package runewidth import ( "os" "github.com/rivo/uniseg" ) //go:generate go run script/generate.go var ( // EastAsianWidth will be set true if the current locale is CJK EastAsianWidth bool // StrictEmojiNeutral should be set false if handle broken fonts StrictEmojiNeutral bool = true // DefaultCondition is a condition in current locale DefaultCondition = &Condition{ EastAsianWidth: false, StrictEmojiNeutral: true, } ) func init() { handleEnv() } func handleEnv() { env := os.Getenv("RUNEWIDTH_EASTASIAN") if env == "" { EastAsianWidth = IsEastAsian() } else { EastAsianWidth = env == "1" } // update DefaultCondition DefaultCondition.EastAsianWidth = EastAsianWidth } type interval struct { first rune last rune } type table []interval func inTables(r rune, ts ...table) bool { for _, t := range ts { if inTable(r, t) { return true } } return false } func inTable(r rune, t table) bool { if r < t[0].first { return false } bot := 0 top := len(t) - 1 for top >= bot { mid := (bot + top) >> 1 switch { case t[mid].last < r: bot = mid + 1 case t[mid].first > r: top = mid - 1 default: return true } } return false } var private = table{ {0x00E000, 0x00F8FF}, {0x0F0000, 0x0FFFFD}, {0x100000, 0x10FFFD}, } var nonprint = table{ {0x0000, 0x001F}, {0x007F, 0x009F}, {0x00AD, 0x00AD}, {0x070F, 0x070F}, {0x180B, 0x180E}, {0x200B, 0x200F}, {0x2028, 0x202E}, {0x206A, 0x206F}, {0xD800, 0xDFFF}, {0xFEFF, 0xFEFF}, {0xFFF9, 0xFFFB}, {0xFFFE, 0xFFFF}, } // Condition have flag EastAsianWidth whether the current locale is CJK or not. type Condition struct { EastAsianWidth bool StrictEmojiNeutral bool } // NewCondition return new instance of Condition which is current locale. func NewCondition() *Condition { return &Condition{ EastAsianWidth: EastAsianWidth, StrictEmojiNeutral: StrictEmojiNeutral, } } // RuneWidth returns the number of cells in r. // See http://www.unicode.org/reports/tr11/ func (c *Condition) RuneWidth(r rune) int { // optimized version, verified by TestRuneWidthChecksums() if !c.EastAsianWidth { switch { case r < 0x20 || r > 0x10FFFF: return 0 case (r >= 0x7F && r <= 0x9F) || r == 0xAD: // nonprint return 0 case r < 0x300: return 1 case inTable(r, narrow): return 1 case inTables(r, nonprint, combining): return 0 case inTable(r, doublewidth): return 2 default: return 1 } } else { switch { case r < 0 || r > 0x10FFFF || inTables(r, nonprint, combining): return 0 case inTable(r, narrow): return 1 case inTables(r, ambiguous, doublewidth): return 2 case !c.StrictEmojiNeutral && inTables(r, ambiguous, emoji, narrow): return 2 default: return 1 } } } // StringWidth return width as you can see func (c *Condition) StringWidth(s string) (width int) { g := uniseg.NewGraphemes(s) for g.Next() { var chWidth int for _, r := range g.Runes() { chWidth = c.RuneWidth(r) if chWidth > 0 { break // Our best guess at this point is to use the width of the first non-zero-width rune. } } width += chWidth } return } // Truncate return string truncated with w cells func (c *Condition) Truncate(s string, w int, tail string) string { if c.StringWidth(s) <= w { return s } w -= c.StringWidth(tail) var width int pos := len(s) g := uniseg.NewGraphemes(s) for g.Next() { var chWidth int for _, r := range g.Runes() { chWidth = c.RuneWidth(r) if chWidth > 0 { break // See StringWidth() for details. } } if width+chWidth > w { pos, _ = g.Positions() break } width += chWidth } return s[:pos] + tail } // Wrap return string wrapped with w cells func (c *Condition) Wrap(s string, w int) string { width := 0 out := "" for _, r := range []rune(s) { cw := c.RuneWidth(r) if r == '\n' { out += string(r) width = 0 continue } else if width+cw > w { out += "\n" width = 0 out += string(r) width += cw continue } out += string(r) width += cw } return out } // FillLeft return string filled in left by spaces in w cells func (c *Condition) FillLeft(s string, w int) string { width := c.StringWidth(s) count := w - width if count > 0 { b := make([]byte, count) for i := range b { b[i] = ' ' } return string(b) + s } return s } // FillRight return string filled in left by spaces in w cells func (c *Condition) FillRight(s string, w int) string { width := c.StringWidth(s) count := w - width if count > 0 { b := make([]byte, count) for i := range b { b[i] = ' ' } return s + string(b) } return s } // RuneWidth returns the number of cells in r. // See http://www.unicode.org/reports/tr11/ func RuneWidth(r rune) int { return DefaultCondition.RuneWidth(r) } // IsAmbiguousWidth returns whether is ambiguous width or not. func IsAmbiguousWidth(r rune) bool { return inTables(r, private, ambiguous) } // IsNeutralWidth returns whether is neutral width or not. func IsNeutralWidth(r rune) bool { return inTable(r, neutral) } // StringWidth return width as you can see func StringWidth(s string) (width int) { return DefaultCondition.StringWidth(s) } // Truncate return string truncated with w cells func Truncate(s string, w int, tail string) string { return DefaultCondition.Truncate(s, w, tail) } // Wrap return string wrapped with w cells func Wrap(s string, w int) string { return DefaultCondition.Wrap(s, w) } // FillLeft return string filled in left by spaces in w cells func FillLeft(s string, w int) string { return DefaultCondition.FillLeft(s, w) } // FillRight return string filled in left by spaces in w cells func FillRight(s string, w int) string { return DefaultCondition.FillRight(s, w) }