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4ed46869 | 1 | /* Coding system handler (conversion, detection, and etc). |
4a2f9c6a | 2 | Copyright (C) 1995, 1997, 1998 Electrotechnical Laboratory, JAPAN. |
203cb916 | 3 | Licensed to the Free Software Foundation. |
70ad9fc4 | 4 | Copyright (C) 2001 Free Software Foundation, Inc. |
4ed46869 | 5 | |
369314dc KH |
6 | This file is part of GNU Emacs. |
7 | ||
8 | GNU Emacs is free software; you can redistribute it and/or modify | |
9 | it under the terms of the GNU General Public License as published by | |
10 | the Free Software Foundation; either version 2, or (at your option) | |
11 | any later version. | |
4ed46869 | 12 | |
369314dc KH |
13 | GNU Emacs is distributed in the hope that it will be useful, |
14 | but WITHOUT ANY WARRANTY; without even the implied warranty of | |
15 | MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the | |
16 | GNU General Public License for more details. | |
4ed46869 | 17 | |
369314dc KH |
18 | You should have received a copy of the GNU General Public License |
19 | along with GNU Emacs; see the file COPYING. If not, write to | |
20 | the Free Software Foundation, Inc., 59 Temple Place - Suite 330, | |
21 | Boston, MA 02111-1307, USA. */ | |
4ed46869 KH |
22 | |
23 | /*** TABLE OF CONTENTS *** | |
24 | ||
b73bfc1c | 25 | 0. General comments |
4ed46869 | 26 | 1. Preamble |
0ef69138 | 27 | 2. Emacs' internal format (emacs-mule) handlers |
4ed46869 KH |
28 | 3. ISO2022 handlers |
29 | 4. Shift-JIS and BIG5 handlers | |
1397dc18 KH |
30 | 5. CCL handlers |
31 | 6. End-of-line handlers | |
32 | 7. C library functions | |
33 | 8. Emacs Lisp library functions | |
34 | 9. Post-amble | |
4ed46869 KH |
35 | |
36 | */ | |
37 | ||
b73bfc1c KH |
38 | /*** 0. General comments ***/ |
39 | ||
40 | ||
cfb43547 | 41 | /*** GENERAL NOTE on CODING SYSTEMS *** |
4ed46869 | 42 | |
cfb43547 | 43 | A coding system is an encoding mechanism for one or more character |
4ed46869 KH |
44 | sets. Here's a list of coding systems which Emacs can handle. When |
45 | we say "decode", it means converting some other coding system to | |
cfb43547 | 46 | Emacs' internal format (emacs-mule), and when we say "encode", |
0ef69138 KH |
47 | it means converting the coding system emacs-mule to some other |
48 | coding system. | |
4ed46869 | 49 | |
0ef69138 | 50 | 0. Emacs' internal format (emacs-mule) |
4ed46869 | 51 | |
cfb43547 | 52 | Emacs itself holds a multi-lingual character in buffers and strings |
f4dee582 | 53 | in a special format. Details are described in section 2. |
4ed46869 KH |
54 | |
55 | 1. ISO2022 | |
56 | ||
57 | The most famous coding system for multiple character sets. X's | |
f4dee582 RS |
58 | Compound Text, various EUCs (Extended Unix Code), and coding |
59 | systems used in Internet communication such as ISO-2022-JP are | |
60 | all variants of ISO2022. Details are described in section 3. | |
4ed46869 KH |
61 | |
62 | 2. SJIS (or Shift-JIS or MS-Kanji-Code) | |
63 | ||
64 | A coding system to encode character sets: ASCII, JISX0201, and | |
65 | JISX0208. Widely used for PC's in Japan. Details are described in | |
f4dee582 | 66 | section 4. |
4ed46869 KH |
67 | |
68 | 3. BIG5 | |
69 | ||
cfb43547 DL |
70 | A coding system to encode the character sets ASCII and Big5. Widely |
71 | used for Chinese (mainly in Taiwan and Hong Kong). Details are | |
f4dee582 RS |
72 | described in section 4. In this file, when we write "BIG5" |
73 | (all uppercase), we mean the coding system, and when we write | |
74 | "Big5" (capitalized), we mean the character set. | |
4ed46869 | 75 | |
27901516 KH |
76 | 4. Raw text |
77 | ||
cfb43547 DL |
78 | A coding system for text containing random 8-bit code. Emacs does |
79 | no code conversion on such text except for end-of-line format. | |
27901516 KH |
80 | |
81 | 5. Other | |
4ed46869 | 82 | |
cfb43547 DL |
83 | If a user wants to read/write text encoded in a coding system not |
84 | listed above, he can supply a decoder and an encoder for it as CCL | |
4ed46869 KH |
85 | (Code Conversion Language) programs. Emacs executes the CCL program |
86 | while reading/writing. | |
87 | ||
d46c5b12 KH |
88 | Emacs represents a coding system by a Lisp symbol that has a property |
89 | `coding-system'. But, before actually using the coding system, the | |
4ed46869 | 90 | information about it is set in a structure of type `struct |
f4dee582 | 91 | coding_system' for rapid processing. See section 6 for more details. |
4ed46869 KH |
92 | |
93 | */ | |
94 | ||
95 | /*** GENERAL NOTES on END-OF-LINE FORMAT *** | |
96 | ||
cfb43547 DL |
97 | How end-of-line of text is encoded depends on the operating system. |
98 | For instance, Unix's format is just one byte of `line-feed' code, | |
f4dee582 | 99 | whereas DOS's format is two-byte sequence of `carriage-return' and |
d46c5b12 KH |
100 | `line-feed' codes. MacOS's format is usually one byte of |
101 | `carriage-return'. | |
4ed46869 | 102 | |
cfb43547 DL |
103 | Since text character encoding and end-of-line encoding are |
104 | independent, any coding system described above can have any | |
105 | end-of-line format. So Emacs has information about end-of-line | |
106 | format in each coding-system. See section 6 for more details. | |
4ed46869 KH |
107 | |
108 | */ | |
109 | ||
110 | /*** GENERAL NOTES on `detect_coding_XXX ()' functions *** | |
111 | ||
112 | These functions check if a text between SRC and SRC_END is encoded | |
113 | in the coding system category XXX. Each returns an integer value in | |
cfb43547 | 114 | which appropriate flag bits for the category XXX are set. The flag |
4ed46869 | 115 | bits are defined in macros CODING_CATEGORY_MASK_XXX. Below is the |
cfb43547 | 116 | template for these functions. If MULTIBYTEP is nonzero, 8-bit codes |
0a28aafb | 117 | of the range 0x80..0x9F are in multibyte form. */ |
4ed46869 KH |
118 | #if 0 |
119 | int | |
0a28aafb | 120 | detect_coding_emacs_mule (src, src_end, multibytep) |
4ed46869 | 121 | unsigned char *src, *src_end; |
0a28aafb | 122 | int multibytep; |
4ed46869 KH |
123 | { |
124 | ... | |
125 | } | |
126 | #endif | |
127 | ||
128 | /*** GENERAL NOTES on `decode_coding_XXX ()' functions *** | |
129 | ||
b73bfc1c KH |
130 | These functions decode SRC_BYTES length of unibyte text at SOURCE |
131 | encoded in CODING to Emacs' internal format. The resulting | |
132 | multibyte text goes to a place pointed to by DESTINATION, the length | |
133 | of which should not exceed DST_BYTES. | |
d46c5b12 | 134 | |
cfb43547 DL |
135 | These functions set the information about original and decoded texts |
136 | in the members `produced', `produced_char', `consumed', and | |
137 | `consumed_char' of the structure *CODING. They also set the member | |
138 | `result' to one of CODING_FINISH_XXX indicating how the decoding | |
139 | finished. | |
d46c5b12 | 140 | |
cfb43547 | 141 | DST_BYTES zero means that the source area and destination area are |
d46c5b12 | 142 | overlapped, which means that we can produce a decoded text until it |
cfb43547 | 143 | reaches the head of the not-yet-decoded source text. |
d46c5b12 | 144 | |
cfb43547 | 145 | Below is a template for these functions. */ |
4ed46869 | 146 | #if 0 |
b73bfc1c | 147 | static void |
d46c5b12 | 148 | decode_coding_XXX (coding, source, destination, src_bytes, dst_bytes) |
4ed46869 KH |
149 | struct coding_system *coding; |
150 | unsigned char *source, *destination; | |
151 | int src_bytes, dst_bytes; | |
4ed46869 KH |
152 | { |
153 | ... | |
154 | } | |
155 | #endif | |
156 | ||
157 | /*** GENERAL NOTES on `encode_coding_XXX ()' functions *** | |
158 | ||
cfb43547 | 159 | These functions encode SRC_BYTES length text at SOURCE from Emacs' |
b73bfc1c KH |
160 | internal multibyte format to CODING. The resulting unibyte text |
161 | goes to a place pointed to by DESTINATION, the length of which | |
162 | should not exceed DST_BYTES. | |
d46c5b12 | 163 | |
cfb43547 DL |
164 | These functions set the information about original and encoded texts |
165 | in the members `produced', `produced_char', `consumed', and | |
166 | `consumed_char' of the structure *CODING. They also set the member | |
167 | `result' to one of CODING_FINISH_XXX indicating how the encoding | |
168 | finished. | |
d46c5b12 | 169 | |
cfb43547 DL |
170 | DST_BYTES zero means that the source area and destination area are |
171 | overlapped, which means that we can produce encoded text until it | |
172 | reaches at the head of the not-yet-encoded source text. | |
d46c5b12 | 173 | |
cfb43547 | 174 | Below is a template for these functions. */ |
4ed46869 | 175 | #if 0 |
b73bfc1c | 176 | static void |
d46c5b12 | 177 | encode_coding_XXX (coding, source, destination, src_bytes, dst_bytes) |
4ed46869 KH |
178 | struct coding_system *coding; |
179 | unsigned char *source, *destination; | |
180 | int src_bytes, dst_bytes; | |
4ed46869 KH |
181 | { |
182 | ... | |
183 | } | |
184 | #endif | |
185 | ||
186 | /*** COMMONLY USED MACROS ***/ | |
187 | ||
b73bfc1c KH |
188 | /* The following two macros ONE_MORE_BYTE and TWO_MORE_BYTES safely |
189 | get one, two, and three bytes from the source text respectively. | |
190 | If there are not enough bytes in the source, they jump to | |
191 | `label_end_of_loop'. The caller should set variables `coding', | |
192 | `src' and `src_end' to appropriate pointer in advance. These | |
193 | macros are called from decoding routines `decode_coding_XXX', thus | |
194 | it is assumed that the source text is unibyte. */ | |
4ed46869 | 195 | |
b73bfc1c KH |
196 | #define ONE_MORE_BYTE(c1) \ |
197 | do { \ | |
198 | if (src >= src_end) \ | |
199 | { \ | |
200 | coding->result = CODING_FINISH_INSUFFICIENT_SRC; \ | |
201 | goto label_end_of_loop; \ | |
202 | } \ | |
203 | c1 = *src++; \ | |
4ed46869 KH |
204 | } while (0) |
205 | ||
b73bfc1c KH |
206 | #define TWO_MORE_BYTES(c1, c2) \ |
207 | do { \ | |
208 | if (src + 1 >= src_end) \ | |
209 | { \ | |
210 | coding->result = CODING_FINISH_INSUFFICIENT_SRC; \ | |
211 | goto label_end_of_loop; \ | |
212 | } \ | |
213 | c1 = *src++; \ | |
214 | c2 = *src++; \ | |
4ed46869 KH |
215 | } while (0) |
216 | ||
4ed46869 | 217 | |
0a28aafb KH |
218 | /* Like ONE_MORE_BYTE, but 8-bit bytes of data at SRC are in multibyte |
219 | form if MULTIBYTEP is nonzero. */ | |
220 | ||
221 | #define ONE_MORE_BYTE_CHECK_MULTIBYTE(c1, multibytep) \ | |
222 | do { \ | |
223 | if (src >= src_end) \ | |
224 | { \ | |
225 | coding->result = CODING_FINISH_INSUFFICIENT_SRC; \ | |
226 | goto label_end_of_loop; \ | |
227 | } \ | |
228 | c1 = *src++; \ | |
229 | if (multibytep && c1 == LEADING_CODE_8_BIT_CONTROL) \ | |
230 | c1 = *src++ - 0x20; \ | |
231 | } while (0) | |
232 | ||
b73bfc1c KH |
233 | /* Set C to the next character at the source text pointed by `src'. |
234 | If there are not enough characters in the source, jump to | |
235 | `label_end_of_loop'. The caller should set variables `coding' | |
236 | `src', `src_end', and `translation_table' to appropriate pointers | |
237 | in advance. This macro is used in encoding routines | |
238 | `encode_coding_XXX', thus it assumes that the source text is in | |
239 | multibyte form except for 8-bit characters. 8-bit characters are | |
240 | in multibyte form if coding->src_multibyte is nonzero, else they | |
241 | are represented by a single byte. */ | |
4ed46869 | 242 | |
b73bfc1c KH |
243 | #define ONE_MORE_CHAR(c) \ |
244 | do { \ | |
245 | int len = src_end - src; \ | |
246 | int bytes; \ | |
247 | if (len <= 0) \ | |
248 | { \ | |
249 | coding->result = CODING_FINISH_INSUFFICIENT_SRC; \ | |
250 | goto label_end_of_loop; \ | |
251 | } \ | |
252 | if (coding->src_multibyte \ | |
253 | || UNIBYTE_STR_AS_MULTIBYTE_P (src, len, bytes)) \ | |
254 | c = STRING_CHAR_AND_LENGTH (src, len, bytes); \ | |
255 | else \ | |
256 | c = *src, bytes = 1; \ | |
257 | if (!NILP (translation_table)) \ | |
39658efc | 258 | c = translate_char (translation_table, c, -1, 0, 0); \ |
b73bfc1c | 259 | src += bytes; \ |
4ed46869 KH |
260 | } while (0) |
261 | ||
4ed46869 | 262 | |
8ca3766a | 263 | /* Produce a multibyte form of character C to `dst'. Jump to |
b73bfc1c KH |
264 | `label_end_of_loop' if there's not enough space at `dst'. |
265 | ||
cfb43547 | 266 | If we are now in the middle of a composition sequence, the decoded |
b73bfc1c KH |
267 | character may be ALTCHAR (for the current composition). In that |
268 | case, the character goes to coding->cmp_data->data instead of | |
269 | `dst'. | |
270 | ||
271 | This macro is used in decoding routines. */ | |
272 | ||
273 | #define EMIT_CHAR(c) \ | |
4ed46869 | 274 | do { \ |
b73bfc1c KH |
275 | if (! COMPOSING_P (coding) \ |
276 | || coding->composing == COMPOSITION_RELATIVE \ | |
277 | || coding->composing == COMPOSITION_WITH_RULE) \ | |
278 | { \ | |
279 | int bytes = CHAR_BYTES (c); \ | |
280 | if ((dst + bytes) > (dst_bytes ? dst_end : src)) \ | |
281 | { \ | |
282 | coding->result = CODING_FINISH_INSUFFICIENT_DST; \ | |
283 | goto label_end_of_loop; \ | |
284 | } \ | |
285 | dst += CHAR_STRING (c, dst); \ | |
286 | coding->produced_char++; \ | |
287 | } \ | |
ec6d2bb8 | 288 | \ |
b73bfc1c KH |
289 | if (COMPOSING_P (coding) \ |
290 | && coding->composing != COMPOSITION_RELATIVE) \ | |
291 | { \ | |
292 | CODING_ADD_COMPOSITION_COMPONENT (coding, c); \ | |
293 | coding->composition_rule_follows \ | |
294 | = coding->composing != COMPOSITION_WITH_ALTCHARS; \ | |
295 | } \ | |
4ed46869 KH |
296 | } while (0) |
297 | ||
4ed46869 | 298 | |
b73bfc1c KH |
299 | #define EMIT_ONE_BYTE(c) \ |
300 | do { \ | |
301 | if (dst >= (dst_bytes ? dst_end : src)) \ | |
302 | { \ | |
303 | coding->result = CODING_FINISH_INSUFFICIENT_DST; \ | |
304 | goto label_end_of_loop; \ | |
305 | } \ | |
306 | *dst++ = c; \ | |
307 | } while (0) | |
308 | ||
309 | #define EMIT_TWO_BYTES(c1, c2) \ | |
310 | do { \ | |
311 | if (dst + 2 > (dst_bytes ? dst_end : src)) \ | |
312 | { \ | |
313 | coding->result = CODING_FINISH_INSUFFICIENT_DST; \ | |
314 | goto label_end_of_loop; \ | |
315 | } \ | |
316 | *dst++ = c1, *dst++ = c2; \ | |
317 | } while (0) | |
318 | ||
319 | #define EMIT_BYTES(from, to) \ | |
320 | do { \ | |
321 | if (dst + (to - from) > (dst_bytes ? dst_end : src)) \ | |
322 | { \ | |
323 | coding->result = CODING_FINISH_INSUFFICIENT_DST; \ | |
324 | goto label_end_of_loop; \ | |
325 | } \ | |
326 | while (from < to) \ | |
327 | *dst++ = *from++; \ | |
4ed46869 KH |
328 | } while (0) |
329 | ||
330 | \f | |
331 | /*** 1. Preamble ***/ | |
332 | ||
68c45bf0 PE |
333 | #ifdef emacs |
334 | #include <config.h> | |
335 | #endif | |
336 | ||
4ed46869 KH |
337 | #include <stdio.h> |
338 | ||
339 | #ifdef emacs | |
340 | ||
4ed46869 KH |
341 | #include "lisp.h" |
342 | #include "buffer.h" | |
343 | #include "charset.h" | |
ec6d2bb8 | 344 | #include "composite.h" |
4ed46869 KH |
345 | #include "ccl.h" |
346 | #include "coding.h" | |
347 | #include "window.h" | |
348 | ||
349 | #else /* not emacs */ | |
350 | ||
351 | #include "mulelib.h" | |
352 | ||
353 | #endif /* not emacs */ | |
354 | ||
355 | Lisp_Object Qcoding_system, Qeol_type; | |
356 | Lisp_Object Qbuffer_file_coding_system; | |
357 | Lisp_Object Qpost_read_conversion, Qpre_write_conversion; | |
27901516 | 358 | Lisp_Object Qno_conversion, Qundecided; |
bb0115a2 | 359 | Lisp_Object Qcoding_system_history; |
05e6f5dc | 360 | Lisp_Object Qsafe_chars; |
1397dc18 | 361 | Lisp_Object Qvalid_codes; |
4ed46869 KH |
362 | |
363 | extern Lisp_Object Qinsert_file_contents, Qwrite_region; | |
364 | Lisp_Object Qcall_process, Qcall_process_region, Qprocess_argument; | |
365 | Lisp_Object Qstart_process, Qopen_network_stream; | |
366 | Lisp_Object Qtarget_idx; | |
367 | ||
d46c5b12 KH |
368 | Lisp_Object Vselect_safe_coding_system_function; |
369 | ||
7722baf9 EZ |
370 | /* Mnemonic string for each format of end-of-line. */ |
371 | Lisp_Object eol_mnemonic_unix, eol_mnemonic_dos, eol_mnemonic_mac; | |
372 | /* Mnemonic string to indicate format of end-of-line is not yet | |
4ed46869 | 373 | decided. */ |
7722baf9 | 374 | Lisp_Object eol_mnemonic_undecided; |
4ed46869 | 375 | |
9ce27fde KH |
376 | /* Format of end-of-line decided by system. This is CODING_EOL_LF on |
377 | Unix, CODING_EOL_CRLF on DOS/Windows, and CODING_EOL_CR on Mac. */ | |
378 | int system_eol_type; | |
379 | ||
4ed46869 KH |
380 | #ifdef emacs |
381 | ||
4608c386 KH |
382 | Lisp_Object Vcoding_system_list, Vcoding_system_alist; |
383 | ||
384 | Lisp_Object Qcoding_system_p, Qcoding_system_error; | |
4ed46869 | 385 | |
d46c5b12 KH |
386 | /* Coding system emacs-mule and raw-text are for converting only |
387 | end-of-line format. */ | |
388 | Lisp_Object Qemacs_mule, Qraw_text; | |
9ce27fde | 389 | |
4ed46869 KH |
390 | /* Coding-systems are handed between Emacs Lisp programs and C internal |
391 | routines by the following three variables. */ | |
392 | /* Coding-system for reading files and receiving data from process. */ | |
393 | Lisp_Object Vcoding_system_for_read; | |
394 | /* Coding-system for writing files and sending data to process. */ | |
395 | Lisp_Object Vcoding_system_for_write; | |
396 | /* Coding-system actually used in the latest I/O. */ | |
397 | Lisp_Object Vlast_coding_system_used; | |
398 | ||
c4825358 | 399 | /* A vector of length 256 which contains information about special |
94487c4e | 400 | Latin codes (especially for dealing with Microsoft codes). */ |
3f003981 | 401 | Lisp_Object Vlatin_extra_code_table; |
c4825358 | 402 | |
9ce27fde KH |
