| blob | 0fa1cc2b0e231c85976b8c99157b0c267ee88ccb |
1 /* Low-level bidirectional buffer/string-scanning functions for GNU Emacs.
2 Copyright (C) 2000-2001, 2004-2005, 2009-2012
3 Free Software Foundation, Inc.
5 This file is part of GNU Emacs.
7 GNU Emacs is free software: you can redistribute it and/or modify
8 it under the terms of the GNU General Public License as published by
9 the Free Software Foundation, either version 3 of the License, or
10 (at your option) any later version.
12 GNU Emacs is distributed in the hope that it will be useful,
13 but WITHOUT ANY WARRANTY; without even the implied warranty of
14 MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
15 GNU General Public License for more details.
17 You should have received a copy of the GNU General Public License
18 along with GNU Emacs. If not, see <http://www.gnu.org/licenses/>. */
20 /* Written by Eli Zaretskii <eliz@gnu.org>.
22 A sequential implementation of the Unicode Bidirectional algorithm,
23 (UBA) as per UAX#9, a part of the Unicode Standard.
25 Unlike the reference and most other implementations, this one is
26 designed to be called once for every character in the buffer or
27 string.
29 The main entry point is bidi_move_to_visually_next. Each time it
30 is called, it finds the next character in the visual order, and
31 returns its information in a special structure. The caller is then
32 expected to process this character for display or any other
33 purposes, and call bidi_move_to_visually_next for the next
34 character. See the comments in bidi_move_to_visually_next for more
35 details about its algorithm that finds the next visual-order
36 character by resolving their levels on the fly.
38 Two other entry points are bidi_paragraph_init and
39 bidi_mirror_char. The first determines the base direction of a
40 paragraph, while the second returns the mirrored version of its
41 argument character.
43 A few auxiliary entry points are used to initialize the bidi
44 iterator for iterating an object (buffer or string), push and pop
45 the bidi iterator state, and save and restore the state of the bidi
46 cache.
48 If you want to understand the code, you will have to read it
49 together with the relevant portions of UAX#9. The comments include
50 references to UAX#9 rules, for that very reason.
52 A note about references to UAX#9 rules: if the reference says
53 something like "X9/Retaining", it means that you need to refer to
54 rule X9 and to its modifications described in the "Implementation
55 Notes" section of UAX#9, under "Retaining Format Codes". */
57 #include <config.h>
58 #include <stdio.h>
59 #include <setjmp.h>
70 #define LRM_CHAR 0x200E
71 #define RLM_CHAR 0x200F
72 #define BIDI_EOB -1
74 /* Data type for describing the bidirectional character categories. */
76 UNKNOWN_BC,
77 NEUTRAL,
78 WEAK,
79 STRONG
82 /* UAX#9 says to search only for L, AL, or R types of characters, and
83 ignore RLE, RLO, LRE, and LRO, when determining the base paragraph
84 level. Yudit indeed ignores them. This variable is therefore set
85 by default to ignore them, but setting it to zero will take them
86 into account. */
93 \f
94 /***********************************************************************
95 Utilities
96 ***********************************************************************/
98 /* Return the bidi type of a character CH, subject to the current
99 directional OVERRIDE. */
102 {
103 bidi_type_t default_type;
111 /* Every valid character code, even those that are unassigned by the
112 UCD, have some bidi-class property, according to
113 DerivedBidiClass.txt file. Therefore, if we ever get UNKNOWN_BT
114 (= zero) code from CHAR_TABLE_REF, that's a bug. */
122 {
123 /* Although UAX#9 does not tell, it doesn't make sense to
124 override NEUTRAL_B and LRM/RLM characters. */
134 {
143 else
145 }
146 }
147 }
151 {
153 }
155 /* Given a bidi TYPE of a character, return its category. */
158 {
160 {
187 }
188 }
190 /* Return the mirrored character of C, if it has one. If C has no
191 mirrored counterpart, return C.
