// Copyright 2025 The TCell Authors // // Licensed under the Apache License, Version 2.0 (the "License"); // you may not use file except in compliance with the License. // You may obtain a copy of the license at // // http://www.apache.org/licenses/LICENSE-2.0 // // Unless required by applicable law or agreed to in writing, software // distributed under the License is distributed on an "AS IS" BASIS, // WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. // See the License for the specific language governing permissions and // limitations under the License. //go:build !(js && wasm) // +build !js !wasm package tcell import ( "bytes" "encoding/base64" "errors" "io" "maps" "os" "runtime" "strconv" "strings" "sync" "unicode/utf8" "golang.org/x/term" "golang.org/x/text/transform" "github.com/gdamore/tcell/v2/terminfo" ) // NewTerminfoScreen returns a Screen that uses the stock TTY interface // and POSIX terminal control, combined with a terminfo description taken from // the $TERM environment variable. It returns an error if the terminal // is not supported for any reason. // // For terminals that do not support dynamic resize events, the $LINES // $COLUMNS environment variables can be set to the actual window size, // otherwise defaults taken from the terminal database are used. func NewTerminfoScreen() (Screen, error) { return NewTerminfoScreenFromTty(nil) } // LookupTerminfo attempts to find a definition for the named $TERM falling // back to attempting to parse the output from infocmp. func LookupTerminfo(name string) (ti *terminfo.Terminfo, e error) { ti, e = terminfo.LookupTerminfo(name) if e != nil { ti, e = loadDynamicTerminfo(name) if e != nil { return nil, e } terminfo.AddTerminfo(ti) } return } var defaultTerm string // NewTerminfoScreenFromTtyTerminfo returns a Screen using a custom Tty // implementation and custom terminfo specification. // If the passed in tty is nil, then a reasonable default (typically /dev/tty) // is presumed, at least on UNIX hosts. (Windows hosts will typically fail this // call altogether.) // If passed terminfo is nil, then TERM environment variable is queried for // terminal specification. func NewTerminfoScreenFromTtyTerminfo(tty Tty, ti *terminfo.Terminfo) (s Screen, e error) { term := defaultTerm if term == "" { term = os.Getenv("TERM") } if ti == nil { ti, e = LookupTerminfo(term) if e != nil { return nil, e } } t := &tScreen{ti: ti, tty: tty} if len(ti.Mouse) > 0 { t.mouse = []byte(ti.Mouse) } t.prepareKeys() t.buildAcsMap() t.resizeQ = make(chan bool, 1) t.fallback = make(map[rune]string) maps.Copy(t.fallback, RuneFallbacks) return &baseScreen{screenImpl: t}, nil } // NewTerminfoScreenFromTty returns a Screen using a custom Tty implementation. // If the passed in tty is nil, then a reasonable default (typically /dev/tty) // is presumed, at least on UNIX hosts. (Windows hosts will typically fail this // call altogether.) func NewTerminfoScreenFromTty(tty Tty) (Screen, error) { return NewTerminfoScreenFromTtyTerminfo(tty, nil) } // tKeyCode represents a combination of a key code and modifiers. type tKeyCode struct { key Key mod ModMask } // tScreen represents a screen backed by a terminfo implementation. type tScreen struct { ti *terminfo.Terminfo tty Tty h int w int fini bool cells CellBuffer buffering bool // true if we are collecting writes to buf instead of sending directly to out buf bytes.Buffer curstyle Style style Style resizeQ chan bool quit chan struct{} keychan chan []byte cx int cy int mouse []byte