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tcell/tscreen.go
Garrett D'Amore 8f08469772 fixes #167 Break up the database 
This completely restructures the database of terminal types, putting
each terminal in its own file.  We also compress the database files,
and use infocmp instead of trying to use the C level API.

The mkdatabase script will rebuild the entire database from the terminfo
files on the system.  Individual entries can also be built by simply running
the mkinfo program with the terminal type.
2017-11-24 13:13:06 -08:00

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// Copyright 2017 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.
package tcell
import (
"bytes"
"io"
"os"
"strconv"
"sync"
"time"
"unicode/utf8"
"golang.org/x/text/transform"
"github.com/gdamore/tcell/terminfo"
)
// NewTerminfoScreen returns a Screen that uses the stock TTY interface
// and POSIX termios, 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) {
ti, e := terminfo.LookupTerminfo(os.Getenv("TERM"))
if e != nil {
return nil, e
}
t := &tScreen{ti: ti}
t.keyexist = make(map[Key]bool)
t.keycodes = make(map[string]*tKeyCode)
if len(ti.Mouse) > 0 {
t.mouse = []byte(ti.Mouse)
}
t.prepareKeys()
t.buildAcsMap()
t.sigwinch = make(chan os.Signal, 10)
t.fallback = make(map[rune]string)
for k, v := range RuneFallbacks {
t.fallback[k] = v
}
return t, 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
h int
w int
fini bool
cells CellBuffer
in *os.File
out *os.File
curstyle Style
style Style
evch chan Event
sigwinch chan os.Signal
quit chan struct{}
indoneq chan struct{}
keyexist map[Key]bool
keycodes map[string]*tKeyCode
keychan chan []byte
keytimer *time.Timer
keyexpire time.Time
cx int
cy int
mouse []byte
clear bool
cursorx int
cursory int
tiosp *termiosPrivate
baud int
wasbtn bool
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
sync.Mutex
}
func (t *tScreen) Init() error {
t.evch = make(chan Event, 10)
t.indoneq = make(chan struct{})
t.keychan = make(chan []byte, 10)
t.keytimer = time.NewTimer(time.Millisecond * 50)
t.charset = "UTF-8"
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 e := t.termioInit(); e != nil {
return e
}
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
}
if !t.truecolor {
t.colors = make(map[Color]Color)
t.palette = make([]Color, t.Colors())
for i := 0; i < t.Colors(); i++ {
t.palette[i] = Color(i)
// identity map for our builtin colors
t.colors[Color(i)] = Color(i)
}
}
t.TPuts(ti.EnterCA)
t.TPuts(ti.HideCursor)
t.TPuts(ti.EnableAcs)
t.TPuts(ti.Clear)
t.quit = make(chan struct{})
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()
go t.mainLoop()
go t.inputLoop()
return nil
}
func (t *tScreen) prepareKeyMod(key Key, mod ModMask, val string) {
if val != "" {
// Do not overrride codes that already exist
