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source: vbox/trunk/src/VBox/Frontends/Common/VBoxKeyboard/keyboard.c@ 33656

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1/* $Id: keyboard.c 33656 2010-11-01 14:18:11Z vboxsync $ */
2/** @file
3 * VBox/Frontends/Common - X11 keyboard handler library.
4 */
5
6/* This code is originally from the Wine project. */
7
8/*
9 * X11 keyboard driver
10 *
11 * Copyright 1993 Bob Amstadt
12 * Copyright 1996 Albrecht Kleine
13 * Copyright 1997 David Faure
14 * Copyright 1998 Morten Welinder
15 * Copyright 1998 Ulrich Weigand
16 * Copyright 1999 Ove K�ven
17 *
18 * This library is free software; you can redistribute it and/or
19 * modify it under the terms of the GNU Lesser General Public
20 * License as published by the Free Software Foundation; either
21 * version 2.1 of the License, or (at your option) any later version.
22 *
23 * This library is distributed in the hope that it will be useful,
24 * but WITHOUT ANY WARRANTY; without even the implied warranty of
25 * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
26 * Lesser General Public License for more details.
27 *
28 * You should have received a copy of the GNU Lesser General Public
29 * License along with this library; if not, write to the Free Software
30 * Foundation, Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301, USA
31 */
32
33/*
34 * Oracle LGPL Disclaimer: For the avoidance of doubt, except that if any license choice
35 * other than GPL or LGPL is available it will apply instead, Oracle elects to use only
36 * the Lesser General Public License version 2.1 (LGPLv2) at this time for any software where
37 * a choice of LGPL license versions is made available with the language indicating
38 * that LGPLv2 or any later version may be used, or where a choice of which version
39 * of the LGPL is applied is otherwise unspecified.
40 */
41
42#include <X11/Xatom.h>
43#include <X11/keysym.h>
44#include <X11/XKBlib.h>
45#include <X11/Xlib.h>
46#include <X11/Xresource.h>
47#include <X11/Xutil.h>
48
49#include <ctype.h>
50#include <stdarg.h>
51#include <string.h>
52#include <stdlib.h>
53#include <stdio.h>
54
55#include <VBox/VBoxKeyboard.h>
56
57#define KEYC2SCAN_SIZE 256
58
59/**
60 * Array containing the current mapping of keycodes to scan codes, detected
61 * using the keyboard layout algorithm in X11DRV_InitKeyboardByLayout.
62 */
63static unsigned keyc2scan[KEYC2SCAN_SIZE];
64/** Whether to output basic debugging information to standard output */
65static int log_kb_1 = 0;
66/** Whether to output verbose debugging information to standard output */
67static int log_kb_2 = 0;
68
69/** Output basic debugging information if wished */
70#define LOG_KB_1(a) \
71do { \
72 if (log_kb_1) { \
73 printf a; \
74 } \
75} while (0)
76
77/** Output verbose debugging information if wished */
78#define LOG_KB_2(a) \
79do { \
80 if (log_kb_2) { \
81 printf a; \
82 } \
83} while (0)
84
85/** Keyboard layout tables for guessing the current keyboard layout. */
86#include "keyboard-tables.h"
87
88/** Tables of keycode to scan code mappings for well-known keyboard types. */
89#include "keyboard-types.h"
90
91/**
92 * Translate a keycode in a key event to a scan code. If the keycode maps
93 * to a key symbol which is in the same place on all PC keyboards, look it
94 * up by symbol in one of our hard-coded translation tables. It it maps to
95 * a symbol which can be in a different place on different PC keyboards, look
96 * it up by keycode using either the lookup table which we constructed
97 * earlier, or using a hard-coded table if we know what type of keyboard is
98 * in use.
