rxvt-unicode/src/keyboard.C

/*----------------------------------------------------------------------*
 * File:        keyboard.C
 *----------------------------------------------------------------------*
 *
 * All portions of code are copyright by their respective author/s.
 * Copyright (c) 2005      WU Fengguang
 * Copyright (c) 2005-2006 Marc Lehmann <schmorp@schmorp.de>
 *
 * This program is free software; you can redistribute it and/or modify
 * it under the terms of the GNU General Public License as published by
 * the Free Software Foundation; either version 2 of the License, or
 * (at your option) any later version.
 *
 * This program is distributed in the hope that it will be useful,
 * but WITHOUT ANY WARRANTY; without even the implied warranty of
 * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
 * GNU General Public License for more details.
 *
 * You should have received a copy of the GNU General Public License
 * along with this program; if not, write to the Free Software
 * Foundation, Inc., 675 Mass Ave, Cambridge, MA 02139, USA.
 *----------------------------------------------------------------------*/

#include "../config.h"
#include "rxvt.h"

#ifdef KEYSYM_RESOURCE

#include <string.h>

#include "rxvtperl.h"
#include "keyboard.h"

/* an intro to the data structure:
 *
 * vector keymap[] is grouped.
 *
 * inside each group, elements are sorted by the criteria given by compare_priority().
 * the lookup of keysym is done in two steps:
 * 1) locate the group corresponds to the keysym;
 * 2) do a linear search inside the group.
 *
 * array hash[] effectively defines a map from a keysym to a group in keymap[].
 *
 * each group has its address(the index of first group element in keymap[]),
 * which is computed and stored in hash[].
 * hash[] stores the addresses in the form of:
 * index: 0      I1       I2       I3            In
 * value: 0...0, A1...A1, A2...A2, A3...A3, ..., An...An
 * where
 * A1 = 0;
 * Ai+1 = N1 + N2 + ... + Ni.
 * it is computed from hash_bucket_size[]:
 * index: 0      I1         I2         I3             In
 * value: 0...0, N1, 0...0, N2, 0...0, N3,    ...,    Nn, 0...0
 *        0...0, 0.......0, N1.....N1, N1+N2...N1+N2, ... (the computation of hash[])
 * or we can say
 * hash_bucket_size[Ii] = Ni; hash_bucket_size[elsewhere] = 0,
 * where
 * set {I1, I2, ..., In} = { hashkey of keymap[0]->keysym, ..., keymap[keymap.size-1]->keysym }
 * where hashkey of keymap[i]->keysym = keymap[i]->keysym & KEYSYM_HASH_MASK
 *       n(the number of groups) = the number of non-zero member of hash_bucket_size[];
 *       Ni(the size of group i) = hash_bucket_size[Ii].
 */

static void
output_string (rxvt_term *term, const char *str)
{
  if (strncmp (str, "command:", 8) == 0)
    term->cmdbuf_append (str + 8, strlen (str) - 8);
  else if (strncmp (str, "perl:", 5) == 0)
    HOOK_INVOKE((term, HOOK_USER_COMMAND, DT_STR, str + 5, DT_END));
  else
    term->tt_write (str, strlen (str));
}

// return: priority_of_a - priority_of_b
static int
compare_priority (keysym_t *a, keysym_t *b)
{
  // (the more '1's in state; the less range): the greater priority
  int ca = ecb_popcount32 (a->state /* & OtherModMask */);
  int cb = ecb_popcount32 (b->state /* & OtherModMask */);

  return ca - cb;
}

////////////////////////////////////////////////////////////////////////////////
keyboard_manager::keyboard_manager ()
{
  keymap.reserve (256);
  hash [0] = 1;                 // hash[0] != 0 indicates uninitialized data
}

keyboard_manager::~keyboard_manager ()
{
  for (unsigned int i = 0; i < keymap.size (); ++i)
    {
      free (keymap [i]->str);
      delete keymap [i];
    }
}

void
keyboard_manager::register_user_translation (KeySym keysym, unsigned int state, const wchar_t *ws)
{
  char *translation = rxvt_wcstoutf8 (ws);

  keysym_t *key = new keysym_t;

  key->keysym = keysym;
  key->state  = state;
  key->str    = translation;
  key->type   = keysym_t::STRING;

  if (strncmp (translation, "builtin:", 8) == 0)
    key->type = keysym_t::BUILTIN;

  if (keymap.size () == keymap.capacity ())
    keymap.reserve (keymap.size () * 2);

  keymap.push_back (key);
  hash[0] = 3;
}

bool
keyboard_manager::dispatch (rxvt_term *term, KeySym keysym, unsigned int state, const char *kbuf, int len)
{
  assert (("register_done() need to be called", hash[0] == 0));