if _, exist := t.keycodes[val]; !exist {
t.keyexist[key] = true
t.keycodes[val] = &tKeyCode{key: key, mod: mod}
}
}
}
func (t *tScreen) prepareKey(key Key, val string) {
t.prepareKeyMod(key, ModNone, val)
}
func (t *tScreen) prepareKeys() {
ti := t.ti
t.prepareKey(KeyBackspace, ti.KeyBackspace)
t.prepareKey(KeyF1, ti.KeyF1)
t.prepareKey(KeyF2, ti.KeyF2)
t.prepareKey(KeyF3, ti.KeyF3)
t.prepareKey(KeyF4, ti.KeyF4)
t.prepareKey(KeyF5, ti.KeyF5)
t.prepareKey(KeyF6, ti.KeyF6)
t.prepareKey(KeyF7, ti.KeyF7)
t.prepareKey(KeyF8, ti.KeyF8)
t.prepareKey(KeyF9, ti.KeyF9)
t.prepareKey(KeyF10, ti.KeyF10)
t.prepareKey(KeyF11, ti.KeyF11)
t.prepareKey(KeyF12, ti.KeyF12)
t.prepareKey(KeyF13, ti.KeyF13)
t.prepareKey(KeyF14, ti.KeyF14)
t.prepareKey(KeyF15, ti.KeyF15)
t.prepareKey(KeyF16, ti.KeyF16)
t.prepareKey(KeyF17, ti.KeyF17)
t.prepareKey(KeyF18, ti.KeyF18)
t.prepareKey(KeyF19, ti.KeyF19)
t.prepareKey(KeyF20, ti.KeyF20)
t.prepareKey(KeyF21, ti.KeyF21)
t.prepareKey(KeyF22, ti.KeyF22)
t.prepareKey(KeyF23, ti.KeyF23)
t.prepareKey(KeyF24, ti.KeyF24)
t.prepareKey(KeyF25, ti.KeyF25)
t.prepareKey(KeyF26, ti.KeyF26)
t.prepareKey(KeyF27, ti.KeyF27)
t.prepareKey(KeyF28, ti.KeyF28)
t.prepareKey(KeyF29, ti.KeyF29)
t.prepareKey(KeyF30, ti.KeyF30)
t.prepareKey(KeyF31, ti.KeyF31)
t.prepareKey(KeyF32, ti.KeyF32)
t.prepareKey(KeyF33, ti.KeyF33)
t.prepareKey(KeyF34, ti.KeyF34)
t.prepareKey(KeyF35, ti.KeyF35)
t.prepareKey(KeyF36, ti.KeyF36)
t.prepareKey(KeyF37, ti.KeyF37)
t.prepareKey(KeyF38, ti.KeyF38)
t.prepareKey(KeyF39, ti.KeyF39)
t.prepareKey(KeyF40, ti.KeyF40)
t.prepareKey(KeyF41, ti.KeyF41)
t.prepareKey(KeyF42, ti.KeyF42)
t.prepareKey(KeyF43, ti.KeyF43)
t.prepareKey(KeyF44, ti.KeyF44)
t.prepareKey(KeyF45, ti.KeyF45)
t.prepareKey(KeyF46, ti.KeyF46)
t.prepareKey(KeyF47, ti.KeyF47)
t.prepareKey(KeyF48, ti.KeyF48)
t.prepareKey(KeyF49, ti.KeyF49)
t.prepareKey(KeyF50, ti.KeyF50)
t.prepareKey(KeyF51, ti.KeyF51)
t.prepareKey(KeyF52, ti.KeyF52)
t.prepareKey(KeyF53, ti.KeyF53)
t.prepareKey(KeyF54, ti.KeyF54)
t.prepareKey(KeyF55, ti.KeyF55)
t.prepareKey(KeyF56, ti.KeyF56)
t.prepareKey(KeyF57, ti.KeyF57)
t.prepareKey(KeyF58, ti.KeyF58)
t.prepareKey(KeyF59, ti.KeyF59)
t.prepareKey(KeyF60, ti.KeyF60)
t.prepareKey(KeyF61, ti.KeyF61)
t.prepareKey(KeyF62, ti.KeyF62)
t.prepareKey(KeyF63, ti.KeyF63)
t.prepareKey(KeyF64, ti.KeyF64)
t.prepareKey(KeyInsert, ti.KeyInsert)
t.prepareKey(KeyDelete, ti.KeyDelete)
t.prepareKey(KeyHome, ti.KeyHome)
t.prepareKey(KeyEnd, ti.KeyEnd)
t.prepareKey(KeyUp, ti.KeyUp)
t.prepareKey(KeyDown, ti.KeyDown)
t.prepareKey(KeyLeft, ti.KeyLeft)
t.prepareKey(KeyRight, ti.KeyRight)
t.prepareKey(KeyPgUp, ti.KeyPgUp)
t.prepareKey(KeyPgDn, ti.KeyPgDn)
t.prepareKey(KeyHelp, ti.KeyHelp)
t.prepareKey(KeyPrint, ti.KeyPrint)
t.prepareKey(KeyCancel, ti.KeyCancel)