192 Note: The conditions in UAX#9 clause L4 regarding the surrounding
193 context must be tested by the caller. */
194 int
196 {
197 Lisp_Object val;
206 {
209 /* When debugging, check before assigning to V, so that the check
210 isn't broken by undefined behavior due to int overflow. */
215 /* Minimal test we must do in optimized builds, to prevent weird
216 crashes further down the road. */
221 }
224 }
226 /* Determine the start-of-run (sor) directional type given the two
227 embedding levels on either side of the run boundary. Also, update
228 the saved info about previously seen characters, since that info is
229 generally valid for a single level run. */
232 {
235 /* The prev_was_pdf gork is required for when we have several PDFs
236 in a row. In that case, we want to compute the sor type for the
237 next level run only once: when we see the first PDF. That's
238 because the sor type depends only on the higher of the two levels
239 that we find on the two sides of the level boundary (see UAX#9,
240 clause X10), and so we don't need to know the final embedding
241 level to which we descend after processing all the PDFs. */
243 /* FIXME: should the default sor direction be user selectable? */
257 }
259 /* Push the current embedding level and override status; reset the
260 current level to LEVEL and the current override status to OVERRIDE. */
264 {
269 }
271 /* Pop the embedding level and directional override status from the
272 stack, and return the new level. */
275 {
276 /* UAX#9 says to ignore invalid PDFs. */
280 }
282 /* Record in SAVED_INFO the information about the current character. */
286 {
295 }
297 /* Copy the bidi iterator from FROM to TO. To save cycles, this only
298 copies the part of the level stack that is actually in use. */
301 {
304 /* Copy everything except the level stack and beyond. */
307 /* Copy the active part of the level stack. */
311 }
313 \f
314 /***********************************************************************
315 Caching the bidi iterator states
316 ***********************************************************************/
318 #define BIDI_CACHE_CHUNK 200
325 "stack" level */
327 /* 5-slot stack for saving the start of the previous level of the
328 cache. xdisp.c maintains a 5-slot stack for its iterator state,
329 and we need the same size of our stack. */
333 /* Size of header used by bidi_shelve_cache. */
334 enum
335 {
336 bidi_shelve_header_size
340 };
342 /* Reset the cache state to the empty state. We only reset the part
343 of the cache relevant to iteration of the current object. Previous
344 objects, which are pushed on the display iterator's stack, are left
345 intact. This is called when the cached information is no more
346 useful for the current iteration, e.g. when we were reseated to a
347 new position on the same object. */
350 {
353 }
355 /* Shrink the cache to its minimal size. Called when we init the bidi
356 iterator for reordering a buffer or a string that does not come
357 from display properties, because that means all the previously
358 cached info is of no further use. */
361 {
363 {
366 }
368 }
372 {
381 }
383 /* Find a cached state with a given CHARPOS and resolved embedding
384 level less or equal to LEVEL. if LEVEL is -1, disregard the
385 resolved levels in cached states. DIR, if non-zero, means search
386 in that direction from the last cache hit. */
389 {
393 {
397 {
400 }
403 {
406 }
409 else
410 {
413 }
416 {
417 /* Linear search for now; FIXME! */
423 }
424 else
425 {
431 }
432 }
435 }
437 /* Find a cached state where the resolved level changes to a value
438 that is lower than LEVEL, and return its cache slot index. DIR is
439 the direction to search, starting with the last used cache slot.
440 If DIR is zero, we search backwards from the last occupied cache
441 slot. BEFORE, if non-zero, means return the index of the slot that
442 is ``before'' the level change in the search direction. That is,
443 given the cached levels like this:
445 1122333442211
446 AB C
448 and assuming we are at the position cached at the slot marked with
449 C, searching backwards (DIR = -1) for LEVEL = 2 will return the
450 index of slot B or A, depending whether BEFORE is, respectively,
451 non-zero or zero. */
452 static ptrdiff_t
454 {
456 {
468 {
470 {
474 i--;
475 }
476 }
477 else
478 {
480 {
484 i++;
485 }
486 }
487 }
490 }
494 {
495 /* Enlarge the cache as needed. */
497 {
498 /* The bidi cache cannot be larger than the largest Lisp string
499 or buffer. */
500 ptrdiff_t string_or_buffer_bound
503 /* Also, it cannot be larger than what C can represent. */
504 ptrdiff_t c_bound
507 bidi_cache
511 }
512 }
516 {
519 /* We should never cache on backward scans. */
525 {
528 /* Character positions should correspond to cache positions 1:1.
