libgo/go/math/big/ftoa.go - gofrontend - Git at Google

 // Copyright 2015 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.

 // This file implements Float-to-string conversion functions.
 // It is closely following the corresponding implementation
 // in strconv/ftoa.go, but modified and simplified for Float.

 package big

 import (
 	"bytes"
 	"fmt"
 	"strconv"
 )

 // Text converts the floating-point number x to a string according
 // to the given format and precision prec. The format is one of:
 //
 //	'e'	-d.dddde±dd, decimal exponent, at least two (possibly 0) exponent digits
 //	'E'	-d.ddddE±dd, decimal exponent, at least two (possibly 0) exponent digits
 //	'f'	-ddddd.dddd, no exponent
 //	'g'	like 'e' for large exponents, like 'f' otherwise
 //	'G'	like 'E' for large exponents, like 'f' otherwise
 //	'b'	-ddddddp±dd, binary exponent
 //	'p'	-0x.dddp±dd, binary exponent, hexadecimal mantissa
 //
 // For the binary exponent formats, the mantissa is printed in normalized form:
 //
 //	'b'	decimal integer mantissa using x.Prec() bits, or -0
 //	'p'	hexadecimal fraction with 0.5 <= 0.mantissa < 1.0, or -0
 //
 // If format is a different character, Text returns a "%" followed by the
 // unrecognized format character.
 //
 // The precision prec controls the number of digits (excluding the exponent)
 // printed by the 'e', 'E', 'f', 'g', and 'G' formats. For 'e', 'E', and 'f'
 // it is the number of digits after the decimal point. For 'g' and 'G' it is
 // the total number of digits. A negative precision selects the smallest
 // number of decimal digits necessary to identify the value x uniquely using
 // x.Prec() mantissa bits.
 // The prec value is ignored for the 'b' or 'p' format.
 func (x *Float) Text(format byte, prec int) string {
 	cap := 10 // TODO(gri) determine a good/better value here
 	if prec > 0 {
 		cap += prec
 	}
 	return string(x.Append(make([]byte, 0, cap), format, prec))
 }

 // String formats x like x.Text('g', 10).
 // (String must be called explicitly, Float.Format does not support %s verb.)
 func (x *Float) String() string {
 	return x.Text('g', 10)
 }

 // Append appends to buf the string form of the floating-point number x,
 // as generated by x.Text, and returns the extended buffer.
 func (x *Float) Append(buf []byte, fmt byte, prec int) []byte {
 	// sign
 	if x.neg {
 		buf = append(buf, '-')
 	}

 	// Inf
 	if x.form == inf {
 		if !x.neg {
 			buf = append(buf, '+')
 		}
 		return append(buf, "Inf"...)
 	}

 	// pick off easy formats
 	switch fmt {
 	case 'b':
 		return x.fmtB(buf)
 	case 'p':
 		return x.fmtP(buf)
 	}

 	// Algorithm:
 	//   1) convert Float to multiprecision decimal
 	//   2) round to desired precision
 	//   3) read digits out and format

 	// 1) convert Float to multiprecision decimal
 	var d decimal // == 0.0
 	if x.form == finite {
 		// x != 0
 		d.init(x.mant, int(x.exp)-x.mant.bitLen())
 	}

 	// 2) round to desired precision
 	shortest := false
 	if prec < 0 {
 		shortest = true
 		roundShortest(&d, x)
 		// Precision for shortest representation mode.
 		switch fmt {
 		case 'e', 'E':
 			prec = len(d.mant) - 1
 		case 'f':
 			prec = max(len(d.mant)-d.exp, 0)
 		case 'g', 'G':
 			prec = len(d.mant)
 		}
 	} else {
 		// round appropriately
 		switch fmt {
 		case 'e', 'E':
 			// one digit before and number of digits after decimal point
 			d.round(1 + prec)
 		case 'f':
 			// number of digits before and after decimal point
 			d.round(d.exp + prec)
 		case 'g', 'G':
 			if prec == 0 {
 				prec = 1
 			}
 			d.round(prec)
 		}
 	}