clear bool cursorx int cursory int acs map[rune]string charset string encoder transform.Transformer decoder transform.Transformer fallback map[rune]string colors map[Color]Color palette []Color truecolor bool escaped bool buttondn bool finiOnce sync.Once enablePaste string disablePaste string enterUrl string exitUrl string setWinSize string enableFocus string disableFocus string doubleUnder string curlyUnder string dottedUnder string dashedUnder string underColor string underRGB string underFg string // reset underline color to foreground cursorStyles map[CursorStyle]string cursorStyle CursorStyle cursorColor Color cursorRGB string cursorFg string saved *term.State stopQ chan struct{} eventQ chan Event running bool wg sync.WaitGroup mouseFlags MouseFlags pasteEnabled bool focusEnabled bool setTitle string saveTitle string restoreTitle string title string setClipboard string startSyncOut string endSyncOut string enableCsiU string disableCsiU string disableEmojiWA bool // if true don't try to workaround emoji bugs input InputProcessor sync.Mutex } func (t *tScreen) Init() error { if e := t.initialize(); e != nil { return e } t.keychan = make(chan []byte, 10) t.charset = getCharset() if enc := GetEncoding(t.charset); enc != nil { t.encoder = enc.NewEncoder() t.decoder = enc.NewDecoder() } else { return ErrNoCharset } ti := t.ti // environment overrides w := ti.Columns h := ti.Lines if i, _ := strconv.Atoi(os.Getenv("LINES")); i != 0 { h = i } if i, _ := strconv.Atoi(os.Getenv("COLUMNS")); i != 0 { w = i } if t.ti.SetFgBgRGB != "" || t.ti.SetFgRGB != "" || t.ti.SetBgRGB != "" { t.truecolor = true } // A user who wants to have his themes honored can // set this environment variable. if os.Getenv("TCELL_TRUECOLOR") == "disable" { t.truecolor = false } // clip to reasonable limits nColors := min(t.nColors(), 256) t.colors = make(map[Color]Color, nColors) t.palette = make([]Color, nColors) for i := range nColors { t.palette[i] = Color(i) | ColorValid // identity map for our builtin colors t.colors[Color(i)|ColorValid] = Color(i) | ColorValid } t.quit = make(chan struct{}) t.eventQ = make(chan Event, 256) t.input = NewInputProcessor(t.eventQ) t.Lock() t.cx = -1 t.cy = -1 t.style = StyleDefault t.cells.Resize(w, h) t.cursorx = -1 t.cursory = -1 t.resize() t.Unlock() if err := t.engage(); err != nil { return err } return nil } func (t *tScreen) prepareBracketedPaste() { // Another workaround for lack of reporting in terminfo. // We assume if the terminal has a mouse entry, that it // offers bracketed paste. But we allow specific overrides // via our terminal database. if t.ti.Mouse != "" || t.ti.XTermLike { t.enablePaste = "\x1b[?2004h" t.disablePaste = "\x1b[?2004l" } } func (t *tScreen) prepareUnderlines() { if t.ti.XTermLike { t.doubleUnder = "\x1b[4:2m" t.curlyUnder = "\x1b[4:3m" t.dottedUnder = "\x1b[4:4m" t.dashedUnder = "\x1b[4:5m" t.underColor = "\x1b[58:5:%p1%dm" t.underRGB = "\x1b[58:2::%p1%d:%p2%d:%p3%dm" t.underFg = "\x1b[59m" } } func (t *tScreen) prepareExtendedOSC() { // Linux is a special beast - because it has a mouse entry, but does // not swallow these OSC commands properly. if strings.Contains(t.ti.Name, "linux") { return } // More stuff for limits in terminfo. This time we are applying // the most common OSC (operating system commands). Generally // terminals that don't understand these will ignore them. // Again, we condition this based on mouse capabilities. if t.ti.Mouse != "" || t.ti.XTermLike { t.enterUrl = "\x1b]8;%p2%s;%p1%s\x1b\\" t.exitUrl = "\x1b]8;;\x1b\\" } if t.ti.Mouse != "" || t.ti.XTermLike { t.setWinSize = "\x1b[8;%p1%p2%d;%dt" } if t.ti.Mouse != "" || t.ti.XTermLike { t.enableFocus = "\x1b[?1004h" t.disableFocus = "\x1b[?1004l" } if t.ti.XTermLike { t.saveTitle = "\x1b[22;2t" t.restoreTitle = "\x1b[23;2t" // this also tries to request that UTF-8 is allowed in the title t.setTitle = "\x1b[>2t\x1b]2;%p1%s\x1b\\" } if t.setClipboard == "" && t.ti.XTermLike { // this string takes a base64 string and sends it to the clipboard. // it will also be able to retrieve the clipboard using "?" as the // sent string, when we support that. t.setClipboard = "\x1b]52;c;%p1%s\x1b\\" } if t.startSyncOut == "" && t.ti.XTermLike { // this is in theory a queryable private mode, but we just assume it will be ok // The terminals we have been able to test it all either just swallow it, or // handle it. t.startSyncOut = "\x1b[?2026h" t.endSyncOut = "\x1b[?2026l" } if t.enableCsiU == "" && t.ti.XTermLike { if runtime.GOOS == "windows" && os.Getenv("TERM") == "" { // on Windows, if we don't have a TERM, use only win32-input-mode t.enableCsiU = "\x1b[?9001h" t.disableCsiU = "\x1b[?9001l" } else { // three advanced keyboard protocols: // - xterm modifyOtherKeys (uses CSI 27 ~ ) // - kitty csi-u (uses CSI u) // - win32-input-mode (uses CSI _) t.enableCsiU = "\x1b[>4;2m" + "\x1b[>1u" + "\x1b[?9001h" t.disableCsiU = "\x1b[?9001l" + "\x1b[4;0m" } } } func (t *tScreen) prepareCursorStyles() { if t.ti.Mouse != "" || t.ti.XTermLike { t.cursorStyles = map[CursorStyle]string{ CursorStyleDefault: "\x1b[0 q", CursorStyleBlinkingBlock: "\x1b[1 q", CursorStyleSteadyBlock: "\x1b[2 q", CursorStyleBlinkingUnderline: "\x1b[3 q", CursorStyleSteadyUnderline: "\x1b[4 q", CursorStyleBlinkingBar: "\x1b[5 q", CursorStyleSteadyBar: "\x1b[6 q", } if t.cursorRGB == "" { t.cursorRGB = "\x1b]12;#%p1%02x%p2%02x%p3%02x\007" t.cursorFg = "\x1b]112\007" } } } func (t *tScreen) prepareKeys() { ti := t.ti if strings.HasPrefix(ti.Name, "xterm") { // assume its some form of XTerm clone t.ti.XTermLike = true ti.XTermLike = true } t.prepareBracketedPaste() t.prepareCursorStyles() t.prepareUnderlines() t.prepareExtendedOSC() } func (t *tScreen) Fini() { t.finiOnce.Do(t.finish) } func (t *tScreen) finish() { close(t.quit) t.finalize() } func (t *tScreen) SetStyle(style Style) { t.Lock() if !t.fini { t.style = style } t.Unlock() } func (t *tScreen) encodeStr(s string) []byte { var dstBuf [128]byte var buf []byte nb := dstBuf[:] dst := 0 var err error if enc := t.encoder; enc != nil { enc.Reset() dst, _, err = enc.Transform(nb, []byte(s), true) } if err != nil || dst == 0 || nb[0] == '\x1a' { // Combining characters are elided r, _ := utf8.DecodeRuneInString(s) if len(buf) == 0 { if acs, ok := t.acs[r]; ok { buf = append(buf, []byte(acs)...) } else if fb, ok := t.fallback[r]; ok { buf = append(buf, []byte(fb)...) } else { buf = append(buf, '?') } } } else { buf = append(buf, nb[:dst]...) } return buf } func (t *tScreen) sendFgBg(fg Color, bg Color, attr AttrMask) AttrMask { ti := t.ti if t.Colors() == 0 { // foreground vs background, we calculate luminance // and possibly do a reverse video if !fg.Valid() { return attr } v, ok := t.colors[fg] if !ok { v = FindColor(fg, []Color{ColorBlack, ColorWhite}) t.colors[fg] = v } switch v { case ColorWhite: return attr case ColorBlack: return attr ^ AttrReverse } } if fg == ColorReset || bg == ColorReset { t.TPuts(ti.ResetFgBg) } if t.truecolor { if ti.SetFgBgRGB != "" && fg.IsRGB() && bg.IsRGB() { r1, g1, b1 := fg.RGB() r2, g2, b2 := bg.RGB() t.TPuts(ti.TParm(ti.SetFgBgRGB, int(r1), int(g1), int(b1), int(r2), int(g2), int(b2))) return attr } if fg.IsRGB() && ti.SetFgRGB != "" { r, g, b := fg.RGB() t.TPuts(ti.TParm(ti.SetFgRGB, int(r), int(g), int(b))) fg = ColorDefault } if bg.IsRGB() && ti.SetBgRGB != "" { r, g, b := bg.RGB() t.TPuts(ti.TParm(ti.SetBgRGB, int(r), int(g), int(b))) bg = ColorDefault } } if fg.Valid() { if v, ok := t.colors[fg]; ok { fg = v } else { v = FindColor(fg, t.palette) t.colors[fg] = v fg = v } } if bg.Valid() { if v, ok := t.colors[bg]; ok { bg = v } else { v = FindColor(bg, t.palette) t.colors[bg] = v bg = v } } if fg.Valid() && bg.Valid() && ti.SetFgBg != "" { t.TPuts(ti.TParm(ti.SetFgBg, int(fg&0xff), int(bg&0xff))) } else { if fg.Valid() && ti.SetFg != "" { t.TPuts(ti.TParm(ti.SetFg, int(fg&0xff))) } if bg.Valid() && ti.SetBg != "" { t.TPuts(ti.TParm(ti.SetBg, int(bg&0xff))) } } return attr } func (t *tScreen) drawCell(x, y int) int { ti := t.ti str, style, width := t.cells.Get(x, y) if !t.cells.Dirty(x, y) { return width } if y == t.h-1 && x == t.w-1 && t.ti.AutoMargin && ti.DisableAutoMargin == "" && ti.InsertChar != "" { // our solution is somewhat goofy. // we write to the second to the last cell what we want in the last cell, then we // insert a character at that 2nd to last position to shift the last column into // place, then we rewrite that 2nd to last cell. Old terminals suck. t.TPuts(ti.TGoto(x-1, y)) defer func() { t.TPuts(ti.TGoto(x-1, y)) t.TPuts(ti.InsertChar) t.cy = y t.cx = x - 1 t.cells.SetDirty(x-1, y, true) _ = t.drawCell(x-1, y) t.TPuts(t.ti.TGoto(0, 0)) t.cy = 0 t.cx = 0 }() } else if t.cy != y || t.cx != x { t.TPuts(ti.TGoto(x, y)) t.cx = x t.cy = y } if style == StyleDefault { style = t.style } if style != t.curstyle { fg, bg, attrs := style.fg, style.bg, style.attrs t.TPuts(ti.AttrOff) attrs = t.sendFgBg(fg, bg, attrs) if attrs&AttrBold != 0 { t.TPuts(ti.Bold) } if us, uc := style.ulStyle, style.ulColor; us != UnderlineStyleNone { if t.underColor != "" || t.underRGB != "" { if uc == ColorReset { t.TPuts(t.underFg) } else if uc.IsRGB() { if t.underRGB != "" { r, g, b := uc.RGB() t.TPuts(ti.TParm(t.underRGB, int(r), int(g), int(b))) } else { if v, ok := t.colors[uc]; ok { uc = v } else { v = FindColor(uc, t.palette) t.colors[uc] = v uc = v } t.TPuts(ti.TParm(t.underColor, int(uc&0xff))) } } else if uc.Valid() { t.TPuts(ti.TParm(t.underColor, int(uc&0xff))) } } t.TPuts(ti.Underline) // to ensure everyone gets at least a basic underline switch us { case UnderlineStyleDouble: t.TPuts(t.doubleUnder) case UnderlineStyleCurly: t.TPuts(t.curlyUnder) case UnderlineStyleDotted: t.TPuts(t.dottedUnder) case UnderlineStyleDashed: t.TPuts(t.dashedUnder) } } if attrs&AttrReverse != 0 { t.TPuts(ti.Reverse) } if attrs&AttrBlink != 0 { t.TPuts(ti.Blink) } if attrs&AttrDim != 0 { t.TPuts(ti.Dim) } if attrs&AttrItalic != 0 { t.TPuts(ti.Italic) } if attrs&AttrStrikeThrough != 0 { t.TPuts(ti.StrikeThrough) } // URL string can be long, so don't send it unless we really need to if t.enterUrl != "" && t.curstyle.url != style.url { if style.url != "" { t.TPuts(ti.TParm(t.enterUrl, style.url, style.urlId)) } else { t.TPuts(t.exitUrl) } } t.curstyle = style } // now emit runes - taking care to not overrun width with a // wide character, and to ensure that we emit exactly one regular // character followed up by any residual combing characters if width < 1 { width = 1 } buf := t.encodeStr(str) str = string(buf) if width > 