529 If we are outside the range of cached positions, the cache is
530 useless and must be reset. */
535 {
538 }
544 }
545 else
546 {
547 /* Copy only the members which could have changed, to avoid
548 costly copying of the entire struct. */
555 else
564 }
569 }
573 {
577 {
582 /* Don't let scan direction from the cached state override
583 the current scan direction. */
586 }
589 }
593 {
597 }
599 \f
600 /***********************************************************************
601 Pushing and popping the bidi iterator state
602 ***********************************************************************/
604 /* Push the bidi iterator state in preparation for reordering a
605 different object, e.g. display string found at certain buffer
606 position. Pushing the bidi iterator boils down to saving its
607 entire state on the cache and starting a new cache "stacked" on top
608 of the current cache. */
609 void
611 {
612 /* Save the current iterator state in its entirety after the last
613 used cache slot. */
617 /* Push the current cache start onto the stack. */
621 /* Start a new level of cache, and make it empty. */
624 }
626 /* Restore the iterator state saved by bidi_push_it and return the
627 cache to the corresponding state. */
628 void
630 {
634 /* Reset the next free cache slot index to what it was before the
635 call to bidi_push_it. */
638 /* Restore the bidi iterator state saved in the cache. */
641 /* Pop the previous cache start from the stack. */
646 /* Invalidate the last-used cache slot data. */
648 }
652 /* Stash away a copy of the cache and its control variables. */
655 {
659 /* Empty cache. */
663 alloc = (bidi_shelve_header_size
689 }
691 /* Restore the cache state from a copy stashed away by
692 bidi_shelve_cache, and free the buffer used to stash that copy.
693 JUST_FREE non-zero means free the buffer, but don't restore the
694 cache; used when the corresponding iterator is discarded instead of
695 being restored. */
696 void
698 {
702 {
704 {
705 /* A NULL pointer means an empty cache. */
709 }
710 }
711 else
712 {
714 {
718 bidi_cache_total_alloc
720 }
721 else
722 {
747 bidi_cache_total_alloc
748 -= (bidi_shelve_header_size
750 }
753 }
754 }
756 \f
757 /***********************************************************************
758 Initialization
759 ***********************************************************************/
760 static void
762 {
790 }
792 /* Do whatever UAX#9 clause X8 says should be done at paragraph's
793 end. */
796 {
801 }
803 /* Initialize the bidi iterator from buffer/string position CHARPOS. */
804 void
807 {
839 /* We can only shrink the cache if we are at the bottom level of its
840 "stack". */
843 else
845 }
847 /* Perform initializations for reordering a new line of bidi text. */
848 static void
850 {
856 /* Setting this to zero will force its recomputation the first time
857 we need it for W5. */
866 }
868 \f
869 /***********************************************************************
870 Fetching characters
871 ***********************************************************************/
873 /* Count bytes in string S between BEG/BEGBYTE and END. BEG and END
874 are zero-based character positions in S, BEGBYTE is byte position
875 corresponding to BEG. UNIBYTE, if non-zero, means S is a unibyte
876 string. */
880 {
886 else
887 {
892 {
894 pos++;
895 }
896 }
899 }
901 /* Fetch and returns the character at byte position BYTEPOS. If S is
902 non-NULL, fetch the character from string S; otherwise fetch the
903 character from the current buffer. UNIBYTE non-zero means S is a
904 unibyte string. */
907 {
909 {
912 else
914 }
915 else
917 }
919 /* Fetch and return the character at BYTEPOS/CHARPOS. If that
920 character is covered by a display string, treat the entire run of
921 covered characters as a single character, either u+2029 or u+FFFC,
922 and return their combined length in CH_LEN and NCHARS. DISP_POS
923 specifies the character position of the next display string, or -1
924 if not yet computed. When the next character is at or beyond that
925 position, the function updates DISP_POS with the position of the
926 next display string. DISP_PROP non-zero means that there's really
927 a display string at DISP_POS, as opposed to when we searched till
928 DISP_POS without finding one. If DISP_PROP is 2, it means the
929 display spec is of the form `(space ...)', which is replaced with
930 u+2029 to handle it as a paragraph separator. STRING->s is the C
931 string to iterate, or NULL if iterating over a buffer or a Lisp
932 string; in the latter case, STRING->lstring is the Lisp string. */
937 {
939 ptrdiff_t endpos
944 /* If we got past the last known position of display string, compute
945 the position of the next one. That position could be at CHARPOS. */
947 {
950 disp_prop);
951 }
953 /* Fetch the character at BYTEPOS. */
955 {
961 }
963 {
966 /* We don't expect to find ourselves in the middle of a display
967 property. Hopefully, it will never be needed. */
970 /* Text covered by `display' properties and overlays with
971 display properties or display strings is handled as a single
972 character that represents the entire run of characters
973 covered by the display property. */
975 {
976 /* `(space ...)' display specs are handled as paragraph
977 separators for the purposes of the reordering; see UAX#9
978 section 3 and clause HL1 in section 4.3 there. */
980 }
981 else
982 {
983 /* All other display specs are handled as the Unicode Object
984 Replacement Character. */
986 }
989 {
990 /* Somebody removed the display string from the buffer
991 behind our back. Recover by processing this buffer
992 position as if no display property were present there to
993 begin with. */
996 }
1006 else
1008 }
1009 else
1010 {
1011 normal_char:
1013 {
1016 {
1019 }
1020 else
1021 {
1024 }
1025 }
1027 {
1029 {
1031 len);
1033 }
1034 else
1035 {
1038 }
1039 }
1040 else
1041 {
1044 }
1046 }
1048 /* If we just entered a run of characters covered by a display
1049 string, compute the position of the next display string. */
1052 {
1055 disp_prop);
1056 }
1059 }
1061 \f
1062 /***********************************************************************
1063 Determining paragraph direction
1064 ***********************************************************************/
1066 /* Check if buffer position CHARPOS/BYTEPOS is the end of a paragraph.