403 | /* Flag to inhibit code conversion of end-of-line format. */ |
404 | int inhibit_eol_conversion; | |
405 | ||
74383408 KH |
406 | /* Flag to inhibit ISO2022 escape sequence detection. */ |
407 | int inhibit_iso_escape_detection; | |
408 | ||
ed29121d EZ |
409 | /* Flag to make buffer-file-coding-system inherit from process-coding. */ |
410 | int inherit_process_coding_system; | |
411 | ||
c4825358 | 412 | /* Coding system to be used to encode text for terminal display. */ |
4ed46869 KH |
413 | struct coding_system terminal_coding; |
414 | ||
c4825358 KH |
415 | /* Coding system to be used to encode text for terminal display when |
416 | terminal coding system is nil. */ | |
417 | struct coding_system safe_terminal_coding; | |
418 | ||
419 | /* Coding system of what is sent from terminal keyboard. */ | |
4ed46869 KH |
420 | struct coding_system keyboard_coding; |
421 | ||
6bc51348 KH |
422 | /* Default coding system to be used to write a file. */ |
423 | struct coding_system default_buffer_file_coding; | |
424 | ||
02ba4723 KH |
425 | Lisp_Object Vfile_coding_system_alist; |
426 | Lisp_Object Vprocess_coding_system_alist; | |
427 | Lisp_Object Vnetwork_coding_system_alist; | |
4ed46869 | 428 | |
68c45bf0 PE |
429 | Lisp_Object Vlocale_coding_system; |
430 | ||
4ed46869 KH |
431 | #endif /* emacs */ |
432 | ||
d46c5b12 | 433 | Lisp_Object Qcoding_category, Qcoding_category_index; |
4ed46869 KH |
434 | |
435 | /* List of symbols `coding-category-xxx' ordered by priority. */ | |
436 | Lisp_Object Vcoding_category_list; | |
437 | ||
d46c5b12 KH |
438 | /* Table of coding categories (Lisp symbols). */ |
439 | Lisp_Object Vcoding_category_table; | |
4ed46869 KH |
440 | |
441 | /* Table of names of symbol for each coding-category. */ | |
442 | char *coding_category_name[CODING_CATEGORY_IDX_MAX] = { | |
0ef69138 | 443 | "coding-category-emacs-mule", |
4ed46869 KH |
444 | "coding-category-sjis", |
445 | "coding-category-iso-7", | |
d46c5b12 | 446 | "coding-category-iso-7-tight", |
4ed46869 KH |
447 | "coding-category-iso-8-1", |
448 | "coding-category-iso-8-2", | |
7717c392 KH |
449 | "coding-category-iso-7-else", |
450 | "coding-category-iso-8-else", | |
89fa8b36 | 451 | "coding-category-ccl", |
4ed46869 | 452 | "coding-category-big5", |
fa42c37f KH |
453 | "coding-category-utf-8", |
454 | "coding-category-utf-16-be", | |
455 | "coding-category-utf-16-le", | |
27901516 | 456 | "coding-category-raw-text", |
89fa8b36 | 457 | "coding-category-binary" |
4ed46869 KH |
458 | }; |
459 | ||
66cfb530 | 460 | /* Table of pointers to coding systems corresponding to each coding |
d46c5b12 KH |
461 | categories. */ |
462 | struct coding_system *coding_system_table[CODING_CATEGORY_IDX_MAX]; | |
463 | ||
66cfb530 | 464 | /* Table of coding category masks. Nth element is a mask for a coding |
8ca3766a | 465 | category of which priority is Nth. */ |
66cfb530 KH |
466 | static |
467 | int coding_priorities[CODING_CATEGORY_IDX_MAX]; | |
468 | ||
f967223b KH |
469 | /* Flag to tell if we look up translation table on character code |
470 | conversion. */ | |
84fbb8a0 | 471 | Lisp_Object Venable_character_translation; |
f967223b KH |
472 | /* Standard translation table to look up on decoding (reading). */ |
473 | Lisp_Object Vstandard_translation_table_for_decode; | |
474 | /* Standard translation table to look up on encoding (writing). */ | |
475 | Lisp_Object Vstandard_translation_table_for_encode; | |
84fbb8a0 | 476 | |
f967223b KH |
477 | Lisp_Object Qtranslation_table; |
478 | Lisp_Object Qtranslation_table_id; | |
479 | Lisp_Object Qtranslation_table_for_decode; | |
480 | Lisp_Object Qtranslation_table_for_encode; | |
4ed46869 KH |
481 | |
482 | /* Alist of charsets vs revision number. */ | |
483 | Lisp_Object Vcharset_revision_alist; | |
484 | ||
02ba4723 KH |
485 | /* Default coding systems used for process I/O. */ |
486 | Lisp_Object Vdefault_process_coding_system; | |
487 | ||
b843d1ae KH |
488 | /* Global flag to tell that we can't call post-read-conversion and |
489 | pre-write-conversion functions. Usually the value is zero, but it | |
490 | is set to 1 temporarily while such functions are running. This is | |
491 | to avoid infinite recursive call. */ | |
492 | static int inhibit_pre_post_conversion; | |
493 | ||
05e6f5dc KH |
494 | /* Char-table containing safe coding systems of each character. */ |
495 | Lisp_Object Vchar_coding_system_table; | |
496 | Lisp_Object Qchar_coding_system; | |
497 | ||
498 | /* Return `safe-chars' property of coding system CODING. Don't check | |
499 | validity of CODING. */ | |
500 | ||
501 | Lisp_Object | |
502 | coding_safe_chars (coding) | |
503 | struct coding_system *coding; | |
504 | { | |
505 | Lisp_Object coding_spec, plist, safe_chars; | |
506 | ||
507 | coding_spec = Fget (coding->symbol, Qcoding_system); | |
508 | plist = XVECTOR (coding_spec)->contents[3]; | |
509 | safe_chars = Fplist_get (XVECTOR (coding_spec)->contents[3], Qsafe_chars); | |
510 | return (CHAR_TABLE_P (safe_chars) ? safe_chars : Qt); | |
511 | } | |
512 | ||
513 | #define CODING_SAFE_CHAR_P(safe_chars, c) \ | |
514 | (EQ (safe_chars, Qt) || !NILP (CHAR_TABLE_REF (safe_chars, c))) | |
515 | ||
4ed46869 | 516 | \f |
0ef69138 | 517 | /*** 2. Emacs internal format (emacs-mule) handlers ***/ |
4ed46869 | 518 | |
aa72b389 KH |
519 | /* Emacs' internal format for representation of multiple character |
520 | sets is a kind of multi-byte encoding, i.e. characters are | |
521 | represented by variable-length sequences of one-byte codes. | |
b73bfc1c KH |
522 | |
523 | ASCII characters and control characters (e.g. `tab', `newline') are | |
524 | represented by one-byte sequences which are their ASCII codes, in | |
525 | the range 0x00 through 0x7F. | |
526 | ||
527 | 8-bit characters of the range 0x80..0x9F are represented by | |
528 | two-byte sequences of LEADING_CODE_8_BIT_CONTROL and (their 8-bit | |
529 | code + 0x20). | |
530 | ||
531 | 8-bit characters of the range 0xA0..0xFF are represented by | |
532 | one-byte sequences which are their 8-bit code. | |
533 | ||
534 | The other characters are represented by a sequence of `base | |
535 | leading-code', optional `extended leading-code', and one or two | |
536 | `position-code's. The length of the sequence is determined by the | |
aa72b389 | 537 | base leading-code. Leading-code takes the range 0x81 through 0x9D, |
b73bfc1c KH |
538 | whereas extended leading-code and position-code take the range 0xA0 |
539 | through 0xFF. See `charset.h' for more details about leading-code | |
540 | and position-code. | |
f4dee582 | 541 | |
4ed46869 | 542 | --- CODE RANGE of Emacs' internal format --- |
b73bfc1c KH |
543 | character set range |
544 | ------------- ----- | |
545 | ascii 0x00..0x7F | |
546 | eight-bit-control LEADING_CODE_8_BIT_CONTROL + 0xA0..0xBF | |
547 | eight-bit-graphic 0xA0..0xBF | |
aa72b389 | 548 | ELSE 0x81..0x9D + [0xA0..0xFF]+ |
4ed46869 KH |
549 | --------------------------------------------- |
550 | ||
aa72b389 KH |
551 | As this is the internal character representation, the format is |
552 | usually not used externally (i.e. in a file or in a data sent to a | |
553 | process). But, it is possible to have a text externally in this | |
554 | format (i.e. by encoding by the coding system `emacs-mule'). | |
555 | ||
556 | In that case, a sequence of one-byte codes has a slightly different | |
557 | form. | |
558 | ||
ae5145c2 | 559 | Firstly, all characters in eight-bit-control are represented by |
aa72b389 KH |
560 | one-byte sequences which are their 8-bit code. |
561 | ||
562 | Next, character composition data are represented by the byte | |
563 | sequence of the form: 0x80 METHOD BYTES CHARS COMPONENT ..., | |
564 | where, | |
565 | METHOD is 0xF0 plus one of composition method (enum | |
566 | composition_method), | |
567 | ||
ae5145c2 | 568 | BYTES is 0xA0 plus the byte length of these composition data, |
aa72b389 | 569 | |
ae5145c2 | 570 | CHARS is 0xA0 plus the number of characters composed by these |
aa72b389 KH |
571 | data, |
572 | ||
8ca3766a | 573 | COMPONENTs are characters of multibyte form or composition |
aa72b389 KH |
574 | rules encoded by two-byte of ASCII codes. |
575 | ||
576 | In addition, for backward compatibility, the following formats are | |
577 | also recognized as composition data on decoding. | |
578 | ||
579 | 0x80 MSEQ ... | |
580 | 0x80 0xFF MSEQ RULE MSEQ RULE ... MSEQ | |
581 | ||
582 | Here, | |
583 | MSEQ is a multibyte form but in these special format: | |
584 | ASCII: 0xA0 ASCII_CODE+0x80, | |
585 | other: LEADING_CODE+0x20 FOLLOWING-BYTE ..., | |
586 | RULE is a one byte code of the range 0xA0..0xF0 that | |
587 | represents a composition rule. | |
4ed46869 KH |
588 | */ |
589 | ||
590 | enum emacs_code_class_type emacs_code_class[256]; | |
591 | ||
4ed46869 KH |
592 | /* See the above "GENERAL NOTES on `detect_coding_XXX ()' functions". |
593 | Check if a text is encoded in Emacs' internal format. If it is, | |
d46c5b12 | 594 | return CODING_CATEGORY_MASK_EMACS_MULE, else return 0. */ |
4ed46869 | 595 | |
0a28aafb KH |
596 | static int |
597 | detect_coding_emacs_mule (src, src_end, multibytep) | |
b73bfc1c | 598 | unsigned char *src, *src_end; |
0a28aafb | 599 | int multibytep; |
4ed46869 KH |
600 | { |
601 | unsigned char c; | |
602 | int composing = 0; | |
b73bfc1c KH |
603 | /* Dummy for ONE_MORE_BYTE. */ |
604 | struct coding_system dummy_coding; | |
605 | struct coding_system *coding = &dummy_coding; | |
4ed46869 | 606 | |
b73bfc1c | 607 | while (1) |
4ed46869 | 608 | { |
0a28aafb | 609 | ONE_MORE_BYTE_CHECK_MULTIBYTE (c, multibytep); |
4ed46869 KH |
610 | |
611 | if (composing) | |
612 | { | |
613 | if (c < 0xA0) | |
614 | composing = 0; | |
b73bfc1c KH |
615 | else if (c == 0xA0) |
616 | { | |
0a28aafb | 617 | ONE_MORE_BYTE_CHECK_MULTIBYTE (c, multibytep); |
b73bfc1c KH |
618 | c &= 0x7F; |
619 | } | |
4ed46869 KH |
620 | else |
621 | c -= 0x20; | |
622 | } | |
623 | ||
b73bfc1c | 624 | if (c < 0x20) |
4ed46869 | 625 | { |
4ed46869 KH |
626 | if (c == ISO_CODE_ESC || c == ISO_CODE_SI || c == ISO_CODE_SO) |
627 | return 0; | |
b73bfc1c KH |
628 | } |
629 | else if (c >= 0x80 && c < 0xA0) | |
630 | { | |
631 | if (c == 0x80) | |
632 | /* Old leading code for a composite character. */ | |
633 | composing = 1; | |
634 | else | |
635 | { | |
636 | unsigned char *src_base = src - 1; | |
637 | int bytes; | |
4ed46869 | 638 | |
b73bfc1c KH |
639 | if (!UNIBYTE_STR_AS_MULTIBYTE_P (src_base, src_end - src_base, |
640 | bytes)) | |
641 | return 0; | |
642 | src = src_base + bytes; | |
643 | } | |
644 | } | |
645 | } | |
646 | label_end_of_loop: | |
647 | return CODING_CATEGORY_MASK_EMACS_MULE; | |
648 | } | |
4ed46869 | 649 | |
4ed46869 | 650 | |
aa72b389 KH |
651 | /* Record the starting position START and METHOD of one composition. */ |
652 | ||
653 | #define CODING_ADD_COMPOSITION_START(coding, start, method) \ | |
654 | do { \ | |
655 | struct composition_data *cmp_data = coding->cmp_data; \ | |
656 | int *data = cmp_data->data + cmp_data->used; \ | |
657 | coding->cmp_data_start = cmp_data->used; \ | |
658 | data[0] = -1; \ | |
659 | data[1] = cmp_data->char_offset + start; \ | |
660 | data[3] = (int) method; \ | |
661 | cmp_data->used += 4; \ | |
662 | } while (0) | |
663 | ||
664 | /* Record the ending position END of the current composition. */ | |
665 | ||
666 | #define CODING_ADD_COMPOSITION_END(coding, end) \ | |
667 | do { \ | |
668 | struct composition_data *cmp_data = coding->cmp_data; \ | |
669 | int *data = cmp_data->data + coding->cmp_data_start; \ | |
670 | data[0] = cmp_data->used - coding->cmp_data_start; \ | |
671 | data[2] = cmp_data->char_offset + end; \ | |
672 | } while (0) | |
673 | ||
674 | /* Record one COMPONENT (alternate character or composition rule). */ | |
675 | ||
676 | #define CODING_ADD_COMPOSITION_COMPONENT(coding, component) \ | |
677 | (coding->cmp_data->data[coding->cmp_data->used++] = component) | |
678 | ||
679 | ||
680 | /* Get one byte from a data pointed by SRC and increment SRC. If SRC | |
8ca3766a | 681 | is not less than SRC_END, return -1 without incrementing Src. */ |
aa72b389 KH |
682 | |
683 | #define SAFE_ONE_MORE_BYTE() (src >= src_end ? -1 : *src++) | |
684 | ||
685 | ||
686 | /* Decode a character represented as a component of composition | |
687 | sequence of Emacs 20 style at SRC. Set C to that character, store | |
688 | its multibyte form sequence at P, and set P to the end of that | |
689 | sequence. If no valid character is found, set C to -1. */ | |
690 | ||
691 | #define DECODE_EMACS_MULE_COMPOSITION_CHAR(c, p) \ | |
692 | do { \ | |
693 | int bytes; \ | |
694 | \ | |
695 | c = SAFE_ONE_MORE_BYTE (); \ | |
696 | if (c < 0) \ | |
697 | break; \ | |
698 | if (CHAR_HEAD_P (c)) \ | |
699 | c = -1; \ | |
700 | else if (c == 0xA0) \ | |
701 | { \ | |
702 | c = SAFE_ONE_MORE_BYTE (); \ | |
703 | if (c < 0xA0) \ | |
704 | c = -1; \ | |
705 | else \ | |
706 | { \ | |
707 | c -= 0xA0; \ | |
708 | *p++ = c; \ | |
709 | } \ | |
710 | } \ | |
711 | else if (BASE_LEADING_CODE_P (c - 0x20)) \ | |
712 | { \ | |
713 | unsigned char *p0 = p; \ | |
714 | \ | |
715 | c -= 0x20; \ | |
716 | *p++ = c; \ | |
717 | bytes = BYTES_BY_CHAR_HEAD (c); \ | |
718 | while (--bytes) \ | |
719 | { \ | |
720 | c = SAFE_ONE_MORE_BYTE (); \ | |
721 | if (c < 0) \ | |
722 | break; \ | |
723 | *p++ = c; \ | |
724 | } \ | |
725 | if (UNIBYTE_STR_AS_MULTIBYTE_P (p0, p - p0, bytes)) \ | |
726 | c = STRING_CHAR (p0, bytes); \ | |
727 | else \ | |
728 | c = -1; \ | |
729 | } \ | |
730 | else \ | |
731 | c = -1; \ | |
732 | } while (0) | |
733 | ||
734 | ||
735 | /* Decode a composition rule represented as a component of composition | |
736 | sequence of Emacs 20 style at SRC. Set C to the rule. If not | |
737 | valid rule is found, set C to -1. */ | |
738 | ||
739 | #define DECODE_EMACS_MULE_COMPOSITION_RULE(c) \ | |
740 | do { \ | |
741 | c = SAFE_ONE_MORE_BYTE (); \ | |
742 | c -= 0xA0; \ | |
743 | if (c < 0 || c >= 81) \ | |
744 | c = -1; \ | |
745 | else \ | |
746 | { \ | |
747 | gref = c / 9, nref = c % 9; \ | |
748 | c = COMPOSITION_ENCODE_RULE (gref, nref); \ | |
749 | } \ | |
750 | } while (0) | |
751 | ||
752 | ||
753 | /* Decode composition sequence encoded by `emacs-mule' at the source | |
754 | pointed by SRC. SRC_END is the end of source. Store information | |
755 | of the composition in CODING->cmp_data. | |
756 | ||
757 | For backward compatibility, decode also a composition sequence of | |
758 | Emacs 20 style. In that case, the composition sequence contains | |
759 | characters that should be extracted into a buffer or string. Store | |
760 | those characters at *DESTINATION in multibyte form. | |
761 | ||
762 | If we encounter an invalid byte sequence, return 0. | |
763 | If we encounter an insufficient source or destination, or | |
764 | insufficient space in CODING->cmp_data, return 1. | |
765 | Otherwise, return consumed bytes in the source. | |
766 | ||
767 | */ | |
768 | static INLINE int | |
769 | decode_composition_emacs_mule (coding, src, src_end, | |
770 | destination, dst_end, dst_bytes) | |
771 | struct coding_system *coding; | |
772 | unsigned char *src, *src_end, **destination, *dst_end; | |
773 | int dst_bytes; | |
774 | { | |
775 | unsigned char *dst = *destination; | |
776 | int method, data_len, nchars; | |
777 | unsigned char *src_base = src++; | |
8ca3766a | 778 | /* Store components of composition. */ |
aa72b389 KH |
779 | int component[COMPOSITION_DATA_MAX_BUNCH_LENGTH]; |
780 | int ncomponent; | |
781 | /* Store multibyte form of characters to be composed. This is for | |
782 | Emacs 20 style composition sequence. */ | |
783 | unsigned char buf[MAX_COMPOSITION_COMPONENTS * MAX_MULTIBYTE_LENGTH]; | |
784 | unsigned char *bufp = buf; | |
785 | int c, i, gref, nref; | |
786 | ||
787 | if (coding->cmp_data->used + COMPOSITION_DATA_MAX_BUNCH_LENGTH | |
788 | >= COMPOSITION_DATA_SIZE) | |
789 | { | |
790 | coding->result = CODING_FINISH_INSUFFICIENT_CMP; | |
791 | return -1; | |
792 | } | |
793 | ||
794 | ONE_MORE_BYTE (c); | |
795 | if (c - 0xF0 >= COMPOSITION_RELATIVE | |
796 | && c - 0xF0 <= COMPOSITION_WITH_RULE_ALTCHARS) | |
797 | { | |
798 | int with_rule; | |
799 | ||
800 | method = c - 0xF0; | |
801 | with_rule = (method == COMPOSITION_WITH_RULE | |
802 | || method == COMPOSITION_WITH_RULE_ALTCHARS); | |
803 | ONE_MORE_BYTE (c); | |
804 | data_len = c - 0xA0; | |
805 | if (data_len < 4 | |
806 | || src_base + data_len > src_end) | |
807 | return 0; | |
808 | ONE_MORE_BYTE (c); | |
809 | nchars = c - 0xA0; | |
810 | if (c < 1) | |
811 | return 0; | |
812 | for (ncomponent = 0; src < src_base + data_len; ncomponent++) | |
813 | { | |
814 | if (ncomponent % 2 && with_rule) | |
815 | { | |
816 | ONE_MORE_BYTE (gref); | |
817 | gref -= 32; | |
818 | ONE_MORE_BYTE (nref); | |
819 | nref -= 32; | |
820 | c = COMPOSITION_ENCODE_RULE (gref, nref); | |
821 | } | |
822 | else | |
823 | { | |
824 | int bytes; | |
825 | if (UNIBYTE_STR_AS_MULTIBYTE_P (src, src_end - src, bytes)) | |
826 | c = STRING_CHAR (src, bytes); | |
827 | else | |
828 | c = *src, bytes = 1; | |
829 | src += bytes; | |
830 | } | |
831 | component[ncomponent] = c; | |
832 | } | |
833 | } | |
834 | else | |
835 | { | |
836 | /* This may be an old Emacs 20 style format. See the comment at | |
837 | the section 2 of this file. */ | |
838 | while (src < src_end && !CHAR_HEAD_P (*src)) src++; | |
839 | if (src == src_end | |
840 | && !(coding->mode & CODING_MODE_LAST_BLOCK)) | |
