number.go - third_party/go-humanize - Git at Google

 package humanize

 /*
 Slightly adapted from the source to fit go-humanize.

 Author: https://github.com/gorhill
 Source: https://gist.github.com/gorhill/5285193

 */

 import (
 	"math"
 	"strconv"
 )

 var (
 	renderFloatPrecisionMultipliers = [...]float64{
 		1,
 		10,
 		100,
 		1000,
 		10000,
 		100000,
 		1000000,
 		10000000,
 		100000000,
 		1000000000,
 	}

 	renderFloatPrecisionRounders = [...]float64{
 		0.5,
 		0.05,
 		0.005,
 		0.0005,
 		0.00005,
 		0.000005,
 		0.0000005,
 		0.00000005,
 		0.000000005,
 		0.0000000005,
 	}
 )

 // FormatFloat produces a formatted number as string based on the following user-specified criteria:
 // * thousands separator
 // * decimal separator
 // * decimal precision
 //
 // Usage: s := RenderFloat(format, n)
 // The format parameter tells how to render the number n.
 //
 // See examples: http://play.golang.org/p/LXc1Ddm1lJ
 //
 // Examples of format strings, given n = 12345.6789:
 // "#,###.##" => "12,345.67"
 // "#,###." => "12,345"
 // "#,###" => "12345,678"
 // "#\u202F###,##" => "12 345,68"
 // "#.###,###### => 12.345,678900
 // "" (aka default format) => 12,345.67
 //
 // The highest precision allowed is 9 digits after the decimal symbol.
 // There is also a version for integer number, FormatInteger(),
 // which is convenient for calls within template.
 func FormatFloat(format string, n float64) string {
 	// Special cases:
 	//   NaN = "NaN"
 	//   +Inf = "+Infinity"
 	//   -Inf = "-Infinity"
 	if math.IsNaN(n) {
 		return "NaN"
 	}
 	if n > math.MaxFloat64 {
 		return "Infinity"
 	}
 	if n < -math.MaxFloat64 {
 		return "-Infinity"
 	}

 	// default format
 	precision := 2
 	decimalStr := "."
 	thousandStr := ","
 	positiveStr := ""
 	negativeStr := "-"

 	if len(format) > 0 {
 		format := []rune(format)

 		// If there is an explicit format directive,
 		// then default values are these:
 		precision = 9
 		thousandStr = ""

 		// collect indices of meaningful formatting directives
 		formatIndx := []int{}
 		for i, char := range format {
 			if char != '#' && char != '0' {
 				formatIndx = append(formatIndx, i)
 			}
 		}

 		if len(formatIndx) > 0 {
 			// Directive at index 0:
 			//   Must be a '+'
 			//   Raise an error if not the case
 			// index: 0123456789
 			//        +0.000,000
 			//        +000,000.0
 			//        +0000.00
 			//        +0000
 			if formatIndx[0] == 0 {
 				if format[formatIndx[0]] != '+' {
 					panic("RenderFloat(): invalid positive sign directive")
 				}
 				positiveStr = "+"
 				formatIndx = formatIndx[1:]
 			}

 			// Two directives:
 			//   First is thousands separator
 			//   Raise an error if not followed by 3-digit
 			// 0123456789
 			// 0.000,000
 			// 000,000.00
 			if len(formatIndx) == 2 {
 				if (formatIndx[1] - formatIndx[0]) != 4 {
 					panic("RenderFloat(): thousands separator directive must be followed by 3 digit-specifiers")
 				}
 				thousandStr = string(format[formatIndx[0]])
 				formatIndx = formatIndx[1:]
 			}

 			// One directive:
 			//   Directive is decimal separator
 			//   The number of digit-specifier following the separator indicates wanted precision
 			// 0123456789
 			// 0.00
 			// 000,0000
 			if len(formatIndx) == 1 {
 				decimalStr = string(format[formatIndx[0]])
 				precision = len(format) - formatIndx[0] - 1
 			}
 		}
 	}

 	// generate sign part
 	var signStr string
 	if n >= 0.000000001 {
 		signStr = positiveStr
 	} else if n <= -0.000000001 {
 		signStr = negativeStr
 		n = -n
 	} else {
 		signStr = ""
 		n = 0.0
 	}

 	// split number into integer and fractional parts
 	intf, fracf := math.Modf(n + renderFloatPrecisionRounders[precision])

 	// generate integer part string
 	intStr := strconv.Itoa(int(intf))

 	// add thousand separator if required
 	if len(thousandStr) > 0 {
 		for i := len(intStr); i > 3; {
 			i -= 3
 			intStr = intStr[:i] + thousandStr + intStr[i:]
 		}
 	}

 	// no fractional part, we can leave now
 	if precision == 0 {
 		return signStr + intStr
 	}

 	// generate fractional part
 	fracStr := strconv.Itoa(int(fracf * renderFloatPrecisionMultipliers[precision]))
 	// may need padding
 	if len(fracStr) < precision {
 		fracStr = "000000000000000"[:precision-len(fracStr)] + fracStr
 	}

 	return signStr + intStr + decimalStr + fracStr
 }

 // FormatInteger produces a formatted number as string.
 // See FormatFloat.
 func FormatInteger(format string, n int) string {
 	return FormatFloat(format, float64(n))
 }
	package humanize

	/*
	Slightly adapted from the source to fit go-humanize.