99 *
100 * @returns the scan code number, with 0x100 added for extended scan codes
101 * @param code the X11 key code to be looked up
102 */
103
104unsigned X11DRV_KeyEvent(Display *display, KeyCode code)
105{
106 unsigned scan;
107 KeySym keysym = XKeycodeToKeysym(display, code, 0);
108 scan = 0;
109 if (keyc2scan[code] == 0 && keysym != 0)
110 {
111 if ((keysym >> 8) == 0xFF) /* non-character key */
112 scan = nonchar_key_scan[keysym & 0xff];
113 else if ((keysym >> 8) == 0x1008FF) /* XFree86 vendor keys */
114 scan = xfree86_vendor_key_scan[keysym & 0xff];
115 else if ((keysym >> 8) == 0x1005FF) /* Sun keys */
116 scan = sun_key_scan[keysym & 0xff];
117 else if (keysym == 0x20) /* Spacebar */
118 scan = 0x39;
119 else if (keysym == 0xFE03) /* ISO level3 shift, aka AltGr */
120 scan = 0x138;
121 }
122 if (keyc2scan[code])
123 scan = keyc2scan[code];
124
125 return scan;
126}
127
128/**
129 * Called from X11DRV_InitKeyboardByLayout
130 * See the comments for that function for a description what this function
131 * does.
132 *
133 * @returns an index into the table of keyboard layouts, or 0 if absolutely
134 * nothing fits
135 * @param display pointer to the X11 display handle
136 * @param min_keycode the lowest value in use as a keycode on this server
137 * @param max_keycode the highest value in use as a keycode on this server
138 */
139static int
140X11DRV_KEYBOARD_DetectLayout (Display *display, unsigned min_keycode,
141 unsigned max_keycode)
142{
143 /** Counter variable for iterating through the keyboard layout tables. */
144 unsigned current;
145 /** The best candidate so far for the layout. */
146 unsigned kbd_layout = 0;
147 /** The number of matching keys in the current best candidate layout. */
148 unsigned max_score = 0;
149 /** The number of changes of scan-code direction in the current
150 best candidate. */
151 unsigned max_seq = 0;
152 /** Table for the current keycode to keysym mapping. */
153 char ckey[256][2];
154 /** Counter variable representing a keycode */
155 unsigned keyc;
156
157 /* Fill in our keycode to keysym mapping table. */
158 memset( ckey, 0, sizeof(ckey) );
159 for (keyc = min_keycode; keyc <= max_keycode; keyc++) {
160 /* get data for keycodes from X server */
161 KeySym keysym = XKeycodeToKeysym (display, keyc, 0);
162 /* We leave keycodes which will definitely not be in the lookup tables
163 marked with 0 so that we know that we know not to look them up when
164 we scan the tables. */
165 if ( (0xFF != (keysym >> 8)) /* Non-character key */
166 && (0x1008FF != (keysym >> 8)) /* XFree86 vendor keys */
167 && (0x1005FF != (keysym >> 8)) /* Sun keys */
168 && (0x20 != keysym) /* Spacebar */
169 && (0xFE03 != keysym) /* ISO level3 shift, aka AltGr */
170 ) {
171 ckey[keyc][0] = keysym & 0xFF;
172 ckey[keyc][1] = XKeycodeToKeysym(display, keyc, 1) & 0xFF;
173 }
174 }
175
176 /* Now scan the lookup tables, looking for one that is as close as
177 possible to our current keycode to keysym mapping. */
178 for (current = 0; main_key_tab[current].comment; current++) {
179 /** How many keys have matched so far in this layout? */
180 unsigned match = 0;
181 /** How many keys have not changed the direction? */
182 unsigned seq = 0;
183 /** Pointer to the layout we are currently comparing against. */
184 const char (*lkey)[MAIN_LEN][2] = main_key_tab[current].key;
185 /** For detecting dvorak layouts - in which direction do the server's