1067 Value is the non-negative length of the paragraph separator
1068 following the buffer position, -1 if position is at the beginning
1069 of a new paragraph, or -2 if position is neither at beginning nor
1070 at end of a paragraph. */
1071 static ptrdiff_t
1073 {
1074 Lisp_Object sep_re;
1075 Lisp_Object start_re;
1083 {
1086 else
1088 }
1091 }
1093 /* On my 2005-vintage machine, searching back for paragraph start
1094 takes ~1 ms per line. And bidi_paragraph_init is called 4 times
1095 when user types C-p. The number below limits each call to
1096 bidi_paragraph_init to about 10 ms. */
1097 #define MAX_PARAGRAPH_SEARCH 7500
1099 /* Find the beginning of this paragraph by looking back in the buffer.
1100 Value is the byte position of the paragraph's beginning, or
1101 BEGV_BYTE if paragraph_start_re is still not found after looking
1102 back MAX_PARAGRAPH_SEARCH lines in the buffer. */
1103 static ptrdiff_t
1105 {
1113 {
1114 /* FIXME: What if the paragraph beginning is covered by a
1115 display string? And what if a display string covering some
1116 of the text over which we scan back includes
1117 paragraph_start_re? */
1120 }
1124 }
1126 /* Determine the base direction, a.k.a. base embedding level, of the
1127 paragraph we are about to iterate through. If DIR is either L2R or
1128 R2L, just use that. Otherwise, determine the paragraph direction
1129 from the first strong directional character of the paragraph.
1131 NO_DEFAULT_P non-zero means don't default to L2R if the paragraph
1132 has no strong directional characters and both DIR and
1133 bidi_it->paragraph_dir are NEUTRAL_DIR. In that case, search back
1134 in the buffer until a paragraph is found with a strong character,
1135 or until hitting BEGV. In the latter case, fall back to L2R. This
1136 flag is used in current-bidi-paragraph-direction.
1138 Note that this function gives the paragraph separator the same
1139 direction as the preceding paragraph, even though Emacs generally
1140 views the separator as not belonging to any paragraph. */
1141 void
1143 {
1147 /* Note that begbyte is a byte position, while end is a character
1148 position. Yes, this is ugly, but we are trying to avoid costly
1149 calls to BYTE_TO_CHAR and its ilk. */
1153 /* Special case for an empty buffer. */
1156 /* We should never be called at EOB or before BEGV. */
1161 {
1164 }
1166 {
1169 }
1171 {
1176 bidi_type_t type;
1182 /* If we are inside a paragraph separator, we are just waiting
1183 for the separator to be exhausted; use the previous paragraph
1184 direction. But don't do that if we have been just reseated,
1185 because we need to reinitialize below in that case. */
1190 /* If we are on a newline, get past it to where the next
1191 paragraph might start. But don't do that at BEGV since then
1192 we are potentially in a new paragraph that doesn't yet
1193 exist. */
1200 {
1201 bytepos++;
1202 pos++;
1203 }
1205 /* We are either at the beginning of a paragraph or in the
1206 middle of it. Find where this paragraph starts. */
1208 {
1209 /* We don't support changes of paragraph direction inside a
1210 string. It is treated as a single paragraph. */
1212 }
1213 else
1218 /* The following loop is run more than once only if NO_DEFAULT_P
1219 is non-zero, and only if we are iterating on a buffer. */
1231 || (bidi_ignore_explicit_marks_for_paragraph_level
1235 {
1237 {
1238 /* Pretend there's a paragraph separator at end of
1239 buffer/string. */
1242 }
1247 /* Fetch next character and advance to get past it. */
1253 }
1255 || (!bidi_ignore_explicit_marks_for_paragraph_level
1259 || (!bidi_ignore_explicit_marks_for_paragraph_level
1264 {
1265 /* If this paragraph is at BEGV, default to L2R. */
1268 else
1269 {
1273 /* Find the beginning of the previous paragraph, if any. */
1275 {
1276 /* FXIME: What if p is covered by a display
1277 string? See also a FIXME inside
1278 bidi_find_paragraph_start. */
1279 p--;