	Author: https://github.com/gorhill
	Source: https://gist.github.com/gorhill/5285193

	*/

	import (
	"math"
	"strconv"
	)

	var (
	renderFloatPrecisionMultipliers = [...]float64{
	1,
	10,
	100,
	1000,
	10000,
	100000,
	1000000,
	10000000,
	100000000,
	1000000000,
	}

	renderFloatPrecisionRounders = [...]float64{
	0.5,
	0.05,
	0.005,
	0.0005,
	0.00005,
	0.000005,
	0.0000005,
	0.00000005,
	0.000000005,
	0.0000000005,
	}
	)

	// FormatFloat produces a formatted number as string based on the following user-specified criteria:
	// * thousands separator
	// * decimal separator
	// * decimal precision
	//
	// Usage: s := RenderFloat(format, n)
	// The format parameter tells how to render the number n.
	//
	// See examples: http://play.golang.org/p/LXc1Ddm1lJ
	//
	// Examples of format strings, given n = 12345.6789:
	// "#,###.##" => "12,345.67"
	// "#,###." => "12,345"
	// "#,###" => "12345,678"
	// "#\u202F###,##" => "12 345,68"
	// "#.###,###### => 12.345,678900
	// "" (aka default format) => 12,345.67
	//
	// The highest precision allowed is 9 digits after the decimal symbol.
	// There is also a version for integer number, FormatInteger(),
	// which is convenient for calls within template.
	func FormatFloat(format string, n float64) string {
	// Special cases:
	// NaN = "NaN"
	// +Inf = "+Infinity"
	// -Inf = "-Infinity"
	if math.IsNaN(n) {
	return "NaN"
	}
	if n > math.MaxFloat64 {
	return "Infinity"
	}
	if n < -math.MaxFloat64 {
	return "-Infinity"
	}

	// default format
	precision := 2
	decimalStr := "."
	thousandStr := ","
	positiveStr := ""
	negativeStr := "-"

	if len(format) > 0 {
	format := []rune(format)

	// If there is an explicit format directive,
	// then default values are these:
	precision = 9
	thousandStr = ""

	// collect indices of meaningful formatting directives
	formatIndx := []int{}
	for i, char := range format {
	if char != '#' && char != '0' {
	formatIndx = append(formatIndx, i)
	}
	}

	if len(formatIndx) > 0 {
	// Directive at index 0:
	// Must be a '+'
	// Raise an error if not the case
	// index: 0123456789
	// +0.000,000
	// +000,000.0
	// +0000.00
	// +0000
	if formatIndx[0] == 0 {
	if format[formatIndx[0]] != '+' {
	panic("RenderFloat(): invalid positive sign directive")
	}
	positiveStr = "+"
	formatIndx = formatIndx[1:]
	}

	// Two directives:
	// First is thousands separator
	// Raise an error if not followed by 3-digit
	// 0123456789
	// 0.000,000
	// 000,000.00
	if len(formatIndx) == 2 {
	if (formatIndx[1] - formatIndx[0]) != 4 {
	panic("RenderFloat(): thousands separator directive must be followed by 3 digit-specifiers")
	}
	thousandStr = string(format[formatIndx[0]])
	formatIndx = formatIndx[1:]
	}

	// One directive:
	// Directive is decimal separator
	// The number of digit-specifier following the separator indicates wanted precision
	// 0123456789
	// 0.00
	// 000,0000
	if len(formatIndx) == 1 {
	decimalStr = string(format[formatIndx[0]])
	precision = len(format) - formatIndx[0] - 1
	}
	}
	}

	// generate sign part
	var signStr string
	if n >= 0.000000001 {
	signStr = positiveStr
	} else if n <= -0.000000001 {
	signStr = negativeStr
	n = -n
	} else {
	signStr = ""
	n = 0.0
	}

	// split number into integer and fractional parts
	intf, fracf := math.Modf(n + renderFloatPrecisionRounders[precision])

	// generate integer part string
	intStr := strconv.Itoa(int(intf))

	// add thousand separator if required
	if len(thousandStr) > 0 {
	for i := len(intStr); i > 3; {
	i -= 3
	intStr = intStr[:i] + thousandStr + intStr[i:]
	}
	}

	// no fractional part, we can leave now
	if precision == 0 {
	return signStr + intStr
	}

	// generate fractional part
	fracStr := strconv.Itoa(int(fracf * renderFloatPrecisionMultipliers[precision]))
	// may need padding
	if len(fracStr) < precision {
	fracStr = "000000000000000"[:precision-len(fracStr)] + fracStr
	}

	return signStr + intStr + decimalStr + fracStr
	}

	// FormatInteger produces a formatted number as string.
	// See FormatFloat.
	func FormatInteger(format string, n int) string {
	return FormatFloat(format, float64(n))
	}