t.prepareKey(KeyExit, ti.KeyExit)
t.prepareKey(KeyBacktab, ti.KeyBacktab)
t.prepareKeyMod(KeyRight, ModShift, ti.KeyShfRight)
t.prepareKeyMod(KeyLeft, ModShift, ti.KeyShfLeft)
t.prepareKeyMod(KeyUp, ModShift, ti.KeyShfUp)
t.prepareKeyMod(KeyDown, ModShift, ti.KeyShfDown)
t.prepareKeyMod(KeyHome, ModShift, ti.KeyShfHome)
t.prepareKeyMod(KeyEnd, ModShift, ti.KeyShfEnd)
t.prepareKeyMod(KeyRight, ModCtrl, ti.KeyCtrlRight)
t.prepareKeyMod(KeyLeft, ModCtrl, ti.KeyCtrlLeft)
t.prepareKeyMod(KeyUp, ModCtrl, ti.KeyCtrlUp)
t.prepareKeyMod(KeyDown, ModCtrl, ti.KeyCtrlDown)
t.prepareKeyMod(KeyHome, ModCtrl, ti.KeyCtrlHome)
t.prepareKeyMod(KeyEnd, ModCtrl, ti.KeyCtrlEnd)
t.prepareKeyMod(KeyRight, ModAlt, ti.KeyAltRight)
t.prepareKeyMod(KeyLeft, ModAlt, ti.KeyAltLeft)
t.prepareKeyMod(KeyUp, ModAlt, ti.KeyAltUp)
t.prepareKeyMod(KeyDown, ModAlt, ti.KeyAltDown)
t.prepareKeyMod(KeyHome, ModAlt, ti.KeyAltHome)
t.prepareKeyMod(KeyEnd, ModAlt, ti.KeyAltEnd)
t.prepareKeyMod(KeyRight, ModAlt, ti.KeyMetaRight)
t.prepareKeyMod(KeyLeft, ModAlt, ti.KeyMetaLeft)
t.prepareKeyMod(KeyUp, ModAlt, ti.KeyMetaUp)
t.prepareKeyMod(KeyDown, ModAlt, ti.KeyMetaDown)
t.prepareKeyMod(KeyHome, ModAlt, ti.KeyMetaHome)
t.prepareKeyMod(KeyEnd, ModAlt, ti.KeyMetaEnd)
t.prepareKeyMod(KeyRight, ModAlt|ModShift, ti.KeyAltShfRight)
t.prepareKeyMod(KeyLeft, ModAlt|ModShift, ti.KeyAltShfLeft)
t.prepareKeyMod(KeyUp, ModAlt|ModShift, ti.KeyAltShfUp)
t.prepareKeyMod(KeyDown, ModAlt|ModShift, ti.KeyAltShfDown)
t.prepareKeyMod(KeyHome, ModAlt|ModShift, ti.KeyAltShfHome)
t.prepareKeyMod(KeyEnd, ModAlt|ModShift, ti.KeyAltShfEnd)
t.prepareKeyMod(KeyRight, ModAlt|ModShift, ti.KeyMetaShfRight)
t.prepareKeyMod(KeyLeft, ModAlt|ModShift, ti.KeyMetaShfLeft)
t.prepareKeyMod(KeyUp, ModAlt|ModShift, ti.KeyMetaShfUp)
t.prepareKeyMod(KeyDown, ModAlt|ModShift, ti.KeyMetaShfDown)
t.prepareKeyMod(KeyHome, ModAlt|ModShift, ti.KeyMetaShfHome)
t.prepareKeyMod(KeyEnd, ModAlt|ModShift, ti.KeyMetaShfEnd)
t.prepareKeyMod(KeyRight, ModCtrl|ModShift, ti.KeyCtrlShfRight)
t.prepareKeyMod(KeyLeft, ModCtrl|ModShift, ti.KeyCtrlShfLeft)
t.prepareKeyMod(KeyUp, ModCtrl|ModShift, ti.KeyCtrlShfUp)
t.prepareKeyMod(KeyDown, ModCtrl|ModShift, ti.KeyCtrlShfDown)
t.prepareKeyMod(KeyHome, ModCtrl|ModShift, ti.KeyCtrlShfHome)
t.prepareKeyMod(KeyEnd, ModCtrl|ModShift, ti.KeyCtrlShfEnd)
// Sadly, xterm handling of keycodes is somewhat erratic. In
// particular, different codes are sent depending on application
// mode is in use or not, and the entries for many of these are
// simply absent from terminfo on many systems. So we insert
// a number of escape sequences if they are not already used, in
// order to have the widest correct usage. Note that prepareKey
// will not inject codes if the escape sequence is already known.
