[ViewVC] Diff of: cvs/rxvt-unicode/src/keyboard.C

Comparing rxvt-unicode/src/keyboard.C (file contents):
Revision 1.1 by root, Sun Jan 16 15:59:45 2005 UTC vs.
Revision 1.64 by sf-exg, Tue Apr 29 13:10:06 2014 UTC

		1	/----------------------------------------------------------------------
		2	* File: keyboard.C
		3	----------------------------------------------------------------------
		4	*
		5	* All portions of code are copyright by their respective author/s.
		6	* Copyright (c) 2005 WU Fengguang
		7	* Copyright (c) 2005-2006 Marc Lehmann <schmorp@schmorp.de>
		8	*
		9	* This program is free software; you can redistribute it and/or modify
		10	* it under the terms of the GNU General Public License as published by
		11	* the Free Software Foundation; either version 2 of the License, or
		12	* (at your option) any later version.
		13	*
		14	* This program is distributed in the hope that it will be useful,
		15	* but WITHOUT ANY WARRANTY; without even the implied warranty of
		16	* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
		17	* GNU General Public License for more details.
		18	*
		19	* You should have received a copy of the GNU General Public License
		20	* along with this program; if not, write to the Free Software
		21	* Foundation, Inc., 675 Mass Ave, Cambridge, MA 02139, USA.
		22	----------------------------------------------------------------------/
		23
1	#include "../config.h"	24	#include "../config.h"
2	#include "rxvt.h"	25	#include "rxvt.h"
		26
		27	#ifdef KEYSYM_RESOURCE
		28
		29	#include <string.h>
		30
		31	#include "rxvtperl.h"
3	#include "keyboard.h"	32	#include "keyboard.h"
4	#include "command.h"
5	#include <string.h>
6	#include <X11/X.h>
7		33
8	#ifdef KEYSYM_RESOURCE	34	/* an intro to the data structure:
		35	*
		36	* vector keymap[] is grouped.
		37	*
		38	* inside each group, elements are sorted by the criteria given by compare_priority().
		39	* the lookup of keysym is done in two steps:
		40	* 1) locate the group corresponds to the keysym;
		41	* 2) do a linear search inside the group.
		42	*
		43	* array hash[] effectively defines a map from a keysym to a group in keymap[].
		44	*
		45	* each group has its address(the index of first group element in keymap[]),
		46	* which is computed and stored in hash[].
		47	* hash[] stores the addresses in the form of:
		48	* index: 0 I1 I2 I3 In
		49	* value: 0...0, A1...A1, A2...A2, A3...A3, ..., An...An
		50	* where
		51	* A1 = 0;
		52	* Ai+1 = N1 + N2 + ... + Ni.
		53	* it is computed from hash_bucket_size[]:
		54	* index: 0 I1 I2 I3 In
		55	* value: 0...0, N1, 0...0, N2, 0...0, N3, ..., Nn, 0...0
		56	* 0...0, 0.......0, N1.....N1, N1+N2...N1+N2, ... (the computation of hash[])
		57	* or we can say
		58	* hash_bucket_size[Ii] = Ni; hash_bucket_size[elsewhere] = 0,
		59	* where
		60	* set {I1, I2, ..., In} = { hashkey of keymap[0]->keysym, ..., keymap[keymap.size-1]->keysym }
		61	* where hashkey of keymap[i]->keysym = keymap[i]->keysym & KEYSYM_HASH_MASK
		62	* n(the number of groups) = the number of non-zero member of hash_bucket_size[];
		63	* Ni(the size of group i) = hash_bucket_size[Ii].