 	// 3) read digits out and format
 	switch fmt {
 	case 'e', 'E':
 		return fmtE(buf, fmt, prec, d)
 	case 'f':
 		return fmtF(buf, prec, d)
 	case 'g', 'G':
 		// trim trailing fractional zeros in %e format
 		eprec := prec
 		if eprec > len(d.mant) && len(d.mant) >= d.exp {
 			eprec = len(d.mant)
 		}
 		// %e is used if the exponent from the conversion
 		// is less than -4 or greater than or equal to the precision.
 		// If precision was the shortest possible, use eprec = 6 for
 		// this decision.
 		if shortest {
 			eprec = 6
 		}
 		exp := d.exp - 1
 		if exp < -4 || exp >= eprec {
 			if prec > len(d.mant) {
 				prec = len(d.mant)
 			}
 			return fmtE(buf, fmt+'e'-'g', prec-1, d)
 		}
 		if prec > d.exp {
 			prec = len(d.mant)
 		}
 		return fmtF(buf, max(prec-d.exp, 0), d)
 	}

 	// unknown format
 	if x.neg {
 		buf = buf[:len(buf)-1] // sign was added prematurely - remove it again
 	}
 	return append(buf, '%', fmt)
 }

 func roundShortest(d *decimal, x *Float) {
 	// if the mantissa is zero, the number is zero - stop now
 	if len(d.mant) == 0 {
 		return
 	}

 	// Approach: All numbers in the interval [x - 1/2ulp, x + 1/2ulp]
 	// (possibly exclusive) round to x for the given precision of x.
 	// Compute the lower and upper bound in decimal form and find the
 	// shortest decimal number d such that lower <= d <= upper.

 	// TODO(gri) strconv/ftoa.do describes a shortcut in some cases.
 	// See if we can use it (in adjusted form) here as well.

 	// 1) Compute normalized mantissa mant and exponent exp for x such
 	// that the lsb of mant corresponds to 1/2 ulp for the precision of
 	// x (i.e., for mant we want x.prec + 1 bits).
 	mant := nat(nil).set(x.mant)
 	exp := int(x.exp) - mant.bitLen()
 	s := mant.bitLen() - int(x.prec+1)
 	switch {
 	case s < 0:
 		mant = mant.shl(mant, uint(-s))
 	case s > 0:
 		mant = mant.shr(mant, uint(+s))
 	}
 	exp += s
 	// x = mant * 2**exp with lsb(mant) == 1/2 ulp of x.prec

 	// 2) Compute lower bound by subtracting 1/2 ulp.
 	var lower decimal
 	var tmp nat
 	lower.init(tmp.sub(mant, natOne), exp)

 	// 3) Compute upper bound by adding 1/2 ulp.
 	var upper decimal
 	upper.init(tmp.add(mant, natOne), exp)

 	// The upper and lower bounds are possible outputs only if
 	// the original mantissa is even, so that ToNearestEven rounding
 	// would round to the original mantissa and not the neighbors.
 	inclusive := mant[0]&2 == 0 // test bit 1 since original mantissa was shifted by 1

 	// Now we can figure out the minimum number of digits required.
 	// Walk along until d has distinguished itself from upper and lower.
 	for i, m := range d.mant {
 		l := lower.at(i)
 		u := upper.at(i)

 		// Okay to round down (truncate) if lower has a different digit
 		// or if lower is inclusive and is exactly the result of rounding
 		// down (i.e., and we have reached the final digit of lower).
 		okdown := l != m || inclusive && i+1 == len(lower.mant)

 		// Okay to round up if upper has a different digit and either upper
 		// is inclusive or upper is bigger than the result of rounding up.
 		okup := m != u && (inclusive || m+1 < u || i+1 < len(upper.mant))

 		// If it's okay to do either, then round to the nearest one.
 		// If it's okay to do only one, do it.
 		switch {
 		case okdown && okup:
 			d.round(i + 1)
 			return
 		case okdown:
 			d.roundDown(i + 1)
 			return
 		case okup:
 			d.roundUp(i + 1)
 			return
 		}
 	}
 }

 // %e: d.ddddde±dd
 func fmtE(buf []byte, fmt byte, prec int, d decimal) []byte {
 	// first digit
 	ch := byte('0')
 	if len(d.mant) > 0 {
 		ch = d.mant[0]
 	}
 	buf = append(buf, ch)