186 keycodes seem to be running? We count the number of times that
187 this direction changes as an additional hint as to how likely this
188 layout is to be the right one. */
189 int direction = 1;
190 /** The keycode of the last key that we matched. This is used to
191 determine the direction that the keycodes are running in. */
192 int pkey = -1;
193 LOG_KB_2(("Attempting to match against \"%s\"\n", main_key_tab[current].comment));
194 for (keyc = min_keycode; keyc <= max_keycode; keyc++) {
195 if (0 != ckey[keyc][0]) {
196 /** The candidate key in the current layout for this keycode. */
197 int key;
198 /** Does this key match? */
199 int ok = 0;
200 /* search for a match in layout table */
201 for (key = 0; (key < MAIN_LEN) && (0 == ok); key++) {
202 if ( ((*lkey)[key][0] == ckey[keyc][0])
203 && ((*lkey)[key][1] == ckey[keyc][1])
204 ) {
205 ok = 1;
206 }
207 }
208 /* count the matches and mismatches */
209 if (0 != ok) {
210 match++;
211 /* How well in sequence are the keys? For dvorak layouts. */
212 if (key > pkey) {
213 if (1 == direction) {
214 ++seq;
215 } else {
216 direction = -1;
217 }
218 }
219 if (key < pkey) {
220 if (1 != direction) {
221 ++seq;
222 } else {
223 direction = 1;
224 }
225 }
226 pkey = key;
227 } else {
228#ifdef DEBUG
229 /* print spaces instead of \0's */
230 char str[3] = " ";
231 if ((ckey[keyc][0] > 32) && (ckey[keyc][0] < 127)) {
232 str[0] = ckey[keyc][0];
233 }
234 if ((ckey[keyc][0] > 32) && (ckey[keyc][0] < 127)) {
235 str[0] = ckey[keyc][0];
236 }
237 LOG_KB_2(("Mismatch for keycode %d, keysym \"%s\" (0x%.2hx 0x%.2hx)\n",
238 keyc, str, ckey[keyc][0], ckey[keyc][1]));
239#endif /* DEBUG defined */
240 }
241 }
242 }
243 LOG_KB_2(("Matches=%d, seq=%d\n", match, seq));
244 if ( (match > max_score)
245 || ((match == max_score) && (seq > max_seq))
246 ) {
247 /* best match so far */
248 kbd_layout = current;
249 max_score = match;
250 max_seq = seq;
251 }
252 }
253 /* we're done, report results if necessary */
254 LOG_KB_1(("Detected layout is \"%s\", matches=%d, seq=%d\n",
255 main_key_tab[kbd_layout].comment, max_score, max_seq));
256 return kbd_layout;
257}
258
259/**
260 * Initialise the X11 keyboard driver by building up a table to convert X11
261 * keycodes to scan codes using a heuristic based on comparing the current
262 * keyboard map to known international keyboard layouts.
263 * The basic idea is to examine each key in the current layout to see which
264 * characters it produces in its normal and its "shifted" state, and to look
265 * for known keyboard layouts which it could belong to. We then guess the
266 * current layout based on the number of matches we find.
267 * One difficulty with this approach is so-called Dvorak layouts, which are
268 * identical to non-Dvorak layouts, but with the keys in a different order.
269 * To deal with this, we compare the different candidate layouts to see in
270 * which one the X11 keycodes would be most sequential and hope that they
271 * really are arranged more or less sequentially.
272 *
273 * The actual detection of the current layout is done in the sub-function
274 * X11DRV_KEYBOARD_DetectLayout. Once we have determined the layout, since we
275 * know which PC scan code corresponds to each key in the layout, we can use
276 * this information to associate the scan code with an X11 keycode, which is
277 * what the rest of this function does.