841 | goto label_end_of_loop; | |
842 | ||
843 | src_end = src; | |
844 | src = src_base + 1; | |
845 | if (c < 0xC0) | |
846 | { | |
847 | method = COMPOSITION_RELATIVE; | |
848 | for (ncomponent = 0; ncomponent < MAX_COMPOSITION_COMPONENTS;) | |
849 | { | |
850 | DECODE_EMACS_MULE_COMPOSITION_CHAR (c, bufp); | |
851 | if (c < 0) | |
852 | break; | |
853 | component[ncomponent++] = c; | |
854 | } | |
855 | if (ncomponent < 2) | |
856 | return 0; | |
857 | nchars = ncomponent; | |
858 | } | |
859 | else if (c == 0xFF) | |
860 | { | |
861 | method = COMPOSITION_WITH_RULE; | |
862 | src++; | |
863 | DECODE_EMACS_MULE_COMPOSITION_CHAR (c, bufp); | |
864 | if (c < 0) | |
865 | return 0; | |
866 | component[0] = c; | |
867 | for (ncomponent = 1; | |
868 | ncomponent < MAX_COMPOSITION_COMPONENTS * 2 - 1;) | |
869 | { | |
870 | DECODE_EMACS_MULE_COMPOSITION_RULE (c); | |
871 | if (c < 0) | |
872 | break; | |
873 | component[ncomponent++] = c; | |
874 | DECODE_EMACS_MULE_COMPOSITION_CHAR (c, bufp); | |
875 | if (c < 0) | |
876 | break; | |
877 | component[ncomponent++] = c; | |
878 | } | |
879 | if (ncomponent < 3) | |
880 | return 0; | |
881 | nchars = (ncomponent + 1) / 2; | |
882 | } | |
883 | else | |
884 | return 0; | |
885 | } | |
886 | ||
887 | if (buf == bufp || dst + (bufp - buf) <= (dst_bytes ? dst_end : src)) | |
888 | { | |
889 | CODING_ADD_COMPOSITION_START (coding, coding->produced_char, method); | |
890 | for (i = 0; i < ncomponent; i++) | |
891 | CODING_ADD_COMPOSITION_COMPONENT (coding, component[i]); | |
892 | CODING_ADD_COMPOSITION_END (coding, coding->produced_char + nchars); | |
893 | if (buf < bufp) | |
894 | { | |
895 | unsigned char *p = buf; | |
896 | EMIT_BYTES (p, bufp); | |
897 | *destination += bufp - buf; | |
898 | coding->produced_char += nchars; | |
899 | } | |
900 | return (src - src_base); | |
901 | } | |
902 | label_end_of_loop: | |
903 | return -1; | |
904 | } | |
905 | ||
b73bfc1c | 906 | /* See the above "GENERAL NOTES on `decode_coding_XXX ()' functions". */ |
4ed46869 | 907 | |
b73bfc1c KH |
908 | static void |
909 | decode_coding_emacs_mule (coding, source, destination, src_bytes, dst_bytes) | |
910 | struct coding_system *coding; | |
911 | unsigned char *source, *destination; | |
912 | int src_bytes, dst_bytes; | |
913 | { | |
914 | unsigned char *src = source; | |
915 | unsigned char *src_end = source + src_bytes; | |
916 | unsigned char *dst = destination; | |
917 | unsigned char *dst_end = destination + dst_bytes; | |
918 | /* SRC_BASE remembers the start position in source in each loop. | |
919 | The loop will be exited when there's not enough source code, or | |
920 | when there's not enough destination area to produce a | |
921 | character. */ | |
922 | unsigned char *src_base; | |
4ed46869 | 923 | |
b73bfc1c | 924 | coding->produced_char = 0; |
8a33cf7b | 925 | while ((src_base = src) < src_end) |
b73bfc1c KH |
926 | { |
927 | unsigned char tmp[MAX_MULTIBYTE_LENGTH], *p; | |
928 | int bytes; | |
ec6d2bb8 | 929 | |
4af310db EZ |
930 | if (*src == '\r') |
931 | { | |
2bcdf662 | 932 | int c = *src++; |
4af310db | 933 | |
4af310db EZ |
934 | if (coding->eol_type == CODING_EOL_CR) |
935 | c = '\n'; | |
936 | else if (coding->eol_type == CODING_EOL_CRLF) | |
937 | { | |
938 | ONE_MORE_BYTE (c); | |
939 | if (c != '\n') | |
940 | { | |
941 | if (coding->mode & CODING_MODE_INHIBIT_INCONSISTENT_EOL) | |
942 | { | |
943 | coding->result = CODING_FINISH_INCONSISTENT_EOL; | |
944 | goto label_end_of_loop; | |
945 | } | |
946 | src--; | |
947 | c = '\r'; | |
948 | } | |
949 | } | |
950 | *dst++ = c; | |
951 | coding->produced_char++; | |
952 | continue; | |
953 | } | |
954 | else if (*src == '\n') | |
955 | { | |
956 | if ((coding->eol_type == CODING_EOL_CR | |
957 | || coding->eol_type == CODING_EOL_CRLF) | |
958 | && coding->mode & CODING_MODE_INHIBIT_INCONSISTENT_EOL) | |
959 | { | |
960 | coding->result = CODING_FINISH_INCONSISTENT_EOL; | |
961 | goto label_end_of_loop; | |
962 | } | |
963 | *dst++ = *src++; | |
964 | coding->produced_char++; | |
965 | continue; | |
966 | } | |
aa72b389 KH |
967 | else if (*src == 0x80) |
968 | { | |
969 | /* Start of composition data. */ | |
970 | int consumed = decode_composition_emacs_mule (coding, src, src_end, | |
971 | &dst, dst_end, | |
972 | dst_bytes); | |
973 | if (consumed < 0) | |
974 | goto label_end_of_loop; | |
975 | else if (consumed > 0) | |
976 | { | |
977 | src += consumed; | |
978 | continue; | |
979 | } | |
980 | bytes = CHAR_STRING (*src, tmp); | |
981 | p = tmp; | |
982 | src++; | |
983 | } | |
4af310db | 984 | else if (UNIBYTE_STR_AS_MULTIBYTE_P (src, src_end - src, bytes)) |
b73bfc1c KH |
985 | { |
986 | p = src; | |
987 | src += bytes; | |
988 | } | |
989 | else | |
990 | { | |
991 | bytes = CHAR_STRING (*src, tmp); | |
992 | p = tmp; | |
993 | src++; | |
994 | } | |
995 | if (dst + bytes >= (dst_bytes ? dst_end : src)) | |
996 | { | |
997 | coding->result = CODING_FINISH_INSUFFICIENT_DST; | |
4ed46869 KH |
998 | break; |
999 | } | |
b73bfc1c KH |
1000 | while (bytes--) *dst++ = *p++; |
1001 | coding->produced_char++; | |
4ed46869 | 1002 | } |
4af310db | 1003 | label_end_of_loop: |
b73bfc1c KH |
1004 | coding->consumed = coding->consumed_char = src_base - source; |
1005 | coding->produced = dst - destination; | |
4ed46869 KH |
1006 | } |
1007 | ||
b73bfc1c | 1008 | |
aa72b389 KH |
1009 | /* Encode composition data stored at DATA into a special byte sequence |
1010 | starting by 0x80. Update CODING->cmp_data_start and maybe | |
1011 | CODING->cmp_data for the next call. */ | |
1012 | ||
1013 | #define ENCODE_COMPOSITION_EMACS_MULE(coding, data) \ | |
1014 | do { \ | |
1015 | unsigned char buf[1024], *p0 = buf, *p; \ | |
1016 | int len = data[0]; \ | |
1017 | int i; \ | |
1018 | \ | |
1019 | buf[0] = 0x80; \ | |
1020 | buf[1] = 0xF0 + data[3]; /* METHOD */ \ | |
1021 | buf[3] = 0xA0 + (data[2] - data[1]); /* COMPOSED-CHARS */ \ | |
1022 | p = buf + 4; \ | |
1023 | if (data[3] == COMPOSITION_WITH_RULE \ | |
1024 | || data[3] == COMPOSITION_WITH_RULE_ALTCHARS) \ | |
1025 | { \ | |
1026 | p += CHAR_STRING (data[4], p); \ | |
1027 | for (i = 5; i < len; i += 2) \ | |
1028 | { \ | |
1029 | int gref, nref; \ | |
1030 | COMPOSITION_DECODE_RULE (data[i], gref, nref); \ | |
1031 | *p++ = 0x20 + gref; \ | |
1032 | *p++ = 0x20 + nref; \ | |
1033 | p += CHAR_STRING (data[i + 1], p); \ | |
1034 | } \ | |
1035 | } \ | |
1036 | else \ | |
1037 | { \ | |
1038 | for (i = 4; i < len; i++) \ | |
1039 | p += CHAR_STRING (data[i], p); \ | |
1040 | } \ | |
1041 | buf[2] = 0xA0 + (p - buf); /* COMPONENTS-BYTES */ \ | |
1042 | \ | |
1043 | if (dst + (p - buf) + 4 > (dst_bytes ? dst_end : src)) \ | |
1044 | { \ | |
1045 | coding->result = CODING_FINISH_INSUFFICIENT_DST; \ | |
1046 | goto label_end_of_loop; \ | |
1047 | } \ | |
1048 | while (p0 < p) \ | |
1049 | *dst++ = *p0++; \ | |
1050 | coding->cmp_data_start += data[0]; \ | |
1051 | if (coding->cmp_data_start == coding->cmp_data->used \ | |
1052 | && coding->cmp_data->next) \ | |
1053 | { \ | |
1054 | coding->cmp_data = coding->cmp_data->next; \ | |
1055 | coding->cmp_data_start = 0; \ | |
1056 | } \ | |
1057 | } while (0) | |
1058 | ||
1059 | ||
1060 | static void encode_eol P_ ((struct coding_system *, unsigned char *, | |
1061 | unsigned char *, int, int)); | |
1062 | ||
1063 | static void | |
1064 | encode_coding_emacs_mule (coding, source, destination, src_bytes, dst_bytes) | |
1065 | struct coding_system *coding; | |
1066 | unsigned char *source, *destination; | |
1067 | int src_bytes, dst_bytes; | |
1068 | { | |
1069 | unsigned char *src = source; | |
1070 | unsigned char *src_end = source + src_bytes; | |
1071 | unsigned char *dst = destination; | |
1072 | unsigned char *dst_end = destination + dst_bytes; | |
1073 | unsigned char *src_base; | |
1074 | int c; | |
1075 | int char_offset; | |
1076 | int *data; | |
1077 | ||
1078 | Lisp_Object translation_table; | |
1079 | ||
1080 | translation_table = Qnil; | |
1081 | ||
1082 | /* Optimization for the case that there's no composition. */ | |
1083 | if (!coding->cmp_data || coding->cmp_data->used == 0) | |
1084 | { | |
1085 | encode_eol (coding, source, destination, src_bytes, dst_bytes); | |
1086 | return; | |
1087 | } | |
1088 | ||
1089 | char_offset = coding->cmp_data->char_offset; | |
1090 | data = coding->cmp_data->data + coding->cmp_data_start; | |
1091 | while (1) | |
1092 | { | |
1093 | src_base = src; | |
1094 | ||
1095 | /* If SRC starts a composition, encode the information about the | |
1096 | composition in advance. */ | |
1097 | if (coding->cmp_data_start < coding->cmp_data->used | |
1098 | && char_offset + coding->consumed_char == data[1]) | |
1099 | { | |
1100 | ENCODE_COMPOSITION_EMACS_MULE (coding, data); | |
1101 | char_offset = coding->cmp_data->char_offset; | |
1102 | data = coding->cmp_data->data + coding->cmp_data_start; | |
1103 | } | |
1104 | ||
1105 | ONE_MORE_CHAR (c); | |
1106 | if (c == '\n' && (coding->eol_type == CODING_EOL_CRLF | |
1107 | || coding->eol_type == CODING_EOL_CR)) | |
1108 | { | |
1109 | if (coding->eol_type == CODING_EOL_CRLF) | |
1110 | EMIT_TWO_BYTES ('\r', c); | |
1111 | else | |
1112 | EMIT_ONE_BYTE ('\r'); | |
1113 | } | |
1114 | else if (SINGLE_BYTE_CHAR_P (c)) | |
1115 | EMIT_ONE_BYTE (c); | |
1116 | else | |
1117 | EMIT_BYTES (src_base, src); | |
1118 | coding->consumed_char++; | |
1119 | } | |
1120 | label_end_of_loop: | |
1121 | coding->consumed = src_base - source; | |
1122 | coding->produced = coding->produced_char = dst - destination; | |
1123 | return; | |
1124 | } | |
b73bfc1c | 1125 | |
4ed46869 KH |
1126 | \f |
1127 | /*** 3. ISO2022 handlers ***/ | |
1128 | ||
1129 | /* The following note describes the coding system ISO2022 briefly. | |
39787efd | 1130 | Since the intention of this note is to help understand the |
cfb43547 | 1131 | functions in this file, some parts are NOT ACCURATE or are OVERLY |
39787efd | 1132 | SIMPLIFIED. For thorough understanding, please refer to the |
cfb43547 DL |
1133 | original document of ISO2022. This is equivalent to the standard |
1134 | ECMA-35, obtainable from <URL:http://www.ecma.ch/> (*). | |
4ed46869 KH |
1135 | |
1136 | ISO2022 provides many mechanisms to encode several character sets | |
cfb43547 | 1137 | in 7-bit and 8-bit environments. For 7-bit environments, all text |
39787efd KH |
1138 | is encoded using bytes less than 128. This may make the encoded |
1139 | text a little bit longer, but the text passes more easily through | |
cfb43547 | 1140 | several types of gateway, some of which strip off the MSB (Most |
8ca3766a | 1141 | Significant Bit). |
b73bfc1c | 1142 | |
cfb43547 DL |
1143 | There are two kinds of character sets: control character sets and |
1144 | graphic character sets. The former contain control characters such | |
4ed46869 | 1145 | as `newline' and `escape' to provide control functions (control |
39787efd | 1146 | functions are also provided by escape sequences). The latter |
cfb43547 | 1147 | contain graphic characters such as 'A' and '-'. Emacs recognizes |
4ed46869 KH |
1148 | two control character sets and many graphic character sets. |
1149 | ||
1150 | Graphic character sets are classified into one of the following | |
39787efd KH |
1151 | four classes, according to the number of bytes (DIMENSION) and |
1152 | number of characters in one dimension (CHARS) of the set: | |
1153 | - DIMENSION1_CHARS94 | |
1154 | - DIMENSION1_CHARS96 | |
1155 | - DIMENSION2_CHARS94 | |
1156 | - DIMENSION2_CHARS96 | |
1157 | ||
1158 | In addition, each character set is assigned an identification tag, | |
cfb43547 | 1159 | unique for each set, called the "final character" (denoted as <F> |
39787efd KH |
1160 | hereafter). The <F> of each character set is decided by ECMA(*) |
1161 | when it is registered in ISO. The code range of <F> is 0x30..0x7F | |
1162 | (0x30..0x3F are for private use only). | |
4ed46869 KH |
1163 | |
1164 | Note (*): ECMA = European Computer Manufacturers Association | |
1165 | ||
cfb43547 | 1166 | Here are examples of graphic character sets [NAME(<F>)]: |
4ed46869 KH |
1167 | o DIMENSION1_CHARS94 -- ASCII('B'), right-half-of-JISX0201('I'), ... |
1168 | o DIMENSION1_CHARS96 -- right-half-of-ISO8859-1('A'), ... | |
1169 | o DIMENSION2_CHARS94 -- GB2312('A'), JISX0208('B'), ... | |
1170 | o DIMENSION2_CHARS96 -- none for the moment | |
1171 | ||
39787efd | 1172 | A code area (1 byte=8 bits) is divided into 4 areas, C0, GL, C1, and GR. |
4ed46869 KH |
1173 | C0 [0x00..0x1F] -- control character plane 0 |
1174 | GL [0x20..0x7F] -- graphic character plane 0 | |
1175 | C1 [0x80..0x9F] -- control character plane 1 | |
1176 | GR [0xA0..0xFF] -- graphic character plane 1 | |
1177 | ||
1178 | A control character set is directly designated and invoked to C0 or | |
39787efd KH |
1179 | C1 by an escape sequence. The most common case is that: |
1180 | - ISO646's control character set is designated/invoked to C0, and | |
1181 | - ISO6429's control character set is designated/invoked to C1, | |
1182 | and usually these designations/invocations are omitted in encoded | |
1183 | text. In a 7-bit environment, only C0 can be used, and a control | |
1184 | character for C1 is encoded by an appropriate escape sequence to | |
1185 | fit into the environment. All control characters for C1 are | |
1186 | defined to have corresponding escape sequences. | |
4ed46869 KH |
1187 | |
1188 | A graphic character set is at first designated to one of four | |
1189 | graphic registers (G0 through G3), then these graphic registers are | |
1190 | invoked to GL or GR. These designations and invocations can be | |
1191 | done independently. The most common case is that G0 is invoked to | |
39787efd KH |
1192 | GL, G1 is invoked to GR, and ASCII is designated to G0. Usually |
1193 | these invocations and designations are omitted in encoded text. | |
1194 | In a 7-bit environment, only GL can be used. | |
4ed46869 | 1195 | |
39787efd KH |
1196 | When a graphic character set of CHARS94 is invoked to GL, codes |
1197 | 0x20 and 0x7F of the GL area work as control characters SPACE and | |
1198 | DEL respectively, and codes 0xA0 and 0xFF of the GR area should not | |
1199 | be used. | |
4ed46869 KH |
1200 | |
1201 | There are two ways of invocation: locking-shift and single-shift. | |
1202 | With locking-shift, the invocation lasts until the next different | |
39787efd KH |
1203 | invocation, whereas with single-shift, the invocation affects the |
1204 | following character only and doesn't affect the locking-shift | |
1205 | state. Invocations are done by the following control characters or | |
1206 | escape sequences: | |
4ed46869 KH |
1207 | |
1208 | ---------------------------------------------------------------------- | |
39787efd | 1209 | abbrev function cntrl escape seq description |
4ed46869 | 1210 | ---------------------------------------------------------------------- |
39787efd KH |
1211 | SI/LS0 (shift-in) 0x0F none invoke G0 into GL |
1212 | SO/LS1 (shift-out) 0x0E none invoke G1 into GL | |
1213 | LS2 (locking-shift-2) none ESC 'n' invoke G2 into GL | |
1214 | LS3 (locking-shift-3) none ESC 'o' invoke G3 into GL | |
1215 | LS1R (locking-shift-1 right) none ESC '~' invoke G1 into GR (*) | |
1216 | LS2R (locking-shift-2 right) none ESC '}' invoke G2 into GR (*) | |
1217 | LS3R (locking-shift 3 right) none ESC '|' invoke G3 into GR (*) | |
1218 | SS2 (single-shift-2) 0x8E ESC 'N' invoke G2 for one char | |
1219 | SS3 (single-shift-3) 0x8F ESC 'O' invoke G3 for one char | |
4ed46869 | 1220 | ---------------------------------------------------------------------- |
39787efd KH |
1221 | (*) These are not used by any known coding system. |
1222 | ||
1223 | Control characters for these functions are defined by macros | |
1224 | ISO_CODE_XXX in `coding.h'. | |
4ed46869 | 1225 | |
39787efd | 1226 | Designations are done by the following escape sequences: |
4ed46869 KH |
1227 | ---------------------------------------------------------------------- |
1228 | escape sequence description | |
1229 | ---------------------------------------------------------------------- | |
1230 | ESC '(' <F> designate DIMENSION1_CHARS94<F> to G0 | |
1231 | ESC ')' <F> designate DIMENSION1_CHARS94<F> to G1 | |
1232 | ESC '*' <F> designate DIMENSION1_CHARS94<F> to G2 | |
1233 | ESC '+' <F> designate DIMENSION1_CHARS94<F> to G3 | |
1234 | ESC ',' <F> designate DIMENSION1_CHARS96<F> to G0 (*) | |
1235 | ESC '-' <F> designate DIMENSION1_CHARS96<F> to G1 | |
1236 | ESC '.' <F> designate DIMENSION1_CHARS96<F> to G2 | |
1237 | ESC '/' <F> designate DIMENSION1_CHARS96<F> to G3 | |
1238 | ESC '$' '(' <F> designate DIMENSION2_CHARS94<F> to G0 (**) | |
1239 | ESC '$' ')' <F> designate DIMENSION2_CHARS94<F> to G1 | |
1240 | ESC '$' '*' <F> designate DIMENSION2_CHARS94<F> to G2 | |
1241 | ESC '$' '+' <F> designate DIMENSION2_CHARS94<F> to G3 | |
1242 | ESC '$' ',' <F> designate DIMENSION2_CHARS96<F> to G0 (*) | |
1243 | ESC '$' '-' <F> designate DIMENSION2_CHARS96<F> to G1 | |
1244 | ESC '$' '.' <F> designate DIMENSION2_CHARS96<F> to G2 | |
1245 | ESC '$' '/' <F> designate DIMENSION2_CHARS96<F> to G3 | |
1246 | ---------------------------------------------------------------------- | |
1247 | ||
1248 | In this list, "DIMENSION1_CHARS94<F>" means a graphic character set | |
39787efd | 1249 | of dimension 1, chars 94, and final character <F>, etc... |
4ed46869 KH |
1250 | |
1251 | Note (*): Although these designations are not allowed in ISO2022, | |
