stone/backends/x/unicode.go

188 lines
4.5 KiB
Go

package x
import "unicode"
import "github.com/jezek/xgb/xproto"
import "github.com/jezek/xgbutil/keybind"
import "git.tebibyte.media/sashakoshka/stone"
// when making changes to this file, look at keysymdef.h and
// https://tronche.com/gui/x/xlib/input/keyboard-encoding.html
var buttonCodeTable = map[xproto.Keysym] stone.Button {
0xFFFFFF: stone.ButtonUnknown,
0xFF63: stone.KeyInsert,
0xFF67: stone.KeyMenu,
0xFF61: stone.KeyPrintScreen,
0xFF6B: stone.KeyPause,
0xFFE5: stone.KeyCapsLock,
0xFF14: stone.KeyScrollLock,
0xFF7F: stone.KeyNumLock,
0xFF08: stone.KeyBackspace,
0xFF09: stone.KeyTab,
0xFF0D: stone.KeyEnter,
0xFF1B: stone.KeyEscape,
0xFF52: stone.KeyUp,
0xFF54: stone.KeyDown,
0xFF51: stone.KeyLeft,
0xFF53: stone.KeyRight,
0xFF55: stone.KeyPageUp,
0xFF56: stone.KeyPageDown,
0xFF50: stone.KeyHome,
0xFF57: stone.KeyEnd,
0xFFE1: stone.KeyLeftShift,
0xFFE2: stone.KeyRightShift,
0xFFE3: stone.KeyLeftControl,
0xFFE4: stone.KeyRightControl,
0xFFE9: stone.KeyLeftAlt,
0xFFEA: stone.KeyRightAlt,
0xFFEB: stone.KeyLeftSuper,
0xFFEC: stone.KeyRightSuper,
0xFFFF: stone.KeyDelete,
0xFFBE: stone.KeyF1,
0xFFBF: stone.KeyF2,
0xFFC0: stone.KeyF3,
0xFFC1: stone.KeyF4,
0xFFC2: stone.KeyF5,
0xFFC3: stone.KeyF6,
0xFFC4: stone.KeyF7,
0xFFC5: stone.KeyF8,
0xFFC6: stone.KeyF9,
0xFFC7: stone.KeyF10,
0xFFC8: stone.KeyF11,
0xFFC9: stone.KeyF12,
}
func (backend *Backend) keycodeToButton (
keycode xproto.Keycode,
state uint16,
) (
button stone.Button,
) {
// FIXME: also set shift to true if the lock modifier is on and the lock
// modifier is interpreted as shiftLock
shift := state & xproto.ModMaskShift > 0
// FIXME: only set this to true if the lock modifier is on and the lock
// modifier is interpreted as capsLock
capsLock := state & xproto.ModMaskLock > 0
symbol1 := keybind.KeysymGet(backend.connection, keycode, 0)
symbol2 := keybind.KeysymGet(backend.connection, keycode, 1)
symbol3 := keybind.KeysymGet(backend.connection, keycode, 2)
symbol4 := keybind.KeysymGet(backend.connection, keycode, 3)
cased := false
// third paragraph
switch {
case symbol2 == 0 && symbol3 == 0 && symbol4 == 0:
symbol3 = symbol1
case symbol3 == 0 && symbol4 == 0:
symbol3 = symbol1
symbol2 = symbol2
case symbol4 == 0:
symbol4 = 0
}
symbol1Rune := keysymToRune(symbol1)
symbol2Rune := keysymToRune(symbol2)
symbol3Rune := keysymToRune(symbol3)
symbol4Rune := keysymToRune(symbol4)
// FIXME: we ignore mode switch stuff
_ = symbol4Rune
// fourth paragraph
if symbol2 == 0 {
upper := unicode.IsUpper(symbol1Rune)
lower := unicode.IsLower(symbol1Rune)
if upper || lower {
symbol1Rune = unicode.ToLower(symbol1Rune)
symbol2Rune = unicode.ToUpper(symbol1Rune)
cased = true
} else {
symbol2 = symbol1
}
}
if symbol4 == 0 {
upper := unicode.IsUpper(symbol3Rune)
lower := unicode.IsLower(symbol3Rune)
if upper || lower {
symbol3Rune = unicode.ToLower(symbol3Rune)
symbol4Rune = unicode.ToUpper(symbol3Rune)
cased = true
} else {
symbol4 = symbol3
}
}
var selectedKeysym xproto.Keysym
var selectedRune rune
// big ol list in the middle
switch {
// FIXME: take into account numlock
case !shift && !capsLock:
selectedKeysym = symbol1
selectedRune = symbol1Rune
case !shift && capsLock:
if cased && unicode.IsLower(symbol1Rune) {
selectedRune = symbol2Rune
} else {
selectedKeysym = symbol1
selectedRune = symbol1Rune
}
case shift && capsLock:
if cased && unicode.IsLower(symbol2Rune) {
selectedRune = unicode.ToUpper(symbol2Rune)
} else {
selectedKeysym = symbol2
selectedRune = symbol2Rune
}
case shift:
selectedKeysym = symbol2
selectedRune = symbol2Rune
}
// look up in table
var isControl bool
button, isControl = buttonCodeTable[selectedKeysym]
// if it wasn't found,
if !isControl {
button = stone.Button(selectedRune)
}
return
}
func keysymToRune (keysym xproto.Keysym) (character rune) {
// X keysyms like 0xFF.. or 0xFE.. are non-character keys. these cannot
// be converted so we return a zero.
if (keysym >> 8) == 0xFF || (keysym >> 8) == 0xFE {
character = 0
return
}
// some X keysyms have a single bit set to 1 here. i believe this is to
// prevent conflicts with existing codes. if we mask it off we will get
// a correct utf-32 code point.
if keysym & 0xF000000 == 0x1000000 {
character = rune(keysym & 0x0111111)
return
}
// if none of these things happened, we can safely (i think) assume that
// the keysym is an exact utf-32 code point.
character = rune(keysym)
return
}