278 *
279 * @warning not re-entrant
280 * @returns 1 if the layout found was optimal, 0 if it was not. This is
281 * for diagnostic purposes
282 * @param display a pointer to the X11 display
283 */
284static unsigned
285X11DRV_InitKeyboardByLayout(Display *display)
286{
287 KeySym keysym;
288 unsigned scan;
289 int keyc, keyn;
290 const char (*lkey)[MAIN_LEN][2];
291 int min_keycode, max_keycode;
292 int kbd_layout;
293 unsigned matches = 0, entries = 0;
294
295 /* Should we log to standard output? */
296 if (NULL != getenv("LOG_KB_PRIMARY")) {
297 log_kb_1 = 1;
298 }
299 if (NULL != getenv("LOG_KB_SECONDARY")) {
300 log_kb_1 = 1;
301 log_kb_2 = 1;
302 }
303 XDisplayKeycodes(display, &min_keycode, &max_keycode);
304
305 /* according to the space this function is guaranteed to never return
306 * values for min_keycode < 8 and values for max_keycode > 255 */
307 if (min_keycode < 0)
308 min_keycode = 0;
309 if (max_keycode > 255)
310 max_keycode = 255;
311
312 /* Detect the keyboard layout */
313 kbd_layout = X11DRV_KEYBOARD_DetectLayout(display, min_keycode,
314 max_keycode);
315 lkey = main_key_tab[kbd_layout].key;
316
317 /* Now build a conversion array :
318 * keycode -> scancode + extended */
319
320 for (keyc = min_keycode; keyc <= max_keycode; keyc++)
321 {
322 keysym = XKeycodeToKeysym(display, keyc, 0);
323 scan = 0;
324 if (keysym) /* otherwise, keycode not used */
325 {
326 /* Skip over keysyms which we look up on the fly */
327 if ( (0xFF != (keysym >> 8)) /* Non-character key */
328 && (0x1008FF != (keysym >> 8)) /* XFree86 vendor keys */
329 && (0x1005FF != (keysym >> 8)) /* Sun keys */
330 && (0x20 != keysym) /* Spacebar */
331 && (0xFE03 != keysym) /* ISO level3 shift, aka AltGr */
332 ) {
333 unsigned found = 0;
334
335 /* we seem to need to search the layout-dependent scancodes */
336 char unshifted = keysym & 0xFF;
337 char shifted = XKeycodeToKeysym(display, keyc, 1) & 0xFF;
338 /* find a key which matches */
339 for (keyn = 0; (0 == found) && (keyn<MAIN_LEN); keyn++) {
340 if ( ((*lkey)[keyn][0] == unshifted)
341 && ((*lkey)[keyn][1] == shifted)
342 ) {
343 found = 1;
344 }
345 }
346 if (0 != found) {
347 /* got it */
348 scan = main_key_scan[keyn - 1];
349 /* We keep track of the number of keys that we found a
350 * match for to see if the layout is optimal or not.
351 * We ignore the 102nd key though (key number 48), since
352 * not all keyboards have it. */
353 if (keyn != 48)
354 ++matches;
355 }
356 if (0 == scan) {
357 /* print spaces instead of \0's */
358 char str[3] = " ";
359 if ((unshifted > 32) && (unshifted < 127)) {
360 str[0] = unshifted;
361 }
362 if ((shifted > 32) && (shifted < 127)) {
363 str[1] = shifted;
364 }
365 LOG_KB_1(("No match found for keycode %d, keysym \"%s\" (0x%x 0x%x)\n",
366 keyc, str, unshifted, shifted));
367 } else if ((keyc > 8) && (keyc < 97) && (keyc - scan != 8)) {
368 /* print spaces instead of \0's */
369 char str[3] = " ";
370 if ((unshifted > 32) && (unshifted < 127)) {
371 str[0] = unshifted;
372 }
373 if ((shifted > 32) && (shifted < 127)) {
374 str[1] = shifted;
375 }
376 LOG_KB_1(("Warning - keycode %d, keysym \"%s\" (0x%x 0x%x) was matched to scancode %d\n",
377 keyc, str, unshifted, shifted, scan));
378 }
379 }
380 }
381 keyc2scan[keyc] = scan;
382 } /* for */
383 /* Did we find a match for all keys in the layout? Count them first.
