package fs // SizeSuffix is parsed by flag with K/M/G binary suffixes import ( "encoding/json" "errors" "fmt" "math" "sort" "strconv" "strings" ) // SizeSuffix is an int64 with a friendly way of printing setting type SizeSuffix int64 // Common multipliers for SizeSuffix const ( SizeSuffixBase SizeSuffix = 1 << (iota * 10) Kibi Mebi Gibi Tebi Pebi Exbi ) const ( // SizeSuffixMax is the largest SizeSuffix multiplier SizeSuffixMax = Exbi // SizeSuffixMaxValue is the largest value that can be used to create SizeSuffix SizeSuffixMaxValue = math.MaxInt64 // SizeSuffixMinValue is the smallest value that can be used to create SizeSuffix SizeSuffixMinValue = math.MinInt64 ) // Turn SizeSuffix into a string and a suffix func (x SizeSuffix) string() (string, string) { scaled := float64(0) suffix := "" switch { case x < 0: return "off", "" case x == 0: return "0", "" case x < Kibi: scaled = float64(x) suffix = "" case x < Mebi: scaled = float64(x) / float64(Kibi) suffix = "Ki" case x < Gibi: scaled = float64(x) / float64(Mebi) suffix = "Mi" case x < Tebi: scaled = float64(x) / float64(Gibi) suffix = "Gi" case x < Pebi: scaled = float64(x) / float64(Tebi) suffix = "Ti" case x < Exbi: scaled = float64(x) / float64(Pebi) suffix = "Pi" default: scaled = float64(x) / float64(Exbi) suffix = "Ei" } if math.Floor(scaled) == scaled { return fmt.Sprintf("%.0f", scaled), suffix } return fmt.Sprintf("%.3f", scaled), suffix } // String turns SizeSuffix into a string func (x SizeSuffix) String() string { val, suffix := x.string() return val + suffix } // Unit turns SizeSuffix into a string with a unit func (x SizeSuffix) unit(unit string) string { val, suffix := x.string() if val == "off" { return val } return val + " " + suffix + unit } // BitUnit turns SizeSuffix into a string with bit unit func (x SizeSuffix) BitUnit() string { return x.unit("bit") } // BitRateUnit turns SizeSuffix into a string with bit rate unit func (x SizeSuffix) BitRateUnit() string { return x.unit("bit/s") } // ByteUnit turns SizeSuffix into a string with byte unit func (x SizeSuffix) ByteUnit() string { return x.unit("B") } // ByteRateUnit turns SizeSuffix into a string with byte rate unit func (x SizeSuffix) ByteRateUnit() string { return x.unit("B/s") } func (x *SizeSuffix) multiplierFromSymbol(s byte) (found bool, multiplier float64) { switch s { case 'k', 'K': return true, float64(Kibi) case 'm', 'M': return true, float64(Mebi) case 'g', 'G': return true, float64(Gibi) case 't', 'T': return true, float64(Tebi) case 'p', 'P': return true, float64(Pebi) case 'e', 'E': return true, float64(Exbi) default: return false, float64(SizeSuffixBase) } } // Set a SizeSuffix func (x *SizeSuffix) Set(s string) error { if len(s) == 0 { return errors.New("empty string") } if strings.ToLower(s) == "off" { *x = -1 return nil } suffix := s[len(s)-1] suffixLen := 1 multiplierFound := false var multiplier float64 switch suffix { case '0', '1', '2', '3', '4', '5', '6', '7', '8', '9', '.': suffixLen = 0 multiplier = float64(Kibi) case 'b', 'B': if len(s) > 2 && s[len(s)-2] == 'i' { suffix = s[len(s)-3] suffixLen = 3 if multiplierFound, multiplier = x.multiplierFromSymbol(suffix); !multiplierFound { return fmt.Errorf("bad suffix %q", suffix) } // Could also support SI form MB, and treat it equivalent to MiB, but perhaps better to reserve it for CountSuffix? //} else if len(s) > 1 { // suffix = s[len(s)-2] // if multiplierFound, multiplier = x.multiplierFromSymbol(suffix); multiplierFound { // suffixLen = 2 // } //} } else { multiplier = float64(SizeSuffixBase) } case 'i', 'I': if len(s) > 1 { suffix = s[len(s)-2] suffixLen = 2 multiplierFound, multiplier = x.multiplierFromSymbol(suffix) } if !multiplierFound { return fmt.Errorf("bad suffix %q", suffix) } default: if multiplierFound, multiplier = x.multiplierFromSymbol(suffix); !multiplierFound { return fmt.Errorf("bad suffix %q", suffix) } } s = s[:len(s)-suffixLen] value, err := strconv.ParseFloat(s, 64) if err != nil { return err } if value < 0 { return fmt.Errorf("size can't be negative %q", s) } value *= multiplier *x = SizeSuffix(value) return nil } // Type of the value func (x SizeSuffix) Type() string { return "SizeSuffix" } // Scan implements the fmt.Scanner interface func (x *SizeSuffix) Scan(s fmt.ScanState, ch rune) error { token, err := s.Token(true, nil) if err != nil { return err } return x.Set(string(token)) } // SizeSuffixList is a slice SizeSuffix values type SizeSuffixList []SizeSuffix func (l SizeSuffixList) Len() int { return len(l) } func (l SizeSuffixList) Swap(i, j int) { l[i], l[j] = l[j], l[i] } func (l SizeSuffixList) Less(i, j int) bool { return l[i] < l[j] } // Sort sorts the list func (l SizeSuffixList) Sort() { sort.Sort(l) } // UnmarshalJSONFlag unmarshals a JSON input for a flag. If the input // is a string then it calls the Set method on the flag otherwise it // calls the setInt function with a parsed int64. func UnmarshalJSONFlag(in []byte, x interface{ Set(string) error }, setInt func(int64) error) error { // Try to parse as string first var s string err := json.Unmarshal(in, &s) if err == nil { return x.Set(s) } // If that fails parse as integer var i int64 err = json.Unmarshal(in, &i) if err != nil { return err } return setInt(i) } // UnmarshalJSON makes sure the value can be parsed as a string or integer in JSON func (x *SizeSuffix) UnmarshalJSON(in []byte) error { return UnmarshalJSONFlag(in, x, func(i int64) error { *x = SizeSuffix(i) return nil }) }