1252 | Emacs accepts them on decoding, and produces them on encoding | |
39787efd | 1253 | CHARS96 character sets in a coding system which is characterized as |
4ed46869 KH |
1254 | 7-bit environment, non-locking-shift, and non-single-shift. |
1255 | ||
1256 | Note (**): If <F> is '@', 'A', or 'B', the intermediate character | |
39787efd | 1257 | '(' can be omitted. We refer to this as "short-form" hereafter. |
4ed46869 | 1258 | |
cfb43547 | 1259 | Now you may notice that there are a lot of ways of encoding the |
39787efd KH |
1260 | same multilingual text in ISO2022. Actually, there exist many |
1261 | coding systems such as Compound Text (used in X11's inter client | |
8ca3766a DL |
1262 | communication, ISO-2022-JP (used in Japanese Internet), ISO-2022-KR |
1263 | (used in Korean Internet), EUC (Extended UNIX Code, used in Asian | |
4ed46869 KH |
1264 | localized platforms), and all of these are variants of ISO2022. |
1265 | ||
1266 | In addition to the above, Emacs handles two more kinds of escape | |
1267 | sequences: ISO6429's direction specification and Emacs' private | |
1268 | sequence for specifying character composition. | |
1269 | ||
39787efd | 1270 | ISO6429's direction specification takes the following form: |
4ed46869 KH |
1271 | o CSI ']' -- end of the current direction |
1272 | o CSI '0' ']' -- end of the current direction | |
1273 | o CSI '1' ']' -- start of left-to-right text | |
1274 | o CSI '2' ']' -- start of right-to-left text | |
1275 | The control character CSI (0x9B: control sequence introducer) is | |
39787efd KH |
1276 | abbreviated to the escape sequence ESC '[' in a 7-bit environment. |
1277 | ||
1278 | Character composition specification takes the following form: | |
ec6d2bb8 KH |
1279 | o ESC '0' -- start relative composition |
1280 | o ESC '1' -- end composition | |
1281 | o ESC '2' -- start rule-base composition (*) | |
1282 | o ESC '3' -- start relative composition with alternate chars (**) | |
1283 | o ESC '4' -- start rule-base composition with alternate chars (**) | |
b73bfc1c | 1284 | Since these are not standard escape sequences of any ISO standard, |
cfb43547 | 1285 | the use of them with these meanings is restricted to Emacs only. |
ec6d2bb8 | 1286 | |
cfb43547 | 1287 | (*) This form is used only in Emacs 20.5 and older versions, |
b73bfc1c | 1288 | but the newer versions can safely decode it. |
cfb43547 | 1289 | (**) This form is used only in Emacs 21.1 and newer versions, |
b73bfc1c | 1290 | and the older versions can't decode it. |
ec6d2bb8 | 1291 | |
cfb43547 | 1292 | Here's a list of example usages of these composition escape |
b73bfc1c | 1293 | sequences (categorized by `enum composition_method'). |
ec6d2bb8 | 1294 | |
b73bfc1c | 1295 | COMPOSITION_RELATIVE: |
ec6d2bb8 | 1296 | ESC 0 CHAR [ CHAR ] ESC 1 |
8ca3766a | 1297 | COMPOSITION_WITH_RULE: |
ec6d2bb8 | 1298 | ESC 2 CHAR [ RULE CHAR ] ESC 1 |
b73bfc1c | 1299 | COMPOSITION_WITH_ALTCHARS: |
ec6d2bb8 | 1300 | ESC 3 ALTCHAR [ ALTCHAR ] ESC 0 CHAR [ CHAR ] ESC 1 |
b73bfc1c | 1301 | COMPOSITION_WITH_RULE_ALTCHARS: |
ec6d2bb8 | 1302 | ESC 4 ALTCHAR [ RULE ALTCHAR ] ESC 0 CHAR [ CHAR ] ESC 1 */ |
4ed46869 KH |
1303 | |
1304 | enum iso_code_class_type iso_code_class[256]; | |
1305 | ||
05e6f5dc KH |
1306 | #define CHARSET_OK(idx, charset, c) \ |
1307 | (coding_system_table[idx] \ | |
1308 | && (charset == CHARSET_ASCII \ | |
1309 | || (safe_chars = coding_safe_chars (coding_system_table[idx]), \ | |
1310 | CODING_SAFE_CHAR_P (safe_chars, c))) \ | |
1311 | && (CODING_SPEC_ISO_REQUESTED_DESIGNATION (coding_system_table[idx], \ | |
1312 | charset) \ | |
1313 | != CODING_SPEC_ISO_NO_REQUESTED_DESIGNATION)) | |
d46c5b12 KH |
1314 | |
1315 | #define SHIFT_OUT_OK(idx) \ | |
1316 | (CODING_SPEC_ISO_INITIAL_DESIGNATION (coding_system_table[idx], 1) >= 0) | |
1317 | ||
4ed46869 | 1318 | /* See the above "GENERAL NOTES on `detect_coding_XXX ()' functions". |
cfb43547 | 1319 | Check if a text is encoded in ISO2022. If it is, return an |
4ed46869 KH |
1320 | integer in which appropriate flag bits any of: |
1321 | CODING_CATEGORY_MASK_ISO_7 | |
d46c5b12 | 1322 | CODING_CATEGORY_MASK_ISO_7_TIGHT |
4ed46869 KH |
1323 | CODING_CATEGORY_MASK_ISO_8_1 |
1324 | CODING_CATEGORY_MASK_ISO_8_2 | |
7717c392 KH |
1325 | CODING_CATEGORY_MASK_ISO_7_ELSE |
1326 | CODING_CATEGORY_MASK_ISO_8_ELSE | |
4ed46869 KH |
1327 | are set. If a code which should never appear in ISO2022 is found, |
1328 | returns 0. */ | |
1329 | ||
0a28aafb KH |
1330 | static int |
1331 | detect_coding_iso2022 (src, src_end, multibytep) | |
4ed46869 | 1332 | unsigned char *src, *src_end; |
0a28aafb | 1333 | int multibytep; |
4ed46869 | 1334 | { |
d46c5b12 KH |
1335 | int mask = CODING_CATEGORY_MASK_ISO; |
1336 | int mask_found = 0; | |
f46869e4 | 1337 | int reg[4], shift_out = 0, single_shifting = 0; |
da55a2b7 | 1338 | int c, c1, charset; |
b73bfc1c KH |
1339 | /* Dummy for ONE_MORE_BYTE. */ |
1340 | struct coding_system dummy_coding; | |
1341 | struct coding_system *coding = &dummy_coding; | |
05e6f5dc | 1342 | Lisp_Object safe_chars; |
3f003981 | 1343 | |
d46c5b12 | 1344 | reg[0] = CHARSET_ASCII, reg[1] = reg[2] = reg[3] = -1; |
3f003981 | 1345 | while (mask && src < src_end) |
4ed46869 | 1346 | { |
0a28aafb | 1347 | ONE_MORE_BYTE_CHECK_MULTIBYTE (c, multibytep); |
4ed46869 KH |
1348 | switch (c) |
1349 | { | |
1350 | case ISO_CODE_ESC: | |
74383408 KH |
1351 | if (inhibit_iso_escape_detection) |
1352 | break; | |
f46869e4 | 1353 | single_shifting = 0; |
0a28aafb | 1354 | ONE_MORE_BYTE_CHECK_MULTIBYTE (c, multibytep); |
d46c5b12 | 1355 | if (c >= '(' && c <= '/') |
4ed46869 | 1356 | { |
bf9cdd4e | 1357 | /* Designation sequence for a charset of dimension 1. */ |
0a28aafb | 1358 | ONE_MORE_BYTE_CHECK_MULTIBYTE (c1, multibytep); |
d46c5b12 KH |
1359 | if (c1 < ' ' || c1 >= 0x80 |
1360 | || (charset = iso_charset_table[0][c >= ','][c1]) < 0) | |
1361 | /* Invalid designation sequence. Just ignore. */ | |
1362 | break; | |
1363 | reg[(c - '(') % 4] = charset; | |
bf9cdd4e KH |
1364 | } |
1365 | else if (c == '$') | |
1366 | { | |
1367 | /* Designation sequence for a charset of dimension 2. */ | |
0a28aafb | 1368 | ONE_MORE_BYTE_CHECK_MULTIBYTE (c, multibytep); |
bf9cdd4e KH |
1369 | if (c >= '@' && c <= 'B') |
1370 | /* Designation for JISX0208.1978, GB2312, or JISX0208. */ | |
d46c5b12 | 1371 | reg[0] = charset = iso_charset_table[1][0][c]; |
bf9cdd4e | 1372 | else if (c >= '(' && c <= '/') |
bcf26d6a | 1373 | { |
0a28aafb | 1374 | ONE_MORE_BYTE_CHECK_MULTIBYTE (c1, multibytep); |
d46c5b12 KH |
1375 | if (c1 < ' ' || c1 >= 0x80 |
1376 | || (charset = iso_charset_table[1][c >= ','][c1]) < 0) | |
1377 | /* Invalid designation sequence. Just ignore. */ | |
1378 | break; | |
1379 | reg[(c - '(') % 4] = charset; | |
bcf26d6a | 1380 | } |
bf9cdd4e | 1381 | else |
d46c5b12 KH |
1382 | /* Invalid designation sequence. Just ignore. */ |
1383 | break; | |
1384 | } | |
ae9ff118 | 1385 | else if (c == 'N' || c == 'O') |
d46c5b12 | 1386 | { |
ae9ff118 KH |
1387 | /* ESC <Fe> for SS2 or SS3. */ |
1388 | mask &= CODING_CATEGORY_MASK_ISO_7_ELSE; | |
d46c5b12 | 1389 | break; |
4ed46869 | 1390 | } |
ec6d2bb8 KH |
1391 | else if (c >= '0' && c <= '4') |
1392 | { | |
1393 | /* ESC <Fp> for start/end composition. */ | |
1394 | mask_found |= CODING_CATEGORY_MASK_ISO; | |
1395 | break; | |
1396 | } | |
bf9cdd4e | 1397 | else |
d46c5b12 KH |
1398 | /* Invalid escape sequence. Just ignore. */ |
1399 | break; | |
1400 | ||
1401 | /* We found a valid designation sequence for CHARSET. */ | |
1402 | mask &= ~CODING_CATEGORY_MASK_ISO_8BIT; | |
05e6f5dc KH |
1403 | c = MAKE_CHAR (charset, 0, 0); |
1404 | if (CHARSET_OK (CODING_CATEGORY_IDX_ISO_7, charset, c)) | |
d46c5b12 KH |
1405 | mask_found |= CODING_CATEGORY_MASK_ISO_7; |
1406 | else | |
1407 | mask &= ~CODING_CATEGORY_MASK_ISO_7; | |
05e6f5dc | 1408 | if (CHARSET_OK (CODING_CATEGORY_IDX_ISO_7_TIGHT, charset, c)) |
d46c5b12 KH |
1409 | mask_found |= CODING_CATEGORY_MASK_ISO_7_TIGHT; |
1410 | else | |
1411 | mask &= ~CODING_CATEGORY_MASK_ISO_7_TIGHT; | |
05e6f5dc | 1412 | if (CHARSET_OK (CODING_CATEGORY_IDX_ISO_7_ELSE, charset, c)) |
ae9ff118 KH |
1413 | mask_found |= CODING_CATEGORY_MASK_ISO_7_ELSE; |
1414 | else | |
d46c5b12 | 1415 | mask &= ~CODING_CATEGORY_MASK_ISO_7_ELSE; |
05e6f5dc | 1416 | if (CHARSET_OK (CODING_CATEGORY_IDX_ISO_8_ELSE, charset, c)) |
ae9ff118 KH |
1417 | mask_found |= CODING_CATEGORY_MASK_ISO_8_ELSE; |
1418 | else | |
d46c5b12 | 1419 | mask &= ~CODING_CATEGORY_MASK_ISO_8_ELSE; |
4ed46869 KH |
1420 | break; |
1421 | ||
4ed46869 | 1422 | case ISO_CODE_SO: |
74383408 KH |
1423 | if (inhibit_iso_escape_detection) |
1424 | break; | |
f46869e4 | 1425 | single_shifting = 0; |
d46c5b12 KH |
1426 | if (shift_out == 0 |
1427 | && (reg[1] >= 0 | |
1428 | || SHIFT_OUT_OK (CODING_CATEGORY_IDX_ISO_7_ELSE) | |
1429 | || SHIFT_OUT_OK (CODING_CATEGORY_IDX_ISO_8_ELSE))) | |
1430 | { | |
1431 | /* Locking shift out. */ | |
1432 | mask &= ~CODING_CATEGORY_MASK_ISO_7BIT; | |
1433 | mask_found |= CODING_CATEGORY_MASK_ISO_SHIFT; | |
1434 | } | |
e0e989f6 KH |
1435 | break; |
1436 | ||
d46c5b12 | 1437 | case ISO_CODE_SI: |
74383408 KH |
1438 | if (inhibit_iso_escape_detection) |
1439 | break; | |
f46869e4 | 1440 | single_shifting = 0; |
d46c5b12 KH |
1441 | if (shift_out == 1) |
1442 | { | |
1443 | /* Locking shift in. */ | |
1444 | mask &= ~CODING_CATEGORY_MASK_ISO_7BIT; | |
1445 | mask_found |= CODING_CATEGORY_MASK_ISO_SHIFT; | |
1446 | } | |
1447 | break; | |
1448 | ||
4ed46869 | 1449 | case ISO_CODE_CSI: |
f46869e4 | 1450 | single_shifting = 0; |
4ed46869 KH |
1451 | case ISO_CODE_SS2: |
1452 | case ISO_CODE_SS3: | |
3f003981 KH |
1453 | { |
1454 | int newmask = CODING_CATEGORY_MASK_ISO_8_ELSE; | |
1455 | ||
74383408 KH |
1456 | if (inhibit_iso_escape_detection) |
1457 | break; | |
70c22245 KH |
1458 | if (c != ISO_CODE_CSI) |
1459 | { | |
d46c5b12 KH |
1460 | if (coding_system_table[CODING_CATEGORY_IDX_ISO_8_1]->flags |
1461 | & CODING_FLAG_ISO_SINGLE_SHIFT) | |
70c22245 | 1462 | newmask |= CODING_CATEGORY_MASK_ISO_8_1; |
d46c5b12 KH |
1463 | if (coding_system_table[CODING_CATEGORY_IDX_ISO_8_2]->flags |
1464 | & CODING_FLAG_ISO_SINGLE_SHIFT) | |
70c22245 | 1465 | newmask |= CODING_CATEGORY_MASK_ISO_8_2; |
f46869e4 | 1466 | single_shifting = 1; |
70c22245 | 1467 | } |
3f003981 KH |
1468 | if (VECTORP (Vlatin_extra_code_table) |
1469 | && !NILP (XVECTOR (Vlatin_extra_code_table)->contents[c])) | |
1470 | { | |
d46c5b12 KH |
1471 | if (coding_system_table[CODING_CATEGORY_IDX_ISO_8_1]->flags |
1472 | & CODING_FLAG_ISO_LATIN_EXTRA) | |
3f003981 | 1473 | newmask |= CODING_CATEGORY_MASK_ISO_8_1; |
d46c5b12 KH |
1474 | if (coding_system_table[CODING_CATEGORY_IDX_ISO_8_2]->flags |
1475 | & CODING_FLAG_ISO_LATIN_EXTRA) | |
3f003981 KH |
1476 | newmask |= CODING_CATEGORY_MASK_ISO_8_2; |
1477 | } | |
1478 | mask &= newmask; | |
d46c5b12 | 1479 | mask_found |= newmask; |
3f003981 KH |
1480 | } |
1481 | break; | |
4ed46869 KH |
1482 | |
1483 | default: | |
1484 | if (c < 0x80) | |
f46869e4 KH |
1485 | { |
1486 | single_shifting = 0; | |
1487 | break; | |
1488 | } | |
4ed46869 | 1489 | else if (c < 0xA0) |
c4825358 | 1490 | { |
f46869e4 | 1491 | single_shifting = 0; |
3f003981 KH |
1492 | if (VECTORP (Vlatin_extra_code_table) |
1493 | && !NILP (XVECTOR (Vlatin_extra_code_table)->contents[c])) | |
c4825358 | 1494 | { |
3f003981 KH |
1495 | int newmask = 0; |
1496 | ||
d46c5b12 KH |
1497 | if (coding_system_table[CODING_CATEGORY_IDX_ISO_8_1]->flags |
1498 | & CODING_FLAG_ISO_LATIN_EXTRA) | |
3f003981 | 1499 | newmask |= CODING_CATEGORY_MASK_ISO_8_1; |
d46c5b12 KH |
1500 | if (coding_system_table[CODING_CATEGORY_IDX_ISO_8_2]->flags |
1501 | & CODING_FLAG_ISO_LATIN_EXTRA) | |
3f003981 KH |
1502 | newmask |= CODING_CATEGORY_MASK_ISO_8_2; |
1503 | mask &= newmask; | |
d46c5b12 | 1504 | mask_found |= newmask; |
c4825358 | 1505 | } |
3f003981 KH |
1506 | else |
1507 | return 0; | |
c4825358 | 1508 | } |
4ed46869 KH |
1509 | else |
1510 | { | |
d46c5b12 | 1511 | mask &= ~(CODING_CATEGORY_MASK_ISO_7BIT |
7717c392 | 1512 | | CODING_CATEGORY_MASK_ISO_7_ELSE); |
d46c5b12 | 1513 | mask_found |= CODING_CATEGORY_MASK_ISO_8_1; |
f46869e4 KH |
1514 | /* Check the length of succeeding codes of the range |
1515 | 0xA0..0FF. If the byte length is odd, we exclude | |
1516 | CODING_CATEGORY_MASK_ISO_8_2. We can check this only | |
1517 | when we are not single shifting. */ | |
b73bfc1c KH |
1518 | if (!single_shifting |
1519 | && mask & CODING_CATEGORY_MASK_ISO_8_2) | |
f46869e4 | 1520 | { |
e17de821 | 1521 | int i = 1; |
b73bfc1c KH |
1522 | while (src < src_end) |
1523 | { | |
0a28aafb | 1524 | ONE_MORE_BYTE_CHECK_MULTIBYTE (c, multibytep); |
b73bfc1c KH |
1525 | if (c < 0xA0) |
1526 | break; | |
1527 | i++; | |
1528 | } | |
1529 | ||
1530 | if (i & 1 && src < src_end) | |
f46869e4 KH |
1531 | mask &= ~CODING_CATEGORY_MASK_ISO_8_2; |
1532 | else | |
1533 | mask_found |= CODING_CATEGORY_MASK_ISO_8_2; | |
1534 | } | |
4ed46869 KH |
1535 | } |
1536 | break; | |
1537 | } | |
1538 | } | |
b73bfc1c | 1539 | label_end_of_loop: |
d46c5b12 | 1540 | return (mask & mask_found); |
4ed46869 KH |
1541 | } |
1542 | ||
b73bfc1c KH |
1543 | /* Decode a character of which charset is CHARSET, the 1st position |
1544 | code is C1, the 2nd position code is C2, and return the decoded | |
1545 | character code. If the variable `translation_table' is non-nil, | |
1546 | returned the translated code. */ | |
ec6d2bb8 | 1547 | |
b73bfc1c KH |
1548 | #define DECODE_ISO_CHARACTER(charset, c1, c2) \ |
1549 | (NILP (translation_table) \ | |
1550 | ? MAKE_CHAR (charset, c1, c2) \ | |
1551 | : translate_char (translation_table, -1, charset, c1, c2)) | |
4ed46869 KH |
1552 | |
1553 | /* Set designation state into CODING. */ | |
d46c5b12 KH |
1554 | #define DECODE_DESIGNATION(reg, dimension, chars, final_char) \ |
1555 | do { \ | |
05e6f5dc | 1556 | int charset, c; \ |
944bd420 KH |
1557 | \ |
1558 | if (final_char < '0' || final_char >= 128) \ | |
1559 | goto label_invalid_code; \ | |
1560 | charset = ISO_CHARSET_TABLE (make_number (dimension), \ | |
1561 | make_number (chars), \ | |
1562 | make_number (final_char)); \ | |
05e6f5dc | 1563 | c = MAKE_CHAR (charset, 0, 0); \ |
d46c5b12 | 1564 | if (charset >= 0 \ |
704c5781 | 1565 | && (CODING_SPEC_ISO_REQUESTED_DESIGNATION (coding, charset) == reg \ |
05e6f5dc | 1566 | || CODING_SAFE_CHAR_P (safe_chars, c))) \ |
d46c5b12 KH |
1567 | { \ |
1568 | if (coding->spec.iso2022.last_invalid_designation_register == 0 \ | |
1569 | && reg == 0 \ | |
1570 | && charset == CHARSET_ASCII) \ | |
1571 | { \ | |
1572 | /* We should insert this designation sequence as is so \ | |
1573 | that it is surely written back to a file. */ \ | |
1574 | coding->spec.iso2022.last_invalid_designation_register = -1; \ | |
1575 | goto label_invalid_code; \ | |
1576 | } \ | |
1577 | coding->spec.iso2022.last_invalid_designation_register = -1; \ | |
1578 | if ((coding->mode & CODING_MODE_DIRECTION) \ | |
1579 | && CHARSET_REVERSE_CHARSET (charset) >= 0) \ | |
1580 | charset = CHARSET_REVERSE_CHARSET (charset); \ | |
1581 | CODING_SPEC_ISO_DESIGNATION (coding, reg) = charset; \ | |
1582 | } \ | |
1583 | else \ | |
1584 | { \ | |
1585 | coding->spec.iso2022.last_invalid_designation_register = reg; \ | |
1586 | goto label_invalid_code; \ | |
1587 | } \ | |
4ed46869 KH |
1588 | } while (0) |
1589 | ||
ec6d2bb8 KH |
1590 | /* Allocate a memory block for storing information about compositions. |
1591 | The block is chained to the already allocated blocks. */ | |
d46c5b12 | 1592 | |
33fb63eb | 1593 | void |
ec6d2bb8 | 1594 | coding_allocate_composition_data (coding, char_offset) |
d46c5b12 | 1595 | struct coding_system *coding; |
ec6d2bb8 | 1596 | int char_offset; |
d46c5b12 | 1597 | { |
ec6d2bb8 KH |
1598 | struct composition_data *cmp_data |
1599 | = (struct composition_data *) xmalloc (sizeof *cmp_data); | |
1600 | ||
1601 | cmp_data->char_offset = char_offset; | |
1602 | cmp_data->used = 0; | |
1603 | cmp_data->prev = coding->cmp_data; | |
1604 | cmp_data->next = NULL; | |
1605 | if (coding->cmp_data) | |
1606 | coding->cmp_data->next = cmp_data; | |
1607 | coding->cmp_data = cmp_data; | |
1608 | coding->cmp_data_start = 0; | |
1609 | } | |
d46c5b12 | 1610 | |
aa72b389 KH |
1611 | /* Handle composition start sequence ESC 0, ESC 2, ESC 3, or ESC 4. |
1612 | ESC 0 : relative composition : ESC 0 CHAR ... ESC 1 | |
1613 | ESC 2 : rulebase composition : ESC 2 CHAR RULE CHAR RULE ... CHAR ESC 1 | |
1614 | ESC 3 : altchar composition : ESC 3 ALT ... ESC 0 CHAR ... ESC 1 | |
1615 | ESC 4 : alt&rule composition : ESC 4 ALT RULE .. ALT ESC 0 CHAR ... ESC 1 | |
1616 | */ | |
ec6d2bb8 | 1617 | |
33fb63eb KH |
1618 | #define DECODE_COMPOSITION_START(c1) \ |
1619 | do { \ | |
1620 | if (coding->composing == COMPOSITION_DISABLED) \ | |
1621 | { \ | |
1622 | *dst++ = ISO_CODE_ESC; \ | |
1623 | *dst++ = c1 & 0x7f; \ | |
1624 | coding->produced_char += 2; \ | |
1625 | } \ | |
1626 | else if (!COMPOSING_P (coding)) \ | |
1627 | { \ | |
1628 | /* This is surely the start of a composition. We must be sure \ | |
1629 | that coding->cmp_data has enough space to store the \ | |
1630 | information about the composition. If not, terminate the \ | |
1631 | current decoding loop, allocate one more memory block for \ | |
8ca3766a | 1632 | coding->cmp_data in the caller, then start the decoding \ |
33fb63eb KH |
1633 | loop again. We can't allocate memory here directly because \ |
1634 | it may cause buffer/string relocation. */ \ | |