  state &= OtherModMask; // mask out uninteresting modifiers

  if (state & term->ModMetaMask)    state |= MetaMask;
  if (state & term->ModNumLockMask) state |= NumLockMask;
  if (state & term->ModLevel3Mask)  state |= Level3Mask;

  if (!!(term->priv_modes & PrivMode_aplKP) != !!(state & ShiftMask))
    state |= AppKeypadMask;

  int index = find_keysym (keysym, state);

  if (index >= 0)
    {
      keysym_t *key = keymap [index];

      if (key->type != keysym_t::BUILTIN)
        {
          wchar_t *ws = rxvt_utf8towcs (key->str);
          char *str = rxvt_wcstombs (ws);
          // TODO: do (some) translations, unescaping etc, here (allow \u escape etc.)
          free (ws);

          output_string (term, str);

          free (str);

          return true;
        }
    }

  return false;
}

void
keyboard_manager::register_done ()
{
  unsigned int i, index, hashkey;
  uint16_t hash_bucket_size[KEYSYM_HASH_BUCKETS];       // size of each bucket

  memset (hash_bucket_size, 0, sizeof (hash_bucket_size));

  // determine hash bucket size
  for (i = 0; i < keymap.size (); ++i)
    {
      hashkey = keymap [i]->keysym & KEYSYM_HASH_MASK;
      ++hash_bucket_size [hashkey];
    }

  // now we know the size of each bucket
  // compute the index of each bucket
  for (index = 0, i = 0; i < KEYSYM_HASH_BUCKETS; ++i)
    {
      hash [i] = index;
      index += hash_bucket_size [i];
    }

  // and allocate just enough space
  simplevec <keysym_t *> sorted_keymap (index, 0);

  memset (hash_bucket_size, 0, sizeof (hash_bucket_size));

  // fill in sorted_keymap
  // it is sorted in each bucket
  for (i = 0; i < keymap.size (); ++i)
    {
      hashkey = keymap [i]->keysym & KEYSYM_HASH_MASK;

      index = hash [hashkey] + hash_bucket_size [hashkey];

      while (index > hash [hashkey]
             && compare_priority (keymap [i], sorted_keymap [index - 1]) > 0)
        {
          sorted_keymap [index] = sorted_keymap [index - 1];
          --index;
        }

      sorted_keymap [index] = keymap [i];
      ++hash_bucket_size [hashkey];
    }

  keymap.swap (sorted_keymap);

#ifndef NDEBUG
  // check for invariants
  for (i = 0; i < KEYSYM_HASH_BUCKETS; ++i)
    {
      index = hash[i];
      for (int j = 0; j < hash_bucket_size [i]; ++j)
        {
          assert (i == (keymap [index + j]->keysym & KEYSYM_HASH_MASK));

          if (j)
            assert (compare_priority (keymap [index + j - 1],
                    keymap [index + j]) >= 0);
        }
    }

  // this should be able to detect most possible bugs
  for (i = 0; i < sorted_keymap.size (); ++i)
    {
      keysym_t *a = sorted_keymap[i];
      int index = find_keysym (a->keysym, a->state);

      assert (index >= 0);
      keysym_t *b = keymap [index];
      assert (i == index        // the normally expected result
              || a->keysym == b->keysym
              && compare_priority (a, b) <= 0); // is effectively the same or a closer match
    }
#endif
}

int
keyboard_manager::find_keysym (KeySym keysym, unsigned int state)
{
  int hashkey = keysym & KEYSYM_HASH_MASK;
  unsigned int index = hash [hashkey];
  unsigned int end = hashkey < KEYSYM_HASH_BUCKETS - 1
                     ? hash [hashkey + 1]
                     : keymap.size ();

  for (; index < end; ++index)
    {
      keysym_t *key = keymap [index];

      if (key->keysym == keysym
          // match only the specified bits in state and ignore others
          && (key->state & state) == key->state)
        return index;
    }