// We also only do this for terminals that have the application
// mode present.
// Cursor mode
if ti.EnterKeypad != "" {
t.prepareKey(KeyUp, "\x1b[A")
t.prepareKey(KeyDown, "\x1b[B")
t.prepareKey(KeyRight, "\x1b[C")
t.prepareKey(KeyLeft, "\x1b[D")
t.prepareKey(KeyEnd, "\x1b[F")
t.prepareKey(KeyHome, "\x1b[H")
t.prepareKey(KeyDelete, "\x1b[3~")
t.prepareKey(KeyHome, "\x1b[1~")
t.prepareKey(KeyEnd, "\x1b[4~")
t.prepareKey(KeyPgUp, "\x1b[5~")
t.prepareKey(KeyPgDn, "\x1b[6~")
// Application mode
t.prepareKey(KeyUp, "\x1bOA")
t.prepareKey(KeyDown, "\x1bOB")
t.prepareKey(KeyRight, "\x1bOC")
t.prepareKey(KeyLeft, "\x1bOD")
t.prepareKey(KeyHome, "\x1bOH")
}
outer:
// Add key mappings for control keys.
for i := 0; i < ' '; i++ {
// Do not insert direct key codes for ambiguous keys.
// For example, ESC is used for lots of other keys, so
// when parsing this we don't want to fast path handling
// of it, but instead wait a bit before parsing it as in
// isolation.
for esc := range t.keycodes {
if []byte(esc)[0] == byte(i) {
continue outer
}
}
t.keyexist[Key(i)] = true
mod := ModCtrl
switch Key(i) {
case KeyBS, KeyTAB, KeyESC, KeyCR:
// directly typeable- no control sequence
mod = ModNone
}
t.keycodes[string(rune(i))] = &tKeyCode{key: Key(i), mod: mod}
}
}
func (t *tScreen) Fini() {
ti := t.ti
t.Lock()
t.cells.Resize(0, 0)
t.TPuts(ti.ShowCursor)
t.TPuts(ti.AttrOff)
t.TPuts(ti.Clear)
t.TPuts(ti.ExitCA)
t.TPuts(ti.ExitKeypad)
t.TPuts(ti.TParm(ti.MouseMode, 0))
t.curstyle = Style(-1)
t.clear = false
t.fini = true
t.Unlock()
if t.quit != nil {
close(t.quit)
}
t.termioFini()
}
func (t *tScreen) SetStyle(style Style) {
t.Lock()
if !t.fini {
t.style = style
}
t.Unlock()
}
func (t *tScreen) Clear() {
t.Fill(' ', t.style)
}
func (t *tScreen) Fill(r rune, style Style) {
t.Lock()
if !t.fini {
t.cells.Fill(r, style)
}
t.Unlock()
}
func (t *tScreen) SetContent(x, y int, mainc rune, combc []rune, style Style) {
t.Lock()
if !t.fini {
t.cells.SetContent(x, y, mainc, combc, style)
}
t.Unlock()
}
func (t *tScreen) GetContent(x, y int) (rune, []rune, Style, int) {
t.Lock()
mainc, combc, style, width := t.cells.GetContent(x, y)
t.Unlock()
return mainc, combc, style, width
}
func (t *tScreen) SetCell(x, y int, style Style, ch ...rune) {
if len(ch) > 0 {
t.SetContent(x, y, ch[0], ch[1:], style)
} else {
t.SetContent(x, y, ' ', nil, style)
}
}
func (t *tScreen) encodeRune(r rune, buf []byte) []byte {
nb := make([]byte, 6)
ob := make([]byte, 6)
num := utf8.EncodeRune(ob, r)
ob = ob[:num]
dst := 0
var err error
if enc := t.encoder; enc != nil {
enc.Reset()
dst, _, err = enc.Transform(nb, ob, true)
}
if err != nil || dst == 0 || nb[0] == '\x1a' {
// Combining characters are elided
