math/big: remove Float.Round (not needed anymore), fix a bug in SetInt64

TBR adonovan Change-Id: I30020f39be9183b37275e10a4fd1e1a3b4c48c89 Reviewed-on: https://go-review.googlesource.com/4880 Reviewed-by: Robert Griesemer <gri@golang.org>
2024-09-30 17:28:32 -06:00 · 2015-02-13 16:30:21 -08:00 · 2015-02-13 16:30:21 -08:00 · 2e3c738649
commit 2e3c738649
parent df218d3393
2 changed files with 52 additions and 25 deletions
--- a/src/math/big/float.go
+++ b/src/math/big/float.go
@ -147,6 +147,7 @@ func (mode RoundingMode) String() string {
 // cannot be represented in prec bits without loss of precision.
 func (z *Float) SetPrec(prec uint) *Float {
 	old := z.prec
+	z.acc = Exact
 	z.prec = prec
 	if prec < old {
 		z.round(0)
@ -154,9 +155,10 @@ func (z *Float) SetPrec(prec uint) *Float {
 	return z
 }

-// SetMode sets z's rounding mode to mode and returns z.
+// SetMode sets z's rounding mode to mode and returns an exact z.
 // z remains unchanged otherwise.
 func (z *Float) SetMode(mode RoundingMode) *Float {
+	z.acc = Exact
 	z.mode = mode
 	return z
 }
@ -436,16 +438,6 @@ func (z *Float) round(sbit uint) {
 	return
 }

-// Round sets z to the value of x rounded according to mode to prec bits and returns z.
-// TODO(gri) rethink this signature.
-func (z *Float) Round(x *Float, prec uint, mode RoundingMode) *Float {
-	z.Copy(x)
-	z.prec = prec
-	z.mode = mode
-	z.round(0)
-	return z
-}
-
 // nlz returns the number of leading zero bits in x.
 func nlz(x Word) uint {
 	return _W - uint(bitLen(x))
@ -465,15 +457,12 @@ func nlz64(x uint64) uint {
 	panic("unreachable")
 }

-// SetUint64 sets z to the (possibly rounded) value of x and returns z.
-// If z's precision is 0, it is changed to 64 (and rounding will have
-// no effect).
-func (z *Float) SetUint64(x uint64) *Float {
+func (z *Float) setBits64(neg bool, x uint64) *Float {
 	if z.prec == 0 {
 		z.prec = 64
 	}
 	z.acc = Exact
-	z.neg = false
+	z.neg = neg
 	if x == 0 {
 		z.mant = z.mant[:0]
 		z.exp = 0
@ -489,6 +478,13 @@ func (z *Float) SetUint64(x uint64) *Float {
 	return z
 }

+// SetUint64 sets z to the (possibly rounded) value of x and returns z.
+// If z's precision is 0, it is changed to 64 (and rounding will have
+// no effect).
+func (z *Float) SetUint64(x uint64) *Float {
+	return z.setBits64(false, x)
+}
+
 // SetInt64 sets z to the (possibly rounded) value of x and returns z.
 // If z's precision is 0, it is changed to 64 (and rounding will have
 // no effect).
@ -497,9 +493,9 @@ func (z *Float) SetInt64(x int64) *Float {
 	if u < 0 {
 		u = -u
 	}
-	z.SetUint64(uint64(u))
-	z.neg = x < 0
-	return z
+	// We cannot simply call z.SetUint64(uint64(u)) and change
+	// the sign afterwards because the sign affects rounding.
+	return z.setBits64(x < 0, uint64(u))
 }

 // SetFloat64 sets z to the (possibly rounded) value of x and returns z.
@ -599,6 +595,7 @@ func (z *Float) SetRat(x *Rat) *Float {
 // mode; and z's accuracy reports the result error relative to the
 // exact (not rounded) result.
 func (z *Float) Set(x *Float) *Float {
+	// TODO(gri) what about z.acc? should it be always Exact?
 	if z != x {
 		if z.prec == 0 {
 			z.prec = x.prec
@ -617,6 +614,7 @@ func (z *Float) Set(x *Float) *Float {
 // Copy sets z to x, with the same precision and rounding mode as x,
 // and returns z.
 func (z *Float) Copy(x *Float) *Float {
+	// TODO(gri) what about z.acc? should it be always Exact?
 	if z != x {
 		z.acc = Exact
 		z.neg = x.neg
@ -761,7 +759,9 @@ func (x *Float) Float64() (float64, Accuracy) {
 		return 0, Exact
 	}
 	// x != 0
-	r := new(Float).Round(x, 53, ToNearestEven)
+	var r Float
+	r.prec = 53
+	r.Set(x)
 	var s uint64
 	if r.neg {
 		s = 1 << 63
--- a/src/math/big/float_test.go
+++ b/src/math/big/float_test.go
@ -263,18 +263,46 @@ func testFloatRound(t *testing.T, x, r int64, prec uint, mode RoundingMode) {
 	}

 	// round
-	f := new(Float).SetInt64(x)
-	f.Round(f, prec, mode)
+	f := new(Float).SetMode(mode).SetInt64(x).SetPrec(prec)

 	// check result
 	r1 := f.int64()
 	p1 := f.Prec()
 	a1 := f.Acc()
 	if r1 != r || p1 != prec || a1 != a {
-		t.Errorf("Round(%s, %d, %s): got %s (%d bits, %s); want %s (%d bits, %s)",
+		t.Errorf("round %s (%d bits, %s) incorrect: got %s (%d bits, %s); want %s (%d bits, %s)",
 			toBinary(x), prec, mode,
 			toBinary(r1), p1, a1,
 			toBinary(r), prec, a)
+		return
+	}
+
+	// g and f should be the same
+	// (rounding by SetPrec after SetInt64 using default precision
+	// should be the same as rounding by SetInt64 after setting the
+	// precision)
+	g := new(Float).SetMode(mode).SetPrec(prec).SetInt64(x)
+	if !feq(g, f) {
+		t.Errorf("round %s (%d bits, %s) not symmetric: got %s and %s; want %s",
+			toBinary(x), prec, mode,
+			toBinary(g.int64()),
+			toBinary(r1),
+			toBinary(r),
+		)
+		return
+	}
+
+	// h and f should be the same
+	// (repeated rounding should be idempotent)
+	h := new(Float).SetMode(mode).SetPrec(prec).Set(f)
+	if !feq(h, f) {
+		t.Errorf("round %s (%d bits, %s) not idempotent: got %s and %s; want %s",
+			toBinary(x), prec, mode,
+			toBinary(h.int64()),
+			toBinary(r1),
+			toBinary(r),
+		)
+		return
 	}
 }

@ -383,8 +411,7 @@ func TestFloatRound24(t *testing.T) {
 	const x0 = 1<<26 - 0x10 // 11...110000 (26 bits)
 	for d := 0; d <= 0x10; d++ {
 		x := float64(x0 + d)
-		f := new(Float).SetFloat64(x)
-		f.Round(f, 24, ToNearestEven)
+		f := new(Float).SetPrec(24).SetFloat64(x)
 		got, _ := f.Float64()
 		want := float64(float32(x))
 		if got != want {