  return -1;
}

#endif /* KEYSYM_RESOURCE */
// vim:et:ts=2:sw=2
Revision:	1.61
Committed:	Sat Apr 26 15:05:17 2014 UTC (10 years ago) by sf-exg
Content type:	text/plain
Branch:	MAIN
Changes since 1.60:	+1 -1 lines
Log Message:	Pass kbuf to keyboard_manager::dispatch.
#	User	Rev	Content
1	root	1.25	/----------------------------------------------------------------------
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	root	1.39	* Copyright (c) 2005-2006 Marc Lehmann <schmorp@schmorp.de>
8	root	1.25	*
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
24	root	1.1	#include "../config.h"
25			#include "rxvt.h"
26	root	1.7
27			#ifdef KEYSYM_RESOURCE
28
29	sf-exg	1.58	#include <string.h>
30	root	1.7
31	root	1.18	#include "rxvtperl.h"
32	root	1.1	#include "keyboard.h"
33
34	root	1.13	/* 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	sf-exg	1.34	* it is computed from hash_bucket_size[]:
54	root	1.13	* index: 0 I1 I2 I3 In
55			* value: 0...0, N1, 0...0, N2, 0...0, N3, ..., Nn, 0...0
56	sf-exg	1.33	* 0...0, 0.......0, N1.....N1, N1+N2...N1+N2, ... (the computation of hash[])
57	root	1.13	* or we can say
58	sf-exg	1.34	* hash_bucket_size[Ii] = Ni; hash_bucket_size[elsewhere] = 0,
59	root	1.13	* 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	sf-exg	1.34	* 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	root	1.13	*/
65
66	root	1.2	static void
67	sf-exg	1.48	output_string (rxvt_term term, const char str)
68	root	1.1	{
69	root	1.10	if (strncmp (str, "command:", 8) == 0)
70	sf-exg	1.48	term->cmdbuf_append (str + 8, strlen (str) - 8);
71	root	1.18	else if (strncmp (str, "perl:", 5) == 0)
72	sf-exg	1.48	HOOK_INVOKE((term, HOOK_USER_COMMAND, DT_STR, str + 5, DT_END));
73	root	1.1	else
74	sf-exg	1.48	term->tt_write (str, strlen (str));
75	root	1.1	}
76
77			// return: priority_of_a - priority_of_b
78	root	1.2	static int
79	root	1.1	compare_priority (keysym_t a, keysym_t b)
80			{
81			// (the more '1's in state; the less range): the greater priority
82	sf-exg	1.43	int ca = ecb_popcount32 (a->state /* & OtherModMask */);
83			int cb = ecb_popcount32 (b->state /* & OtherModMask */);
84	root	1.2
85	sf-exg	1.60	return ca - cb;
86	root	1.1	}
87
88			////////////////////////////////////////////////////////////////////////////////
89	root	1.2	keyboard_manager::keyboard_manager ()
90	root	1.1	{
91	root	1.2	keymap.reserve (256);
92	root	1.4	hash [0] = 1; // hash[0] != 0 indicates uninitialized data
93	root	1.1	}
94
95			keyboard_manager::~keyboard_manager ()
96			{
97	sf-exg	1.37	for (unsigned int i = 0; i < keymap.size (); ++i)
98	sf-exg	1.36	{
99	sf-exg	1.45	free (keymap [i]->str);
100	sf-exg	1.37	delete keymap [i];
101	sf-exg	1.36	}
102	root	1.1	}
103
104			void
105	sf-exg	1.52	keyboard_manager::register_user_translation (KeySym keysym, unsigned int state, const wchar_t *ws)
106	root	1.1	{
107	sf-exg	1.51	char *translation = rxvt_wcstoutf8 (ws);
108	root	1.1
109	sf-exg	1.42	keysym_t *key = new keysym_t;
110
111	sf-exg	1.55	key->keysym = keysym;
112			key->state = state;
113			key->str = translation;
114			key->type = keysym_t::STRING;
115	root	1.2
116	sf-exg	1.55	if (strncmp (translation, "builtin:", 8) == 0)
117			key->type = keysym_t::BUILTIN;
118	root	1.1
119	sf-exg	1.55	if (keymap.size () == keymap.capacity ())
120			keymap.reserve (keymap.size () * 2);
121	sf-exg	1.47
122	sf-exg	1.55	keymap.push_back (key);
123			hash[0] = 3;
124	root	1.1	}
125
126	root	1.2	bool
127	sf-exg	1.61	keyboard_manager::dispatch (rxvt_term term, KeySym keysym, unsigned int state, const char kbuf, int len)
128	root	1.1	{
129	sf-exg	1.46	assert (("register_done() need to be called", hash[0] == 0));
130	root	1.1
131	root	1.14	state &= OtherModMask; // mask out uninteresting modifiers
132
133	root	1.6	if (state & term->ModMetaMask) state \|= MetaMask;
134			if (state & term->ModNumLockMask) state \|= NumLockMask;
135			if (state & term->ModLevel3Mask) state \|= Level3Mask;
136	root	1.3
137			if (!!(term->priv_modes & PrivMode_aplKP) != !!(state & ShiftMask))
138			state \|= AppKeypadMask;