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) {
ti := t.ti
if ti.Colors == 0 {
return
}
if t.truecolor {
if ti.SetFgBgRGB != "" &&
fg != ColorDefault && bg != ColorDefault {
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)))
} else {
if fg != ColorDefault && ti.SetFgRGB != "" {
r, g, b := fg.RGB()
t.TPuts(ti.TParm(ti.SetFgRGB,
int(r), int(g), int(b)))
}
if bg != ColorDefault && ti.SetBgRGB != "" {
r, g, b := bg.RGB()
t.TPuts(ti.TParm(ti.SetBgRGB,
int(r), int(g), int(b)))
}
}
return
}
if fg != ColorDefault {
if v, ok := t.colors[fg]; ok {
fg = v
} else {
v = FindColor(fg, t.palette)
t.colors[fg] = v
fg = v
}
}
if bg != ColorDefault {
if v, ok := t.colors[bg]; ok {
bg = v
} else {
v = FindColor(bg, t.palette)
t.colors[bg] = v
bg = v
}
}
if ti.SetFgBg != "" && fg != ColorDefault && bg != ColorDefault {
t.TPuts(ti.TParm(ti.SetFgBg, int(fg), int(bg)))
} else {
if fg != ColorDefault && ti.SetFg != "" {
t.TPuts(ti.TParm(ti.SetFg, int(fg)))
}
if bg != ColorDefault && ti.SetBg != "" {
t.TPuts(ti.TParm(ti.SetBg, int(bg)))
}
}
}
func (t *tScreen) drawCell(x, y int) int {
ti := t.ti
mainc, combc, style, width := t.cells.GetContent(x, y)
if !t.cells.Dirty(x, y) {
return width
}
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.Decompose()
t.TPuts(ti.AttrOff)
t.sendFgBg(fg, bg)
if attrs&AttrBold != 0 {
t.TPuts(ti.Bold)
}
if attrs&AttrUnderline != 0 {
t.TPuts(ti.Underline)
}
if attrs&AttrReverse != 0 {
t.TPuts(ti.Reverse)
}
if attrs&AttrBlink != 0 {
t.TPuts(ti.Blink)
}
if attrs&AttrDim != 0 {
t.TPuts(ti.Dim)
}
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
}
var str string
buf := make([]byte, 0, 6)
buf = t.encodeRune(mainc, buf)
for _, r := range combc {
buf = t.encodeRune(r, buf)
}
str = string(buf)
if width > 1 && str == "?" {
// No FullWidth character support
str = "? "
t.cx = -1
}
// XXX: check for hazeltine not being able to display ~
if x > t.w-width {
// too wide to fit; emit a single space instead
width = 1
str = " "
}
io.WriteString(t.out, 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) 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)
t.cx = x
t.cy = y
}
func (t *tScreen) TPuts(s string) {
t.ti.TPuts(t.out, s, t.baud)
}
func (t *tScreen) Show() {
t.Lock()
if !t.fini {
t.resize()
t.draw()
}
t.Unlock()
}
func (t *tScreen) clearScreen() {
fg, bg, _ := t.style.Decompose()
t.sendFgBg(fg, bg)
t.TPuts(t.ti.Clear)
t.clear = false
}
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 gonna change it all
t.cx = -1
t.cy = -1
// 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()
}
func (t *tScreen) EnableMouse() {
if len(t.mouse) != 0 {
t.TPuts(t.ti.TParm(t.ti.MouseMode, 1))
}
}
func (t *tScreen) DisableMouse() {
if len(t.mouse) != 0 {
