syncthing/vendor/github.com/dustin/go-humanize/bytes.go

package humanize

import (
	"fmt"
	"math"
	"strconv"
	"strings"
	"unicode"
)

// IEC Sizes.
// kibis of bits
const (
	Byte = 1 << (iota * 10)
	KiByte
	MiByte
	GiByte
	TiByte
	PiByte
	EiByte
)

// SI Sizes.
const (
	IByte = 1
	KByte = IByte * 1000
	MByte = KByte * 1000
	GByte = MByte * 1000
	TByte = GByte * 1000
	PByte = TByte * 1000
	EByte = PByte * 1000
)

var bytesSizeTable = map[string]uint64{
	"b":   Byte,
	"kib": KiByte,
	"kb":  KByte,
	"mib": MiByte,
	"mb":  MByte,
	"gib": GiByte,
	"gb":  GByte,
	"tib": TiByte,
	"tb":  TByte,
	"pib": PiByte,
	"pb":  PByte,
	"eib": EiByte,
	"eb":  EByte,
	// Without suffix
	"":   Byte,
	"ki": KiByte,
	"k":  KByte,
	"mi": MiByte,
	"m":  MByte,
	"gi": GiByte,
	"g":  GByte,
	"ti": TiByte,
	"t":  TByte,
	"pi": PiByte,
	"p":  PByte,
	"ei": EiByte,
	"e":  EByte,
}

func logn(n, b float64) float64 {
	return math.Log(n) / math.Log(b)
}

func humanateBytes(s uint64, base float64, sizes []string) string {
	if s < 10 {
		return fmt.Sprintf("%d B", s)
	}
	e := math.Floor(logn(float64(s), base))
	suffix := sizes[int(e)]
	val := math.Floor(float64(s)/math.Pow(base, e)*10+0.5) / 10
	f := "%.0f %s"
	if val < 10 {
		f = "%.1f %s"
	}

	return fmt.Sprintf(f, val, suffix)
}

// Bytes produces a human readable representation of an SI size.
//
// See also: ParseBytes.
//
// Bytes(82854982) -> 83 MB
func Bytes(s uint64) string {
	sizes := []string{"B", "kB", "MB", "GB", "TB", "PB", "EB"}
	return humanateBytes(s, 1000, sizes)
}

// IBytes produces a human readable representation of an IEC size.
//
// See also: ParseBytes.
//
// IBytes(82854982) -> 79 MiB
func IBytes(s uint64) string {
	sizes := []string{"B", "KiB", "MiB", "GiB", "TiB", "PiB", "EiB"}
	return humanateBytes(s, 1024, sizes)
}

// ParseBytes parses a string representation of bytes into the number
// of bytes it represents.
//
// See Also: Bytes, IBytes.
//
// ParseBytes("42 MB") -> 42000000, nil
// ParseBytes("42 mib") -> 44040192, nil
func ParseBytes(s string) (uint64, error) {
	lastDigit := 0
	hasComma := false
	for _, r := range s {
		if !(unicode.IsDigit(r) || r == '.' || r == ',') {
			break
		}
		if r == ',' {
			hasComma = true
		}
		lastDigit++
	}

	num := s[:lastDigit]
	if hasComma {
		num = strings.Replace(num, ",", "", -1)
	}

	f, err := strconv.ParseFloat(num, 64)
	if err != nil {
		return 0, err
	}

	extra := strings.ToLower(strings.TrimSpace(s[lastDigit:]))
	if m, ok := bytesSizeTable[extra]; ok {
		f *= float64(m)
		if f >= math.MaxUint64 {
			return 0, fmt.Errorf("too large: %v", s)
		}
		return uint64(f), nil
	}

	return 0, fmt.Errorf("unhandled size name: %v", extra)
}
cmd/stdiscosrv: New discovery server (fixes #4618) This is a new revision of the discovery server. Relevant changes and non-changes: - Protocol towards clients is unchanged. - Recommended large scale design is still to be deployed nehind nginx (I tested, and it's still a lot faster at terminating TLS). - Database backend is leveldb again, only. It scales enough, is easy to setup, and we don't need any backend to take care of. - Server supports replication. This is a simple TCP channel - protect it with a firewall when deploying over the internet. (We deploy this within the same datacenter, and with firewall.) Any incoming client announces are sent over the replication channel(s) to other peer discosrvs. Incoming replication changes are applied to the database as if they came from clients, but without the TLS/certificate overhead. - Metrics are exposed using the prometheus library, when enabled. - The database values and replication protocol is protobuf, because JSON was quite CPU intensive when I tried that and benchmarked it. - The "Retry-After" value for failed lookups gets slowly increased from a default of 120 seconds, by 5 seconds for each failed lookup, independently by each discosrv. This lowers the query load over time for clients that are never seen. The Retry-After maxes out at 3600 after a couple of weeks of this increase. The number of failed lookups is stored in the database, now and then (avoiding making each lookup a database put). All in all this means clients can be pointed towards a cluster using just multiple A / AAAA records to gain both load sharing and redundancy (if one is down, clients will talk to the remaining ones). GitHub-Pull-Request: https://github.com/syncthing/syncthing/pull/4648 2018-01-14 09:52:31 +01:00			`package humanize`

