number/option.go - text - Git at Google

 // Copyright 2017 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 number

 import (
 	"fmt"

 	"golang.org/x/text/internal/number"
 	"golang.org/x/text/language"
 )

 // An Option configures a Formatter.
 type Option option

 type option func(tag language.Tag, f *number.Formatter)

 // TODO: SpellOut requires support of the ICU RBNF format.
 // func SpellOut() Option

 // NoSeparator causes a number to be displayed without grouping separators.
 func NoSeparator() Option {
 	return func(t language.Tag, f *number.Formatter) {
 		f.GroupingSize = [2]uint8{}
 	}
 }

 // MaxIntegerDigits limits the number of integer digits, eliminating the
 // most significant digits.
 func MaxIntegerDigits(max int) Option {
 	return func(t language.Tag, f *number.Formatter) {
 		if max >= 1<<8 {
 			max = (1 << 8) - 1
 		}
 		f.MaxIntegerDigits = uint8(max)
 	}
 }

 // MinIntegerDigits specifies the minimum number of integer digits, adding
 // leading zeros when needed.
 func MinIntegerDigits(min int) Option {
 	return func(t language.Tag, f *number.Formatter) {
 		if min >= 1<<8 {
 			min = (1 << 8) - 1
 		}
 		f.MinIntegerDigits = uint8(min)
 	}
 }

 // MaxFractionDigits specifies the maximum number of fractional digits.
 func MaxFractionDigits(max int) Option {
 	return func(t language.Tag, f *number.Formatter) {
 		if max >= 1<<15 {
 			max = (1 << 15) - 1
 		}
 		f.MaxFractionDigits = int16(max)
 	}
 }

 // MinFractionDigits specifies the minimum number of fractional digits.
 func MinFractionDigits(min int) Option {
 	return func(t language.Tag, f *number.Formatter) {
 		if min >= 1<<8 {
 			min = (1 << 8) - 1
 		}
 		f.MinFractionDigits = uint8(min)
 	}
 }

 // Precision sets the maximum number of significant digits. A negative value
 // means exact.
 func Precision(prec int) Option {
 	return func(t language.Tag, f *number.Formatter) {
 		f.SetPrecision(prec)
 	}
 }

 // Scale simultaneously sets MinFractionDigits and MaxFractionDigits to the
 // given value.
 func Scale(decimals int) Option {
 	return func(t language.Tag, f *number.Formatter) {
 		f.SetScale(decimals)
 	}
 }

 // IncrementString sets the incremental value to which numbers should be
 // rounded. For instance: Increment("0.05") will cause 1.44 to round to 1.45.
 // IncrementString also sets scale to the scale of the increment.
 func IncrementString(decimal string) Option {
 	increment := 0
 	scale := 0
 	d := decimal
 	p := 0
 	for ; p < len(d) && '0' <= d[p] && d[p] <= '9'; p++ {
 		increment *= 10
 		increment += int(d[p]) - '0'
 	}
 	if p < len(d) && d[p] == '.' {
 		for p++; p < len(d) && '0' <= d[p] && d[p] <= '9'; p++ {
 			increment *= 10
 			increment += int(d[p]) - '0'
 			scale++
 		}
 	}
 	if p < len(d) {
 		increment = 0
 		scale = 0
 	}
 	return func(t language.Tag, f *number.Formatter) {
 		f.Increment = uint32(increment)
 		f.IncrementScale = uint8(scale)
 		f.SetScale(scale)
 	}
 }

 func noop(language.Tag, *number.Formatter) {}

 // PatternOverrides allows users to specify alternative patterns for specific
 // languages. The Pattern will be overridden for all languages in a subgroup as
 // well. The function will panic for invalid input. It is best to create this
 // option at startup time.
 // PatternOverrides must be the first Option passed to a formatter.
 func PatternOverrides(patterns map[string]string) Option {
 	// TODO: make it so that it does not have to be the first option.
 	// TODO: use -x-nochild to indicate it does not override child tags.
 	m := map[language.Tag]*number.Pattern{}
 	for k, v := range patterns {
 		tag := language.MustParse(k)
 		p, err := number.ParsePattern(v)
 		if err != nil {
 			panic(fmt.Errorf("number: PatternOverrides: %v", err))
 		}
 		m[tag] = p
 	}
 	return func(t language.Tag, f *number.Formatter) {
 		// TODO: Use language grouping relation instead of parent relation.
 		// TODO: Should parent implement the grouping relation?
 		for lang := t; ; lang = t.Parent() {
 			if p, ok := m[lang]; ok {
 				f.Pattern = *p
 				break
 			}
 			if lang == language.Und {
 				break
 			}
 		}
 	}
 }

 // FormatWidth sets the total format width.
 func FormatWidth(n int) Option {
 	if n <= 0 {
 		return noop
 	}
 	return func(t language.Tag, f *number.Formatter) {
 		f.FormatWidth = uint16(n)
 		if f.PadRune == 0 {
 			f.PadRune = ' '
 		}
 	}
 }

 // Pad sets the rune to be used for filling up to the format width.
 func Pad(r rune) Option {
 	return func(t language.Tag, f *number.Formatter) {
 		f.PadRune = r
 	}
 }

 // TODO:
 // - FormatPosition (using type aliasing?)
 // - Multiplier: find a better way to represent and figure out what to do
 //   with clashes with percent/permille.
 // - NumberingSystem(nu string): not accessable in number.Info now. Also, should
 //      this be keyed by language or generic?
 // - SymbolOverrides(symbols map[string]map[number.SymbolType]string) Option
	// Copyright 2017 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 number

	import (
	"fmt"

