i3/i3-input/convmap.pl

179 lines
5.7 KiB
Perl
Raw Normal View History

#!/usr/bin/perl
# Generate keysym2ucs.c file
#
# $XFree86: xc/programs/xterm/unicode/convmap.pl,v 1.5 2000/01/24 22:22:05 dawes Exp $
sub utf8 ($) {
my $c = shift(@_);
if ($c < 0x80) {
return sprintf("%c", $c);
} elsif ($c < 0x800) {
return sprintf("%c%c", 0xc0 | ($c >> 6), 0x80 | ($c & 0x3f));
} elsif ($c < 0x10000) {
return sprintf("%c%c%c",
0xe0 | ($c >> 12),
0x80 | (($c >> 6) & 0x3f),
0x80 | ( $c & 0x3f));
} elsif ($c < 0x200000) {
return sprintf("%c%c%c%c",
0xf0 | ($c >> 18),
0x80 | (($c >> 12) & 0x3f),
0x80 | (($c >> 6) & 0x3f),
0x80 | ( $c & 0x3f));
} elsif ($c < 0x4000000) {
return sprintf("%c%c%c%c%c",
0xf8 | ($c >> 24),
0x80 | (($c >> 18) & 0x3f),
0x80 | (($c >> 12) & 0x3f),
0x80 | (($c >> 6) & 0x3f),
0x80 | ( $c & 0x3f));
} elsif ($c < 0x80000000) {
return sprintf("%c%c%c%c%c%c",
0xfe | ($c >> 30),
0x80 | (($c >> 24) & 0x3f),
0x80 | (($c >> 18) & 0x3f),
0x80 | (($c >> 12) & 0x3f),
0x80 | (($c >> 6) & 0x3f),
0x80 | ( $c & 0x3f));
} else {
return utf8(0xfffd);
}
}
$unicodedata = "UnicodeData.txt";
# read list of all Unicode names
if (!open(UDATA, $unicodedata) && !open(UDATA, "$unicodedata")) {
die ("Can't open Unicode database '$unicodedata':\n$!\n\n" .
"Please make sure that you have downloaded the file\n" .
"ftp://ftp.unicode.org/Public/UNIDATA/UnicodeData-Latest.txt\n");
}
while (<UDATA>) {
if (/^([0-9,A-F]{4});([^;]*);([^;]*);([^;]*);([^;]*);([^;]*);([^;]*);([^;]*);([^;]*);([^;]*);([^;]*);([^;]*);([^;]*);([^;]*);([^;]*)$/) {
$name{hex($1)} = $2;
} else {
next;
die("Syntax error in line '$_' in file '$unicodedata'");
}
}
close(UDATA);
# read mapping (from http://wsinwp07.win.tue.nl:1234/unicode/keysym.map)
open(LIST, "<keysym.map") || die ("Can't open map file:\n$!\n");
while (<LIST>) {
if (/^0x([0-9a-f]{4})\s+U([0-9a-f]{4})\s*(\#.*)?$/){
$keysym = hex($1);
$ucs = hex($2);
$keysym_to_ucs{$keysym} = $ucs;
} elsif (/^\s*\#/ || /^\s*$/) {
} else {
die("Syntax error in 'list' in line\n$_\n");
}
}
close(LIST);
# read entries in keysymdef.h
open(LIST, "</usr/include/X11/keysymdef.h") || die ("Can't open keysymdef.h:\n$!\n");
while (<LIST>) {
if (/^\#define\s+XK_([A-Za-z_0-9]+)\s+0x([0-9a-fA-F]+)\s*(\/.*)?$/) {
next if /\/\* deprecated \*\//;
$keysymname = $1;
$keysym = hex($2);
$keysym_to_keysymname{$keysym} = $keysymname;
}
}
close(LIST);
print <<EOT;
/* \$XFree86\$
* This module converts keysym values into the corresponding ISO 10646-1
* (UCS, Unicode) values.
*
* The array keysymtab[] contains pairs of X11 keysym values for graphical
* characters and the corresponding Unicode value. The function
* keysym2ucs() maps a keysym onto a Unicode value using a binary search,
* therefore keysymtab[] must remain SORTED by keysym value.
*
* The keysym -> UTF-8 conversion will hopefully one day be provided
* by Xlib via XmbLookupString() and should ideally not have to be
* done in X applications. But we are not there yet.
*
* We allow to represent any UCS character in the range U+00000000 to
* U+00FFFFFF by a keysym value in the range 0x01000000 to 0x01ffffff.
* This admittedly does not cover the entire 31-bit space of UCS, but
* it does cover all of the characters up to U+10FFFF, which can be
* represented by UTF-16, and more, and it is very unlikely that higher
* UCS codes will ever be assigned by ISO. So to get Unicode character
* U+ABCD you can directly use keysym 0x1000abcd.
*
* NOTE: The comments in the table below contain the actual character
* encoded in UTF-8, so for viewing and editing best use an editor in
* UTF-8 mode.
*
* Author: Markus G. Kuhn <mkuhn\@acm.org>, University of Cambridge, June 1999
*
* Special thanks to Richard Verhoeven <river\@win.tue.nl> for preparing
* an initial draft of the mapping table.
*
* This software is in the public domain. Share and enjoy!
*/
#include <keysym2ucs.h>
struct codepair {
unsigned short keysym;
unsigned short ucs;
} keysymtab[] = {
EOT
for $keysym (sort {$a <=> $b} keys(%keysym_to_keysymname)) {
$ucs = $keysym_to_ucs{$keysym};
next if $keysym >= 0xf000 || $keysym < 0x100;
if ($ucs) {
printf(" { 0x%04x, 0x%04x }, /*%28s %s %s */\n",
$keysym, $ucs, $keysym_to_keysymname{$keysym}, utf8($ucs),
defined($name{$ucs}) ? $name{$ucs} : "???" );
} else {
printf("/* 0x%04x %39s ? ??? */\n",
$keysym, $keysym_to_keysymname{$keysym});
}
}
print <<EOT;
};
long keysym2ucs(KeySym keysym)
{
int min = 0;
int max = sizeof(keysymtab) / sizeof(struct codepair) - 1;
int mid;
/* first check for Latin-1 characters (1:1 mapping) */
if ((keysym >= 0x0020 && keysym <= 0x007e) ||
(keysym >= 0x00a0 && keysym <= 0x00ff))
return keysym;
/* also check for directly encoded 24-bit UCS characters */
if ((keysym & 0xff000000) == 0x01000000)
return keysym & 0x00ffffff;
/* binary search in table */
while (max >= min) {
mid = (min + max) / 2;
if (keysymtab[mid].keysym < keysym)
min = mid + 1;
else if (keysymtab[mid].keysym > keysym)
max = mid - 1;
else {
/* found it */
return keysymtab[mid].ucs;
}
}
/* no matching Unicode value found */
return -1;
}
EOT