1282 }
1284 }
1285 }
1288 }
1289 else
1292 /* Contrary to UAX#9 clause P3, we only default the paragraph
1293 direction to L2R if we have no previous usable paragraph
1294 direction. This is allowed by the HL1 clause. */
1299 else
1303 }
1305 \f
1306 /***********************************************************************
1307 Resolving explicit and implicit levels.
1308 The rest of this file constitutes the core of the UBA implementation.
1309 ***********************************************************************/
1313 {
1314 bidi_type_t ch_type;
1322 }
1324 /* A helper function for bidi_resolve_explicit. It advances to the
1325 next character in logical order and determines the new embedding
1326 level and directional override, but does not take into account
1327 empty embeddings. */
1328 static int
1330 {
1332 bidi_type_t type;
1335 bidi_dir_t override;
1338 /* If reseat()'ed, don't advance, so as to start iteration from the
1339 position where we were reseated. bidi_it->bytepos can be less
1340 than BEGV_BYTE after reseat to BEGV. */
1343 {
1346 {
1356 }
1357 else
1358 {
1362 }
1363 }
1364 /* Don't move at end of buffer/string. */
1366 {
1367 /* Advance to the next character, skipping characters covered by
1368 display strings (nchars > 1). */
1375 }
1382 {
1388 }
1389 else
1390 {
1391 /* Fetch the character at BYTEPOS. If it is covered by a
1392 display string, treat the entire run of covered characters as
1393 a single character u+FFFC. */
1398 }
1401 /* Don't apply directional override here, as all the types we handle
1402 below will not be affected by the override anyway, and we need
1403 the original type unaltered. The override will be applied in
1404 bidi_resolve_weak. */
1415 {
1422 {
1424 {
1425 /* Compute the least odd embedding level greater than
1426 the current level. */
1430 else
1435 }
1436 else
1437 {
1439 /* See the commentary about invalid_rl_levels below. */
1443 }
1444 }
1456 {
1458 {
1459 /* Compute the least even embedding level greater than
1460 the current level. */
1464 else
1467 }
1468 else
1469 {
1471 /* invalid_rl_levels counts invalid levels encountered
1472 while the embedding level was already too high for
1473 LRE/LRO, but not for RLE/RLO. That is because
1474 there may be exactly one PDF which we should not
1475 ignore even though invalid_levels is non-zero.
1476 invalid_rl_levels helps to know what PDF is
1477 that. */
1480 }
1481 }
1492 {
1494 {
1499 /* else nothing: UAX#9 says to ignore invalid PDFs */
1500 }
1503 else
1504 {
1507 }
1508 }
1515 /* Nothing. */
1517 }
1523 }
1525 /* Given an iterator state in BIDI_IT, advance one character position
1526 in the buffer/string to the next character (in the logical order),
1527 resolve any explicit embeddings and directional overrides, and
1528 return the embedding level of the character after resolving
1529 explicit directives and ignoring empty embeddings. */
1530 static int
1532 {
1548 {
1549 /* Avoid pushing and popping embedding levels if the level run
1550 is empty, as this breaks level runs where it shouldn't.