 	// .moredigits
 	if prec > 0 {
 		buf = append(buf, '.')
 		i := 1
 		m := min(len(d.mant), prec+1)
 		if i < m {
 			buf = append(buf, d.mant[i:m]...)
 			i = m
 		}
 		for ; i <= prec; i++ {
 			buf = append(buf, '0')
 		}
 	}

 	// e±
 	buf = append(buf, fmt)
 	var exp int64
 	if len(d.mant) > 0 {
 		exp = int64(d.exp) - 1 // -1 because first digit was printed before '.'
 	}
 	if exp < 0 {
 		ch = '-'
 		exp = -exp
 	} else {
 		ch = '+'
 	}
 	buf = append(buf, ch)

 	// dd...d
 	if exp < 10 {
 		buf = append(buf, '0') // at least 2 exponent digits
 	}
 	return strconv.AppendInt(buf, exp, 10)
 }

 // %f: ddddddd.ddddd
 func fmtF(buf []byte, prec int, d decimal) []byte {
 	// integer, padded with zeros as needed
 	if d.exp > 0 {
 		m := min(len(d.mant), d.exp)
 		buf = append(buf, d.mant[:m]...)
 		for ; m < d.exp; m++ {
 			buf = append(buf, '0')
 		}
 	} else {
 		buf = append(buf, '0')
 	}

 	// fraction
 	if prec > 0 {
 		buf = append(buf, '.')
 		for i := 0; i < prec; i++ {
 			buf = append(buf, d.at(d.exp+i))
 		}
 	}

 	return buf
 }

 // fmtB appends the string of x in the format mantissa "p" exponent
 // with a decimal mantissa and a binary exponent, or 0" if x is zero,
 // and returns the extended buffer.
 // The mantissa is normalized such that is uses x.Prec() bits in binary
 // representation.
 // The sign of x is ignored, and x must not be an Inf.
 func (x *Float) fmtB(buf []byte) []byte {
 	if x.form == zero {
 		return append(buf, '0')
 	}

 	if debugFloat && x.form != finite {
 		panic("non-finite float")
 	}
 	// x != 0

 	// adjust mantissa to use exactly x.prec bits
 	m := x.mant
 	switch w := uint32(len(x.mant)) * _W; {
 	case w < x.prec:
 		m = nat(nil).shl(m, uint(x.prec-w))
 	case w > x.prec:
 		m = nat(nil).shr(m, uint(w-x.prec))
 	}

 	buf = append(buf, m.utoa(10)...)
 	buf = append(buf, 'p')
 	e := int64(x.exp) - int64(x.prec)
 	if e >= 0 {
 		buf = append(buf, '+')
 	}
 	return strconv.AppendInt(buf, e, 10)
 }

 // fmtP appends the string of x in the format "0x." mantissa "p" exponent
 // with a hexadecimal mantissa and a binary exponent, or "0" if x is zero,
 // and returns the extended buffer.
 // The mantissa is normalized such that 0.5 <= 0.mantissa < 1.0.
 // The sign of x is ignored, and x must not be an Inf.
 func (x *Float) fmtP(buf []byte) []byte {
 	if x.form == zero {
 		return append(buf, '0')
 	}

 	if debugFloat && x.form != finite {
 		panic("non-finite float")
 	}
 	// x != 0

 	// remove trailing 0 words early
 	// (no need to convert to hex 0's and trim later)
 	m := x.mant
 	i := 0
 	for i < len(m) && m[i] == 0 {
 		i++
 	}
 	m = m[i:]

 	buf = append(buf, "0x."...)
 	buf = append(buf, bytes.TrimRight(m.utoa(16), "0")...)
 	buf = append(buf, 'p')
 	if x.exp >= 0 {
 		buf = append(buf, '+')
 	}
 	return strconv.AppendInt(buf, int64(x.exp), 10)
 }