		64	*/
		65
		66	// return: priority_of_a - priority_of_b
		67	static int
		68	compare_priority (keysym_t a, keysym_t b)
		69	{
		70	// (the more '1's in state; the less range): the greater priority
		71	int ca = ecb_popcount32 (a->state /* & OtherModMask */);
		72	int cb = ecb_popcount32 (b->state /* & OtherModMask */);
		73
		74	return ca - cb;
		75	}
9		76
10	////////////////////////////////////////////////////////////////////////////////	77	////////////////////////////////////////////////////////////////////////////////
11	// default keycode translation map and keyevent handlers	78	keyboard_manager::keyboard_manager ()
12	keyevent_handler keysym_translator;
13	keyevent_handler keyrange_translator;
14	keyevent_handler keyrange_translator_meta8;
15	keyevent_handler keylist_translator;
16
17	keysym_t keyboard_manager::stock_keymap_[] =
18	{	79	{
19	/* examples */	80	keymap.reserve (256);
20	/* keysym, state, range, handler, str*/	81	hash [0] = 1; // hash[0] != 0 indicates uninitialized data
21	//{XK_ISO_Left_Tab, 0, 1, keysym_translator, "\033[Z"},
22	//{ 'a', 0, 26, keyrange_translator_meta8, "a" "%c"},
23	//{ 'a', ControlMask, 26, keyrange_translator_meta8, "" "%c"},
24	//{ XK_Left, 0, 4, keylist_translator, "DACBZ" "\033[Z"},
25	//{ XK_Left, ShiftMask, 4, keylist_translator, "dacbZ" "\033[Z"},
26	//{ XK_Left, ControlMask, 4, keylist_translator, "dacbZ" "\033OZ"},
27	//{ XK_Tab, ControlMask, 1, keysym_translator, "\033<C-Tab>"},
28	//{ XK_apostrophe, ControlMask, 1, keysym_translator, "\033<C-'>"},
29	//{ XK_slash, ControlMask, 1, keysym_translator, "\033<C-/>"},
30	//{ XK_semicolon, ControlMask, 1, keysym_translator, "\033<C-;>"},
31	//{ XK_grave, ControlMask, 1, keysym_translator, "\033<C-`>"},
32	//{ XK_comma, ControlMask, 1, keysym_translator, "\033<C-\054>"},
33	//{ XK_Return, ControlMask, 1, keysym_translator, "\033<C-Return>"},
34	//{ XK_Return, ShiftMask, 1, keysym_translator, "\033<S-Return>"},
35	//{ ' ', ShiftMask, 1, keysym_translator, "\033<S-Space>"},
36	//{ '.', ControlMask, 1, keysym_translator, "\033<C-.>"},
37	//{ '0', ControlMask, 10, keyrange_translator, "0" "\033<C-%c>"},
38	//{ '0', MetaMask\|ControlMask, 10, keyrange_translator, "0" "\033<M-C-%c>"},
39	//{ 'a', MetaMask\|ControlMask, 26, keyrange_translator, "a" "\033<M-C-%c>"},
40	};
41
42	void output_string (rxvt_term *rt,
43	const char *str)
44	{
45	assert (rt && str);
46	if (strncmp (str, "proto:", 6) == 0)
47	rt->cmd_write ((unsigned char*)str + 6, strlen (str) - 6);
48	else
49	rt->tt_write ((unsigned char*)str, strlen (str));
50	}	82	}
51		83
52	void output_string_meta8 (rxvt_term *rt,	84	keyboard_manager::~keyboard_manager ()
53	unsigned int state,
54	char buf[],
55	int buflen)
56	{	85	{
57	if (state & rt->ModMetaMask)	86	for (unsigned int i = 0; i < keymap.size (); ++i)
		87	{
		88	free (keymap [i]->str);
		89	delete keymap [i];
58	{	90	}
59	#ifdef META8_OPTION	91	}
60	if(rt->meta_char == 0x80) /* set 8-bit on */	92
		93	void
		94	keyboard_manager::register_user_translation (KeySym keysym, unsigned int state, const wchar_t *ws)