1551 UAX#9 removes all the explicit embedding and override codes,
1552 so empty embeddings disappear without a trace. We need to
1553 behave as if we did the same. */
1562 {
1563 /* This advances to the next character, skipping any
1564 characters covered by display strings. */
1566 /* If string.lstring was relocated inside bidi_resolve_explicit_1,
1567 a pointer to its data is no longer valid. */
1570 }
1581 {
1582 /* We pushed a level, but we shouldn't have. Undo that. */
1584 {
1589 }
1592 else
1593 {
1596 }
1597 }
1598 }
1601 {
1603 /* This is needed by bidi_resolve_weak below, and in L1. */
1606 }
1609 }
1611 /* Advance in the buffer/string, resolve weak types and return the
1612 type of the next character after weak type resolution. */
1613 static bidi_type_t
1615 {
1616 bidi_type_t type;
1617 bidi_dir_t override;
1621 bidi_type_t type_of_next;
1623 ptrdiff_t eob
1640 {
1641 /* We've got a new embedding level run, compute the directional
1642 type of sor and initialize per-run variables (UAX#9, clause
1643 X10). */
1645 }
1651 /* Level and directional override status are already recorded in
1652 bidi_it, and do not need any change; see X6. */
1657 else
1658 {
1660 {
1661 /* Note that we don't need to consider the case where the
1662 prev character has its type overridden by an RLO or LRO,
1663 because then either the type of this NSM would have been
1664 also overridden, or the previous character is outside the
1665 current level run, and thus not relevant to this NSM.
1666 This is why NSM gets the type_after_w1 of the previous
1667 character. */
1669 /* if type_after_w1 is NEUTRAL_B, this NSM is at sor */
1678 }
1691 {
1698 ? BIDI_EOB
1705 {
1709 ;
1712 }
1714 /* If the next character is EN, but the last strong-type
1715 character is AL, that next EN will be changed to AN when
1716 we process it in W2 above. So in that case, this ES
1717 should not be changed into EN. */
1723 {
1726 /* If the next character is EN, but the last
1727 strong-type character is AL, EN will be later
1728 changed to AN when we process it in W2 above.
1729 So in that case, this ES should not be
1730 changed into EN. */
1738 }
1739 }
1742 {
1747 {
1750 }
1752 {
1760 next_char
1762 ? BIDI_EOB
1770 {
1775 ;
1779 }
1780 /* Remember this position, to speed up processing of the
1781 next ETs. */
1784 {
1785 /* If the last strong character is AL, the EN we've
1786 found will become AN when we get to it (W2). */
1791 else
1793 }
1795 /* Record the fact that there are no more ENs from
1796 here to the end of paragraph, to avoid entering the
1797 loop above ever again in this paragraph. */
1799 /* Record the type of the character where we ended our search. */
1801 }
1802 }
1803 }
1812 /* Store the type we've got so far, before we clobber it with strong
1813 types in W7 and while resolving neutral types. But leave alone
1814 the original types that were recorded above, because we will need
1815 them for the L1 clause. */
1821 {
1825 }
1830 }
1832 /* Resolve the type of a neutral character according to the type of
1833 surrounding strong text and the current embedding level. */
1836 {
1837 /* N1: European and Arabic numbers are treated as though they were R. */
1847 else
1849 }
1851 static bidi_type_t
1853 {
1870 we are already at paragraph end. */
1873 {
1877 current_level);
1878 /* The next two "else if" clauses are shortcuts for the
1879 important special case when we have a long sequence of
1880 neutral or WEAK_BN characters, such as whitespace or nulls or
1881 other control characters, on the base embedding level of the
1882 paragraph, and that sequence goes all the way to the end of
1883 the paragraph and follows a character whose resolved
1884 directionality is identical to the base embedding level.
1885 (This is what happens in a buffer with plain L2R text that
1886 happens to include long sequences of control characters.) By
1887 virtue of N1, the result of examining this long sequence will
1888 always be either STRONG_L or STRONG_R, depending on the base
1889 embedding level. So we use this fact directly instead of
1890 entering the expensive loop in the "else" clause. */
1898 /* base embedding level is also 1 */
1900 /* previous character is one of those considered R for
1901 the purposes of W5 */
1908 else
1909 {
1910 /* Arrrgh!! The UAX#9 algorithm is too deeply entrenched in
1911 the assumption of batch-style processing; see clauses W4,
1912 W5, and especially N1, which require to look far forward
1913 (as well as back) in the buffer/string. May the fleas of
1914 a thousand camels infest the armpits of those who design
1915 supposedly general-purpose algorithms by looking at their
1916 own implementations, and fail to consider other possible
1917 implementations! */
1919 bidi_type_t next_type;
1925 /* Scan the text forward until we find the first non-neutral
1926 character, and then use that to resolve the neutral we
1927 are dealing with now. We also cache the scanned iterator
1928 states, to salvage some of the effort later. */
1931 /* Record the info about the previous character, so that
1932 it will be cached below with this state. */
1937 /* Paragraph separators have their levels fully resolved
1938 at this point, so cache them as resolved. */
1940 /* FIXME: implement L1 here, by testing for a newline and
1941 resetting the level for any sequence of whitespace
1942 characters adjacent to it. */
1946 /* This is all per level run, so stop when we
1947 reach the end of this level run. */
1954 {
1958 /* Actually, STRONG_AL cannot happen here, because
1959 bidi_resolve_weak converts it to STRONG_R, per W3. */
1965 /* N1: ``European and Arabic numbers are treated as
1966 though they were R.'' */
1972 /* FALLTHROUGH */
1974 /* Marched all the way to the end of this level run.
