go/src/runtime/softfloat64_test.go

// 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_test

import (
	"math"
	"math/rand"
	. "runtime"
	"testing"
)

// turn uint64 op into float64 op
func fop(f func(x, y uint64) uint64) func(x, y float64) float64 {
	return func(x, y float64) float64 {
		bx := math.Float64bits(x)
		by := math.Float64bits(y)
		return math.Float64frombits(f(bx, by))
	}
}

func add(x, y float64) float64 { return x + y }
func sub(x, y float64) float64 { return x - y }
func mul(x, y float64) float64 { return x * y }
func div(x, y float64) float64 { return x / y }

func TestFloat64(t *testing.T) {
	base := []float64{
		0,
		math.Copysign(0, -1),
		-1,
		1,
		math.NaN(),
		math.Inf(+1),
		math.Inf(-1),
		0.1,
		1.5,
		1.9999999999999998,     // all 1s mantissa
		1.3333333333333333,     // 1.010101010101...
		1.1428571428571428,     // 1.001001001001...
		1.112536929253601e-308, // first normal
		2,
		4,
		8,
		16,
		32,
		64,
		128,
		256,
		3,
		12,
		1234,
		123456,
		-0.1,
		-1.5,
		-1.9999999999999998,
		-1.3333333333333333,
		-1.1428571428571428,
		-2,
		-3,
		1e-200,
		1e-300,
		1e-310,
		5e-324,
		1e-105,
		1e-305,
		1e+200,
		1e+306,
		1e+307,
		1e+308,
	}
	all := make([]float64, 200)
	copy(all, base)
	for i := len(base); i < len(all); i++ {
		all[i] = rand.NormFloat64()
	}

	test(t, "+", add, fop(Fadd64), all)
	test(t, "-", sub, fop(Fsub64), all)
	if GOARCH != "386" { // 386 is not precise!
		test(t, "*", mul, fop(Fmul64), all)
		test(t, "/", div, fop(Fdiv64), all)
	}
}

// 64 -hw-> 32 -hw-> 64
func trunc32(f float64) float64 {
	return float64(float32(f))
}

// 64 -sw->32 -hw-> 64
func to32sw(f float64) float64 {
	return float64(math.Float32frombits(F64to32(math.Float64bits(f))))
}

// 64 -hw->32 -sw-> 64
func to64sw(f float64) float64 {
	return math.Float64frombits(F32to64(math.Float32bits(float32(f))))
}

// float64 -hw-> int64 -hw-> float64
func hwint64(f float64) float64 {
	return float64(int64(f))
}

// float64 -hw-> int32 -hw-> float64
func hwint32(f float64) float64 {
	return float64(int32(f))
}

// float64 -sw-> int64 -hw-> float64
func toint64sw(f float64) float64 {
	i, ok := F64toint(math.Float64bits(f))
	if !ok {
		// There's no right answer for out of range.
		// Match the hardware to pass the test.
		i = int64(f)
	}
	return float64(i)
}

// float64 -hw-> int64 -sw-> float64
func fromint64sw(f float64) float64 {
	return math.Float64frombits(Fintto64(int64(f)))
}

var nerr int

func err(t *testing.T, format string, args ...interface{}) {
	t.Errorf(format, args...)

	// cut errors off after a while.
	// otherwise we spend all our time
	// allocating memory to hold the
	// formatted output.
	if nerr++; nerr >= 10 {
		t.Fatal("too many errors")
	}
}

func test(t *testing.T, op string, hw, sw func(float64, float64) float64, all []float64) {
	for _, f := range all {
		for _, g := range all {
			h := hw(f, g)
			s := sw(f, g)
			if !same(h, s) {
				err(t, "%g %s %g = sw %g, hw %g\n", f, op, g, s, h)
			}
			testu(t, "to32", trunc32, to32sw, h)
			testu(t, "to64", trunc32, to64sw, h)
			testu(t, "toint64", hwint64, toint64sw, h)
			testu(t, "fromint64", hwint64, fromint64sw, h)
			testcmp(t, f, h)
			testcmp(t, h, f)
			testcmp(t, g, h)
			testcmp(t, h, g)
		}
	}
}

func testu(t *testing.T, op string, hw, sw func(float64) float64, v float64) {
	h := hw(v)
	s := sw(v)
	if !same(h, s) {
		err(t, "%s %g = sw %g, hw %g\n", op, v, s, h)
	}
}

func hwcmp(f, g float64) (cmp int, isnan bool) {
	switch {
	case f < g:
		return -1, false
	case f > g:
		return +1, false
	case f == g:
		return 0, false
	}
	return 0, true // must be NaN
}