		95	{
		96	char *translation = rxvt_wcstoutf8 (ws);
		97
		98	keysym_t *key = new keysym_t;
		99
		100	key->keysym = keysym;
		101	key->state = state;
		102	key->str = translation;
		103	key->type = keysym_t::STRING;
		104
		105	if (strncmp (translation, "builtin:", 8) == 0)
		106	key->type = keysym_t::BUILTIN;
		107
		108	if (keymap.size () == keymap.capacity ())
		109	keymap.reserve (keymap.size () * 2);
		110
		111	keymap.push_back (key);
		112	hash[0] = 3;
		113	}
		114
		115	bool
		116	keyboard_manager::dispatch (rxvt_term term, KeySym keysym, unsigned int state, const char kbuf, int len)
		117	{
		118	assert (("register_done() need to be called", hash[0] == 0));
		119
		120	state &= OtherModMask; // mask out uninteresting modifiers
		121
		122	if (state & term->ModMetaMask) state \|= MetaMask;
		123	if (state & term->ModNumLockMask) state \|= NumLockMask;
		124	if (state & term->ModLevel3Mask) state \|= Level3Mask;
		125
		126	if (!!(term->priv_modes & PrivMode_aplKP) != !!(state & ShiftMask))
		127	state \|= AppKeypadMask;
		128
		129	int index = find_keysym (keysym, state);
		130
		131	if (index >= 0)
		132	{
		133	keysym_t *key = keymap [index];
		134
		135	if (key->type != keysym_t::BUILTIN)
61	{	136	{
62	for (char *ch = buf; ch < buf + buflen; ch++)	137	wchar_t *ws = rxvt_utf8towcs (key->str);
63	*ch \|= 0x80;	138	char *str = rxvt_wcstombs (ws);
		139	// TODO: do (some) translations, unescaping etc, here (allow \u escape etc.)
		140	free (ws);
		141
		142	if (char *colon = strchr (str, ':'))
		143	{
		144	if (strncmp (str, "command:", 8) == 0)
		145	term->cmdbuf_append (str + 8, strlen (str) - 8);
		146	else if (strncmp (str, "string:", 7) == 0)
		147	term->tt_write_user_input (colon + 1, strlen (colon + 1));
		148	else if (strncmp (str, "perl:", 8) == 0)
		149	HOOK_INVOKE ((term, HOOK_USER_COMMAND, DT_STR, colon + 1, DT_END));
		150	else
		151	HOOK_INVOKE ((term, HOOK_KEYBOARD_DISPATCH, DT_STR_LEN, str, colon - str, DT_STR, colon + 1, DT_END));
		152	}
		153	else
		154	term->tt_write_user_input (str, strlen (str));
		155
		156	free (str);
		157
		158	return true;
64	}	159	}
65	else if(rt->meta_char == C0_ESC) /* escape prefix */
66	#endif
67	{
68	const unsigned char ch = C0_ESC;
69	rt->tt_write (&ch, 1);
70	}
71	}
72
73	rt->tt_write ((unsigned char*)buf, buflen);
74	}
75
76	int format_keyrange_string (keysym_t *key,
77	KeySym keysym,
78	char buf[],
79	int bufsize)
80	{
81	int len;
82
83	assert (key->str);
84	len = snprintf (buf, bufsize, key->str + 1,
85	keysym - key->keysym + (int)(key->str[0]));
86	if (len >= bufsize)
87	{	160	}
88	fprintf (stderr, "buffer overflowed!\n");
89	buf[bufsize-1] = '\0';
90	}
91	else if (len < 0)
92	{
93	perror("keyrange_translator()");
94	}
95		161
96	return len;
97	}
98
99	bool format_keylist_string (keysym_t *key,
100	KeySym keysym,
101	char buf[],
102	int bufsize)
103	{
104	char *p;
105
106	assert (key->str);
107	strncpy (buf, key->str + key->range + 1, bufsize);
108	buf[bufsize-1] = '\0';