 func min(x, y int) int {
 	if x < y {
 		return x
 	}
 	return y
 }

 var _ fmt.Formatter = &floatZero // *Float must implement fmt.Formatter

 // Format implements fmt.Formatter. It accepts all the regular
 // formats for floating-point numbers ('b', 'e', 'E', 'f', 'F',
 // 'g', 'G') as well as 'p' and 'v'. See (*Float).Text for the
 // interpretation of 'p'. The 'v' format is handled like 'g'.
 // Format also supports specification of the minimum precision
 // in digits, the output field width, as well as the format flags
 // '+' and ' ' for sign control, '0' for space or zero padding,
 // and '-' for left or right justification. See the fmt package
 // for details.
 func (x *Float) Format(s fmt.State, format rune) {
 	prec, hasPrec := s.Precision()
 	if !hasPrec {
 		prec = 6 // default precision for 'e', 'f'
 	}

 	switch format {
 	case 'e', 'E', 'f', 'b', 'p':
 		// nothing to do
 	case 'F':
 		// (*Float).Text doesn't support 'F'; handle like 'f'
 		format = 'f'
 	case 'v':
 		// handle like 'g'
 		format = 'g'
 		fallthrough
 	case 'g', 'G':
 		if !hasPrec {
 			prec = -1 // default precision for 'g', 'G'
 		}
 	default:
 		fmt.Fprintf(s, "%%!%c(*big.Float=%s)", format, x.String())
 		return
 	}
 	var buf []byte
 	buf = x.Append(buf, byte(format), prec)
 	if len(buf) == 0 {
 		buf = []byte("?") // should never happen, but don't crash
 	}
 	// len(buf) > 0

 	var sign string
 	switch {
 	case buf[0] == '-':
 		sign = "-"
 		buf = buf[1:]
 	case buf[0] == '+':
 		// +Inf
 		sign = "+"
 		if s.Flag(' ') {
 			sign = " "
 		}
 		buf = buf[1:]
 	case s.Flag('+'):
 		sign = "+"
 	case s.Flag(' '):
 		sign = " "
 	}

 	var padding int
 	if width, hasWidth := s.Width(); hasWidth && width > len(sign)+len(buf) {
 		padding = width - len(sign) - len(buf)
 	}

 	switch {
 	case s.Flag('0') && !x.IsInf():
 		// 0-padding on left
 		writeMultiple(s, sign, 1)
 		writeMultiple(s, "0", padding)
 		s.Write(buf)
 	case s.Flag('-'):
 		// padding on right
 		writeMultiple(s, sign, 1)
 		s.Write(buf)
 		writeMultiple(s, " ", padding)
 	default:
 		// padding on left
 		writeMultiple(s, " ", padding)
 		writeMultiple(s, sign, 1)
 		s.Write(buf)
 	}
 }
	// Copyright 2015 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.

	// This file implements Float-to-string conversion functions.
	// It is closely following the corresponding implementation
	// in strconv/ftoa.go, but modified and simplified for Float.

	package big

	import (
	"bytes"
	"fmt"
	"strconv"
	)

	// Text converts the floating-point number x to a string according
	// to the given format and precision prec. The format is one of:
	//
	// 'e' -d.dddde±dd, decimal exponent, at least two (possibly 0) exponent digits
	// 'E' -d.ddddE±dd, decimal exponent, at least two (possibly 0) exponent digits
	// 'f' -ddddd.dddd, no exponent
	// 'g' like 'e' for large exponents, like 'f' otherwise
	// 'G' like 'E' for large exponents, like 'f' otherwise
	// 'b' -ddddddp±dd, binary exponent
	// 'p' -0x.dddp±dd, binary exponent, hexadecimal mantissa
	//
	// For the binary exponent formats, the mantissa is printed in normalized form:
	//
	// 'b' decimal integer mantissa using x.Prec() bits, or -0
	// 'p' hexadecimal fraction with 0.5 <= 0.mantissa < 1.0, or -0
	//
	// If format is a different character, Text returns a "%" followed by the
	// unrecognized format character.
	//
	// The precision prec controls the number of digits (excluding the exponent)
	// printed by the 'e', 'E', 'f', 'g', and 'G' formats. For 'e', 'E', and 'f'
	// it is the number of digits after the decimal point. For 'g' and 'G' it is
	// the total number of digits. A negative precision selects the smallest
	// number of decimal digits necessary to identify the value x uniquely using
	// x.Prec() mantissa bits.
	// The prec value is ignored for the 'b' or 'p' format.
	func (x *Float) Text(format byte, prec int) string {
	cap := 10 // TODO(gri) determine a good/better value here
	if prec > 0 {
	cap += prec
	}
	return string(x.Append(make([]byte, 0, cap), format, prec))
	}