	"golang.org/x/text/internal/number"
	"golang.org/x/text/language"
	)

	// An Option configures a Formatter.
	type Option option

	type option func(tag language.Tag, f *number.Formatter)

	// TODO: SpellOut requires support of the ICU RBNF format.
	// func SpellOut() Option

	// NoSeparator causes a number to be displayed without grouping separators.
	func NoSeparator() Option {
	return func(t language.Tag, f *number.Formatter) {
	f.GroupingSize = [2]uint8{}
	}
	}

	// MaxIntegerDigits limits the number of integer digits, eliminating the
	// most significant digits.
	func MaxIntegerDigits(max int) Option {
	return func(t language.Tag, f *number.Formatter) {
	if max >= 1<<8 {
	max = (1 << 8) - 1
	}
	f.MaxIntegerDigits = uint8(max)
	}
	}

	// MinIntegerDigits specifies the minimum number of integer digits, adding
	// leading zeros when needed.
	func MinIntegerDigits(min int) Option {
	return func(t language.Tag, f *number.Formatter) {
	if min >= 1<<8 {
	min = (1 << 8) - 1
	}
	f.MinIntegerDigits = uint8(min)
	}
	}

	// MaxFractionDigits specifies the maximum number of fractional digits.
	func MaxFractionDigits(max int) Option {
	return func(t language.Tag, f *number.Formatter) {
	if max >= 1<<15 {
	max = (1 << 15) - 1
	}
	f.MaxFractionDigits = int16(max)
	}
	}

	// MinFractionDigits specifies the minimum number of fractional digits.
	func MinFractionDigits(min int) Option {
	return func(t language.Tag, f *number.Formatter) {
	if min >= 1<<8 {
	min = (1 << 8) - 1
	}
	f.MinFractionDigits = uint8(min)
	}
	}

	// Precision sets the maximum number of significant digits. A negative value
	// means exact.
	func Precision(prec int) Option {
	return func(t language.Tag, f *number.Formatter) {
	f.SetPrecision(prec)
	}
	}

	// Scale simultaneously sets MinFractionDigits and MaxFractionDigits to the
	// given value.
	func Scale(decimals int) Option {
	return func(t language.Tag, f *number.Formatter) {
	f.SetScale(decimals)
	}
	}

	// IncrementString sets the incremental value to which numbers should be
	// rounded. For instance: Increment("0.05") will cause 1.44 to round to 1.45.
	// IncrementString also sets scale to the scale of the increment.
	func IncrementString(decimal string) Option {
	increment := 0
	scale := 0
	d := decimal
	p := 0
	for ; p < len(d) && '0' <= d[p] && d[p] <= '9'; p++ {
	increment *= 10
	increment += int(d[p]) - '0'
	}
	if p < len(d) && d[p] == '.' {
	for p++; p < len(d) && '0' <= d[p] && d[p] <= '9'; p++ {
	increment *= 10
	increment += int(d[p]) - '0'
	scale++
	}
	}
	if p < len(d) {
	increment = 0
	scale = 0
	}
	return func(t language.Tag, f *number.Formatter) {
	f.Increment = uint32(increment)
	f.IncrementScale = uint8(scale)
	f.SetScale(scale)
	}
	}

	func noop(language.Tag, *number.Formatter) {}

	// PatternOverrides allows users to specify alternative patterns for specific
	// languages. The Pattern will be overridden for all languages in a subgroup as
	// well. The function will panic for invalid input. It is best to create this
	// option at startup time.
	// PatternOverrides must be the first Option passed to a formatter.
	func PatternOverrides(patterns map[string]string) Option {
	// TODO: make it so that it does not have to be the first option.
	// TODO: use -x-nochild to indicate it does not override child tags.
	m := map[language.Tag]*number.Pattern{}
	for k, v := range patterns {
	tag := language.MustParse(k)
	p, err := number.ParsePattern(v)
	if err != nil {
	panic(fmt.Errorf("number: PatternOverrides: %v", err))
	}
	m[tag] = p
	}
	return func(t language.Tag, f *number.Formatter) {
	// TODO: Use language grouping relation instead of parent relation.
	// TODO: Should parent implement the grouping relation?
	for lang := t; ; lang = t.Parent() {
	if p, ok := m[lang]; ok {
	f.Pattern = *p
	break
	}
	if lang == language.Und {
	break
	}
	}
	}
	}

	// FormatWidth sets the total format width.
	func FormatWidth(n int) Option {
	if n <= 0 {
	return noop
	}
	return func(t language.Tag, f *number.Formatter) {
	f.FormatWidth = uint16(n)
	if f.PadRune == 0 {
	f.PadRune = ' '
	}
	}
	}

	// Pad sets the rune to be used for filling up to the format width.
	func Pad(r rune) Option {
	return func(t language.Tag, f *number.Formatter) {
	f.PadRune = r
	}
	}

	// TODO:
	// - FormatPosition (using type aliasing?)
	// - Multiplier: find a better way to represent and figure out what to do
	// with clashes with percent/permille.
	// - NumberingSystem(nu string): not accessable in number.Info now. Also, should
	// this be keyed by language or generic?
	// - SymbolOverrides(symbols map[string]map[number.SymbolType]string) Option