1 && str == "?" { // No FullWidth character support str = "? " t.cx = -1 } if x > t.w-width { // too wide to fit; emit a single space instead width = 1 str = " " } if width > 1 && x+width < t.w { // Clobber over any content in the next cell. // This fixes a problem with some terminals where overwriting two // adjacent single cells with a wide rune would leave an image // of the second cell. This is a workaround for buggy terminals. t.writeString(" \b\b") } t.writeString(str) t.cx += width t.cells.SetDirty(x, y, false) if width > 1 { t.cx = -1 } return width } func (t *tScreen) ShowCursor(x, y int) { t.Lock() t.cursorx = x t.cursory = y t.Unlock() } func (t *tScreen) SetCursor(cs CursorStyle, cc Color) { t.Lock() t.cursorStyle = cs t.cursorColor = cc t.Unlock() } func (t *tScreen) HideCursor() { t.ShowCursor(-1, -1) } func (t *tScreen) showCursor() { x, y := t.cursorx, t.cursory w, h := t.cells.Size() if x < 0 || y < 0 || x >= w || y >= h { t.hideCursor() return } t.TPuts(t.ti.TGoto(x, y)) t.TPuts(t.ti.ShowCursor) if t.cursorStyles != nil { if esc, ok := t.cursorStyles[t.cursorStyle]; ok { t.TPuts(esc) } } if t.cursorRGB != "" { if t.cursorColor == ColorReset { t.TPuts(t.cursorFg) } else if t.cursorColor.Valid() { r, g, b := t.cursorColor.RGB() t.TPuts(t.ti.TParm(t.cursorRGB, int(r), int(g), int(b))) } } t.cx = x t.cy = y } // writeString sends a string to the terminal. The string is sent as-is and // this function does not expand inline padding indications (of the form // $<[delay]> where [delay] is msec). In order to have these expanded, use // TPuts. If the screen is "buffering", the string is collected in a buffer, // with the intention that the entire buffer be sent to the terminal in one // write operation at some point later. func (t *tScreen) writeString(s string) { if t.buffering { _, _ = io.WriteString(&t.buf, s) } else { _, _ = io.WriteString(t.tty, s) } } func (t *tScreen) TPuts(s string) { if t.buffering { t.ti.TPuts(&t.buf, s) } else { t.ti.TPuts(t.tty, s) } } func (t *tScreen) Show() { t.Lock() if !t.fini { t.resize() t.draw() } t.Unlock() } func (t *tScreen) clearScreen() { t.TPuts(t.ti.AttrOff) t.TPuts(t.exitUrl) _ = t.sendFgBg(t.style.fg, t.style.bg, AttrNone) t.TPuts(t.ti.Clear) t.clear = false } func (t *tScreen) startBuffering() { t.TPuts(t.startSyncOut) } func (t *tScreen) endBuffering() { t.TPuts(t.endSyncOut) } func (t *tScreen) hideCursor() { // does not update cursor position if t.ti.HideCursor != "" { t.TPuts(t.ti.HideCursor) } else { // No way to hide cursor, stick it // at bottom right of screen t.cx, t.cy = t.cells.Size() t.TPuts(t.ti.TGoto(t.cx, t.cy)) } } func (t *tScreen) draw() { // clobber cursor position, because we're going to change it all t.cx = -1 t.cy = -1 // make no style assumptions t.curstyle = styleInvalid t.buf.Reset() t.buffering = true t.startBuffering() defer func() { t.buffering = false t.endBuffering() }() // hide the cursor while we move stuff around t.hideCursor() if t.clear { t.clearScreen() } for y := 0; y < t.h; y++ { for x := 0; x < t.w; x++ { width := t.drawCell(x, y) if width > 1 { if x+1 < t.w { // this is necessary so that if we ever // go back to drawing that cell, we // actually will *draw* it. t.cells.SetDirty(x+1, y, true) } } x += width - 1 } } // restore the cursor t.showCursor() _, _ = t.buf.WriteTo(t.tty) } func (t *tScreen) EnableMouse(flags ...MouseFlags) { var f MouseFlags flagsPresent := false for _, flag := range flags { f |= flag flagsPresent = true } if !flagsPresent { f = MouseMotionEvents | MouseDragEvents | MouseButtonEvents } t.Lock() t.mouseFlags = f t.enableMouse(f) t.Unlock() } func (t *tScreen) enableMouse(f MouseFlags) { // Rather than using terminfo to find mouse escape sequences, we rely on the fact that // pretty much *every* terminal that supports mouse tracking follows the // XTerm standards (the modern ones). if len(t.mouse) != 0 { // start by disabling all tracking. t.TPuts("\x1b[?1000l\x1b[?1002l\x1b[?1003l\x1b[?1006l") if f&MouseButtonEvents != 0 { t.TPuts("\x1b[?1000h") } if f&MouseDragEvents != 0 { t.TPuts("\x1b[?1002h") } if f&MouseMotionEvents != 0 { t.TPuts("\x1b[?1003h") } if f&(MouseButtonEvents|MouseDragEvents|MouseMotionEvents) != 0 { t.TPuts("\x1b[?1006h") } } } func (t *tScreen) DisableMouse() { t.Lock() t.mouseFlags = 0 t.enableMouse(0) t.Unlock() } func (t *tScreen) EnablePaste() { t.Lock() t.pasteEnabled = true t.enablePasting(true) t.Unlock() } func (t *tScreen) DisablePaste() { t.Lock() t.pasteEnabled = false t.enablePasting(false) t.Unlock() } func (t *tScreen) enablePasting(on bool) { var s string if on { s = t.enablePaste } else { s = t.disablePaste } if s != "" { t.TPuts(s) } } func (t *tScreen) EnableFocus() { t.Lock() t.focusEnabled = true t.enableFocusReporting() t.Unlock() } func (t *tScreen) DisableFocus() { t.Lock() t.focusEnabled = false t.disableFocusReporting() t.Unlock() } func (t *tScreen) enableFocusReporting() { if t.enableFocus != "" { t.TPuts(t.enableFocus) } } func (t *tScreen) disableFocusReporting() { if t.disableFocus != "" { t.TPuts(t.disableFocus) } } func (t *tScreen) Size() (int, int) { t.Lock() w, h := t.w, t.h t.Unlock() return w, h } func (t *tScreen) resize() { ws, err := t.tty.WindowSize() if err != nil { return } if ws.Width == t.w && ws.Height == t.h { return } t.cx = -1 t.cy = -1 t.cells.Resize(ws.Width, ws.Height) t.cells.Invalidate() t.h = ws.Height t.w = ws.Width t.input.SetSize(ws.Width, ws.Height) } func (t *tScreen) Colors() int { if os.Getenv("NO_COLOR") != "" { return 0 } // this doesn't change, no need for lock if t.truecolor { return 1 << 24 } return t.ti.Colors } // nColors returns the size of the built-in palette. // This is distinct from Colors(), as it will generally // always be a small number. (<= 256) func (t *tScreen) nColors() int { if os.Getenv("NO_COLOR") != "" { return 0 } return t.ti.Colors } // vtACSNames is a map of bytes defined by terminfo that are used in // the terminals Alternate Character Set to represent other glyphs. // For example, the upper left corner of the box drawing set can be // displayed by printing "l" while in the alternate character set. // It's not quite that simple, since the "l" is the terminfo name, // and it may be necessary to use a different character based on // the terminal implementation (or the terminal may lack support for // this altogether). See buildAcsMap below for detail. var vtACSNames = map[byte]rune{ '+': RuneRArrow, ',': RuneLArrow, '-': RuneUArrow, '.': RuneDArrow, '0': RuneBlock, '`': RuneDiamond, 'a': RuneCkBoard, 'b': '␉', // VT100, Not defined by terminfo 'c': '␌', // VT100, Not defined by terminfo 'd': '␋', // VT100, Not defined by terminfo 'e': '␊', // VT100, Not defined by terminfo 'f': RuneDegree, 'g': RunePlMinus, 'h': RuneBoard, 'i': RuneLantern, 'j': RuneLRCorner, 'k': RuneURCorner, 'l': RuneULCorner, 'm': RuneLLCorner, 'n': RunePlus, 'o': RuneS1, 'p': RuneS3, 'q': RuneHLine, 'r': RuneS7, 's': RuneS9, 't': RuneLTee, 'u': RuneRTee, 'v': RuneBTee, 'w': RuneTTee, 'x': RuneVLine, 