t.TPuts(t.ti.TParm(t.ti.MouseMode, 0))
}
}
func (t *tScreen) Size() (int, int) {
t.Lock()
w, h := t.w, t.h
t.Unlock()
return w, h
}
func (t *tScreen) resize() {
if w, h, e := t.getWinSize(); e == nil {
if w != t.w || h != t.h {
t.cx = -1
t.cy = -1
t.cells.Resize(w, h)
t.cells.Invalidate()
t.h = h
t.w = w
ev := NewEventResize(w, h)
t.PostEvent(ev)
}
}
}
func (t *tScreen) Colors() int {
// this doesn't change, no need for lock
if t.truecolor {
return 1 << 24
}
return t.ti.Colors
}
func (t *tScreen) PollEvent() Event {
select {
case <-t.quit:
return nil
case ev := <-t.evch:
return ev
}
}
// 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.
// Its 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) PostEventWait(ev Event) {
t.evch <- ev
}
func (t *tScreen) PostEvent(ev Event) error {
select {
case t.evch <- ev:
return nil
default:
return ErrEventQFull
}
}
func (t *tScreen) clip(x, y int) (int, int) {
w, h := t.cells.Size()
if x < 0 {
x = 0
}
if y < 0 {
y = 0
}
if x > w-1 {
x = w - 1
}
if y > h-1 {
y = h - 1
}
return x, y
}
func (t *tScreen) postMouseEvent(x, y, btn int) {
// XTerm mouse events only report at most one button at a time,
// which may include a wheel button. Wheel motion events are
// reported as single impulses, while other button events are reported
// as separate press & release events.
button := ButtonNone
mod := ModNone
// Mouse wheel has bit 6 set, no release events. It should be noted
// that wheel events are sometimes misdelivered as mouse button events
// during a click-drag, so we debounce these, considering them to be
// button press events unless we see an intervening release event.
switch btn & 0x43 {
case 0:
button = Button1
t.wasbtn = true
case 1:
button = Button2
t.wasbtn = true
case 2:
button = Button3
t.wasbtn = true
case 3:
button = ButtonNone
t.wasbtn = false
case 0x40:
if !t.wasbtn {
button = WheelUp
} else {
button = Button1
}
case 0x41:
if !t.wasbtn {
button = WheelDown
} else {
button = Button2
}
}
if btn&0x4 != 0 {
mod |= ModShift
}
if btn&0x8 != 0 {
mod |= ModAlt
}
if btn&0x10 != 0 {
mod |= ModCtrl
}
// Some terminals will report mouse coordinates outside the
// screen, especially with click-drag events. Clip the coordinates
// to the screen in that case.
x, y = t.clip(x, y)
ev := NewEventMouse(x, y, button, mod)
t.PostEvent(ev)
}
// parseSgrMouse attempts to locate an SGR mouse record at the start of the
// buffer. It returns true, true if it found one, and the associated bytes
// be removed from the buffer. It returns true, false if the buffer might
// contain such an event, but more bytes are necessary (partial match), and
// false, false if the content is definitely *not* an SGR mouse record.