109
110	p = strchr (buf, key->str[key->range]);
111	if (p)
112	{
113	*p = key->str[keysym - key->keysym];
114	return true;
115	}
116	else
117	{
118	fprintf (stderr, "invalid str for keylist_translator()!\n");
119	return false;	162	return false;
120	}
121	}
122
123	/////////////////////////////////////////////////////////////////
124	void keysym_translator (rxvt_term *rt,
125	keysym_t *key,
126	KeySym keysym,
127	unsigned int state)
128	{
129	output_string (rt, key->str);
130	}
131
132	void keyrange_translator (rxvt_term *rt,
133	keysym_t *key,
134	KeySym keysym,
135	unsigned int state)
136	{
137	char buf[STRING_MAX];
138
139	if (format_keyrange_string (key, keysym, buf, sizeof(buf)) > 0)
140	output_string (rt, buf);
141	}
142
143	void keyrange_translator_meta8 (rxvt_term *rt,
144	keysym_t *key,
145	KeySym keysym,
146	unsigned int state)
147	{
148	int len;
149	char buf[STRING_MAX];
150
151	len = format_keyrange_string (key, keysym, buf, sizeof(buf));
152	if (len > 0)
153	output_string_meta8 (rt, state, buf, len);
154	}
155
156	void keylist_translator (rxvt_term *rt,
157	keysym_t *key,
158	KeySym keysym,
159	unsigned int state)
160	{
161	char buf[STRING_MAX];
162
163	format_keylist_string (key, keysym, buf, sizeof(buf));
164	output_string (rt, buf);
165	}
166
167	////////////////////////////////////////////////////////////////////////////////
168	// return: #bits of '1'
169	int
170	bitcount (unsigned int n)
171	{
172	int i;
173	for (i = 0; n; ++i, n &= (n - 1));
174	return i;
175	}
176
177	// return: priority_of_a - priority_of_b
178	int
179	compare_priority (keysym_t a, keysym_t b)
180	{
181	assert (a && b);
182
183	// (the more '1's in state; the less range): the greater priority
184	int ca = bitcount (a->state/* & AllModMask*/);
185	int cb = bitcount (b->state/* & AllModMask*/);
186	if (ca != cb)
187	return ca - cb;
188	//else if (a->state != b->state) // this behavior is to be disscussed
189	// return b->state - a->state;
190	else
191	return b->range - a->range;
192	}
193
194	////////////////////////////////////////////////////////////////////////////////
195	keyboard_manager::keyboard_manager (rxvt_term *rt)
196	:term_(rt)
197	{
198	keymap_.reserve (256);
199	hash_[0] = 1; // hash_[0] != 0 indicates uninitialized data
200	}
201
202	keyboard_manager::~keyboard_manager ()
203	{
204	clear ();
205	}
206
207	void
208	keyboard_manager::clear ()
209	{
210	keymap_.clear ();
211	hash_[0] = 2;
212
213	for(unsigned int i = 0;i < user_translations_.size();++i)
214	{
215	delete[] user_translations_[i];
216	user_translations_[i] = 0;
217	}
218
219	for(unsigned int i = 0;i < user_keymap_.size();++i)
220	{
221	delete user_keymap_[i];
222	user_keymap_[i] = 0;
223	}
224
225	user_keymap_.clear();
226	user_translations_.clear();
227	}
228
229	// a wrapper for register_keymap,
230	// so that outside codes don't have to know so much details.
231	//
232	// the string 'trans' is copied to an internal managed buffer,
233	// so the caller can free memory of 'trans' at any time.