			`import (`
			`"fmt"`
			`"math"`
			`"strconv"`
			`"strings"`
			`"unicode"`
			`)`

			`// IEC Sizes.`
			`// kibis of bits`
			`const (`
			`Byte = 1 << (iota * 10)`
			`KiByte`
			`MiByte`
			`GiByte`
			`TiByte`
			`PiByte`
			`EiByte`
			`)`

			`// SI Sizes.`
			`const (`
			`IByte = 1`
			`KByte = IByte * 1000`
			`MByte = KByte * 1000`
			`GByte = MByte * 1000`
			`TByte = GByte * 1000`
			`PByte = TByte * 1000`
			`EByte = PByte * 1000`
			`)`

			`var bytesSizeTable = map[string]uint64{`
			`"b": Byte,`
			`"kib": KiByte,`
			`"kb": KByte,`
			`"mib": MiByte,`
			`"mb": MByte,`
			`"gib": GiByte,`
			`"gb": GByte,`
			`"tib": TiByte,`
			`"tb": TByte,`
			`"pib": PiByte,`
			`"pb": PByte,`
			`"eib": EiByte,`
			`"eb": EByte,`
			`// Without suffix`
			`"": Byte,`
			`"ki": KiByte,`
			`"k": KByte,`
			`"mi": MiByte,`
			`"m": MByte,`
			`"gi": GiByte,`
			`"g": GByte,`
			`"ti": TiByte,`
			`"t": TByte,`
			`"pi": PiByte,`
			`"p": PByte,`
			`"ei": EiByte,`
			`"e": EByte,`
			`}`

			`func logn(n, b float64) float64 {`
			`return math.Log(n) / math.Log(b)`
			`}`

			`func humanateBytes(s uint64, base float64, sizes []string) string {`
			`if s < 10 {`
			`return fmt.Sprintf("%d B", s)`
			`}`
			`e := math.Floor(logn(float64(s), base))`
			`suffix := sizes[int(e)]`
			`val := math.Floor(float64(s)/math.Pow(base, e)*10+0.5) / 10`
			`f := "%.0f %s"`
			`if val < 10 {`
			`f = "%.1f %s"`
			`}`

			`return fmt.Sprintf(f, val, suffix)`
			`}`

			`// Bytes produces a human readable representation of an SI size.`
			`//`
			`// See also: ParseBytes.`
			`//`
			`// Bytes(82854982) -> 83 MB`
			`func Bytes(s uint64) string {`
			`sizes := []string{"B", "kB", "MB", "GB", "TB", "PB", "EB"}`
			`return humanateBytes(s, 1000, sizes)`
			`}`

			`// IBytes produces a human readable representation of an IEC size.`
			`//`
			`// See also: ParseBytes.`
			`//`
			`// IBytes(82854982) -> 79 MiB`
			`func IBytes(s uint64) string {`
			`sizes := []string{"B", "KiB", "MiB", "GiB", "TiB", "PiB", "EiB"}`
			`return humanateBytes(s, 1024, sizes)`
			`}`

			`// ParseBytes parses a string representation of bytes into the number`
			`// of bytes it represents.`
			`//`
			`// See Also: Bytes, IBytes.`
			`//`
			`// ParseBytes("42 MB") -> 42000000, nil`
			`// ParseBytes("42 mib") -> 44040192, nil`
			`func ParseBytes(s string) (uint64, error) {`
			`lastDigit := 0`
			`hasComma := false`
			`for _, r := range s {`
			`if !(unicode.IsDigit(r) \|\| r == '.' \|\| r == ',') {`
			`break`
			`}`
			`if r == ',' {`
			`hasComma = true`
			`}`
			`lastDigit++`
			`}`

			`num := s[:lastDigit]`
			`if hasComma {`
			`num = strings.Replace(num, ",", "", -1)`
			`}`

			`f, err := strconv.ParseFloat(num, 64)`
			`if err != nil {`
			`return 0, err`
			`}`

			`extra := strings.ToLower(strings.TrimSpace(s[lastDigit:]))`
			`if m, ok := bytesSizeTable[extra]; ok {`
			`f *= float64(m)`
			`if f >= math.MaxUint64 {`
			`return 0, fmt.Errorf("too large: %v", s)`
			`}`
			`return uint64(f), nil`
			`}`

			`return 0, fmt.Errorf("unhandled size name: %v", extra)`
			`}`