func (t *tScreen) parseSgrMouse(buf *bytes.Buffer) (bool, bool) {
b := buf.Bytes()
var x, y, btn, state int
dig := false
neg := false
motion := false
i := 0
val := 0
for i = range b {
switch b[i] {
case '\x1b':
if state != 0 {
return false, false
}
state = 1
case '\x9b':
if state != 0 {
return false, false
}
state = 2
case '[':
if state != 1 {
return false, false
}
state = 2
case '<':
if state != 2 {
return false, false
}
val = 0
dig = false
neg = false
state = 3
case '-':
if state != 3 && state != 4 && state != 5 {
return false, false
}
if dig || neg {
return false, false
}
neg = true // stay in state
case '0', '1', '2', '3', '4', '5', '6', '7', '8', '9':
if state != 3 && state != 4 && state != 5 {
return false, false
}
val *= 10
val += int(b[i] - '0')
dig = true // stay in state
case ';':
if neg {
val = -val
}
switch state {
case 3:
btn, val = val, 0
neg, dig, state = false, false, 4
case 4:
x, val = val-1, 0
neg, dig, state = false, false, 5
default:
return false, false
}
case 'm', 'M':
if state != 5 {
return false, false
}
if neg {
val = -val
}
y = val - 1
motion = (btn & 32) != 0
btn &^= 32
if b[i] == 'm' {
// mouse release, clear all buttons
btn |= 3
btn &^= 0x40
t.buttondn = false
} else if motion {
/*
* Some broken terminals appear to send
* mouse button one motion events, instead of
* encoding 35 (no buttons) into these events.
* We resolve these by looking for a non-motion
* event first.
*/
if !t.buttondn {
btn |= 3
btn &^= 0x40
}
} else {
t.buttondn = true
}
// consume the event bytes
for i >= 0 {
buf.ReadByte()
i--
}
t.postMouseEvent(x, y, btn)
return true, true
}
}
// incomplete & inconclusve at this point
return true, false
}
// parseXtermMouse is like parseSgrMouse, but it parses a legacy
// X11 mouse record.
func (t *tScreen) parseXtermMouse(buf *bytes.Buffer) (bool, bool) {
b := buf.Bytes()
state := 0
btn := 0
x := 0
y := 0
for i := range b {
switch state {
case 0:
switch b[i] {
case '\x1b':
state = 1
case '\x9b':
state = 2
default:
return false, false
}
case 1:
if b[i] != '[' {
return false, false
}
state = 2
case 2:
if b[i] != 'M' {
return false, false
}
state++
case 3:
btn = int(b[i])
state++
case 4:
x = int(b[i]) - 32 - 1
state++
case 5:
y = int(b[i]) - 32 - 1
for i >= 0 {
buf.ReadByte()
i--
}
t.postMouseEvent(x, y, btn)
return true, true
}
}
return true, false
}
func (t *tScreen) parseFunctionKey(buf *bytes.Buffer) (bool, bool) {
b := buf.Bytes()
partial := false
for e, k := range t.keycodes {
esc := []byte(e)
if (len(esc) == 1) && (esc[0] == '\x1b') {
continue
}
if bytes.HasPrefix(b, esc) {
// matched
var r rune
if len(esc) == 1 {
r = rune(b[0])
}
mod := k.mod
if t.escaped {
mod |= ModAlt
t.escaped = false
}
ev := NewEventKey(k.key, r, mod)
t.PostEvent(ev)
for i := 0; i < len(esc); i++ {
buf.ReadByte()
}
return true, true
}
if bytes.HasPrefix(esc, b) {
partial = true
}
}
return partial, false
}
func (t *tScreen) parseRune(buf *bytes.Buffer) (bool, bool) {
b := buf.Bytes()
if b[0] >= ' ' && b[0] <= 0x7F {
// printable ASCII easy to deal with -- no encodings
mod := ModNone
if t.escaped {
mod = ModAlt
t.escaped = false
}
ev := NewEventKey(KeyRune, rune(b[0]), mod)
t.PostEvent(ev)
buf.ReadByte()
return true, true
}
if b[0] < 0x80 {
// Low numbered values are control keys, not runes.