func testcmp(t *testing.T, f, g float64) {
	hcmp, hisnan := hwcmp(f, g)
	scmp, sisnan := Fcmp64(math.Float64bits(f), math.Float64bits(g))
	if int32(hcmp) != scmp || hisnan != sisnan {
		err(t, "cmp(%g, %g) = sw %v, %v, hw %v, %v\n", f, g, scmp, sisnan, hcmp, hisnan)
	}
}

func same(f, g float64) bool {
	if math.IsNaN(f) && math.IsNaN(g) {
		return true
	}
	if math.Copysign(1, f) != math.Copysign(1, g) {
		return false
	}
	return f == g
}
all: make copyright headers consistent with one space after period This is a subset of https://golang.org/cl/20022 with only the copyright header lines, so the next CL will be smaller and more reviewable. Go policy has been single space after periods in comments for some time. The copyright header template at: https://golang.org/doc/contribute.html#copyright also uses a single space. Make them all consistent. Change-Id: Icc26c6b8495c3820da6b171ca96a74701b4a01b0 Reviewed-on: https://go-review.googlesource.com/20111 Run-TryBot: Brad Fitzpatrick <bradfitz@golang.org> Reviewed-by: Ian Lance Taylor <iant@golang.org> Reviewed-by: Matthew Dempsky <mdempsky@google.com> TryBot-Result: Gobot Gobot <gobot@golang.org> 2016-03-01 15:57:46 -07:00			`// Copyright 2010 The Go Authors. All rights reserved.`
arm: precise float64 software floating point Adds softfloat64 to generic runtime (will be discarded by linker when unused) and adds test for it. I used the test to check the software code against amd64 hardware and then check the software code against the arm and its simulation of hardware. The latter should have been a no-op (testing against itself) but turned up a bug in 5c causing the vlrt.c routines to miscompile. These changes make the cmath, math, and strconv tests pass without any special accommodations for arm. R=ken2 CC=golang-dev https://golang.org/cl/2713042 2010-10-25 18:55:50 -06:00			`// Use of this source code is governed by a BSD-style`
			`// license that can be found in the LICENSE file.`

			`package runtime_test`

			`import (`
			`"math"`
renaming_3: gofix -r go1pkgrename src/pkg/[m-z]* R=rsc CC=golang-dev https://golang.org/cl/5345045 2011-11-08 16:41:54 -07:00			`"math/rand"`
arm: precise float64 software floating point Adds softfloat64 to generic runtime (will be discarded by linker when unused) and adds test for it. I used the test to check the software code against amd64 hardware and then check the software code against the arm and its simulation of hardware. The latter should have been a no-op (testing against itself) but turned up a bug in 5c causing the vlrt.c routines to miscompile. These changes make the cmath, math, and strconv tests pass without any special accommodations for arm. R=ken2 CC=golang-dev https://golang.org/cl/2713042 2010-10-25 18:55:50 -06:00			`. "runtime"`
			`"testing"`
			`)`

			`// turn uint64 op into float64 op`
			`func fop(f func(x, y uint64) uint64) func(x, y float64) float64 {`
			`return func(x, y float64) float64 {`
			`bx := math.Float64bits(x)`
			`by := math.Float64bits(y)`
			`return math.Float64frombits(f(bx, by))`
			`}`
			`}`

			`func add(x, y float64) float64 { return x + y }`
			`func sub(x, y float64) float64 { return x - y }`
			`func mul(x, y float64) float64 { return x * y }`
			`func div(x, y float64) float64 { return x / y }`

			`func TestFloat64(t *testing.T) {`
			`base := []float64{`
			`0,`
			`math.Copysign(0, -1),`
			`-1,`
			`1,`
			`math.NaN(),`
			`math.Inf(+1),`
			`math.Inf(-1),`
			`0.1,`
			`1.5,`
			`1.9999999999999998, // all 1s mantissa`
			`1.3333333333333333, // 1.010101010101...`
			`1.1428571428571428, // 1.001001001001...`
			`1.112536929253601e-308, // first normal`
			`2,`
			`4,`
			`8,`
			`16,`
			`32,`
			`64,`
			`128,`
			`256,`
			`3,`
			`12,`
			`1234,`
			`123456,`
			`-0.1,`
			`-1.5,`
			`-1.9999999999999998,`
			`-1.3333333333333333,`
			`-1.1428571428571428,`
			`-2,`
			`-3,`
			`1e-200,`
			`1e-300,`
			`1e-310,`
			`5e-324,`
			`1e-105,`
			`1e-305,`
			`1e+200,`
			`1e+306,`
			`1e+307,`
			`1e+308,`
			`}`
			`all := make([]float64, 200)`
			`copy(all, base)`
			`for i := len(base); i < len(all); i++ {`
			`all[i] = rand.NormFloat64()`
			`}`

			`test(t, "+", add, fop(Fadd64), all)`
			`test(t, "-", sub, fop(Fsub64), all)`
			`if GOARCH != "386" { // 386 is not precise!`
			`test(t, "*", mul, fop(Fmul64), all)`
			`test(t, "/", div, fop(Fdiv64), all)`
			`}`
			`}`