384 * Note that we skip the 102nd key, so that owners of 101 key keyboards
385 * don't get bogus messages about bad matches. */
386 for (entries = 0, keyn = 0; keyn < MAIN_LEN; ++keyn) {
387 if ( (0 != (*lkey)[keyn][0])
388 && (0 != (*lkey)[keyn][1])
389 && (keyn != 47) /* don't count the 102nd key */
390 ) {
391 ++entries;
392 }
393 }
394 LOG_KB_1(("Finished mapping keyboard, matches=%d, entries=%d (excluding 102nd key)\n", matches, entries));
395 if (matches != entries)
396 {
397 return 0;
398 }
399 return 1;
400}
401
402static int checkHostKeycode(unsigned hostCode, unsigned targetCode)
403{
404 if (!targetCode)
405 return 0;
406 if (hostCode && hostCode != targetCode)
407 return 0;
408 return 1;
409}
410
411static int compKBMaps(const keyboard_type *pHost, const keyboard_type *pTarget)
412{
413 if ( !pHost->lctrl && !pHost->capslock && !pHost->lshift && !pHost->tab
414 && !pHost->esc && !pHost->enter && !pHost->up && !pHost->down
415 && !pHost->left && !pHost->right && !pHost->f1 && !pHost->f2
416 && !pHost->f3 && !pHost->f4 && !pHost->f5 && !pHost->f6 && !pHost->f7
417 && !pHost->f8)
418 return 0;
419 /* This test is for the people who like to swap control and caps lock */
420 if ( ( !checkHostKeycode(pHost->lctrl, pTarget->lctrl)
421 || !checkHostKeycode(pHost->capslock, pTarget->capslock))
422 && ( !checkHostKeycode(pHost->lctrl, pTarget->capslock)
423 || !checkHostKeycode(pHost->capslock, pTarget->lctrl)))
424 return 0;
425 if ( !checkHostKeycode(pHost->lshift, pTarget->lshift)
426 || !checkHostKeycode(pHost->tab, pTarget->tab)
427 || !checkHostKeycode(pHost->esc, pTarget->esc)
428 || !checkHostKeycode(pHost->enter, pTarget->enter)
429 || !checkHostKeycode(pHost->up, pTarget->up)
430 || !checkHostKeycode(pHost->down, pTarget->down)
431 || !checkHostKeycode(pHost->left, pTarget->left)
432 || !checkHostKeycode(pHost->right, pTarget->right)
433 || !checkHostKeycode(pHost->f1, pTarget->f1)
434 || !checkHostKeycode(pHost->f2, pTarget->f2)
435 || !checkHostKeycode(pHost->f3, pTarget->f3)
436 || !checkHostKeycode(pHost->f4, pTarget->f4)
437 || !checkHostKeycode(pHost->f5, pTarget->f5)
438 || !checkHostKeycode(pHost->f6, pTarget->f6)
439 || !checkHostKeycode(pHost->f7, pTarget->f7)
440 || !checkHostKeycode(pHost->f8, pTarget->f8))
441 return 0;
442 return 1;
443}
444
445static int findHostKBInList(const keyboard_type *pHost,
446 const keyboard_type *pList, int cList)
447{
448 int i = 0;
449 for (; i < cList; ++i)
450 if (compKBMaps(pHost, &pList[i]))
451 return i;
452 return -1;
453}
454
455#ifdef DEBUG
456static void testFindHostKB(void)
457{
458 keyboard_type hostBasic =
459 { NULL, 1 /* lctrl */, 2, 3, 4, 5, 6, 7 /* up */, 8, 9, 10, 11 /* F1 */,
460 12, 13, 14, 15, 16, 17, 18 };
461 keyboard_type hostSwapCtrlCaps =
462 { NULL, 3 /* lctrl */, 2, 1, 4, 5, 6, 7 /* up */, 8, 9, 10, 11 /* F1 */,
463 12, 13, 14, 15, 16, 17, 18 };
464 keyboard_type hostEmpty =
465 { NULL, 0 /* lctrl */, 0, 0, 0, 0, 0, 0 /* up */, 0, 0, 0, 0 /* F1 */,
466 0, 0, 0, 0, 0, 0, 0 };
467 keyboard_type hostNearlyEmpty =
468 { NULL, 1 /* lctrl */, 0, 0, 0, 0, 0, 0 /* up */, 0, 0, 0, 0 /* F1 */,
469 0, 0, 0, 0, 0, 0, 18 };
470 keyboard_type hostNearlyRight =