	// String formats x like x.Text('g', 10).
	// (String must be called explicitly, Float.Format does not support %s verb.)
	func (x *Float) String() string {
	return x.Text('g', 10)
	}

	// Append appends to buf the string form of the floating-point number x,
	// as generated by x.Text, and returns the extended buffer.
	func (x *Float) Append(buf []byte, fmt byte, prec int) []byte {
	// sign
	if x.neg {
	buf = append(buf, '-')
	}

	// Inf
	if x.form == inf {
	if !x.neg {
	buf = append(buf, '+')
	}
	return append(buf, "Inf"...)
	}

	// pick off easy formats
	switch fmt {
	case 'b':
	return x.fmtB(buf)
	case 'p':
	return x.fmtP(buf)
	}

	// Algorithm:
	// 1) convert Float to multiprecision decimal
	// 2) round to desired precision
	// 3) read digits out and format

	// 1) convert Float to multiprecision decimal
	var d decimal // == 0.0
	if x.form == finite {
	// x != 0
	d.init(x.mant, int(x.exp)-x.mant.bitLen())
	}

	// 2) round to desired precision
	shortest := false
	if prec < 0 {
	shortest = true
	roundShortest(&d, x)
	// Precision for shortest representation mode.
	switch fmt {
	case 'e', 'E':
	prec = len(d.mant) - 1
	case 'f':
	prec = max(len(d.mant)-d.exp, 0)
	case 'g', 'G':
	prec = len(d.mant)
	}
	} else {
	// round appropriately
	switch fmt {
	case 'e', 'E':
	// one digit before and number of digits after decimal point
	d.round(1 + prec)
	case 'f':
	// number of digits before and after decimal point
	d.round(d.exp + prec)
	case 'g', 'G':
	if prec == 0 {
	prec = 1
	}
	d.round(prec)
	}
	}

	// 3) read digits out and format
	switch fmt {
	case 'e', 'E':
	return fmtE(buf, fmt, prec, d)
	case 'f':
	return fmtF(buf, prec, d)
	case 'g', 'G':
	// trim trailing fractional zeros in %e format
	eprec := prec
	if eprec > len(d.mant) && len(d.mant) >= d.exp {
	eprec = len(d.mant)
	}
	// %e is used if the exponent from the conversion
	// is less than -4 or greater than or equal to the precision.
	// If precision was the shortest possible, use eprec = 6 for
	// this decision.
	if shortest {
	eprec = 6
	}
	exp := d.exp - 1
	if exp < -4 \|\| exp >= eprec {
	if prec > len(d.mant) {
	prec = len(d.mant)
	}
	return fmtE(buf, fmt+'e'-'g', prec-1, d)
	}
	if prec > d.exp {
	prec = len(d.mant)
	}
	return fmtF(buf, max(prec-d.exp, 0), d)
	}

	// unknown format
	if x.neg {
	buf = buf[:len(buf)-1] // sign was added prematurely - remove it again
	}
	return append(buf, '%', fmt)
	}

	func roundShortest(d decimal, x Float) {
	// if the mantissa is zero, the number is zero - stop now
	if len(d.mant) == 0 {
	return
	}

	// Approach: All numbers in the interval [x - 1/2ulp, x + 1/2ulp]
	// (possibly exclusive) round to x for the given precision of x.
	// Compute the lower and upper bound in decimal form and find the
	// shortest decimal number d such that lower <= d <= upper.

	// TODO(gri) strconv/ftoa.do describes a shortcut in some cases.
	// See if we can use it (in adjusted form) here as well.