234	void
235	keyboard_manager::register_user_translation (KeySym keysym,
236	unsigned int state,
237	const char *trans)
238	{
239	assert(trans);
240
241	keysym_t *key = new keysym_t;
242	const char *translation = new char[1+strlen(trans)];
243
244	if(key && translation)
245	{
246	key->keysym = keysym;
247	key->state = state;
248	key->range = 1;
249	key->str = translation;
250
251	if (strncmp (trans, "list", 4) == 0)
252	{
253	const char *p = &trans[4];
254	if (p && (p = strchr (p+1, p)))
255	if ((p - trans - 5 > 1) && strchr (p+1, *p))
256	{
257	strcpy (translation, trans+5);
258	key->range = p - trans - 5;
259	key->handler = keylist_translator;
260	}
261	}
262	if (key->range == 1)
263	{
264	strcpy (translation, trans);
265	key->handler = keysym_translator;
266	}
267
268	user_keymap_.push_back (key);
269	user_translations_.push_back (translation);
270	register_keymap (key);
271	}
272	else
273	{
274	delete key;
275	delete[] translation;
276	rxvt_fatal ("out of memory, aborting.\n");
277	}
278	}
279
280	void
281	keyboard_manager::register_keymap (keysym_t *key)
282	{
283	assert (key);
284	assert (key->handler);
285	assert (key->range >= 1);
286
287	if (keymap_.size () == keymap_.capacity ())
288	keymap_.reserve (keymap_.size () * 2);
289
290	keymap_.push_back (key);
291	hash_[0] = 3;
292	}	163	}
293		164
294	void	165	void
295	keyboard_manager::register_done ()	166	keyboard_manager::register_done ()
296	{	167	{
297	unsigned int i, n = sizeof(stock_keymap_)/sizeof(keysym_t);	168	unsigned int i, index, hashkey;
		169	uint16_t hash_bucket_size[KEYSYM_HASH_BUCKETS]; // size of each bucket
298		170
299	if(keymap_.back() != &stock_keymap_[n-1])	171	memset (hash_bucket_size, 0, sizeof (hash_bucket_size));
300	for(i = 0;i < n;++i)
301	register_keymap(&stock_keymap_[i]);
302		172
303	purge_duplicate_keymap ();	173	// determine hash bucket size
304
305	for (i = 0; i < keymap_.size(); ++i)	174	for (i = 0; i < keymap.size (); ++i)
		175	{
		176	hashkey = keymap [i]->keysym & KEYSYM_HASH_MASK;
		177	++hash_bucket_size [hashkey];
306	{	178	}
307	keysym_t *key = keymap_[i];
308		179
309	assert (bitcount (term_->ModMetaMask) == 1	180	// now we know the size of each bucket
310	&& "call me after ModMetaMask was set!");	181	// compute the index of each bucket
311	if (key->state & MetaMask)	182	for (index = 0, i = 0; i < KEYSYM_HASH_BUCKETS; ++i)
		183	{
		184	hash [i] = index;
		185	index += hash_bucket_size [i];
		186	}
		187
		188	// and allocate just enough space
		189	simplevec <keysym_t *> sorted_keymap (index, 0);
		190
		191	memset (hash_bucket_size, 0, sizeof (hash_bucket_size));
		192
		193	// fill in sorted_keymap
		194	// it is sorted in each bucket
		195	for (i = 0; i < keymap.size (); ++i)
		196	{
		197	hashkey = keymap [i]->keysym & KEYSYM_HASH_MASK;
		198
		199	index = hash [hashkey] + hash_bucket_size [hashkey];
		200
		201	while (index > hash [hashkey]
		202	&& compare_priority (keymap [i], sorted_keymap [index - 1]) > 0)
312	{	203	{
313	//key->state &= ~MetaMask;	204	sorted_keymap [index] = sorted_keymap [index - 1];
314	key->state \|= term_->ModMetaMask;	205	--index;
315	}	206	}
316		207
317	assert (bitcount (term_->ModNumLockMask) == 1	208	sorted_keymap [index] = keymap [i];
318	&& "call me after ModNumLockMask was set!");	209	++hash_bucket_size [hashkey];
319	if (key->state & NumLockMask)	210	}
		211