471 { NULL, 20 /* lctrl */, 2, 3, 4, 5, 6, 7 /* up */, 8, 9, 10, 11 /* F1 */,
472 12, 13, 14, 15, 16, 17, 18 };
473 keyboard_type targetList[] = {
474 { NULL, 18 /* lctrl */, 17, 16, 15, 14, 13, 12 /* up */, 11, 10, 9,
475 8 /* F1 */, 7, 6, 5, 4, 3, 2, 1 },
476 { NULL, 1 /* lctrl */, 2, 3, 4, 5, 6, 7 /* up */, 8, 9, 10,
477 11 /* F1 */, 12, 13, 14, 15, 16, 17, 18 }
478 };
479
480 /* As we don't have assertions here, just printf. This should *really*
481 * never happen. */
482 if ( hostBasic.f8 != 18 || hostSwapCtrlCaps.f8 != 18
483 || hostNearlyEmpty.f8 != 18 || hostNearlyRight.f8 != 18
484 || targetList[0].f8 != 1 || targetList[1].f8 != 18)
485 printf("ERROR: testFindHostKB: bad structures\n");
486 if (findHostKBInList(&hostBasic, targetList, 2) != 1)
487 printf("ERROR: findHostKBInList failed to find a target in a list\n");
488 if (findHostKBInList(&hostSwapCtrlCaps, targetList, 2) != 1)
489 printf("ERROR: findHostKBInList failed on a ctrl-caps swapped map\n");
490 if (findHostKBInList(&hostEmpty, targetList, 2) != -1)
491 printf("ERROR: findHostKBInList accepted an empty host map\n");
492 if (findHostKBInList(&hostNearlyEmpty, targetList, 2) != 1)
493 printf("ERROR: findHostKBInList failed on a partly empty host map\n");
494 if (findHostKBInList(&hostNearlyRight, targetList, 2) != -1)
495 printf("ERROR: findHostKBInList failed to fail a wrong host map\n");
496}
497#endif
498
499static unsigned
500X11DRV_InitKeyboardByType(Display *display)
501{
502 keyboard_type hostKB;
503 int cMap;
504
505 hostKB.lctrl = XKeysymToKeycode(display, XK_Control_L);
506 hostKB.capslock = XKeysymToKeycode(display, XK_Caps_Lock);
507 hostKB.lshift = XKeysymToKeycode(display, XK_Shift_L);
508 hostKB.tab = XKeysymToKeycode(display, XK_Tab);
509 hostKB.esc = XKeysymToKeycode(display, XK_Escape);
510 hostKB.enter = XKeysymToKeycode(display, XK_Return);
511 hostKB.up = XKeysymToKeycode(display, XK_Up);
512 hostKB.down = XKeysymToKeycode(display, XK_Down);
513 hostKB.left = XKeysymToKeycode(display, XK_Left);
514 hostKB.right = XKeysymToKeycode(display, XK_Right);
515 hostKB.f1 = XKeysymToKeycode(display, XK_F1);
516 hostKB.f2 = XKeysymToKeycode(display, XK_F2);
517 hostKB.f3 = XKeysymToKeycode(display, XK_F3);
518 hostKB.f4 = XKeysymToKeycode(display, XK_F4);
519 hostKB.f5 = XKeysymToKeycode(display, XK_F5);
520 hostKB.f6 = XKeysymToKeycode(display, XK_F6);
521 hostKB.f7 = XKeysymToKeycode(display, XK_F7);
522 hostKB.f8 = XKeysymToKeycode(display, XK_F8);
523
524#ifdef DEBUG
525 testFindHostKB();
526#endif
527 cMap = findHostKBInList(&hostKB, main_keyboard_type_list,
528 sizeof(main_keyboard_type_list)
529 / sizeof(main_keyboard_type_list[0]));
530#ifdef DEBUG
531 /* Assertion */
532 if (sizeof(keyc2scan) != sizeof(main_keyboard_type_scans[cMap]))
533 {
534 printf("ERROR: keyc2scan array size doesn't match main_keyboard_type_scans[]!\n");
535 return 0;
536 }
537#endif
538 if (cMap >= 0)
539 {
540 memcpy(keyc2scan, main_keyboard_type_scans[cMap], sizeof(keyc2scan));
541 return 1;
542 }
543 return 0;
544}
545
546/**
547 * Checks for the XKB extension, and if it is found initialises the X11 keycode
548 * to XT scan code mapping by looking at the XKB names for each keycode.