1975 We need to use the eor type, whose information is
1976 stored by bidi_set_sor_type in the prev_for_neutral
1977 member. */
1981 else
1982 {
1983 /* This is a BN which does not adjoin neutrals.
1984 Leave its type alone. */
1987 }
1991 }
1999 }
2000 }
2002 }
2004 /* Given an iterator state in BIDI_IT, advance one character position
2005 in the buffer/string to the next character (in the logical order),
2006 resolve the bidi type of that next character, and return that
2007 type. */
2008 static bidi_type_t
2010 {
2011 bidi_type_t type;
2013 /* This should always be called during a forward scan. */
2017 /* Reset the limit until which to ignore BNs if we step out of the
2018 area where we found only empty levels. */
2028 }
2030 /* Given an iterator state BIDI_IT, advance one character position in
2031 the buffer/string to the next character (in the current scan
2032 direction), resolve the embedding and implicit levels of that next
2033 character, and return the resulting level. */
2034 static int
2036 {
2037 bidi_type_t type;
2043 {
2044 ptrdiff_t eob
2048 /* There's no sense in trying to advance if we hit end of text. */
2052 /* Record the info about the previous character. */
2060 /* FIXME: it sounds like we don't need both prev and
2061 prev_for_neutral members, but I'm leaving them both for now. */
2066 /* If we overstepped the characters used for resolving neutrals
2067 and whitespace, invalidate their info in the iterator. */
2072 {
2075 }
2080 /* This must be taken before we fill the iterator with the info
2081 about the next char. If we scan backwards, the iterator
2082 state must be already cached, so there's no need to know the
2083 embedding level of the previous character, since we will be
2084 returning to our caller shortly. */
2086 }
2089 /* Perhaps the character we want is already cached. If it is, the
2090 call to bidi_cache_find below will return a type other than
2091 UNKNOWN_BT. */
2093 {
2097 {
2101 }
2103 /* Implementation note: we allow next_char_pos to be as low as
2104 0 for buffers or -1 for strings, and that is okay because
2105 that's the "position" of the sentinel iterator state we
2106 cached at the beginning of the iteration. */
2110 else
2112 }
2113 else
2116 {
2117 /* Don't lose the information for resolving neutrals! The
2118 cached states could have been cached before their
2119 next_for_neutral member was computed. If we are on our way
2120 forward, we can simply take the info from the previous
2121 state. */
2126 /* If resolved_level is -1, it means this state was cached
2127 before it was completely resolved, so we cannot return
2128 it. */
2131 }
2133 /* If we are going backwards, the iterator state is already cached
2134 from previous scans, and should be fully resolved. */
2146 {
2150 /* If the cached state shows a neutral character, it was not
2151 resolved by bidi_resolve_neutral, so do it now. */
2154 level);
2155 }
2166 /* For L1 below, we need to know, for each WS character, whether
2167 it belongs to a sequence of WS characters preceding a newline
2168 or a TAB or a paragraph separator. */
2171 {
2179 bidi_type_t chtype;
2190 else
2198 }
2200 /* Resolve implicit levels, with a twist: PDFs get the embedding
2201 level of the embedding they terminate. See below for the
2202 reason. */
2204 /* Don't do this if this formatting code didn't change the
2205 embedding level due to invalid or empty embeddings. */
2207 {
2208 /* Don't look in UAX#9 for the reason for this: it's our own
2209 private quirk. The reason is that we want the formatting
2210 codes to be delivered so that they bracket the text of their
2211 embedding. For example, given the text
2213 {RLO}teST{PDF}
2215 we want it to be displayed as
2217 {PDF}STet{RLO}
2219 not as
2221 STet{RLO}{PDF}
2223 which will result because we bump up the embedding level as
2224 soon as we see the RLO and pop it as soon as we see the PDF,
2225 so RLO itself has the same embedding level as "teST", and
2226 thus would be normally delivered last, just before the PDF.