			`// 64 -hw-> 32 -hw-> 64`
			`func trunc32(f float64) float64 {`
			`return float64(float32(f))`
			`}`

			`// 64 -sw->32 -hw-> 64`
			`func to32sw(f float64) float64 {`
			`return float64(math.Float32frombits(F64to32(math.Float64bits(f))))`
			`}`

			`// 64 -hw->32 -sw-> 64`
			`func to64sw(f float64) float64 {`
			`return math.Float64frombits(F32to64(math.Float32bits(float32(f))))`
			`}`

			`// float64 -hw-> int64 -hw-> float64`
			`func hwint64(f float64) float64 {`
			`return float64(int64(f))`
			`}`

			`// float64 -hw-> int32 -hw-> float64`
			`func hwint32(f float64) float64 {`
			`return float64(int32(f))`
			`}`

			`// float64 -sw-> int64 -hw-> float64`
			`func toint64sw(f float64) float64 {`
			`i, ok := F64toint(math.Float64bits(f))`
			`if !ok {`
			`// There's no right answer for out of range.`
			`// Match the hardware to pass the test.`
			`i = int64(f)`
			`}`
			`return float64(i)`
			`}`

			`// float64 -hw-> int64 -sw-> float64`
			`func fromint64sw(f float64) float64 {`
			`return math.Float64frombits(Fintto64(int64(f)))`
			`}`

			`var nerr int`

			`func err(t *testing.T, format string, args ...interface{}) {`
			`t.Errorf(format, args...)`

			`// cut errors off after a while.`
			`// otherwise we spend all our time`
			`// allocating memory to hold the`
			`// formatted output.`
			`if nerr++; nerr >= 10 {`
			`t.Fatal("too many errors")`
			`}`
			`}`

			`func test(t *testing.T, op string, hw, sw func(float64, float64) float64, all []float64) {`
			`for _, f := range all {`
			`for _, g := range all {`
			`h := hw(f, g)`
			`s := sw(f, g)`
			`if !same(h, s) {`
			`err(t, "%g %s %g = sw %g, hw %g\n", f, op, g, s, h)`
			`}`
			`testu(t, "to32", trunc32, to32sw, h)`
			`testu(t, "to64", trunc32, to64sw, h)`
			`testu(t, "toint64", hwint64, toint64sw, h)`
			`testu(t, "fromint64", hwint64, fromint64sw, h)`
			`testcmp(t, f, h)`
			`testcmp(t, h, f)`
			`testcmp(t, g, h)`
			`testcmp(t, h, g)`
			`}`
			`}`
			`}`

			`func testu(t *testing.T, op string, hw, sw func(float64) float64, v float64) {`
			`h := hw(v)`
			`s := sw(v)`
			`if !same(h, s) {`
			`err(t, "%s %g = sw %g, hw %g\n", op, v, s, h)`
			`}`
			`}`

			`func hwcmp(f, g float64) (cmp int, isnan bool) {`
			`switch {`
			`case f < g:`
			`return -1, false`
			`case f > g:`
			`return +1, false`
			`case f == g:`
			`return 0, false`
			`}`
			`return 0, true // must be NaN`
			`}`

			`func testcmp(t *testing.T, f, g float64) {`
			`hcmp, hisnan := hwcmp(f, g)`
			`scmp, sisnan := Fcmp64(math.Float64bits(f), math.Float64bits(g))`
[dev.cc] runtime: convert softfloat_arm.c to Go + build fixes Also include onM_signalok fix from issue 8995. Fixes linux/arm build. Fixes #8995. LGTM=r R=r, dave CC=golang-codereviews https://golang.org/cl/168580043 2014-11-11 20:30:02 -07:00			`if int32(hcmp) != scmp \|\| hisnan != sisnan {`
arm: precise float64 software floating point Adds softfloat64 to generic runtime (will be discarded by linker when unused) and adds test for it. I used the test to check the software code against amd64 hardware and then check the software code against the arm and its simulation of hardware. The latter should have been a no-op (testing against itself) but turned up a bug in 5c causing the vlrt.c routines to miscompile. These changes make the cmath, math, and strconv tests pass without any special accommodations for arm. R=ken2 CC=golang-dev https://golang.org/cl/2713042 2010-10-25 18:55:50 -06:00			`err(t, "cmp(%g, %g) = sw %v, %v, hw %v, %v\n", f, g, scmp, sisnan, hcmp, hisnan)`
			`}`
			`}`

			`func same(f, g float64) bool {`
			`if math.IsNaN(f) && math.IsNaN(g) {`
			`return true`
			`}`
			`if math.Copysign(1, f) != math.Copysign(1, g) {`
			`return false`
			`}`
			`return f == g`
			`}`