1635 | if (!coding->cmp_data \ | |
1636 | || (coding->cmp_data->used + COMPOSITION_DATA_MAX_BUNCH_LENGTH \ | |
1637 | >= COMPOSITION_DATA_SIZE)) \ | |
1638 | { \ | |
1639 | coding->result = CODING_FINISH_INSUFFICIENT_CMP; \ | |
1640 | goto label_end_of_loop; \ | |
1641 | } \ | |
1642 | coding->composing = (c1 == '0' ? COMPOSITION_RELATIVE \ | |
1643 | : c1 == '2' ? COMPOSITION_WITH_RULE \ | |
1644 | : c1 == '3' ? COMPOSITION_WITH_ALTCHARS \ | |
1645 | : COMPOSITION_WITH_RULE_ALTCHARS); \ | |
1646 | CODING_ADD_COMPOSITION_START (coding, coding->produced_char, \ | |
1647 | coding->composing); \ | |
1648 | coding->composition_rule_follows = 0; \ | |
1649 | } \ | |
1650 | else \ | |
1651 | { \ | |
1652 | /* We are already handling a composition. If the method is \ | |
1653 | the following two, the codes following the current escape \ | |
1654 | sequence are actual characters stored in a buffer. */ \ | |
1655 | if (coding->composing == COMPOSITION_WITH_ALTCHARS \ | |
1656 | || coding->composing == COMPOSITION_WITH_RULE_ALTCHARS) \ | |
1657 | { \ | |
1658 | coding->composing = COMPOSITION_RELATIVE; \ | |
1659 | coding->composition_rule_follows = 0; \ | |
1660 | } \ | |
1661 | } \ | |
ec6d2bb8 KH |
1662 | } while (0) |
1663 | ||
8ca3766a | 1664 | /* Handle composition end sequence ESC 1. */ |
ec6d2bb8 KH |
1665 | |
1666 | #define DECODE_COMPOSITION_END(c1) \ | |
1667 | do { \ | |
1668 | if (coding->composing == COMPOSITION_DISABLED) \ | |
1669 | { \ | |
1670 | *dst++ = ISO_CODE_ESC; \ | |
1671 | *dst++ = c1; \ | |
1672 | coding->produced_char += 2; \ | |
1673 | } \ | |
1674 | else \ | |
1675 | { \ | |
1676 | CODING_ADD_COMPOSITION_END (coding, coding->produced_char); \ | |
1677 | coding->composing = COMPOSITION_NO; \ | |
1678 | } \ | |
1679 | } while (0) | |
1680 | ||
1681 | /* Decode a composition rule from the byte C1 (and maybe one more byte | |
1682 | from SRC) and store one encoded composition rule in | |
1683 | coding->cmp_data. */ | |
1684 | ||
1685 | #define DECODE_COMPOSITION_RULE(c1) \ | |
1686 | do { \ | |
1687 | int rule = 0; \ | |
1688 | (c1) -= 32; \ | |
1689 | if (c1 < 81) /* old format (before ver.21) */ \ | |
1690 | { \ | |
1691 | int gref = (c1) / 9; \ | |
1692 | int nref = (c1) % 9; \ | |
1693 | if (gref == 4) gref = 10; \ | |
1694 | if (nref == 4) nref = 10; \ | |
1695 | rule = COMPOSITION_ENCODE_RULE (gref, nref); \ | |
1696 | } \ | |
b73bfc1c | 1697 | else if (c1 < 93) /* new format (after ver.21) */ \ |
ec6d2bb8 KH |
1698 | { \ |
1699 | ONE_MORE_BYTE (c2); \ | |
1700 | rule = COMPOSITION_ENCODE_RULE (c1 - 81, c2 - 32); \ | |
1701 | } \ | |
1702 | CODING_ADD_COMPOSITION_COMPONENT (coding, rule); \ | |
1703 | coding->composition_rule_follows = 0; \ | |
1704 | } while (0) | |
88993dfd | 1705 | |
d46c5b12 | 1706 | |
4ed46869 KH |
1707 | /* See the above "GENERAL NOTES on `decode_coding_XXX ()' functions". */ |
1708 | ||
b73bfc1c | 1709 | static void |
d46c5b12 | 1710 | decode_coding_iso2022 (coding, source, destination, src_bytes, dst_bytes) |
4ed46869 KH |
1711 | struct coding_system *coding; |
1712 | unsigned char *source, *destination; | |
1713 | int src_bytes, dst_bytes; | |
4ed46869 KH |
1714 | { |
1715 | unsigned char *src = source; | |
1716 | unsigned char *src_end = source + src_bytes; | |
1717 | unsigned char *dst = destination; | |
1718 | unsigned char *dst_end = destination + dst_bytes; | |
4ed46869 KH |
1719 | /* Charsets invoked to graphic plane 0 and 1 respectively. */ |
1720 | int charset0 = CODING_SPEC_ISO_PLANE_CHARSET (coding, 0); | |
1721 | int charset1 = CODING_SPEC_ISO_PLANE_CHARSET (coding, 1); | |
b73bfc1c KH |
1722 | /* SRC_BASE remembers the start position in source in each loop. |
1723 | The loop will be exited when there's not enough source code | |
1724 | (within macro ONE_MORE_BYTE), or when there's not enough | |
1725 | destination area to produce a character (within macro | |
1726 | EMIT_CHAR). */ | |
1727 | unsigned char *src_base; | |
1728 | int c, charset; | |
1729 | Lisp_Object translation_table; | |
05e6f5dc KH |
1730 | Lisp_Object safe_chars; |
1731 | ||
1732 | safe_chars = coding_safe_chars (coding); | |
bdd9fb48 | 1733 | |
b73bfc1c KH |
1734 | if (NILP (Venable_character_translation)) |
1735 | translation_table = Qnil; | |
1736 | else | |
1737 | { | |
1738 | translation_table = coding->translation_table_for_decode; | |
1739 | if (NILP (translation_table)) | |
1740 | translation_table = Vstandard_translation_table_for_decode; | |
1741 | } | |
4ed46869 | 1742 | |
b73bfc1c KH |
1743 | coding->result = CODING_FINISH_NORMAL; |
1744 | ||
1745 | while (1) | |
4ed46869 | 1746 | { |
b73bfc1c KH |
1747 | int c1, c2; |
1748 | ||
1749 | src_base = src; | |
1750 | ONE_MORE_BYTE (c1); | |
4ed46869 | 1751 | |
ec6d2bb8 | 1752 | /* We produce no character or one character. */ |
4ed46869 KH |
1753 | switch (iso_code_class [c1]) |
1754 | { | |
1755 | case ISO_0x20_or_0x7F: | |
ec6d2bb8 KH |
1756 | if (COMPOSING_P (coding) && coding->composition_rule_follows) |
1757 | { | |
1758 | DECODE_COMPOSITION_RULE (c1); | |
b73bfc1c | 1759 | continue; |
ec6d2bb8 KH |
1760 | } |
1761 | if (charset0 < 0 || CHARSET_CHARS (charset0) == 94) | |
4ed46869 KH |
1762 | { |
1763 | /* This is SPACE or DEL. */ | |
b73bfc1c | 1764 | charset = CHARSET_ASCII; |
4ed46869 KH |
1765 | break; |
1766 | } | |
1767 | /* This is a graphic character, we fall down ... */ | |
1768 | ||
1769 | case ISO_graphic_plane_0: | |
ec6d2bb8 | 1770 | if (COMPOSING_P (coding) && coding->composition_rule_follows) |
b73bfc1c KH |
1771 | { |
1772 | DECODE_COMPOSITION_RULE (c1); | |
1773 | continue; | |
1774 | } | |
1775 | charset = charset0; | |
4ed46869 KH |
1776 | break; |
1777 | ||
1778 | case ISO_0xA0_or_0xFF: | |
d46c5b12 KH |
1779 | if (charset1 < 0 || CHARSET_CHARS (charset1) == 94 |
1780 | || coding->flags & CODING_FLAG_ISO_SEVEN_BITS) | |
fb88bf2d | 1781 | goto label_invalid_code; |
4ed46869 KH |
1782 | /* This is a graphic character, we fall down ... */ |
1783 | ||
1784 | case ISO_graphic_plane_1: | |
b73bfc1c | 1785 | if (charset1 < 0) |
fb88bf2d | 1786 | goto label_invalid_code; |
b73bfc1c | 1787 | charset = charset1; |
4ed46869 KH |
1788 | break; |
1789 | ||
b73bfc1c | 1790 | case ISO_control_0: |
ec6d2bb8 KH |
1791 | if (COMPOSING_P (coding)) |
1792 | DECODE_COMPOSITION_END ('1'); | |
1793 | ||
4ed46869 KH |
1794 | /* All ISO2022 control characters in this class have the |
1795 | same representation in Emacs internal format. */ | |
d46c5b12 KH |
1796 | if (c1 == '\n' |
1797 | && (coding->mode & CODING_MODE_INHIBIT_INCONSISTENT_EOL) | |
1798 | && (coding->eol_type == CODING_EOL_CR | |
1799 | || coding->eol_type == CODING_EOL_CRLF)) | |
1800 | { | |
b73bfc1c KH |
1801 | coding->result = CODING_FINISH_INCONSISTENT_EOL; |
1802 | goto label_end_of_loop; | |
d46c5b12 | 1803 | } |
b73bfc1c | 1804 | charset = CHARSET_ASCII; |
4ed46869 KH |
1805 | break; |
1806 | ||
b73bfc1c KH |
1807 | case ISO_control_1: |
1808 | if (COMPOSING_P (coding)) | |
1809 | DECODE_COMPOSITION_END ('1'); | |
1810 | goto label_invalid_code; | |
1811 | ||
4ed46869 | 1812 | case ISO_carriage_return: |
ec6d2bb8 KH |
1813 | if (COMPOSING_P (coding)) |
1814 | DECODE_COMPOSITION_END ('1'); | |
1815 | ||
4ed46869 | 1816 | if (coding->eol_type == CODING_EOL_CR) |
b73bfc1c | 1817 | c1 = '\n'; |
4ed46869 KH |
1818 | else if (coding->eol_type == CODING_EOL_CRLF) |
1819 | { | |
1820 | ONE_MORE_BYTE (c1); | |
b73bfc1c | 1821 | if (c1 != ISO_CODE_LF) |
4ed46869 | 1822 | { |
d46c5b12 KH |
1823 | if (coding->mode & CODING_MODE_INHIBIT_INCONSISTENT_EOL) |
1824 | { | |
b73bfc1c KH |
1825 | coding->result = CODING_FINISH_INCONSISTENT_EOL; |
1826 | goto label_end_of_loop; | |
d46c5b12 | 1827 | } |
4ed46869 | 1828 | src--; |
b73bfc1c | 1829 | c1 = '\r'; |
4ed46869 KH |
1830 | } |
1831 | } | |
b73bfc1c | 1832 | charset = CHARSET_ASCII; |
4ed46869 KH |
1833 | break; |
1834 | ||
1835 | case ISO_shift_out: | |
d46c5b12 KH |
1836 | if (! (coding->flags & CODING_FLAG_ISO_LOCKING_SHIFT) |
1837 | || CODING_SPEC_ISO_DESIGNATION (coding, 1) < 0) | |
1838 | goto label_invalid_code; | |
4ed46869 KH |
1839 | CODING_SPEC_ISO_INVOCATION (coding, 0) = 1; |
1840 | charset0 = CODING_SPEC_ISO_PLANE_CHARSET (coding, 0); | |
b73bfc1c | 1841 | continue; |
4ed46869 KH |
1842 | |
1843 | case ISO_shift_in: | |
d46c5b12 KH |
1844 | if (! (coding->flags & CODING_FLAG_ISO_LOCKING_SHIFT)) |
1845 | goto label_invalid_code; | |
4ed46869 KH |
1846 | CODING_SPEC_ISO_INVOCATION (coding, 0) = 0; |
1847 | charset0 = CODING_SPEC_ISO_PLANE_CHARSET (coding, 0); | |
b73bfc1c | 1848 | continue; |
4ed46869 KH |
1849 | |
1850 | case ISO_single_shift_2_7: | |
1851 | case ISO_single_shift_2: | |
d46c5b12 KH |
1852 | if (! (coding->flags & CODING_FLAG_ISO_SINGLE_SHIFT)) |
1853 | goto label_invalid_code; | |
4ed46869 KH |
1854 | /* SS2 is handled as an escape sequence of ESC 'N' */ |
1855 | c1 = 'N'; | |
1856 | goto label_escape_sequence; | |
1857 | ||
1858 | case ISO_single_shift_3: | |
d46c5b12 KH |
1859 | if (! (coding->flags & CODING_FLAG_ISO_SINGLE_SHIFT)) |
1860 | goto label_invalid_code; | |
4ed46869 KH |
1861 | /* SS2 is handled as an escape sequence of ESC 'O' */ |
1862 | c1 = 'O'; | |
1863 | goto label_escape_sequence; | |
1864 | ||
1865 | case ISO_control_sequence_introducer: | |
1866 | /* CSI is handled as an escape sequence of ESC '[' ... */ | |
1867 | c1 = '['; | |
1868 | goto label_escape_sequence; | |
1869 | ||
1870 | case ISO_escape: | |
1871 | ONE_MORE_BYTE (c1); | |
1872 | label_escape_sequence: | |
1873 | /* Escape sequences handled by Emacs are invocation, | |
1874 | designation, direction specification, and character | |
1875 | composition specification. */ | |
1876 | switch (c1) | |
1877 | { | |
1878 | case '&': /* revision of following character set */ | |
1879 | ONE_MORE_BYTE (c1); | |
1880 | if (!(c1 >= '@' && c1 <= '~')) | |
d46c5b12 | 1881 | goto label_invalid_code; |
4ed46869 KH |
1882 | ONE_MORE_BYTE (c1); |
1883 | if (c1 != ISO_CODE_ESC) | |
d46c5b12 | 1884 | goto label_invalid_code; |
4ed46869 KH |
1885 | ONE_MORE_BYTE (c1); |
1886 | goto label_escape_sequence; | |
1887 | ||
1888 | case '$': /* designation of 2-byte character set */ | |
d46c5b12 KH |
1889 | if (! (coding->flags & CODING_FLAG_ISO_DESIGNATION)) |
1890 | goto label_invalid_code; | |
4ed46869 KH |
1891 | ONE_MORE_BYTE (c1); |
1892 | if (c1 >= '@' && c1 <= 'B') | |
1893 | { /* designation of JISX0208.1978, GB2312.1980, | |
88993dfd | 1894 | or JISX0208.1980 */ |
4ed46869 KH |
1895 | DECODE_DESIGNATION (0, 2, 94, c1); |
1896 | } | |
1897 | else if (c1 >= 0x28 && c1 <= 0x2B) | |
1898 | { /* designation of DIMENSION2_CHARS94 character set */ | |
1899 | ONE_MORE_BYTE (c2); | |
1900 | DECODE_DESIGNATION (c1 - 0x28, 2, 94, c2); | |
1901 | } | |
1902 | else if (c1 >= 0x2C && c1 <= 0x2F) | |
1903 | { /* designation of DIMENSION2_CHARS96 character set */ | |
1904 | ONE_MORE_BYTE (c2); | |
1905 | DECODE_DESIGNATION (c1 - 0x2C, 2, 96, c2); | |
1906 | } | |
1907 | else | |
d46c5b12 | 1908 | goto label_invalid_code; |
b73bfc1c KH |
1909 | /* We must update these variables now. */ |
1910 | charset0 = CODING_SPEC_ISO_PLANE_CHARSET (coding, 0); | |
1911 | charset1 = CODING_SPEC_ISO_PLANE_CHARSET (coding, 1); | |
1912 | continue; | |
4ed46869 KH |
1913 | |
1914 | case 'n': /* invocation of locking-shift-2 */ | |
d46c5b12 KH |
1915 | if (! (coding->flags & CODING_FLAG_ISO_LOCKING_SHIFT) |
1916 | || CODING_SPEC_ISO_DESIGNATION (coding, 2) < 0) | |
1917 | goto label_invalid_code; | |
4ed46869 | 1918 | CODING_SPEC_ISO_INVOCATION (coding, 0) = 2; |
e0e989f6 | 1919 | charset0 = CODING_SPEC_ISO_PLANE_CHARSET (coding, 0); |
b73bfc1c | 1920 | continue; |
4ed46869 KH |
1921 | |
1922 | case 'o': /* invocation of locking-shift-3 */ | |
d46c5b12 KH |
1923 | if (! (coding->flags & CODING_FLAG_ISO_LOCKING_SHIFT) |
1924 | || CODING_SPEC_ISO_DESIGNATION (coding, 3) < 0) | |
1925 | goto label_invalid_code; | |
4ed46869 | 1926 | CODING_SPEC_ISO_INVOCATION (coding, 0) = 3; |
e0e989f6 | 1927 | charset0 = CODING_SPEC_ISO_PLANE_CHARSET (coding, 0); |
b73bfc1c | 1928 | continue; |
4ed46869 KH |
1929 | |
1930 | case 'N': /* invocation of single-shift-2 */ | |
d46c5b12 KH |
1931 | if (! (coding->flags & CODING_FLAG_ISO_SINGLE_SHIFT) |
1932 | || CODING_SPEC_ISO_DESIGNATION (coding, 2) < 0) | |
1933 | goto label_invalid_code; | |
4ed46869 | 1934 | charset = CODING_SPEC_ISO_DESIGNATION (coding, 2); |
b73bfc1c | 1935 | ONE_MORE_BYTE (c1); |
e7046a18 KH |
1936 | if (c1 < 0x20 || (c1 >= 0x80 && c1 < 0xA0)) |
1937 | goto label_invalid_code; | |
4ed46869 KH |
1938 | break; |
1939 | ||
1940 | case 'O': /* invocation of single-shift-3 */ | |
d46c5b12 KH |
1941 | if (! (coding->flags & CODING_FLAG_ISO_SINGLE_SHIFT) |
1942 | || CODING_SPEC_ISO_DESIGNATION (coding, 3) < 0) | |
1943 | goto label_invalid_code; | |
4ed46869 | 1944 | charset = CODING_SPEC_ISO_DESIGNATION (coding, 3); |
b73bfc1c | 1945 | ONE_MORE_BYTE (c1); |
e7046a18 KH |
1946 | if (c1 < 0x20 || (c1 >= 0x80 && c1 < 0xA0)) |
1947 | goto label_invalid_code; | |
4ed46869 KH |
1948 | break; |
1949 | ||
ec6d2bb8 KH |
1950 | case '0': case '2': case '3': case '4': /* start composition */ |
1951 | DECODE_COMPOSITION_START (c1); | |
b73bfc1c | 1952 | continue; |
4ed46869 | 1953 | |
ec6d2bb8 KH |
1954 | case '1': /* end composition */ |
1955 | DECODE_COMPOSITION_END (c1); | |
b73bfc1c | 1956 | continue; |
4ed46869 KH |
1957 | |
1958 | case '[': /* specification of direction */ | |
d46c5b12 KH |
1959 | if (coding->flags & CODING_FLAG_ISO_NO_DIRECTION) |
1960 | goto label_invalid_code; | |
4ed46869 | 1961 | /* For the moment, nested direction is not supported. |
d46c5b12 | 1962 | So, `coding->mode & CODING_MODE_DIRECTION' zero means |
8ca3766a | 1963 | left-to-right, and nonzero means right-to-left. */ |
4ed46869 KH |
1964 | ONE_MORE_BYTE (c1); |
1965 | switch (c1) | |
1966 | { | |
1967 | case ']': /* end of the current direction */ | |
d46c5b12 | 1968 | coding->mode &= ~CODING_MODE_DIRECTION; |
4ed46869 KH |
1969 | |
1970 | case '0': /* end of the current direction */ | |
1971 | case '1': /* start of left-to-right direction */ | |
1972 | ONE_MORE_BYTE (c1); | |
1973 | if (c1 == ']') | |
d46c5b12 | 1974 | coding->mode &= ~CODING_MODE_DIRECTION; |
4ed46869 | 1975 | else |
d46c5b12 | 1976 | goto label_invalid_code; |
4ed46869 KH |
1977 | break; |
1978 | ||
1979 | case '2': /* start of right-to-left direction */ | |
1980 | ONE_MORE_BYTE (c1); | |
1981 | if (c1 == ']') | |
d46c5b12 | 1982 | coding->mode |= CODING_MODE_DIRECTION; |
4ed46869 | 1983 | else |
d46c5b12 | 1984 | goto label_invalid_code; |
4ed46869 KH |
1985 | break; |
1986 | ||
1987 | default: | |
d46c5b12 | 1988 | goto label_invalid_code; |
4ed46869 | 1989 | } |
b73bfc1c | 1990 | continue; |
4ed46869 KH |
1991 | |
1992 | default: | |
d46c5b12 KH |
1993 | if (! (coding->flags & CODING_FLAG_ISO_DESIGNATION)) |
1994 | goto label_invalid_code; | |
4ed46869 KH |
1995 | if (c1 >= 0x28 && c1 <= 0x2B) |
1996 | { /* designation of DIMENSION1_CHARS94 character set */ | |
1997 | ONE_MORE_BYTE (c2); | |
1998 | DECODE_DESIGNATION (c1 - 0x28, 1, 94, c2); | |
1999 | } | |
2000 | else if (c1 >= 0x2C && c1 <= 0x2F) | |
2001 | { /* designation of DIMENSION1_CHARS96 character set */ | |
2002 | ONE_MORE_BYTE (c2); | |
2003 | DECODE_DESIGNATION (c1 - 0x2C, 1, 96, c2); | |
2004 | } | |
2005 | else | |
b73bfc1c KH |
2006 | goto label_invalid_code; |
2007 | /* We must update these variables now. */ | |
2008 | charset0 = CODING_SPEC_ISO_PLANE_CHARSET (coding, 0); | |
2009 | charset1 = CODING_SPEC_ISO_PLANE_CHARSET (coding, 1); | |
2010 | continue; | |
4ed46869 | 2011 | } |
b73bfc1c | 2012 | } |
4ed46869 | 2013 | |
b73bfc1c KH |
2014 | /* Now we know CHARSET and 1st position code C1 of a character. |
2015 | Produce a multibyte sequence for that character while getting | |
2016 | 2nd position code C2 if necessary. */ | |
2017 | if (CHARSET_DIMENSION (charset) == 2) | |
2018 | { | |
2019 | ONE_MORE_BYTE (c2); | |
2020 | if (c1 < 0x80 ? c2 < 0x20 || c2 >= 0x80 : c2 < 0xA0) | |
2021 | /* C2 is not in a valid range. */ | |
2022 | goto label_invalid_code; | |
4ed46869 | 2023 | } |
b73bfc1c KH |
2024 | c = DECODE_ISO_CHARACTER (charset, c1, c2); |
2025 | EMIT_CHAR (c); | |
4ed46869 KH |
2026 | continue; |
2027 | ||
b73bfc1c KH |
2028 | label_invalid_code: |
2029 | coding->errors++; | |
2030 | if (COMPOSING_P (coding)) | |
2031 | DECODE_COMPOSITION_END ('1'); | |
4ed46869 | 2032 | src = src_base; |
b73bfc1c KH |
2033 | c = *src++; |
2034 | EMIT_CHAR (c); | |
4ed46869 | 2035 | } |
fb88bf2d | 2036 | |
b73bfc1c KH |
2037 | label_end_of_loop: |
2038 | coding->consumed = coding->consumed_char = src_base - source; | |
d46c5b12 | 2039 | coding->produced = dst - destination; |
b73bfc1c | 2040 | return; |
4ed46869 KH |
2041 | } |
2042 | ||
b73bfc1c | 2043 | |
f4dee582 | 2044 | /* ISO2022 encoding stuff. */ |
4ed46869 KH |
2045 | |
2046 | /* | |
f4dee582 | 2047 | It is not enough to say just "ISO2022" on encoding, we have to |
cfb43547 | 2048 | specify more details. In Emacs, each ISO2022 coding system |
4ed46869 | 2049 | variant has the following specifications: |
8ca3766a | 2050 | 1. Initial designation to G0 through G3. |
4ed46869 KH |
2051 | 2. Allows short-form designation? |
2052 | 3. ASCII should be designated to G0 before control characters? | |
2053 | 4. ASCII should be designated to G0 at end of line? | |
2054 | 5. 7-bit environment or 8-bit environment? | |
2055 | 6. Use locking-shift? | |
2056 | 7. Use Single-shift? | |
2057 | And the following two are only for Japanese: | |