'y': RuneLEqual, 'z': RuneGEqual, '{': RunePi, '|': RuneNEqual, '}': RuneSterling, '~': RuneBullet, } // buildAcsMap builds a map of characters that we translate from Unicode to // alternate character encodings. To do this, we use the standard VT100 ACS // maps. This is only done if the terminal lacks support for Unicode; we // always prefer to emit Unicode glyphs when we are able. func (t *tScreen) buildAcsMap() { acsstr := t.ti.AltChars t.acs = make(map[rune]string) for len(acsstr) > 2 { srcv := acsstr[0] dstv := string(acsstr[1]) if r, ok := vtACSNames[srcv]; ok { t.acs[r] = t.ti.EnterAcs + dstv + t.ti.ExitAcs } acsstr = acsstr[2:] } } func (t *tScreen) scanInput(buf *bytes.Buffer) { // The end of the buffer isn't necessarily the end of the input, because // large inputs are chunked. Set atEOF to false so the UTF-8 validating decoder // returns ErrShortSrc instead of ErrInvalidUTF8 for incomplete multi-byte codepoints. const atEOF = false for buf.Len() > 0 { utf := make([]byte, min(8, max(buf.Len()*2, 128))) nOut, nIn, e := t.decoder.Transform(utf, buf.Bytes(), atEOF) _ = buf.Next(nIn) t.input.ScanUTF8(utf[:nOut]) if e == transform.ErrShortSrc { return } } } func (t *tScreen) mainLoop(stopQ chan struct{}) { defer t.wg.Done() buf := &bytes.Buffer{} for { select { case <-stopQ: return case <-t.quit: return case <-t.resizeQ: t.Lock() t.cx = -1 t.cy = -1 t.resize() t.cells.Invalidate() t.draw() t.Unlock() continue case chunk := <-t.keychan: buf.Write(chunk) t.scanInput(buf) } } } func (t *tScreen) inputLoop(stopQ chan struct{}) { defer t.wg.Done() for { select { case <-stopQ: return default: } chunk := make([]byte, 128) n, e := t.tty.Read(chunk) switch e { case nil: default: t.Lock() running := t.running t.Unlock() if running { select { case t.eventQ <- NewEventError(e): case <-t.quit: } } return } if n > 0 { t.keychan <- chunk[:n] } } } func (t *tScreen) Sync() { t.Lock() t.cx = -1 t.cy = -1 if !t.fini { t.resize() t.clear = true t.cells.Invalidate() t.draw() } t.Unlock() } func (t *tScreen) CharacterSet() string { return t.charset } func (t *tScreen) RegisterRuneFallback(orig rune, fallback string) { t.Lock() t.fallback[orig] = fallback t.Unlock() } func (t *tScreen) UnregisterRuneFallback(orig rune) { t.Lock() delete(t.fallback, orig) t.Unlock() } func (t *tScreen) CanDisplay(r rune, checkFallbacks bool) bool { if enc := t.encoder; enc != nil { nb := make([]byte, 6) enc.Reset() dst, _, err := enc.Transform(nb, []byte(string(r)), true) if dst != 0 && err == nil && nb[0] != '\x1A' { return true } } // Terminal fallbacks always permitted, since we assume they are // basically nearly perfect renditions. if _, ok := t.acs[r]; ok { return true } if !checkFallbacks { return false } if _, ok := t.fallback[r]; ok { return true } return false } func (t *tScreen) HasMouse() bool { return len(t.mouse) != 0 } func (t *tScreen) HasKey(_ Key) bool { // We always return true return true } func (t *tScreen) SetSize(w, h int) { if t.setWinSize != "" { t.TPuts(t.ti.TParm(t.setWinSize, w, h)) } t.cells.Invalidate() t.resize() } func (t *tScreen) Resize(int, int, int, int) {} func (t *tScreen) Suspend() error { t.disengage() return nil } func (t *tScreen) Resume() error { return t.engage() } func (t *tScreen) Tty() (Tty, bool) { return t.tty, true } // engage is used to place the terminal in raw mode and establish screen size, etc. // Think of this is as tcell "engaging" the clutch, as it's going to be driving the // terminal interface. func (t *tScreen) engage() error { t.Lock() defer t.Unlock() if t.tty == nil { return ErrNoScreen } t.tty.NotifyResize(func() { select { case t.resizeQ <- true: default: } }) if t.running { return errors.New("already engaged") } if err := t.tty.Start(); err != nil { return err } t.running = true if ws, err := t.tty.WindowSize(); err == nil && ws.Width != 0 && ws.Height != 0 { t.cells.Resize(ws.Width, ws.Height) } stopQ := make(chan struct{}) t.stopQ = stopQ t.enableMouse(t.mouseFlags) t.enablePasting(t.pasteEnabled) if t.focusEnabled { t.enableFocusReporting() } ti := t.ti if os.Getenv("TCELL_ALTSCREEN") != "disable" { // Technically this may not be right, but every terminal we know about // (even Wyse 60) uses this to enter the alternate screen buffer, and // possibly save and restore the window title and/or icon. // (In theory there could be terminals that don't support X,Y cursor // positions without a setup command, but we don't support them.) t.TPuts(ti.EnterCA) t.TPuts(t.saveTitle) } t.TPuts(ti.EnterKeypad) t.TPuts(ti.HideCursor) t.TPuts(ti.EnableAcs) t.TPuts(ti.DisableAutoMargin) t.TPuts(ti.Clear) if t.title != "" && t.setTitle != "" { t.TPuts(t.ti.TParm(t.setTitle, t.title)) } t.TPuts(t.enableCsiU) t.wg.Add(2) go t.inputLoop(stopQ) go t.mainLoop(stopQ) return nil } // disengage is used to release the terminal back to support from the caller. // Think of this as tcell disengaging the clutch, so that another application // can take over the terminal interface. This restores the TTY mode that was // present when the application was first started. func (t *tScreen) disengage() { t.Lock() if !t.running { t.Unlock() return } t.running = false stopQ := t.stopQ close(stopQ) _ = t.tty.Drain() t.Unlock() t.tty.NotifyResize(nil) // wait for everything to shut down t.wg.Wait() // shutdown the screen and disable special modes (e.g. mouse and bracketed paste) ti := t.ti t.cells.Resize(0, 0) t.TPuts(ti.ShowCursor) if t.cursorStyles != nil && t.cursorStyle != CursorStyleDefault { t.TPuts(t.cursorStyles[CursorStyleDefault]) } if t.cursorFg != "" && t.cursorColor.Valid() { t.TPuts(t.cursorFg) } t.TPuts(ti.ResetFgBg) t.TPuts(ti.AttrOff) t.TPuts(ti.ExitKeypad) t.TPuts(ti.EnableAutoMargin) t.TPuts(t.disableCsiU) if os.Getenv("TCELL_ALTSCREEN") != "disable" { if t.restoreTitle != "" { t.TPuts(t.restoreTitle) } t.TPuts(ti.Clear) // only needed if ExitCA is empty t.TPuts(ti.ExitCA) } t.enableMouse(0) t.enablePasting(false) t.disableFocusReporting() _ = t.tty.Stop() } // Beep emits a beep to the terminal. func (t *tScreen) Beep() error { t.writeString(string(byte(7))) return nil } // finalize is used to at application shutdown, and restores the terminal // to it's initial state. It should not be called more than once. func (t *tScreen) finalize() { t.disengage() _ = t.tty.Close() } func (t *tScreen) StopQ() <-chan struct{} { return t.quit } func (t *tScreen) EventQ() chan Event { return t.eventQ } func (t *tScreen) GetCells() *CellBuffer { return &t.cells } func (t *tScreen) SetTitle(title string) { t.Lock() t.title = title if t.setTitle != "" && t.running { t.TPuts(t.ti.TParm(t.setTitle, title)) } t.Unlock() } func (t *tScreen) SetClipboard(data []byte) { // Post binary data to the system clipboard. It might be UTF-8, it might not be. t.Lock() if t.setClipboard != "" { encoded := base64.StdEncoding.EncodeToString(data) t.TPuts(t.ti.TParm(t.setClipboard, encoded)) } t.Unlock() } func (t *tScreen) GetClipboard() { t.Lock() if t.setClipboard != "" { t.TPuts(t.ti.TParm(t.setClipboard, "?")) } t.Unlock() }