		212	keymap.swap (sorted_keymap);
		213
		214	#ifndef NDEBUG
		215	// check for invariants
		216	for (i = 0; i < KEYSYM_HASH_BUCKETS; ++i)
		217	{
		218	index = hash[i];
		219	for (int j = 0; j < hash_bucket_size [i]; ++j)
320	{	220	{
321	//key->state &= ~NumLockMask;
322	key->state \|= term_->ModNumLockMask;
323	}
324	}
325
326	setup_hash ();
327	}
328
329	bool keyboard_manager::dispatch (KeySym keysym, unsigned int state)
330	{
331	assert(hash_[0] == 0 && "register_done() need to be called");
332
333	int index = find_keysym (keysym, state);
334
335	if (index >= 0)
336	{
337	assert (term_ && keymap_[index] && keymap_[index]->handler);
338	keymap_[index]->handler (term_, keymap_[index], keysym, state);
339	return true;
340	}
341	else
342	{
343	// fprintf(stderr,"[%x:%x]",state,keysym);
344	return false;
345	}
346	}
347
348	// purge duplicate keymap_ entries
349	void
350	keyboard_manager::purge_duplicate_keymap ()
351	{
352	for (unsigned int i = 0; i < keymap_.size (); ++i)
353	{
354	for (unsigned int j = 0; j < i; ++j)
355	{
356	if (keymap_[i] == keymap_[j])
357	{
358	while (keymap_[i] == keymap_.back ())
359	keymap_.pop_back ();
360	if (i < keymap_.size ())
361	{
362	keymap_[i] = keymap_.back ();
363	keymap_.pop_back ();
364	}
365	break;
366	}
367	}
368	}
369	}
370
371	void
372	keyboard_manager::setup_hash ()
373	{
374	unsigned int i, index, hashkey;
375	vector<keysym_t *> sorted_keymap;
376	u16 hash_budget_size[KEYSYM_HASH_BUDGETS]; // size of each budget
377	u16 hash_budget_counter[KEYSYM_HASH_BUDGETS]; // #elements in each budget
378
379	memset (hash_budget_size, 0, sizeof (hash_budget_size));
380	memset (hash_budget_counter, 0, sizeof (hash_budget_counter));
381
382	// count keysyms for corresponding hash budgets
383	for (i = 0; i < keymap_.size (); ++i)
384	{
385	assert (keymap_[i]);
386	hashkey = (keymap_[i]->keysym & KEYSYM_HASH_MASK);
387	++hash_budget_size[hashkey];
388	}
389
390	// keysym A with range>1 is counted one more time for
391	// every keysym B lies in its range
392	for (i = 0; i < keymap_.size (); ++i)
393	{
394	if (keymap_[i]->range > 1)
395	{
396	for (int j = min (keymap_[i]->range, KEYSYM_HASH_BUDGETS) - 1;j > 0; --j)
397	{
398	hashkey = ((keymap_[i]->keysym + j) & KEYSYM_HASH_MASK);
399	if (hash_budget_size[hashkey])
400	++hash_budget_size[hashkey];
401	}
402	}
403	}
404
405	// now we know the size of each budget
406	// compute the index of each budget
407	hash_[0] = 0;
408	for (index = 0,i = 1; i < KEYSYM_HASH_BUDGETS; ++i)
409	{
410	index += hash_budget_size[i-1];
411	hash_[i] = (hash_budget_size[i] ? index : hash_[i-1]);
412	}
413	// and allocate just enough space
414	//sorted_keymap.reserve (hash_[i - 1] + hash_budget_size[i - 1]);
415	sorted_keymap.insert (sorted_keymap.begin(), index + hash_budget_size[i - 1], 0);
416
417	// fill in sorted_keymap
418	// it is sorted in each budget
419	for (i = 0; i < keymap_.size (); ++i)
420	{
421	for (int j = min (keymap_[i]->range, KEYSYM_HASH_BUDGETS) - 1;j >= 0; --j)
422	{
423	hashkey = ((keymap_[i]->keysym + j) & KEYSYM_HASH_MASK);
424	if (hash_budget_size[hashkey])
425	{
426	index = hash_[hashkey] + hash_budget_counter[hashkey];
427	while (index > hash_[hashkey] &&
428	compare_priority (keymap_[i],
429	sorted_keymap[index - 1]) > 0)
430	{
431	sorted_keymap[index] = sorted_keymap[index - 1];
432	--index;
433	}
434	sorted_keymap[index] = keymap_[i];