2058 | 8. Use ASCII in place of JIS0201-1976-Roman? | |
2059 | 9. Use JISX0208-1983 in place of JISX0208-1978? | |
2060 | These specifications are encoded in `coding->flags' as flag bits | |
2061 | defined by macros CODING_FLAG_ISO_XXX. See `coding.h' for more | |
f4dee582 | 2062 | details. |
4ed46869 KH |
2063 | */ |
2064 | ||
2065 | /* Produce codes (escape sequence) for designating CHARSET to graphic | |
b73bfc1c KH |
2066 | register REG at DST, and increment DST. If <final-char> of CHARSET is |
2067 | '@', 'A', or 'B' and the coding system CODING allows, produce | |
2068 | designation sequence of short-form. */ | |
4ed46869 KH |
2069 | |
2070 | #define ENCODE_DESIGNATION(charset, reg, coding) \ | |
2071 | do { \ | |
2072 | unsigned char final_char = CHARSET_ISO_FINAL_CHAR (charset); \ | |
2073 | char *intermediate_char_94 = "()*+"; \ | |
2074 | char *intermediate_char_96 = ",-./"; \ | |
70c22245 | 2075 | int revision = CODING_SPEC_ISO_REVISION_NUMBER(coding, charset); \ |
b73bfc1c | 2076 | \ |
70c22245 KH |
2077 | if (revision < 255) \ |
2078 | { \ | |
4ed46869 KH |
2079 | *dst++ = ISO_CODE_ESC; \ |
2080 | *dst++ = '&'; \ | |
70c22245 | 2081 | *dst++ = '@' + revision; \ |
4ed46869 | 2082 | } \ |
b73bfc1c | 2083 | *dst++ = ISO_CODE_ESC; \ |
4ed46869 KH |
2084 | if (CHARSET_DIMENSION (charset) == 1) \ |
2085 | { \ | |
2086 | if (CHARSET_CHARS (charset) == 94) \ | |
2087 | *dst++ = (unsigned char) (intermediate_char_94[reg]); \ | |
2088 | else \ | |
2089 | *dst++ = (unsigned char) (intermediate_char_96[reg]); \ | |
2090 | } \ | |
2091 | else \ | |
2092 | { \ | |
2093 | *dst++ = '$'; \ | |
2094 | if (CHARSET_CHARS (charset) == 94) \ | |
2095 | { \ | |
b73bfc1c KH |
2096 | if (! (coding->flags & CODING_FLAG_ISO_SHORT_FORM) \ |
2097 | || reg != 0 \ | |
2098 | || final_char < '@' || final_char > 'B') \ | |
4ed46869 KH |
2099 | *dst++ = (unsigned char) (intermediate_char_94[reg]); \ |
2100 | } \ | |
2101 | else \ | |
b73bfc1c | 2102 | *dst++ = (unsigned char) (intermediate_char_96[reg]); \ |
4ed46869 | 2103 | } \ |
b73bfc1c | 2104 | *dst++ = final_char; \ |
4ed46869 KH |
2105 | CODING_SPEC_ISO_DESIGNATION (coding, reg) = charset; \ |
2106 | } while (0) | |
2107 | ||
2108 | /* The following two macros produce codes (control character or escape | |
2109 | sequence) for ISO2022 single-shift functions (single-shift-2 and | |
2110 | single-shift-3). */ | |
2111 | ||
2112 | #define ENCODE_SINGLE_SHIFT_2 \ | |
2113 | do { \ | |
2114 | if (coding->flags & CODING_FLAG_ISO_SEVEN_BITS) \ | |
2115 | *dst++ = ISO_CODE_ESC, *dst++ = 'N'; \ | |
2116 | else \ | |
b73bfc1c | 2117 | *dst++ = ISO_CODE_SS2; \ |
4ed46869 KH |
2118 | CODING_SPEC_ISO_SINGLE_SHIFTING (coding) = 1; \ |
2119 | } while (0) | |
2120 | ||
fb88bf2d KH |
2121 | #define ENCODE_SINGLE_SHIFT_3 \ |
2122 | do { \ | |
4ed46869 | 2123 | if (coding->flags & CODING_FLAG_ISO_SEVEN_BITS) \ |
fb88bf2d KH |
2124 | *dst++ = ISO_CODE_ESC, *dst++ = 'O'; \ |
2125 | else \ | |
b73bfc1c | 2126 | *dst++ = ISO_CODE_SS3; \ |
4ed46869 KH |
2127 | CODING_SPEC_ISO_SINGLE_SHIFTING (coding) = 1; \ |
2128 | } while (0) | |
2129 | ||
2130 | /* The following four macros produce codes (control character or | |
2131 | escape sequence) for ISO2022 locking-shift functions (shift-in, | |
2132 | shift-out, locking-shift-2, and locking-shift-3). */ | |
2133 | ||
b73bfc1c KH |
2134 | #define ENCODE_SHIFT_IN \ |
2135 | do { \ | |
2136 | *dst++ = ISO_CODE_SI; \ | |
4ed46869 KH |
2137 | CODING_SPEC_ISO_INVOCATION (coding, 0) = 0; \ |
2138 | } while (0) | |
2139 | ||
b73bfc1c KH |
2140 | #define ENCODE_SHIFT_OUT \ |
2141 | do { \ | |
2142 | *dst++ = ISO_CODE_SO; \ | |
4ed46869 KH |
2143 | CODING_SPEC_ISO_INVOCATION (coding, 0) = 1; \ |
2144 | } while (0) | |
2145 | ||
2146 | #define ENCODE_LOCKING_SHIFT_2 \ | |
2147 | do { \ | |
2148 | *dst++ = ISO_CODE_ESC, *dst++ = 'n'; \ | |
2149 | CODING_SPEC_ISO_INVOCATION (coding, 0) = 2; \ | |
2150 | } while (0) | |
2151 | ||
b73bfc1c KH |
2152 | #define ENCODE_LOCKING_SHIFT_3 \ |
2153 | do { \ | |
2154 | *dst++ = ISO_CODE_ESC, *dst++ = 'o'; \ | |
4ed46869 KH |
2155 | CODING_SPEC_ISO_INVOCATION (coding, 0) = 3; \ |
2156 | } while (0) | |
2157 | ||
f4dee582 RS |
2158 | /* Produce codes for a DIMENSION1 character whose character set is |
2159 | CHARSET and whose position-code is C1. Designation and invocation | |
4ed46869 KH |
2160 | sequences are also produced in advance if necessary. */ |
2161 | ||
6e85d753 KH |
2162 | #define ENCODE_ISO_CHARACTER_DIMENSION1(charset, c1) \ |
2163 | do { \ | |
2164 | if (CODING_SPEC_ISO_SINGLE_SHIFTING (coding)) \ | |
2165 | { \ | |
2166 | if (coding->flags & CODING_FLAG_ISO_SEVEN_BITS) \ | |
2167 | *dst++ = c1 & 0x7F; \ | |
2168 | else \ | |
2169 | *dst++ = c1 | 0x80; \ | |
2170 | CODING_SPEC_ISO_SINGLE_SHIFTING (coding) = 0; \ | |
2171 | break; \ | |
2172 | } \ | |
2173 | else if (charset == CODING_SPEC_ISO_PLANE_CHARSET (coding, 0)) \ | |
2174 | { \ | |
2175 | *dst++ = c1 & 0x7F; \ | |
2176 | break; \ | |
2177 | } \ | |
2178 | else if (charset == CODING_SPEC_ISO_PLANE_CHARSET (coding, 1)) \ | |
2179 | { \ | |
2180 | *dst++ = c1 | 0x80; \ | |
2181 | break; \ | |
2182 | } \ | |
6e85d753 KH |
2183 | else \ |
2184 | /* Since CHARSET is not yet invoked to any graphic planes, we \ | |
2185 | must invoke it, or, at first, designate it to some graphic \ | |
2186 | register. Then repeat the loop to actually produce the \ | |
2187 | character. */ \ | |
2188 | dst = encode_invocation_designation (charset, coding, dst); \ | |
4ed46869 KH |
2189 | } while (1) |
2190 | ||
f4dee582 RS |
2191 | /* Produce codes for a DIMENSION2 character whose character set is |
2192 | CHARSET and whose position-codes are C1 and C2. Designation and | |
4ed46869 KH |
2193 | invocation codes are also produced in advance if necessary. */ |
2194 | ||
6e85d753 KH |
2195 | #define ENCODE_ISO_CHARACTER_DIMENSION2(charset, c1, c2) \ |
2196 | do { \ | |
2197 | if (CODING_SPEC_ISO_SINGLE_SHIFTING (coding)) \ | |
2198 | { \ | |
2199 | if (coding->flags & CODING_FLAG_ISO_SEVEN_BITS) \ | |
2200 | *dst++ = c1 & 0x7F, *dst++ = c2 & 0x7F; \ | |
2201 | else \ | |
2202 | *dst++ = c1 | 0x80, *dst++ = c2 | 0x80; \ | |
2203 | CODING_SPEC_ISO_SINGLE_SHIFTING (coding) = 0; \ | |
2204 | break; \ | |
2205 | } \ | |
2206 | else if (charset == CODING_SPEC_ISO_PLANE_CHARSET (coding, 0)) \ | |
2207 | { \ | |
2208 | *dst++ = c1 & 0x7F, *dst++= c2 & 0x7F; \ | |
2209 | break; \ | |
2210 | } \ | |
2211 | else if (charset == CODING_SPEC_ISO_PLANE_CHARSET (coding, 1)) \ | |
2212 | { \ | |
2213 | *dst++ = c1 | 0x80, *dst++= c2 | 0x80; \ | |
2214 | break; \ | |
2215 | } \ | |
6e85d753 KH |
2216 | else \ |
2217 | /* Since CHARSET is not yet invoked to any graphic planes, we \ | |
2218 | must invoke it, or, at first, designate it to some graphic \ | |
2219 | register. Then repeat the loop to actually produce the \ | |
2220 | character. */ \ | |
2221 | dst = encode_invocation_designation (charset, coding, dst); \ | |
4ed46869 KH |
2222 | } while (1) |
2223 | ||
05e6f5dc KH |
2224 | #define ENCODE_ISO_CHARACTER(c) \ |
2225 | do { \ | |
2226 | int charset, c1, c2; \ | |
2227 | \ | |
2228 | SPLIT_CHAR (c, charset, c1, c2); \ | |
2229 | if (CHARSET_DEFINED_P (charset)) \ | |
2230 | { \ | |
2231 | if (CHARSET_DIMENSION (charset) == 1) \ | |
2232 | { \ | |
2233 | if (charset == CHARSET_ASCII \ | |
2234 | && coding->flags & CODING_FLAG_ISO_USE_ROMAN) \ | |
2235 | charset = charset_latin_jisx0201; \ | |
2236 | ENCODE_ISO_CHARACTER_DIMENSION1 (charset, c1); \ | |
2237 | } \ | |
2238 | else \ | |
2239 | { \ | |
2240 | if (charset == charset_jisx0208 \ | |
2241 | && coding->flags & CODING_FLAG_ISO_USE_OLDJIS) \ | |
2242 | charset = charset_jisx0208_1978; \ | |
2243 | ENCODE_ISO_CHARACTER_DIMENSION2 (charset, c1, c2); \ | |
2244 | } \ | |
2245 | } \ | |
2246 | else \ | |
2247 | { \ | |
2248 | *dst++ = c1; \ | |
2249 | if (c2 >= 0) \ | |
2250 | *dst++ = c2; \ | |
2251 | } \ | |
2252 | } while (0) | |
2253 | ||
2254 | ||
2255 | /* Instead of encoding character C, produce one or two `?'s. */ | |
2256 | ||
2257 | #define ENCODE_UNSAFE_CHARACTER(c) \ | |
6f551029 | 2258 | do { \ |
05e6f5dc KH |
2259 | ENCODE_ISO_CHARACTER (CODING_INHIBIT_CHARACTER_SUBSTITUTION); \ |
2260 | if (CHARSET_WIDTH (CHAR_CHARSET (c)) > 1) \ | |
2261 | ENCODE_ISO_CHARACTER (CODING_INHIBIT_CHARACTER_SUBSTITUTION); \ | |
84fbb8a0 | 2262 | } while (0) |
bdd9fb48 | 2263 | |
05e6f5dc | 2264 | |
4ed46869 KH |
2265 | /* Produce designation and invocation codes at a place pointed by DST |
2266 | to use CHARSET. The element `spec.iso2022' of *CODING is updated. | |
2267 | Return new DST. */ | |
2268 | ||
2269 | unsigned char * | |
2270 | encode_invocation_designation (charset, coding, dst) | |
2271 | int charset; | |
2272 | struct coding_system *coding; | |
2273 | unsigned char *dst; | |
2274 | { | |
2275 | int reg; /* graphic register number */ | |
2276 | ||
2277 | /* At first, check designations. */ | |
2278 | for (reg = 0; reg < 4; reg++) | |
2279 | if (charset == CODING_SPEC_ISO_DESIGNATION (coding, reg)) | |
2280 | break; | |
2281 | ||
2282 | if (reg >= 4) | |
2283 | { | |
2284 | /* CHARSET is not yet designated to any graphic registers. */ | |
2285 | /* At first check the requested designation. */ | |
2286 | reg = CODING_SPEC_ISO_REQUESTED_DESIGNATION (coding, charset); | |
1ba9e4ab KH |
2287 | if (reg == CODING_SPEC_ISO_NO_REQUESTED_DESIGNATION) |
2288 | /* Since CHARSET requests no special designation, designate it | |
2289 | to graphic register 0. */ | |
4ed46869 KH |
2290 | reg = 0; |
2291 | ||
2292 | ENCODE_DESIGNATION (charset, reg, coding); | |
2293 | } | |
2294 | ||
2295 | if (CODING_SPEC_ISO_INVOCATION (coding, 0) != reg | |
2296 | && CODING_SPEC_ISO_INVOCATION (coding, 1) != reg) | |
2297 | { | |
2298 | /* Since the graphic register REG is not invoked to any graphic | |
2299 | planes, invoke it to graphic plane 0. */ | |
2300 | switch (reg) | |
2301 | { | |
2302 | case 0: /* graphic register 0 */ | |
2303 | ENCODE_SHIFT_IN; | |
2304 | break; | |
2305 | ||
2306 | case 1: /* graphic register 1 */ | |
2307 | ENCODE_SHIFT_OUT; | |
2308 | break; | |
2309 | ||
2310 | case 2: /* graphic register 2 */ | |
2311 | if (coding->flags & CODING_FLAG_ISO_SINGLE_SHIFT) | |
2312 | ENCODE_SINGLE_SHIFT_2; | |
2313 | else | |
2314 | ENCODE_LOCKING_SHIFT_2; | |
2315 | break; | |
2316 | ||
2317 | case 3: /* graphic register 3 */ | |
2318 | if (coding->flags & CODING_FLAG_ISO_SINGLE_SHIFT) | |
2319 | ENCODE_SINGLE_SHIFT_3; | |
2320 | else | |
2321 | ENCODE_LOCKING_SHIFT_3; | |
2322 | break; | |
2323 | } | |
2324 | } | |
b73bfc1c | 2325 | |
4ed46869 KH |
2326 | return dst; |
2327 | } | |
2328 | ||
ec6d2bb8 KH |
2329 | /* Produce 2-byte codes for encoded composition rule RULE. */ |
2330 | ||
2331 | #define ENCODE_COMPOSITION_RULE(rule) \ | |
2332 | do { \ | |
2333 | int gref, nref; \ | |
2334 | COMPOSITION_DECODE_RULE (rule, gref, nref); \ | |
2335 | *dst++ = 32 + 81 + gref; \ | |
2336 | *dst++ = 32 + nref; \ | |
2337 | } while (0) | |
2338 | ||
2339 | /* Produce codes for indicating the start of a composition sequence | |
2340 | (ESC 0, ESC 3, or ESC 4). DATA points to an array of integers | |
2341 | which specify information about the composition. See the comment | |
2342 | in coding.h for the format of DATA. */ | |
2343 | ||
2344 | #define ENCODE_COMPOSITION_START(coding, data) \ | |
2345 | do { \ | |
2346 | coding->composing = data[3]; \ | |
2347 | *dst++ = ISO_CODE_ESC; \ | |
2348 | if (coding->composing == COMPOSITION_RELATIVE) \ | |
2349 | *dst++ = '0'; \ | |
2350 | else \ | |
2351 | { \ | |
2352 | *dst++ = (coding->composing == COMPOSITION_WITH_ALTCHARS \ | |
2353 | ? '3' : '4'); \ | |
2354 | coding->cmp_data_index = coding->cmp_data_start + 4; \ | |
2355 | coding->composition_rule_follows = 0; \ | |
2356 | } \ | |
2357 | } while (0) | |
2358 | ||
2359 | /* Produce codes for indicating the end of the current composition. */ | |
2360 | ||
2361 | #define ENCODE_COMPOSITION_END(coding, data) \ | |
2362 | do { \ | |
2363 | *dst++ = ISO_CODE_ESC; \ | |
2364 | *dst++ = '1'; \ | |
2365 | coding->cmp_data_start += data[0]; \ | |
2366 | coding->composing = COMPOSITION_NO; \ | |
2367 | if (coding->cmp_data_start == coding->cmp_data->used \ | |
2368 | && coding->cmp_data->next) \ | |
2369 | { \ | |
2370 | coding->cmp_data = coding->cmp_data->next; \ | |
2371 | coding->cmp_data_start = 0; \ | |
2372 | } \ | |
2373 | } while (0) | |
2374 | ||
2375 | /* Produce composition start sequence ESC 0. Here, this sequence | |
2376 | doesn't mean the start of a new composition but means that we have | |
2377 | just produced components (alternate chars and composition rules) of | |
2378 | the composition and the actual text follows in SRC. */ | |
2379 | ||
2380 | #define ENCODE_COMPOSITION_FAKE_START(coding) \ | |
2381 | do { \ | |
2382 | *dst++ = ISO_CODE_ESC; \ | |
2383 | *dst++ = '0'; \ | |
2384 | coding->composing = COMPOSITION_RELATIVE; \ | |
2385 | } while (0) | |
4ed46869 KH |
2386 | |
2387 | /* The following three macros produce codes for indicating direction | |
2388 | of text. */ | |
b73bfc1c KH |
2389 | #define ENCODE_CONTROL_SEQUENCE_INTRODUCER \ |
2390 | do { \ | |
4ed46869 | 2391 | if (coding->flags == CODING_FLAG_ISO_SEVEN_BITS) \ |
b73bfc1c KH |
2392 | *dst++ = ISO_CODE_ESC, *dst++ = '['; \ |
2393 | else \ | |
2394 | *dst++ = ISO_CODE_CSI; \ | |
4ed46869 KH |
2395 | } while (0) |
2396 | ||
2397 | #define ENCODE_DIRECTION_R2L \ | |
b73bfc1c | 2398 | ENCODE_CONTROL_SEQUENCE_INTRODUCER (dst), *dst++ = '2', *dst++ = ']' |
4ed46869 KH |
2399 | |
2400 | #define ENCODE_DIRECTION_L2R \ | |
b73bfc1c | 2401 | ENCODE_CONTROL_SEQUENCE_INTRODUCER (dst), *dst++ = '0', *dst++ = ']' |
4ed46869 KH |
2402 | |
2403 | /* Produce codes for designation and invocation to reset the graphic | |
2404 | planes and registers to initial state. */ | |
e0e989f6 KH |
2405 | #define ENCODE_RESET_PLANE_AND_REGISTER \ |
2406 | do { \ | |
2407 | int reg; \ | |
2408 | if (CODING_SPEC_ISO_INVOCATION (coding, 0) != 0) \ | |
2409 | ENCODE_SHIFT_IN; \ | |
2410 | for (reg = 0; reg < 4; reg++) \ | |
2411 | if (CODING_SPEC_ISO_INITIAL_DESIGNATION (coding, reg) >= 0 \ | |
2412 | && (CODING_SPEC_ISO_DESIGNATION (coding, reg) \ | |
2413 | != CODING_SPEC_ISO_INITIAL_DESIGNATION (coding, reg))) \ | |
2414 | ENCODE_DESIGNATION \ | |
2415 | (CODING_SPEC_ISO_INITIAL_DESIGNATION (coding, reg), reg, coding); \ | |
4ed46869 KH |
2416 | } while (0) |
2417 | ||
bdd9fb48 | 2418 | /* Produce designation sequences of charsets in the line started from |
b73bfc1c | 2419 | SRC to a place pointed by DST, and return updated DST. |
bdd9fb48 KH |
2420 | |
2421 | If the current block ends before any end-of-line, we may fail to | |
d46c5b12 KH |
2422 | find all the necessary designations. */ |
2423 | ||
b73bfc1c KH |
2424 | static unsigned char * |
2425 | encode_designation_at_bol (coding, translation_table, src, src_end, dst) | |
e0e989f6 | 2426 | struct coding_system *coding; |
b73bfc1c KH |
2427 | Lisp_Object translation_table; |
2428 | unsigned char *src, *src_end, *dst; | |
e0e989f6 | 2429 | { |
bdd9fb48 KH |
2430 | int charset, c, found = 0, reg; |
2431 | /* Table of charsets to be designated to each graphic register. */ | |
2432 | int r[4]; | |
bdd9fb48 KH |
2433 | |
2434 | for (reg = 0; reg < 4; reg++) | |
2435 | r[reg] = -1; | |
2436 | ||
b73bfc1c | 2437 | while (found < 4) |
e0e989f6 | 2438 | { |
b73bfc1c KH |
2439 | ONE_MORE_CHAR (c); |
2440 | if (c == '\n') | |
2441 | break; | |
bdd9fb48 | 2442 | |
b73bfc1c | 2443 | charset = CHAR_CHARSET (c); |
e0e989f6 | 2444 | reg = CODING_SPEC_ISO_REQUESTED_DESIGNATION (coding, charset); |
d46c5b12 | 2445 | if (reg != CODING_SPEC_ISO_NO_REQUESTED_DESIGNATION && r[reg] < 0) |
bdd9fb48 KH |
2446 | { |
2447 | found++; | |
2448 | r[reg] = charset; | |
2449 | } | |
bdd9fb48 KH |
2450 | } |
2451 | ||
b73bfc1c | 2452 | label_end_of_loop: |
bdd9fb48 KH |
2453 | if (found) |
2454 | { | |
2455 | for (reg = 0; reg < 4; reg++) | |
2456 | if (r[reg] >= 0 | |
2457 | && CODING_SPEC_ISO_DESIGNATION (coding, reg) != r[reg]) | |
2458 | ENCODE_DESIGNATION (r[reg], reg, coding); | |
e0e989f6 | 2459 | } |
b73bfc1c KH |
2460 | |
2461 | return dst; | |
e0e989f6 KH |
2462 | } |
2463 | ||
4ed46869 KH |
2464 | /* See the above "GENERAL NOTES on `encode_coding_XXX ()' functions". */ |
2465 | ||
b73bfc1c | 2466 | static void |
d46c5b12 | 2467 | encode_coding_iso2022 (coding, source, destination, src_bytes, dst_bytes) |
4ed46869 KH |
2468 | struct coding_system *coding; |
2469 | unsigned char *source, *destination; | |
2470 | int src_bytes, dst_bytes; | |
4ed46869 KH |
2471 | { |
2472 | unsigned char *src = source; | |
2473 | unsigned char *src_end = source + src_bytes; | |
2474 | unsigned char *dst = destination; | |
2475 | unsigned char *dst_end = destination + dst_bytes; | |
b73bfc1c | 2476 | /* Since the maximum bytes produced by each loop is 20, we subtract 19 |
4ed46869 KH |
2477 | from DST_END to assure overflow checking is necessary only at the |
2478 | head of loop. */ | |
b73bfc1c KH |
2479 | unsigned char *adjusted_dst_end = dst_end - 19; |
2480 | /* SRC_BASE remembers the start position in source in each loop. | |
2481 | The loop will be exited when there's not enough source text to | |
2482 | analyze multi-byte codes (within macro ONE_MORE_CHAR), or when | |
2483 | there's not enough destination area to produce encoded codes | |
2484 | (within macro EMIT_BYTES). */ | |
2485 | unsigned char *src_base; | |
2486 | int c; | |
2487 | Lisp_Object translation_table; | |