return false, false
}
utfb := make([]byte, 12)
for l := 1; l <= len(b); l++ {
t.decoder.Reset()
nout, nin, e := t.decoder.Transform(utfb, b[:l], true)
if e == transform.ErrShortSrc {
continue
}
if nout != 0 {
r, _ := utf8.DecodeRune(utfb[:nout])
if r != utf8.RuneError {
mod := ModNone
if t.escaped {
mod = ModAlt
t.escaped = false
}
ev := NewEventKey(KeyRune, r, mod)
t.PostEvent(ev)
}
for nin > 0 {
buf.ReadByte()
nin--
}
return true, true
}
}
// Looks like potential escape
return true, false
}
func (t *tScreen) scanInput(buf *bytes.Buffer, expire bool) {
t.Lock()
defer t.Unlock()
for {
b := buf.Bytes()
if len(b) == 0 {
buf.Reset()
return
}
partials := 0
if part, comp := t.parseRune(buf); comp {
continue
} else if part {
partials++
}
if part, comp := t.parseFunctionKey(buf); comp {
continue
} else if part {
partials++
}
// Only parse mouse records if this term claims to have
// mouse support
if t.ti.Mouse != "" {
if part, comp := t.parseXtermMouse(buf); comp {
continue
} else if part {
partials++
}
if part, comp := t.parseSgrMouse(buf); comp {
continue
} else if part {
partials++
}
}
if partials == 0 || expire {
if b[0] == '\x1b' {
if len(b) == 1 {
ev := NewEventKey(KeyEsc, 0, ModNone)
t.PostEvent(ev)
t.escaped = false
} else {
t.escaped = true
}
buf.ReadByte()
continue
}
// Nothing was going to match, or we timed out
// waiting for more data -- just deliver the characters
// to the app & let them sort it out. Possibly we
// should only do this for control characters like ESC.
by, _ := buf.ReadByte()
mod := ModNone
if t.escaped {
t.escaped = false
mod = ModAlt
}
ev := NewEventKey(KeyRune, rune(by), mod)
t.PostEvent(ev)
continue
}
// well we have some partial data, wait until we get
// some more
break
}
}
func (t *tScreen) mainLoop() {
buf := &bytes.Buffer{}
for {
select {
case <-t.quit:
close(t.indoneq)
return
case <-t.sigwinch:
t.Lock()
t.cx = -1
t.cy = -1
t.resize()
t.cells.Invalidate()
t.draw()
t.Unlock()
continue
case <-t.keytimer.C:
// If the timer fired, and the current time
// is after the expiration of the escape sequence,
// then we assume the escape sequence reached it's
// conclusion, and process the chunk independently.
// This lets us detect conflicts such as a lone ESC.
if buf.Len() > 0 {
if time.Now().After(t.keyexpire) {
t.scanInput(buf, true)
}
}
if buf.Len() > 0 {
if !t.keytimer.Stop() {
select {
case <-t.keytimer.C:
default:
}
}
t.keytimer.Reset(time.Millisecond * 50)
}
case chunk := <-t.keychan:
buf.Write(chunk)
t.keyexpire = time.Now().Add(time.Millisecond * 50)
t.scanInput(buf, false)
if !t.keytimer.Stop() {
select {
case <-t.keytimer.C:
default:
}
}
if buf.Len() > 0 {
t.keytimer.Reset(time.Millisecond * 50)
}
}
}
}
func (t *tScreen) inputLoop() {
chunk := make([]byte, 128)
for {
n, e := t.in.Read(chunk)
switch e {
case io.EOF:
case nil:
default:
t.PostEvent(NewEventError(e))
return
}
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)
ob := make([]byte, 6)
num := utf8.EncodeRune(ob, r)
enc.Reset()
dst, _, err := enc.Transform(nb, ob[:num], 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(k Key) bool {
if k == KeyRune {
return true
}
return t.keyexist[k]
}
func (t *tScreen) Resize(int, int, int, int) {}
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