435	++hash_budget_counter[hashkey];
436	}
437	}
438	}
439
440	keymap_.swap (sorted_keymap);
441
442	#if defined (DEBUG_STRICT) \|\| defined (DEBUG_KEYBOARD)
443	// check for invariants
444	for (i = 0; i < KEYSYM_HASH_BUDGETS; ++i)
445	{
446	index = hash_[i];
447	for (int j = 0; j < hash_budget_size[i]; ++j)
448	{
449	if (keymap_[index + j]->range == 1)
450	assert (i == (keymap_[index + j]->keysym & KEYSYM_HASH_MASK));	221	assert (i == (keymap [index + j]->keysym & KEYSYM_HASH_MASK));
		222
451	if (j)	223	if (j)
452	assert (compare_priority (keymap_[index + j - 1],	224	assert (compare_priority (keymap [index + j - 1],
453	keymap_[index + j]) >= 0);	225	keymap [index + j]) >= 0);
454	}	226	}
455	}	227	}
456		228
457	// this should be able to detect most possible bugs	229	// this should be able to detect most possible bugs
458	for (i = 0; i < sorted_keymap.size (); ++i)	230	for (i = 0; i < sorted_keymap.size (); ++i)
459	{	231	{
460	keysym_t *a = sorted_keymap[i];	232	keysym_t *a = sorted_keymap[i];
461	for (int j = 0; j < a->range; ++j)
462	{
463	int index = find_keysym (a->keysym + j, a->state & AllModMask);	233	int index = find_keysym (a->keysym, a->state);
		234
464	assert (index >= 0);	235	assert (index >= 0);
465	keysym_t *b = keymap_[index];	236	keysym_t *b = keymap [index];
466	assert (i == (signed)index \|\| // the normally expected result	237	assert (i == index // the normally expected result
467	(a->keysym + j) >= b->keysym &&	238	\|\| a->keysym == b->keysym
468	(a->keysym + j) <= (b->keysym + b->range) &&
469	compare_priority (a, b) <= 0); // is effectively the same	239	&& compare_priority (a, b) <= 0); // is effectively the same or a closer match
470	}
471	}	240	}
472	#endif	241	#endif
473	}	242	}
474		243
475	int	244	int
476	keyboard_manager::find_keysym (KeySym keysym, unsigned int state)	245	keyboard_manager::find_keysym (KeySym keysym, unsigned int state)
477	{	246	{
478	int hashkey = (keysym & KEYSYM_HASH_MASK);	247	int hashkey = keysym & KEYSYM_HASH_MASK;
479	unsigned int index = hash_[hashkey];	248	unsigned int index = hash [hashkey];
		249	unsigned int end = hashkey < KEYSYM_HASH_BUCKETS - 1
		250	? hash [hashkey + 1]
		251	: keymap.size ();
480		252
481	for (;index < keymap_.size(); ++index)	253	for (; index < end; ++index)
482	{	254	{
483	keysym_t *key = keymap_[index];	255	keysym_t *key = keymap [index];
484	assert (key);	256
485	if (key->keysym <= keysym &&	257	if (key->keysym == keysym
486	key->keysym + key->range > keysym &&
487	// match only the specified bits in state and ignore others	258	// match only the specified bits in state and ignore others
488	(key->state & (unsigned int)AllModMask) == (key->state & state))	259	&& (key->state & state) == key->state)
489	{
490	return index;	260	return index;
491	}
492	else if (key->keysym > keysym &&
493	key->range == 1)
494	return -1;
495	}	261	}
496		262
497	return -1;	263	return -1;
498	}	264	}
499		265

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Comparing rxvt-unicode/src/keyboard.C (file contents): Revision 1.1 by root, Sun Jan 16 15:59:45 2005 UTC vs. Revision 1.64 by sf-exg, Tue Apr 29 13:10:06 2014 UTC

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Comparing rxvt-unicode/src/keyboard.C (file contents):
Revision 1.1 by root, Sun Jan 16 15:59:45 2005 UTC vs.
Revision 1.64 by sf-exg, Tue Apr 29 13:10:06 2014 UTC