05e6f5dc KH |
2488 | Lisp_Object safe_chars; |
2489 | ||
2490 | safe_chars = coding_safe_chars (coding); | |
bdd9fb48 | 2491 | |
b73bfc1c KH |
2492 | if (NILP (Venable_character_translation)) |
2493 | translation_table = Qnil; | |
2494 | else | |
2495 | { | |
2496 | translation_table = coding->translation_table_for_encode; | |
2497 | if (NILP (translation_table)) | |
2498 | translation_table = Vstandard_translation_table_for_encode; | |
2499 | } | |
4ed46869 | 2500 | |
d46c5b12 | 2501 | coding->consumed_char = 0; |
b73bfc1c KH |
2502 | coding->errors = 0; |
2503 | while (1) | |
4ed46869 | 2504 | { |
b73bfc1c KH |
2505 | src_base = src; |
2506 | ||
2507 | if (dst >= (dst_bytes ? adjusted_dst_end : (src - 19))) | |
2508 | { | |
2509 | coding->result = CODING_FINISH_INSUFFICIENT_DST; | |
2510 | break; | |
2511 | } | |
4ed46869 | 2512 | |
e0e989f6 KH |
2513 | if (coding->flags & CODING_FLAG_ISO_DESIGNATE_AT_BOL |
2514 | && CODING_SPEC_ISO_BOL (coding)) | |
2515 | { | |
bdd9fb48 | 2516 | /* We have to produce designation sequences if any now. */ |
b73bfc1c KH |
2517 | dst = encode_designation_at_bol (coding, translation_table, |
2518 | src, src_end, dst); | |
e0e989f6 KH |
2519 | CODING_SPEC_ISO_BOL (coding) = 0; |
2520 | } | |
2521 | ||
ec6d2bb8 KH |
2522 | /* Check composition start and end. */ |
2523 | if (coding->composing != COMPOSITION_DISABLED | |
2524 | && coding->cmp_data_start < coding->cmp_data->used) | |
4ed46869 | 2525 | { |
ec6d2bb8 KH |
2526 | struct composition_data *cmp_data = coding->cmp_data; |
2527 | int *data = cmp_data->data + coding->cmp_data_start; | |
2528 | int this_pos = cmp_data->char_offset + coding->consumed_char; | |
2529 | ||
2530 | if (coding->composing == COMPOSITION_RELATIVE) | |
4ed46869 | 2531 | { |
ec6d2bb8 KH |
2532 | if (this_pos == data[2]) |
2533 | { | |
2534 | ENCODE_COMPOSITION_END (coding, data); | |
2535 | cmp_data = coding->cmp_data; | |
2536 | data = cmp_data->data + coding->cmp_data_start; | |
2537 | } | |
4ed46869 | 2538 | } |
ec6d2bb8 | 2539 | else if (COMPOSING_P (coding)) |
4ed46869 | 2540 | { |
ec6d2bb8 KH |
2541 | /* COMPOSITION_WITH_ALTCHARS or COMPOSITION_WITH_RULE_ALTCHAR */ |
2542 | if (coding->cmp_data_index == coding->cmp_data_start + data[0]) | |
2543 | /* We have consumed components of the composition. | |
8ca3766a | 2544 | What follows in SRC is the composition's base |
ec6d2bb8 KH |
2545 | text. */ |
2546 | ENCODE_COMPOSITION_FAKE_START (coding); | |
2547 | else | |
4ed46869 | 2548 | { |
ec6d2bb8 KH |
2549 | int c = cmp_data->data[coding->cmp_data_index++]; |
2550 | if (coding->composition_rule_follows) | |
2551 | { | |
2552 | ENCODE_COMPOSITION_RULE (c); | |
2553 | coding->composition_rule_follows = 0; | |
2554 | } | |
2555 | else | |
2556 | { | |
05e6f5dc KH |
2557 | if (coding->flags & CODING_FLAG_ISO_SAFE |
2558 | && ! CODING_SAFE_CHAR_P (safe_chars, c)) | |
2559 | ENCODE_UNSAFE_CHARACTER (c); | |
2560 | else | |
2561 | ENCODE_ISO_CHARACTER (c); | |
ec6d2bb8 KH |
2562 | if (coding->composing == COMPOSITION_WITH_RULE_ALTCHARS) |
2563 | coding->composition_rule_follows = 1; | |
2564 | } | |
4ed46869 KH |
2565 | continue; |
2566 | } | |
ec6d2bb8 KH |
2567 | } |
2568 | if (!COMPOSING_P (coding)) | |
2569 | { | |
2570 | if (this_pos == data[1]) | |
4ed46869 | 2571 | { |
ec6d2bb8 KH |
2572 | ENCODE_COMPOSITION_START (coding, data); |
2573 | continue; | |
4ed46869 | 2574 | } |
4ed46869 KH |
2575 | } |
2576 | } | |
ec6d2bb8 | 2577 | |
b73bfc1c | 2578 | ONE_MORE_CHAR (c); |
4ed46869 | 2579 | |
b73bfc1c KH |
2580 | /* Now encode the character C. */ |
2581 | if (c < 0x20 || c == 0x7F) | |
2582 | { | |
2583 | if (c == '\r') | |
19a8d9e0 | 2584 | { |
b73bfc1c KH |
2585 | if (! (coding->mode & CODING_MODE_SELECTIVE_DISPLAY)) |
2586 | { | |
2587 | if (coding->flags & CODING_FLAG_ISO_RESET_AT_CNTL) | |
2588 | ENCODE_RESET_PLANE_AND_REGISTER; | |
2589 | *dst++ = c; | |
2590 | continue; | |
2591 | } | |
2592 | /* fall down to treat '\r' as '\n' ... */ | |
2593 | c = '\n'; | |
19a8d9e0 | 2594 | } |
b73bfc1c | 2595 | if (c == '\n') |
19a8d9e0 | 2596 | { |
b73bfc1c KH |
2597 | if (coding->flags & CODING_FLAG_ISO_RESET_AT_EOL) |
2598 | ENCODE_RESET_PLANE_AND_REGISTER; | |
2599 | if (coding->flags & CODING_FLAG_ISO_INIT_AT_BOL) | |
2600 | bcopy (coding->spec.iso2022.initial_designation, | |
2601 | coding->spec.iso2022.current_designation, | |
2602 | sizeof coding->spec.iso2022.initial_designation); | |
2603 | if (coding->eol_type == CODING_EOL_LF | |
2604 | || coding->eol_type == CODING_EOL_UNDECIDED) | |
2605 | *dst++ = ISO_CODE_LF; | |
2606 | else if (coding->eol_type == CODING_EOL_CRLF) | |
2607 | *dst++ = ISO_CODE_CR, *dst++ = ISO_CODE_LF; | |
2608 | else | |
2609 | *dst++ = ISO_CODE_CR; | |
2610 | CODING_SPEC_ISO_BOL (coding) = 1; | |
19a8d9e0 | 2611 | } |
b73bfc1c | 2612 | else |
19a8d9e0 | 2613 | { |
b73bfc1c KH |
2614 | if (coding->flags & CODING_FLAG_ISO_RESET_AT_CNTL) |
2615 | ENCODE_RESET_PLANE_AND_REGISTER; | |
2616 | *dst++ = c; | |
19a8d9e0 | 2617 | } |
4ed46869 | 2618 | } |
b73bfc1c | 2619 | else if (ASCII_BYTE_P (c)) |
05e6f5dc | 2620 | ENCODE_ISO_CHARACTER (c); |
b73bfc1c | 2621 | else if (SINGLE_BYTE_CHAR_P (c)) |
88993dfd | 2622 | { |
b73bfc1c KH |
2623 | *dst++ = c; |
2624 | coding->errors++; | |
88993dfd | 2625 | } |
05e6f5dc KH |
2626 | else if (coding->flags & CODING_FLAG_ISO_SAFE |
2627 | && ! CODING_SAFE_CHAR_P (safe_chars, c)) | |
2628 | ENCODE_UNSAFE_CHARACTER (c); | |
b73bfc1c | 2629 | else |
05e6f5dc | 2630 | ENCODE_ISO_CHARACTER (c); |
b73bfc1c KH |
2631 | |
2632 | coding->consumed_char++; | |
84fbb8a0 | 2633 | } |
b73bfc1c KH |
2634 | |
2635 | label_end_of_loop: | |
2636 | coding->consumed = src_base - source; | |
d46c5b12 | 2637 | coding->produced = coding->produced_char = dst - destination; |
4ed46869 KH |
2638 | } |
2639 | ||
2640 | \f | |
2641 | /*** 4. SJIS and BIG5 handlers ***/ | |
2642 | ||
cfb43547 | 2643 | /* Although SJIS and BIG5 are not ISO coding systems, they are used |
4ed46869 KH |
2644 | quite widely. So, for the moment, Emacs supports them in the bare |
2645 | C code. But, in the future, they may be supported only by CCL. */ | |
2646 | ||
2647 | /* SJIS is a coding system encoding three character sets: ASCII, right | |
2648 | half of JISX0201-Kana, and JISX0208. An ASCII character is encoded | |
2649 | as is. A character of charset katakana-jisx0201 is encoded by | |
2650 | "position-code + 0x80". A character of charset japanese-jisx0208 | |
2651 | is encoded in 2-byte but two position-codes are divided and shifted | |
cfb43547 | 2652 | so that it fits in the range below. |
4ed46869 KH |
2653 | |
2654 | --- CODE RANGE of SJIS --- | |
2655 | (character set) (range) | |
2656 | ASCII 0x00 .. 0x7F | |
682169fe | 2657 | KATAKANA-JISX0201 0xA1 .. 0xDF |
c28a9453 | 2658 | JISX0208 (1st byte) 0x81 .. 0x9F and 0xE0 .. 0xEF |
d14d03ac | 2659 | (2nd byte) 0x40 .. 0x7E and 0x80 .. 0xFC |
4ed46869 KH |
2660 | ------------------------------- |
2661 | ||
2662 | */ | |
2663 | ||
2664 | /* BIG5 is a coding system encoding two character sets: ASCII and | |
2665 | Big5. An ASCII character is encoded as is. Big5 is a two-byte | |
cfb43547 | 2666 | character set and is encoded in two bytes. |
4ed46869 KH |
2667 | |
2668 | --- CODE RANGE of BIG5 --- | |
2669 | (character set) (range) | |
2670 | ASCII 0x00 .. 0x7F | |
2671 | Big5 (1st byte) 0xA1 .. 0xFE | |
2672 | (2nd byte) 0x40 .. 0x7E and 0xA1 .. 0xFE | |
2673 | -------------------------- | |
2674 | ||
2675 | Since the number of characters in Big5 is larger than maximum | |
2676 | characters in Emacs' charset (96x96), it can't be handled as one | |
2677 | charset. So, in Emacs, Big5 is divided into two: `charset-big5-1' | |
2678 | and `charset-big5-2'. Both are DIMENSION2 and CHARS94. The former | |
2679 | contains frequently used characters and the latter contains less | |
2680 | frequently used characters. */ | |
2681 | ||
2682 | /* Macros to decode or encode a character of Big5 in BIG5. B1 and B2 | |
2683 | are the 1st and 2nd position-codes of Big5 in BIG5 coding system. | |
2684 | C1 and C2 are the 1st and 2nd position-codes of of Emacs' internal | |
2685 | format. CHARSET is `charset_big5_1' or `charset_big5_2'. */ | |
2686 | ||
2687 | /* Number of Big5 characters which have the same code in 1st byte. */ | |
2688 | #define BIG5_SAME_ROW (0xFF - 0xA1 + 0x7F - 0x40) | |
2689 | ||
2690 | #define DECODE_BIG5(b1, b2, charset, c1, c2) \ | |
2691 | do { \ | |
2692 | unsigned int temp \ | |
2693 | = (b1 - 0xA1) * BIG5_SAME_ROW + b2 - (b2 < 0x7F ? 0x40 : 0x62); \ | |
2694 | if (b1 < 0xC9) \ | |
2695 | charset = charset_big5_1; \ | |
2696 | else \ | |
2697 | { \ | |
2698 | charset = charset_big5_2; \ | |
2699 | temp -= (0xC9 - 0xA1) * BIG5_SAME_ROW; \ | |
2700 | } \ | |
2701 | c1 = temp / (0xFF - 0xA1) + 0x21; \ | |
2702 | c2 = temp % (0xFF - 0xA1) + 0x21; \ | |
2703 | } while (0) | |
2704 | ||
2705 | #define ENCODE_BIG5(charset, c1, c2, b1, b2) \ | |
2706 | do { \ | |
2707 | unsigned int temp = (c1 - 0x21) * (0xFF - 0xA1) + (c2 - 0x21); \ | |
2708 | if (charset == charset_big5_2) \ | |
2709 | temp += BIG5_SAME_ROW * (0xC9 - 0xA1); \ | |
2710 | b1 = temp / BIG5_SAME_ROW + 0xA1; \ | |
2711 | b2 = temp % BIG5_SAME_ROW; \ | |
2712 | b2 += b2 < 0x3F ? 0x40 : 0x62; \ | |
2713 | } while (0) | |
2714 | ||
2715 | /* See the above "GENERAL NOTES on `detect_coding_XXX ()' functions". | |
2716 | Check if a text is encoded in SJIS. If it is, return | |
2717 | CODING_CATEGORY_MASK_SJIS, else return 0. */ | |
2718 | ||
0a28aafb KH |
2719 | static int |
2720 | detect_coding_sjis (src, src_end, multibytep) | |
4ed46869 | 2721 | unsigned char *src, *src_end; |
0a28aafb | 2722 | int multibytep; |
4ed46869 | 2723 | { |
b73bfc1c KH |
2724 | int c; |
2725 | /* Dummy for ONE_MORE_BYTE. */ | |
2726 | struct coding_system dummy_coding; | |
2727 | struct coding_system *coding = &dummy_coding; | |
4ed46869 | 2728 | |
b73bfc1c | 2729 | while (1) |
4ed46869 | 2730 | { |
0a28aafb | 2731 | ONE_MORE_BYTE_CHECK_MULTIBYTE (c, multibytep); |
682169fe KH |
2732 | if (c < 0x80) |
2733 | continue; | |
2734 | if (c == 0x80 || c == 0xA0 || c > 0xEF) | |
2735 | return 0; | |
2736 | if (c <= 0x9F || c >= 0xE0) | |
4ed46869 | 2737 | { |
682169fe KH |
2738 | ONE_MORE_BYTE_CHECK_MULTIBYTE (c, multibytep); |
2739 | if (c < 0x40 || c == 0x7F || c > 0xFC) | |
4ed46869 KH |
2740 | return 0; |
2741 | } | |
2742 | } | |
b73bfc1c | 2743 | label_end_of_loop: |
4ed46869 KH |
2744 | return CODING_CATEGORY_MASK_SJIS; |
2745 | } | |
2746 | ||
2747 | /* See the above "GENERAL NOTES on `detect_coding_XXX ()' functions". | |
2748 | Check if a text is encoded in BIG5. If it is, return | |
2749 | CODING_CATEGORY_MASK_BIG5, else return 0. */ | |
2750 | ||
0a28aafb KH |
2751 | static int |
2752 | detect_coding_big5 (src, src_end, multibytep) | |
4ed46869 | 2753 | unsigned char *src, *src_end; |
0a28aafb | 2754 | int multibytep; |
4ed46869 | 2755 | { |
b73bfc1c KH |
2756 | int c; |
2757 | /* Dummy for ONE_MORE_BYTE. */ | |
2758 | struct coding_system dummy_coding; | |
2759 | struct coding_system *coding = &dummy_coding; | |
4ed46869 | 2760 | |
b73bfc1c | 2761 | while (1) |
4ed46869 | 2762 | { |
0a28aafb | 2763 | ONE_MORE_BYTE_CHECK_MULTIBYTE (c, multibytep); |
682169fe KH |
2764 | if (c < 0x80) |
2765 | continue; | |
2766 | if (c < 0xA1 || c > 0xFE) | |
2767 | return 0; | |
2768 | ONE_MORE_BYTE_CHECK_MULTIBYTE (c, multibytep); | |
2769 | if (c < 0x40 || (c > 0x7F && c < 0xA1) || c > 0xFE) | |
2770 | return 0; | |
4ed46869 | 2771 | } |
b73bfc1c | 2772 | label_end_of_loop: |
4ed46869 KH |
2773 | return CODING_CATEGORY_MASK_BIG5; |
2774 | } | |
2775 | ||
fa42c37f KH |
2776 | /* See the above "GENERAL NOTES on `detect_coding_XXX ()' functions". |
2777 | Check if a text is encoded in UTF-8. If it is, return | |
2778 | CODING_CATEGORY_MASK_UTF_8, else return 0. */ | |
2779 | ||
2780 | #define UTF_8_1_OCTET_P(c) ((c) < 0x80) | |
2781 | #define UTF_8_EXTRA_OCTET_P(c) (((c) & 0xC0) == 0x80) | |
2782 | #define UTF_8_2_OCTET_LEADING_P(c) (((c) & 0xE0) == 0xC0) | |
2783 | #define UTF_8_3_OCTET_LEADING_P(c) (((c) & 0xF0) == 0xE0) | |
2784 | #define UTF_8_4_OCTET_LEADING_P(c) (((c) & 0xF8) == 0xF0) | |
2785 | #define UTF_8_5_OCTET_LEADING_P(c) (((c) & 0xFC) == 0xF8) | |
2786 | #define UTF_8_6_OCTET_LEADING_P(c) (((c) & 0xFE) == 0xFC) | |
2787 | ||
0a28aafb KH |
2788 | static int |
2789 | detect_coding_utf_8 (src, src_end, multibytep) | |
fa42c37f | 2790 | unsigned char *src, *src_end; |
0a28aafb | 2791 | int multibytep; |
fa42c37f KH |
2792 | { |
2793 | unsigned char c; | |
2794 | int seq_maybe_bytes; | |
b73bfc1c KH |
2795 | /* Dummy for ONE_MORE_BYTE. */ |
2796 | struct coding_system dummy_coding; | |
2797 | struct coding_system *coding = &dummy_coding; | |
fa42c37f | 2798 | |
b73bfc1c | 2799 | while (1) |
fa42c37f | 2800 | { |
0a28aafb | 2801 | ONE_MORE_BYTE_CHECK_MULTIBYTE (c, multibytep); |
fa42c37f KH |
2802 | if (UTF_8_1_OCTET_P (c)) |
2803 | continue; | |
2804 | else if (UTF_8_2_OCTET_LEADING_P (c)) | |
2805 | seq_maybe_bytes = 1; | |
2806 | else if (UTF_8_3_OCTET_LEADING_P (c)) | |
2807 | seq_maybe_bytes = 2; | |
2808 | else if (UTF_8_4_OCTET_LEADING_P (c)) | |
2809 | seq_maybe_bytes = 3; | |
2810 | else if (UTF_8_5_OCTET_LEADING_P (c)) | |
2811 | seq_maybe_bytes = 4; | |
2812 | else if (UTF_8_6_OCTET_LEADING_P (c)) | |
2813 | seq_maybe_bytes = 5; | |
2814 | else | |
2815 | return 0; | |
2816 | ||
2817 | do | |
2818 | { | |
0a28aafb | 2819 | ONE_MORE_BYTE_CHECK_MULTIBYTE (c, multibytep); |
fa42c37f KH |
2820 | if (!UTF_8_EXTRA_OCTET_P (c)) |
2821 | return 0; | |
2822 | seq_maybe_bytes--; | |
2823 | } | |
2824 | while (seq_maybe_bytes > 0); | |
2825 | } | |
2826 | ||
b73bfc1c | 2827 | label_end_of_loop: |
fa42c37f KH |
2828 | return CODING_CATEGORY_MASK_UTF_8; |
2829 | } | |
2830 | ||
2831 | /* See the above "GENERAL NOTES on `detect_coding_XXX ()' functions". | |
2832 | Check if a text is encoded in UTF-16 Big Endian (endian == 1) or | |
2833 | Little Endian (otherwise). If it is, return | |
2834 | CODING_CATEGORY_MASK_UTF_16_BE or CODING_CATEGORY_MASK_UTF_16_LE, | |
2835 | else return 0. */ | |
2836 | ||
2837 | #define UTF_16_INVALID_P(val) \ | |
2838 | (((val) == 0xFFFE) \ | |
2839 | || ((val) == 0xFFFF)) | |
2840 | ||
2841 | #define UTF_16_HIGH_SURROGATE_P(val) \ | |
2842 | (((val) & 0xD800) == 0xD800) | |
2843 | ||
2844 | #define UTF_16_LOW_SURROGATE_P(val) \ | |
2845 | (((val) & 0xDC00) == 0xDC00) | |
2846 | ||
0a28aafb KH |
2847 | static int |
2848 | detect_coding_utf_16 (src, src_end, multibytep) | |
fa42c37f | 2849 | unsigned char *src, *src_end; |
0a28aafb | 2850 | int multibytep; |
fa42c37f | 2851 | { |
b73bfc1c KH |
2852 | unsigned char c1, c2; |
2853 | /* Dummy for TWO_MORE_BYTES. */ | |
2854 | struct coding_system dummy_coding; | |
2855 | struct coding_system *coding = &dummy_coding; | |
fa42c37f | 2856 | |
0a28aafb KH |
2857 | ONE_MORE_BYTE_CHECK_MULTIBYTE (c1, multibytep); |
2858 | ONE_MORE_BYTE_CHECK_MULTIBYTE (c2, multibytep); | |
b73bfc1c KH |
2859 | |
2860 | if ((c1 == 0xFF) && (c2 == 0xFE)) | |
fa42c37f | 2861 | return CODING_CATEGORY_MASK_UTF_16_LE; |
b73bfc1c | 2862 | else if ((c1 == 0xFE) && (c2 == 0xFF)) |
fa42c37f KH |
2863 | return CODING_CATEGORY_MASK_UTF_16_BE; |
2864 | ||
b73bfc1c | 2865 | label_end_of_loop: |
fa42c37f KH |
2866 | return 0; |
2867 | } | |
2868 | ||
4ed46869 KH |
2869 | /* See the above "GENERAL NOTES on `decode_coding_XXX ()' functions". |
2870 | If SJIS_P is 1, decode SJIS text, else decode BIG5 test. */ | |
2871 | ||
b73bfc1c | 2872 | static void |
4ed46869 | 2873 | decode_coding_sjis_big5 (coding, source, destination, |
d46c5b12 | 2874 | src_bytes, dst_bytes, sjis_p) |
4ed46869 KH |
2875 | struct coding_system *coding; |
2876 | unsigned char *source, *destination; | |
2877 | int src_bytes, dst_bytes; | |
4ed46869 KH |
2878 | int sjis_p; |
2879 | { | |
2880 | unsigned char *src = source; | |
2881 | unsigned char *src_end = source + src_bytes; | |
2882 | unsigned char *dst = destination; | |
2883 | unsigned char *dst_end = destination + dst_bytes; | |
b73bfc1c KH |
2884 | /* SRC_BASE remembers the start position in source in each loop. |
2885 | The loop will be exited when there's not enough source code | |
2886 | (within macro ONE_MORE_BYTE), or when there's not enough | |
2887 | destination area to produce a character (within macro | |
2888 | EMIT_CHAR). */ | |
2889 | unsigned char *src_base; | |
2890 | Lisp_Object translation_table; | |
a5d301df | 2891 | |
b73bfc1c KH |
2892 | if (NILP (Venable_character_translation)) |
2893 | translation_table = Qnil; | |
2894 | else | |
2895 | { | |
2896 | translation_table = coding->translation_table_for_decode; | |
2897 | if (NILP (translation_table)) | |
2898 | translation_table = Vstandard_translation_table_for_decode; | |
2899 | } | |
4ed46869 | 2900 | |
d46c5b12 | 2901 | coding->produced_char = 0; |
b73bfc1c | 2902 | while (1) |
4ed46869 | 2903 | { |
b73bfc1c KH |
2904 | int c, charset, c1, c2; |
2905 | ||
2906 | src_base = src; | |
2907 | ONE_MORE_BYTE (c1); | |
2908 | ||
2909 | if (c1 < 0x80) | |
4ed46869 | 2910 | { |
b73bfc1c KH |
2911 | charset = CHARSET_ASCII; |
2912 | if (c1 < 0x20) | |
4ed46869 | 2913 | { |
b73bfc1c | 2914 | if (c1 == '\r') |
d46c5b12 | 2915 | { |
b73bfc1c | 2916 | if (coding->eol_type == CODING_EOL_CRLF) |
d46c5b12 | 2917 | { |
b73bfc1c KH |
2918 | ONE_MORE_BYTE (c2); |
2919 | if (c2 == '\n') | |
2920 | c1 = c2; | |
2921 | else if (coding->mode | |
2922 | & CODING_MODE_INHIBIT_INCONSISTENT_EOL) | |
2923 | { | |