	// 1) Compute normalized mantissa mant and exponent exp for x such
	// that the lsb of mant corresponds to 1/2 ulp for the precision of
	// x (i.e., for mant we want x.prec + 1 bits).
	mant := nat(nil).set(x.mant)
	exp := int(x.exp) - mant.bitLen()
	s := mant.bitLen() - int(x.prec+1)
	switch {
	case s < 0:
	mant = mant.shl(mant, uint(-s))
	case s > 0:
	mant = mant.shr(mant, uint(+s))
	}
	exp += s
	// x = mant * 2**exp with lsb(mant) == 1/2 ulp of x.prec

	// 2) Compute lower bound by subtracting 1/2 ulp.
	var lower decimal
	var tmp nat
	lower.init(tmp.sub(mant, natOne), exp)

	// 3) Compute upper bound by adding 1/2 ulp.
	var upper decimal
	upper.init(tmp.add(mant, natOne), exp)

	// The upper and lower bounds are possible outputs only if
	// the original mantissa is even, so that ToNearestEven rounding
	// would round to the original mantissa and not the neighbors.
	inclusive := mant[0]&2 == 0 // test bit 1 since original mantissa was shifted by 1

	// Now we can figure out the minimum number of digits required.
	// Walk along until d has distinguished itself from upper and lower.
	for i, m := range d.mant {
	l := lower.at(i)
	u := upper.at(i)

	// Okay to round down (truncate) if lower has a different digit
	// or if lower is inclusive and is exactly the result of rounding
	// down (i.e., and we have reached the final digit of lower).
	okdown := l != m \|\| inclusive && i+1 == len(lower.mant)

	// Okay to round up if upper has a different digit and either upper
	// is inclusive or upper is bigger than the result of rounding up.
	okup := m != u && (inclusive \|\| m+1 < u \|\| i+1 < len(upper.mant))

	// If it's okay to do either, then round to the nearest one.
	// If it's okay to do only one, do it.
	switch {
	case okdown && okup:
	d.round(i + 1)
	return
	case okdown:
	d.roundDown(i + 1)
	return
	case okup:
	d.roundUp(i + 1)
	return
	}
	}
	}

	// %e: d.ddddde±dd
	func fmtE(buf []byte, fmt byte, prec int, d decimal) []byte {
	// first digit
	ch := byte('0')
	if len(d.mant) > 0 {
	ch = d.mant[0]
	}
	buf = append(buf, ch)

	// .moredigits
	if prec > 0 {
	buf = append(buf, '.')
	i := 1
	m := min(len(d.mant), prec+1)
	if i < m {
	buf = append(buf, d.mant[i:m]...)
	i = m
	}
	for ; i <= prec; i++ {
	buf = append(buf, '0')
	}
	}

	// e±
	buf = append(buf, fmt)
	var exp int64
	if len(d.mant) > 0 {
	exp = int64(d.exp) - 1 // -1 because first digit was printed before '.'
	}
	if exp < 0 {
	ch = '-'
	exp = -exp
	} else {
	ch = '+'
	}
	buf = append(buf, ch)

	// dd...d
	if exp < 10 {
	buf = append(buf, '0') // at least 2 exponent digits
	}
	return strconv.AppendInt(buf, exp, 10)
	}

	// %f: ddddddd.ddddd
	func fmtF(buf []byte, prec int, d decimal) []byte {
	// integer, padded with zeros as needed
	if d.exp > 0 {
	m := min(len(d.mant), d.exp)
	buf = append(buf, d.mant[:m]...)
	for ; m < d.exp; m++ {
	buf = append(buf, '0')
	}
	} else {
	buf = append(buf, '0')
	}

	// fraction
	if prec > 0 {
	buf = append(buf, '.')
	for i := 0; i < prec; i++ {
	buf = append(buf, d.at(d.exp+i))
	}
	}

	return buf
	}

	// fmtB appends the string of x in the format mantissa "p" exponent
	// with a decimal mantissa and a binary exponent, or 0" if x is zero,
	// and returns the extended buffer.
	// The mantissa is normalized such that is uses x.Prec() bits in binary
	// representation.
	// The sign of x is ignored, and x must not be an Inf.
	func (x *Float) fmtB(buf []byte) []byte {
	if x.form == zero {
	return append(buf, '0')
	}

	if debugFloat && x.form != finite {
	panic("non-finite float")
	}
	// x != 0

	// adjust mantissa to use exactly x.prec bits
	m := x.mant
	switch w := uint32(len(x.mant)) * _W; {
	case w < x.prec:
	m = nat(nil).shl(m, uint(x.prec-w))
	case w > x.prec:
	m = nat(nil).shr(m, uint(w-x.prec))
	}

	buf = append(buf, m.utoa(10)...)
	buf = append(buf, 'p')
	e := int64(x.exp) - int64(x.prec)
	if e >= 0 {
	buf = append(buf, '+')
	}
	return strconv.AppendInt(buf, e, 10)
	}