549 */
550static unsigned
551X11DRV_InitKeyboardByXkb(Display *pDisplay)
552{
553 int major = XkbMajorVersion, minor = XkbMinorVersion;
554 XkbDescPtr pKBDesc;
555 if (!XkbLibraryVersion(&major, &minor))
556 return 0;
557 if (!XkbQueryExtension(pDisplay, NULL, NULL, &major, &minor, NULL))
558 return 0;
559 pKBDesc = XkbGetKeyboard(pDisplay, XkbAllComponentsMask, XkbUseCoreKbd);
560 if (!pKBDesc)
561 return 0;
562 if (XkbGetNames(pDisplay, XkbKeyNamesMask, pKBDesc) != Success)
563 return 0;
564 {
565 unsigned i, j;
566
567 memset(keyc2scan, 0, sizeof(keyc2scan));
568 for (i = pKBDesc->min_key_code; i < pKBDesc->max_key_code; ++i)
569 for (j = 0; j < sizeof(xkbMap) / sizeof(xkbMap[0]); ++j)
570 if (!memcmp(xkbMap[j].cszName,
571 &pKBDesc->names->keys->name[i * XKB_NAME_SIZE],
572 XKB_NAME_SIZE))
573 {
574 keyc2scan[i] = xkbMap[j].uScan;
575 break;
576 }
577 }
578 XkbFreeNames(pKBDesc, XkbKeyNamesMask, True);
579 XkbFreeKeyboard(pKBDesc, XkbAllComponentsMask, True);
580 return 1;
581}
582
583/**
584 * Initialise the X11 keyboard driver by finding which X11 keycodes correspond
585 * to which PC scan codes. If the keyboard being used is not a PC keyboard,
586 * the X11 keycodes will be mapped to the scan codes which the equivalent keys
587 * on a PC keyboard would use.
588 *
589 * We use two algorithms to try to determine the mapping. See the comments
590 * attached to the two algorithm functions (X11DRV_InitKeyboardByLayout and
591 * X11DRV_InitKeyboardByType) for descriptions of the algorithms used. Both
592 * functions tell us on return whether they think that they have correctly
593 * determined the mapping. If both functions claim to have determined the
594 * mapping correctly, we prefer the second (ByType). However, if neither does
595 * then we prefer the first (ByLayout), as it produces a fuzzy result which is
596 * still likely to be partially correct.
597 *
598 * @warning not re-entrant
599 * @returns 1 if the layout found was optimal, 0 if it was not. This is
600 * for diagnostic purposes
601 * @param display a pointer to the X11 display
602 * @param byLayoutOK diagnostic - set to one if detection by layout
603 * succeeded, and to 0 otherwise
604 * @param byTypeOK diagnostic - set to one if detection by type
605 * succeeded, and to 0 otherwise
606 * @param byXkbOK diagnostic - set to one if detection using XKB
607 * succeeded, and to 0 otherwise
608 * @param remapScancode array of tuples that remap the keycode (first
609 * part) to a scancode (second part)
610 */
611unsigned X11DRV_InitKeyboard(Display *display, unsigned *byLayoutOK,
612 unsigned *byTypeOK, unsigned *byXkbOK,
613 int (*remapScancodes)[2])
614{
615 unsigned byLayout, byType, byXkb;
616
617 byLayout = X11DRV_InitKeyboardByLayout(display);
618 if (byLayoutOK)
619 *byLayoutOK = byLayout;
620
621 byType = X11DRV_InitKeyboardByType(display);
622 if (byTypeOK)
623 *byTypeOK = byType;
624
625 byXkb = X11DRV_InitKeyboardByXkb(display);
626 if (byXkbOK)
627 *byXkbOK = byXkb;
628
629 /* Remap keycodes after initialization. Remapping stops after an
630 identity mapping is seen */
631 if (remapScancodes != NULL)
632 for (; (*remapScancodes)[0] != (*remapScancodes)[1]; remapScancodes++)
633 keyc2scan[(*remapScancodes)[0]] = (*remapScancodes)[1];
634
635 return (byLayout || byType || byXkb) ? 1 : 0;
636}
637
638/**
639 * Returns the keycode to scancode array
640 */
641unsigned *X11DRV_getKeyc2scan(void)
642{
643 return keyc2scan;
644}
645
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