copysign(inf, c) * a
	f = copysign(inf, c) * b

	case (isInf(a) \|\| isInf(b)) && isFinite(c) && isFinite(d):
	a = inf2one(a)
	b = inf2one(b)
	e = inf * (ac + bd)
	f = inf * (bc - ad)

	case (isInf(c) \|\| isInf(d)) && isFinite(a) && isFinite(b):
	c = inf2one(c)
	d = inf2one(d)
	e = 0 * (ac + bd)
	f = 0 * (bc - ad)
	}
	}

	return complex(e, f)
	}