2227 The switch below fiddles with the level of PDF so that this
2228 ugly side effect does not happen.
2230 (This is, of course, only important if the formatting codes
2231 are actually displayed, but Emacs does need to display them
2232 if the user wants to.) */
2234 }
2243 {
2245 level++;
2248 }
2250 {
2252 level++;
2253 }
2257 }
2259 /* Move to the other edge of a level given by LEVEL. If END_FLAG is
2260 non-zero, we are at the end of a level, and we need to prepare to
2261 resume the scan of the lower level.
2263 If this level's other edge is cached, we simply jump to it, filling
2264 the iterator structure with the iterator state on the other edge.
2265 Otherwise, we walk the buffer or string until we come back to the
2266 same level as LEVEL.
2268 Note: we are not talking here about a ``level run'' in the UAX#9
2269 sense of the term, but rather about a ``level'' which includes
2270 all the levels higher than it. In other words, given the levels
2271 like this:
2273 11111112222222333333334443343222222111111112223322111
2274 A B C
2276 and assuming we are at point A scanning left to right, this
2277 function moves to point C, whereas the UAX#9 ``level 2 run'' ends
2278 at point B. */
2279 static void
2281 {
2285 /* Try the cache first. */
2289 else
2290 {
2301 }
2302 }
2304 void
2306 {
2315 {
2317 }
2319 /* The code below can call eval, and thus cause GC. If we are
2320 iterating a Lisp string, make sure it won't be GCed. */
2324 /* If we just passed a newline, initialize for the next line. */
2329 /* Prepare the sentinel iterator state, and cache it. When we bump
2330 into it, scanning backwards, we'll know that the last non-base
2331 level is exhausted. */
2333 {
2336 {
2342 }
2344 }
2349 /* Reordering of resolved levels (clause L2) is implemented by
2350 jumping to the other edge of the level and flipping direction of
2351 scanning the text whenever we find a level change. */
2353 {
2359 /* Jump (or walk) to the other edge of this level. */
2361 /* Switch scan direction and peek at the next character in the
2362 new direction. */
2365 /* The following loop handles the case where the resolved level
2366 jumps by more than one. This is typical for numbers inside a
2367 run of text with left-to-right embedding direction, but can
2368 also happen in other situations. In those cases the decision
2369 where to continue after a level change, and in what direction,
2370 is tricky. For example, given a text like below:
2372 abcdefgh
2373 11336622
2375 (where the numbers below the text show the resolved levels),
2376 the result of reordering according to UAX#9 should be this:
2378 efdcghba
2380 This is implemented by the loop below which flips direction
2381 and jumps to the other edge of the level each time it finds
2382 the new level not to be the expected one. The expected level
2383 is always one more or one less than the previous one. */
2386 {
2392 }
2394 /* Finally, deliver the next character in the new direction. */
2396 }
2398 /* Take note when we have just processed the newline that precedes
2399 the end of the paragraph. The next time we are about to be
2400 called, set_iterator_to_next will automatically reinit the
2401 paragraph direction, if needed. We do this at the newline before
2402 the paragraph separator, because the next character might not be
2403 the first character of the next paragraph, due to the bidi
2404 reordering, whereas we _must_ know the paragraph base direction
2405 _before_ we process the paragraph's text, since the base
2406 direction affects the reordering. */
2409 {
2410 /* The paragraph direction of the entire string, once
2411 determined, is in effect for the entire string. Setting the
2412 separator limit to the end of the string prevents
2413 bidi_paragraph_init from being called automatically on this
2414 string. */
2418 {
2419 ptrdiff_t sep_len
2425 {
2427 /* Record the buffer position of the last character of the
2428 paragraph separator. */
2429 bidi_it->separator_limit
2431 }
2432 }
2433 }
2436 {
2437 /* If we are at paragraph's base embedding level and beyond the
2438 last cached position, the cache's job is done and we can
2439 discard it. */
2444 /* But as long as we are caching during forward scan, we must
2445 cache each state, or else the cache integrity will be
2446 compromised: it assumes cached states correspond to buffer
2447 positions 1:1. */
2448 else
2450 }
2453 UNGCPRO;
2454 }
2456 /* This is meant to be called from within the debugger, whenever you
2457 wish to examine the cache contents. */
2459 void
2461 {
2466 {
2469 }
2474 ndigits++;
2487 }