139
140	root	1.1	int index = find_keysym (keysym, state);
141
142			if (index >= 0)
143			{
144	sf-exg	1.49	keysym_t *key = keymap [index];
145	root	1.2
146	sf-exg	1.49	if (key->type != keysym_t::BUILTIN)
147	root	1.16	{
148	sf-exg	1.51	wchar_t *ws = rxvt_utf8towcs (key->str);
149			char *str = rxvt_wcstombs (ws);
150	root	1.16	// TODO: do (some) translations, unescaping etc, here (allow \u escape etc.)
151	sf-exg	1.51	free (ws);
152	root	1.2
153	sf-exg	1.44	output_string (term, str);
154	root	1.2
155	root	1.16	free (str);
156	root	1.2
157	root	1.16	return true;
158			}
159	root	1.1	}
160	root	1.16
161			return false;
162	root	1.1	}
163
164			void
165	sf-exg	1.47	keyboard_manager::register_done ()
166	root	1.1	{
167			unsigned int i, index, hashkey;
168	sf-exg	1.34	uint16_t hash_bucket_size[KEYSYM_HASH_BUCKETS]; // size of each bucket
169	root	1.1
170	sf-exg	1.34	memset (hash_bucket_size, 0, sizeof (hash_bucket_size));
171	root	1.1
172	root	1.11	// determine hash bucket size
173	root	1.2	for (i = 0; i < keymap.size (); ++i)
174	sf-exg	1.41	{
175			hashkey = keymap [i]->keysym & KEYSYM_HASH_MASK;
176			++hash_bucket_size [hashkey];
177			}
178	root	1.1
179	sf-exg	1.34	// now we know the size of each bucket
180			// compute the index of each bucket
181	sf-exg	1.60	for (index = 0, i = 0; i < KEYSYM_HASH_BUCKETS; ++i)
182	root	1.1	{
183	root	1.11	hash [i] = index;
184	sf-exg	1.60	index += hash_bucket_size [i];
185	root	1.1	}
186	root	1.2
187	root	1.1	// and allocate just enough space
188	sf-exg	1.60	simplevec <keysym_t *> sorted_keymap (index, 0);
189	root	1.1
190	sf-exg	1.38	memset (hash_bucket_size, 0, sizeof (hash_bucket_size));
191
192	root	1.1	// fill in sorted_keymap
193	sf-exg	1.34	// it is sorted in each bucket
194	root	1.2	for (i = 0; i < keymap.size (); ++i)
195	sf-exg	1.41	{
196			hashkey = keymap [i]->keysym & KEYSYM_HASH_MASK;
197
198			index = hash [hashkey] + hash_bucket_size [hashkey];
199
200			while (index > hash [hashkey]
201			&& compare_priority (keymap [i], sorted_keymap [index - 1]) > 0)
202			{
203			sorted_keymap [index] = sorted_keymap [index - 1];
204			--index;
205			}
206
207			sorted_keymap [index] = keymap [i];
208			++hash_bucket_size [hashkey];
209			}
210	root	1.1
211	root	1.2	keymap.swap (sorted_keymap);
212	root	1.1
213	root	1.32	#ifndef NDEBUG
214	root	1.1	// check for invariants
215	sf-exg	1.34	for (i = 0; i < KEYSYM_HASH_BUCKETS; ++i)
216	root	1.1	{
217	root	1.2	index = hash[i];
218	sf-exg	1.34	for (int j = 0; j < hash_bucket_size [i]; ++j)
219	root	1.1	{
220	sf-exg	1.41	assert (i == (keymap [index + j]->keysym & KEYSYM_HASH_MASK));
221	root	1.2
222	root	1.1	if (j)
223	root	1.4	assert (compare_priority (keymap [index + j - 1],
224			keymap [index + j]) >= 0);
225	root	1.1	}
226			}
227
228			// this should be able to detect most possible bugs
229			for (i = 0; i < sorted_keymap.size (); ++i)
230			{
231			keysym_t *a = sorted_keymap[i];
232	sf-exg	1.41	int index = find_keysym (a->keysym, a->state);
233	root	1.6
234	sf-exg	1.41	assert (index >= 0);
235			keysym_t *b = keymap [index];
236			assert (i == index // the normally expected result
237			\|\| a->keysym == b->keysym
238			&& compare_priority (a, b) <= 0); // is effectively the same or a closer match
239	root	1.1	}
240			#endif
241			}
242
243			int
244			keyboard_manager::find_keysym (KeySym keysym, unsigned int state)
245			{
246	root	1.2	int hashkey = keysym & KEYSYM_HASH_MASK;
247			unsigned int index = hash [hashkey];
248	sf-exg	1.34	unsigned int end = hashkey < KEYSYM_HASH_BUCKETS - 1
249	ayin	1.28	? hash [hashkey + 1]
250	root	1.11	: keymap.size ();
251	root	1.1
252	root	1.11	for (; index < end; ++index)
253	root	1.1	{
254	root	1.4	keysym_t *key = keymap [index];
255	root	1.2
256	sf-exg	1.41	if (key->keysym == keysym
257	root	1.1	// match only the specified bits in state and ignore others
258	root	1.16	&& (key->state & state) == key->state)
259	root	1.2	return index;
260	root	1.1	}
261
262			return -1;
263			}
264
265			#endif /* KEYSYM_RESOURCE */
266			// vim:et:ts=2:sw=2