	// fmtP appends the string of x in the format "0x." mantissa "p" exponent
	// with a hexadecimal mantissa and a binary exponent, or "0" if x is zero,
	// and returns the extended buffer.
	// The mantissa is normalized such that 0.5 <= 0.mantissa < 1.0.
	// The sign of x is ignored, and x must not be an Inf.
	func (x *Float) fmtP(buf []byte) []byte {
	if x.form == zero {
	return append(buf, '0')
	}

	if debugFloat && x.form != finite {
	panic("non-finite float")
	}
	// x != 0

	// remove trailing 0 words early
	// (no need to convert to hex 0's and trim later)
	m := x.mant
	i := 0
	for i < len(m) && m[i] == 0 {
	i++
	}
	m = m[i:]

	buf = append(buf, "0x."...)
	buf = append(buf, bytes.TrimRight(m.utoa(16), "0")...)
	buf = append(buf, 'p')
	if x.exp >= 0 {
	buf = append(buf, '+')
	}
	return strconv.AppendInt(buf, int64(x.exp), 10)
	}

	func min(x, y int) int {
	if x < y {
	return x
	}
	return y
	}

	var _ fmt.Formatter = &floatZero // *Float must implement fmt.Formatter

	// Format implements fmt.Formatter. It accepts all the regular
	// formats for floating-point numbers ('b', 'e', 'E', 'f', 'F',
	// 'g', 'G') as well as 'p' and 'v'. See (*Float).Text for the
	// interpretation of 'p'. The 'v' format is handled like 'g'.
	// Format also supports specification of the minimum precision
	// in digits, the output field width, as well as the format flags
	// '+' and ' ' for sign control, '0' for space or zero padding,
	// and '-' for left or right justification. See the fmt package
	// for details.
	func (x *Float) Format(s fmt.State, format rune) {
	prec, hasPrec := s.Precision()
	if !hasPrec {
	prec = 6 // default precision for 'e', 'f'
	}

	switch format {
	case 'e', 'E', 'f', 'b', 'p':
	// nothing to do
	case 'F':
	// (*Float).Text doesn't support 'F'; handle like 'f'
	format = 'f'
	case 'v':
	// handle like 'g'
	format = 'g'
	fallthrough
	case 'g', 'G':
	if !hasPrec {
	prec = -1 // default precision for 'g', 'G'
	}
	default:
	fmt.Fprintf(s, "%%!%c(*big.Float=%s)", format, x.String())
	return
	}
	var buf []byte
	buf = x.Append(buf, byte(format), prec)
	if len(buf) == 0 {
	buf = []byte("?") // should never happen, but don't crash
	}
	// len(buf) > 0

	var sign string
	switch {
	case buf[0] == '-':
	sign = "-"
	buf = buf[1:]
	case buf[0] == '+':
	// +Inf
	sign = "+"
	if s.Flag(' ') {
	sign = " "
	}
	buf = buf[1:]
	case s.Flag('+'):
	sign = "+"
	case s.Flag(' '):
	sign = " "
	}

	var padding int
	if width, hasWidth := s.Width(); hasWidth && width > len(sign)+len(buf) {
	padding = width - len(sign) - len(buf)
	}

	switch {
	case s.Flag('0') && !x.IsInf():
	// 0-padding on left
	writeMultiple(s, sign, 1)
	writeMultiple(s, "0", padding)
	s.Write(buf)
	case s.Flag('-'):
	// padding on right
	writeMultiple(s, sign, 1)
	s.Write(buf)
	writeMultiple(s, " ", padding)
	default:
	// padding on left
	writeMultiple(s, " ", padding)
	writeMultiple(s, sign, 1)
	s.Write(buf)
	}
	}