2924 | coding->result = CODING_FINISH_INCONSISTENT_EOL; | |
2925 | goto label_end_of_loop; | |
2926 | } | |
2927 | else | |
2928 | /* To process C2 again, SRC is subtracted by 1. */ | |
2929 | src--; | |
d46c5b12 | 2930 | } |
b73bfc1c KH |
2931 | else if (coding->eol_type == CODING_EOL_CR) |
2932 | c1 = '\n'; | |
2933 | } | |
2934 | else if (c1 == '\n' | |
2935 | && (coding->mode & CODING_MODE_INHIBIT_INCONSISTENT_EOL) | |
2936 | && (coding->eol_type == CODING_EOL_CR | |
2937 | || coding->eol_type == CODING_EOL_CRLF)) | |
2938 | { | |
2939 | coding->result = CODING_FINISH_INCONSISTENT_EOL; | |
2940 | goto label_end_of_loop; | |
d46c5b12 | 2941 | } |
4ed46869 | 2942 | } |
4ed46869 | 2943 | } |
54f78171 | 2944 | else |
b73bfc1c | 2945 | { |
4ed46869 KH |
2946 | if (sjis_p) |
2947 | { | |
682169fe | 2948 | if (c1 == 0x80 || c1 == 0xA0 || c1 > 0xEF) |
b73bfc1c | 2949 | goto label_invalid_code; |
682169fe | 2950 | if (c1 <= 0x9F || c1 >= 0xE0) |
fb88bf2d | 2951 | { |
54f78171 KH |
2952 | /* SJIS -> JISX0208 */ |
2953 | ONE_MORE_BYTE (c2); | |
b73bfc1c KH |
2954 | if (c2 < 0x40 || c2 == 0x7F || c2 > 0xFC) |
2955 | goto label_invalid_code; | |
2956 | DECODE_SJIS (c1, c2, c1, c2); | |
2957 | charset = charset_jisx0208; | |
5e34de15 | 2958 | } |
fb88bf2d | 2959 | else |
b73bfc1c KH |
2960 | /* SJIS -> JISX0201-Kana */ |
2961 | charset = charset_katakana_jisx0201; | |
4ed46869 | 2962 | } |
fb88bf2d | 2963 | else |
fb88bf2d | 2964 | { |
54f78171 | 2965 | /* BIG5 -> Big5 */ |
682169fe | 2966 | if (c1 < 0xA0 || c1 > 0xFE) |
b73bfc1c KH |
2967 | goto label_invalid_code; |
2968 | ONE_MORE_BYTE (c2); | |
2969 | if (c2 < 0x40 || (c2 > 0x7E && c2 < 0xA1) || c2 > 0xFE) | |
2970 | goto label_invalid_code; | |
2971 | DECODE_BIG5 (c1, c2, charset, c1, c2); | |
4ed46869 KH |
2972 | } |
2973 | } | |
4ed46869 | 2974 | |
b73bfc1c KH |
2975 | c = DECODE_ISO_CHARACTER (charset, c1, c2); |
2976 | EMIT_CHAR (c); | |
fb88bf2d KH |
2977 | continue; |
2978 | ||
b73bfc1c KH |
2979 | label_invalid_code: |
2980 | coding->errors++; | |
4ed46869 | 2981 | src = src_base; |
b73bfc1c KH |
2982 | c = *src++; |
2983 | EMIT_CHAR (c); | |
fb88bf2d | 2984 | } |
d46c5b12 | 2985 | |
b73bfc1c KH |
2986 | label_end_of_loop: |
2987 | coding->consumed = coding->consumed_char = src_base - source; | |
d46c5b12 | 2988 | coding->produced = dst - destination; |
b73bfc1c | 2989 | return; |
4ed46869 KH |
2990 | } |
2991 | ||
2992 | /* See the above "GENERAL NOTES on `encode_coding_XXX ()' functions". | |
b73bfc1c KH |
2993 | This function can encode charsets `ascii', `katakana-jisx0201', |
2994 | `japanese-jisx0208', `chinese-big5-1', and `chinese-big5-2'. We | |
2995 | are sure that all these charsets are registered as official charset | |
4ed46869 KH |
2996 | (i.e. do not have extended leading-codes). Characters of other |
2997 | charsets are produced without any encoding. If SJIS_P is 1, encode | |
2998 | SJIS text, else encode BIG5 text. */ | |
2999 | ||
b73bfc1c | 3000 | static void |
4ed46869 | 3001 | encode_coding_sjis_big5 (coding, source, destination, |
d46c5b12 | 3002 | src_bytes, dst_bytes, sjis_p) |
4ed46869 KH |
3003 | struct coding_system *coding; |
3004 | unsigned char *source, *destination; | |
3005 | int src_bytes, dst_bytes; | |
4ed46869 KH |
3006 | int sjis_p; |
3007 | { | |
3008 | unsigned char *src = source; | |
3009 | unsigned char *src_end = source + src_bytes; | |
3010 | unsigned char *dst = destination; | |
3011 | unsigned char *dst_end = destination + dst_bytes; | |
b73bfc1c KH |
3012 | /* SRC_BASE remembers the start position in source in each loop. |
3013 | The loop will be exited when there's not enough source text to | |
3014 | analyze multi-byte codes (within macro ONE_MORE_CHAR), or when | |
3015 | there's not enough destination area to produce encoded codes | |
3016 | (within macro EMIT_BYTES). */ | |
3017 | unsigned char *src_base; | |
3018 | Lisp_Object translation_table; | |
4ed46869 | 3019 | |
b73bfc1c KH |
3020 | if (NILP (Venable_character_translation)) |
3021 | translation_table = Qnil; | |
3022 | else | |
4ed46869 | 3023 | { |
39658efc | 3024 | translation_table = coding->translation_table_for_encode; |
b73bfc1c | 3025 | if (NILP (translation_table)) |
39658efc | 3026 | translation_table = Vstandard_translation_table_for_encode; |
b73bfc1c | 3027 | } |
a5d301df | 3028 | |
b73bfc1c KH |
3029 | while (1) |
3030 | { | |
3031 | int c, charset, c1, c2; | |
4ed46869 | 3032 | |
b73bfc1c KH |
3033 | src_base = src; |
3034 | ONE_MORE_CHAR (c); | |
3035 | ||
3036 | /* Now encode the character C. */ | |
3037 | if (SINGLE_BYTE_CHAR_P (c)) | |
3038 | { | |
3039 | switch (c) | |
4ed46869 | 3040 | { |
b73bfc1c KH |
3041 | case '\r': |
3042 | if (!coding->mode & CODING_MODE_SELECTIVE_DISPLAY) | |
3043 | { | |
3044 | EMIT_ONE_BYTE (c); | |
3045 | break; | |
3046 | } | |
3047 | c = '\n'; | |
3048 | case '\n': | |
3049 | if (coding->eol_type == CODING_EOL_CRLF) | |
3050 | { | |
3051 | EMIT_TWO_BYTES ('\r', c); | |
3052 | break; | |
3053 | } | |
3054 | else if (coding->eol_type == CODING_EOL_CR) | |
3055 | c = '\r'; | |
3056 | default: | |
3057 | EMIT_ONE_BYTE (c); | |
3058 | } | |
3059 | } | |
3060 | else | |
3061 | { | |
3062 | SPLIT_CHAR (c, charset, c1, c2); | |
3063 | if (sjis_p) | |
3064 | { | |
3065 | if (charset == charset_jisx0208 | |
3066 | || charset == charset_jisx0208_1978) | |
3067 | { | |
3068 | ENCODE_SJIS (c1, c2, c1, c2); | |
3069 | EMIT_TWO_BYTES (c1, c2); | |
3070 | } | |
39658efc KH |
3071 | else if (charset == charset_katakana_jisx0201) |
3072 | EMIT_ONE_BYTE (c1 | 0x80); | |
fc53a214 KH |
3073 | else if (charset == charset_latin_jisx0201) |
3074 | EMIT_ONE_BYTE (c1); | |
b73bfc1c KH |
3075 | else |
3076 | /* There's no way other than producing the internal | |
3077 | codes as is. */ | |
3078 | EMIT_BYTES (src_base, src); | |
4ed46869 | 3079 | } |
4ed46869 | 3080 | else |
b73bfc1c KH |
3081 | { |
3082 | if (charset == charset_big5_1 || charset == charset_big5_2) | |
3083 | { | |
3084 | ENCODE_BIG5 (charset, c1, c2, c1, c2); | |
3085 | EMIT_TWO_BYTES (c1, c2); | |
3086 | } | |
3087 | else | |
3088 | /* There's no way other than producing the internal | |
3089 | codes as is. */ | |
3090 | EMIT_BYTES (src_base, src); | |
3091 | } | |
4ed46869 | 3092 | } |
b73bfc1c | 3093 | coding->consumed_char++; |
4ed46869 KH |
3094 | } |
3095 | ||
b73bfc1c KH |
3096 | label_end_of_loop: |
3097 | coding->consumed = src_base - source; | |
d46c5b12 | 3098 | coding->produced = coding->produced_char = dst - destination; |
4ed46869 KH |
3099 | } |
3100 | ||
3101 | \f | |
1397dc18 KH |
3102 | /*** 5. CCL handlers ***/ |
3103 | ||
3104 | /* See the above "GENERAL NOTES on `detect_coding_XXX ()' functions". | |
3105 | Check if a text is encoded in a coding system of which | |
3106 | encoder/decoder are written in CCL program. If it is, return | |
3107 | CODING_CATEGORY_MASK_CCL, else return 0. */ | |
3108 | ||
0a28aafb KH |
3109 | static int |
3110 | detect_coding_ccl (src, src_end, multibytep) | |
1397dc18 | 3111 | unsigned char *src, *src_end; |
0a28aafb | 3112 | int multibytep; |
1397dc18 KH |
3113 | { |
3114 | unsigned char *valid; | |
b73bfc1c KH |
3115 | int c; |
3116 | /* Dummy for ONE_MORE_BYTE. */ | |
3117 | struct coding_system dummy_coding; | |
3118 | struct coding_system *coding = &dummy_coding; | |
1397dc18 KH |
3119 | |
3120 | /* No coding system is assigned to coding-category-ccl. */ | |
3121 | if (!coding_system_table[CODING_CATEGORY_IDX_CCL]) | |
3122 | return 0; | |
3123 | ||
3124 | valid = coding_system_table[CODING_CATEGORY_IDX_CCL]->spec.ccl.valid_codes; | |
b73bfc1c | 3125 | while (1) |
1397dc18 | 3126 | { |
0a28aafb | 3127 | ONE_MORE_BYTE_CHECK_MULTIBYTE (c, multibytep); |
b73bfc1c KH |
3128 | if (! valid[c]) |
3129 | return 0; | |
1397dc18 | 3130 | } |
b73bfc1c | 3131 | label_end_of_loop: |
1397dc18 KH |
3132 | return CODING_CATEGORY_MASK_CCL; |
3133 | } | |
3134 | ||
3135 | \f | |
3136 | /*** 6. End-of-line handlers ***/ | |
4ed46869 | 3137 | |
b73bfc1c | 3138 | /* See the above "GENERAL NOTES on `decode_coding_XXX ()' functions". */ |
4ed46869 | 3139 | |
b73bfc1c | 3140 | static void |
d46c5b12 | 3141 | decode_eol (coding, source, destination, src_bytes, dst_bytes) |
4ed46869 KH |
3142 | struct coding_system *coding; |
3143 | unsigned char *source, *destination; | |
3144 | int src_bytes, dst_bytes; | |
4ed46869 KH |
3145 | { |
3146 | unsigned char *src = source; | |
4ed46869 | 3147 | unsigned char *dst = destination; |
b73bfc1c KH |
3148 | unsigned char *src_end = src + src_bytes; |
3149 | unsigned char *dst_end = dst + dst_bytes; | |
3150 | Lisp_Object translation_table; | |
3151 | /* SRC_BASE remembers the start position in source in each loop. | |
3152 | The loop will be exited when there's not enough source code | |
3153 | (within macro ONE_MORE_BYTE), or when there's not enough | |
3154 | destination area to produce a character (within macro | |
3155 | EMIT_CHAR). */ | |
3156 | unsigned char *src_base; | |
3157 | int c; | |
3158 | ||
3159 | translation_table = Qnil; | |
4ed46869 KH |
3160 | switch (coding->eol_type) |
3161 | { | |
3162 | case CODING_EOL_CRLF: | |
b73bfc1c | 3163 | while (1) |
d46c5b12 | 3164 | { |
b73bfc1c KH |
3165 | src_base = src; |
3166 | ONE_MORE_BYTE (c); | |
3167 | if (c == '\r') | |
fb88bf2d | 3168 | { |
b73bfc1c KH |
3169 | ONE_MORE_BYTE (c); |
3170 | if (c != '\n') | |
3171 | { | |
3172 | if (coding->mode & CODING_MODE_INHIBIT_INCONSISTENT_EOL) | |
3173 | { | |
3174 | coding->result = CODING_FINISH_INCONSISTENT_EOL; | |
3175 | goto label_end_of_loop; | |
3176 | } | |
3177 | src--; | |
3178 | c = '\r'; | |
3179 | } | |
fb88bf2d | 3180 | } |
b73bfc1c KH |
3181 | else if (c == '\n' |
3182 | && (coding->mode & CODING_MODE_INHIBIT_INCONSISTENT_EOL)) | |
d46c5b12 | 3183 | { |
b73bfc1c KH |
3184 | coding->result = CODING_FINISH_INCONSISTENT_EOL; |
3185 | goto label_end_of_loop; | |
d46c5b12 | 3186 | } |
b73bfc1c | 3187 | EMIT_CHAR (c); |
d46c5b12 | 3188 | } |
b73bfc1c KH |
3189 | break; |
3190 | ||
3191 | case CODING_EOL_CR: | |
3192 | while (1) | |
d46c5b12 | 3193 | { |
b73bfc1c KH |
3194 | src_base = src; |
3195 | ONE_MORE_BYTE (c); | |
3196 | if (c == '\n') | |
3197 | { | |
3198 | if (coding->mode & CODING_MODE_INHIBIT_INCONSISTENT_EOL) | |
3199 | { | |
3200 | coding->result = CODING_FINISH_INCONSISTENT_EOL; | |
3201 | goto label_end_of_loop; | |
3202 | } | |
3203 | } | |
3204 | else if (c == '\r') | |
3205 | c = '\n'; | |
3206 | EMIT_CHAR (c); | |
d46c5b12 | 3207 | } |
4ed46869 KH |
3208 | break; |
3209 | ||
b73bfc1c KH |
3210 | default: /* no need for EOL handling */ |
3211 | while (1) | |
d46c5b12 | 3212 | { |
b73bfc1c KH |
3213 | src_base = src; |
3214 | ONE_MORE_BYTE (c); | |
3215 | EMIT_CHAR (c); | |
d46c5b12 | 3216 | } |
4ed46869 KH |
3217 | } |
3218 | ||
b73bfc1c KH |
3219 | label_end_of_loop: |
3220 | coding->consumed = coding->consumed_char = src_base - source; | |
3221 | coding->produced = dst - destination; | |
3222 | return; | |
4ed46869 KH |
3223 | } |
3224 | ||
3225 | /* See "GENERAL NOTES about `encode_coding_XXX ()' functions". Encode | |
b73bfc1c | 3226 | format of end-of-line according to `coding->eol_type'. It also |
8ca3766a | 3227 | convert multibyte form 8-bit characters to unibyte if |
b73bfc1c KH |
3228 | CODING->src_multibyte is nonzero. If `coding->mode & |
3229 | CODING_MODE_SELECTIVE_DISPLAY' is nonzero, code '\r' in source text | |
3230 | also means end-of-line. */ | |
4ed46869 | 3231 | |
b73bfc1c | 3232 | static void |
d46c5b12 | 3233 | encode_eol (coding, source, destination, src_bytes, dst_bytes) |
4ed46869 KH |
3234 | struct coding_system *coding; |
3235 | unsigned char *source, *destination; | |
3236 | int src_bytes, dst_bytes; | |
4ed46869 KH |
3237 | { |
3238 | unsigned char *src = source; | |
3239 | unsigned char *dst = destination; | |
b73bfc1c KH |
3240 | unsigned char *src_end = src + src_bytes; |
3241 | unsigned char *dst_end = dst + dst_bytes; | |
3242 | Lisp_Object translation_table; | |
3243 | /* SRC_BASE remembers the start position in source in each loop. | |
3244 | The loop will be exited when there's not enough source text to | |
3245 | analyze multi-byte codes (within macro ONE_MORE_CHAR), or when | |
3246 | there's not enough destination area to produce encoded codes | |
3247 | (within macro EMIT_BYTES). */ | |
3248 | unsigned char *src_base; | |
3249 | int c; | |
3250 | int selective_display = coding->mode & CODING_MODE_SELECTIVE_DISPLAY; | |
3251 | ||
3252 | translation_table = Qnil; | |
3253 | if (coding->src_multibyte | |
3254 | && *(src_end - 1) == LEADING_CODE_8_BIT_CONTROL) | |
3255 | { | |
3256 | src_end--; | |
3257 | src_bytes--; | |
3258 | coding->result = CODING_FINISH_INSUFFICIENT_SRC; | |
3259 | } | |
fb88bf2d | 3260 | |
d46c5b12 KH |
3261 | if (coding->eol_type == CODING_EOL_CRLF) |
3262 | { | |
b73bfc1c | 3263 | while (src < src_end) |
d46c5b12 | 3264 | { |
b73bfc1c | 3265 | src_base = src; |
d46c5b12 | 3266 | c = *src++; |
b73bfc1c KH |
3267 | if (c >= 0x20) |
3268 | EMIT_ONE_BYTE (c); | |
3269 | else if (c == '\n' || (c == '\r' && selective_display)) | |
3270 | EMIT_TWO_BYTES ('\r', '\n'); | |
d46c5b12 | 3271 | else |
b73bfc1c | 3272 | EMIT_ONE_BYTE (c); |
d46c5b12 | 3273 | } |
ff2b1ea9 | 3274 | src_base = src; |
b73bfc1c | 3275 | label_end_of_loop: |
005f0d35 | 3276 | ; |
d46c5b12 KH |
3277 | } |
3278 | else | |
4ed46869 | 3279 | { |
78a629d2 | 3280 | if (!dst_bytes || src_bytes <= dst_bytes) |
4ed46869 | 3281 | { |
b73bfc1c KH |
3282 | safe_bcopy (src, dst, src_bytes); |
3283 | src_base = src_end; | |
3284 | dst += src_bytes; | |
d46c5b12 | 3285 | } |
d46c5b12 | 3286 | else |
b73bfc1c KH |
3287 | { |
3288 | if (coding->src_multibyte | |
3289 | && *(src + dst_bytes - 1) == LEADING_CODE_8_BIT_CONTROL) | |
3290 | dst_bytes--; | |
3291 | safe_bcopy (src, dst, dst_bytes); | |
3292 | src_base = src + dst_bytes; | |
3293 | dst = destination + dst_bytes; | |
3294 | coding->result = CODING_FINISH_INSUFFICIENT_DST; | |
3295 | } | |
993824c9 | 3296 | if (coding->eol_type == CODING_EOL_CR) |
d46c5b12 | 3297 | { |
b73bfc1c KH |
3298 | for (src = destination; src < dst; src++) |
3299 | if (*src == '\n') *src = '\r'; | |
d46c5b12 | 3300 | } |
b73bfc1c | 3301 | else if (selective_display) |
d46c5b12 | 3302 | { |
b73bfc1c KH |
3303 | for (src = destination; src < dst; src++) |
3304 | if (*src == '\r') *src = '\n'; | |
4ed46869 | 3305 | } |
4ed46869 | 3306 | } |
b73bfc1c KH |
3307 | if (coding->src_multibyte) |
3308 | dst = destination + str_as_unibyte (destination, dst - destination); | |
4ed46869 | 3309 | |
b73bfc1c KH |
3310 | coding->consumed = src_base - source; |
3311 | coding->produced = dst - destination; | |
78a629d2 | 3312 | coding->produced_char = coding->produced; |
4ed46869 KH |
3313 | } |
3314 | ||
3315 | \f | |
1397dc18 | 3316 | /*** 7. C library functions ***/ |
4ed46869 | 3317 | |
cfb43547 | 3318 | /* In Emacs Lisp, a coding system is represented by a Lisp symbol which |
4ed46869 | 3319 | has a property `coding-system'. The value of this property is a |
cfb43547 | 3320 | vector of length 5 (called the coding-vector). Among elements of |
4ed46869 KH |
3321 | this vector, the first (element[0]) and the fifth (element[4]) |
3322 | carry important information for decoding/encoding. Before | |
3323 | decoding/encoding, this information should be set in fields of a | |
3324 | structure of type `coding_system'. | |
3325 | ||
cfb43547 | 3326 | The value of the property `coding-system' can be a symbol of another |
4ed46869 KH |
3327 | subsidiary coding-system. In that case, Emacs gets coding-vector |
3328 | from that symbol. | |
3329 | ||
3330 | `element[0]' contains information to be set in `coding->type'. The | |
3331 | value and its meaning is as follows: | |
3332 | ||
0ef69138 KH |
3333 | 0 -- coding_type_emacs_mule |
3334 | 1 -- coding_type_sjis | |
3335 | 2 -- coding_type_iso2022 | |
3336 | 3 -- coding_type_big5 | |
3337 | 4 -- coding_type_ccl encoder/decoder written in CCL | |
3338 | nil -- coding_type_no_conversion | |
3339 | t -- coding_type_undecided (automatic conversion on decoding, | |
3340 | no-conversion on encoding) | |
4ed46869 KH |
3341 | |
3342 | `element[4]' contains information to be set in `coding->flags' and | |
3343 | `coding->spec'. The meaning varies by `coding->type'. | |
3344 | ||
3345 | If `coding->type' is `coding_type_iso2022', element[4] is a vector | |
3346 | of length 32 (of which the first 13 sub-elements are used now). | |
3347 | Meanings of these sub-elements are: | |
3348 | ||
3349 | sub-element[N] where N is 0 through 3: to be set in `coding->spec.iso2022' | |
3350 | If the value is an integer of valid charset, the charset is | |
3351 | assumed to be designated to graphic register N initially. | |
3352 | ||
3353 | If the value is minus, it is a minus value of charset which | |
3354 | reserves graphic register N, which means that the charset is | |
3355 | not designated initially but should be designated to graphic | |
3356 | register N just before encoding a character in that charset. | |
3357 | ||
3358 | If the value is nil, graphic register N is never used on | |
3359 | encoding. | |
3360 | ||
3361 | sub-element[N] where N is 4 through 11: to be set in `coding->flags' | |
3362 | Each value takes t or nil. See the section ISO2022 of | |
3363 | `coding.h' for more information. | |
3364 | ||
3365 | If `coding->type' is `coding_type_big5', element[4] is t to denote | |
3366 | BIG5-ETen or nil to denote BIG5-HKU. | |
3367 | ||
3368 | If `coding->type' takes the other value, element[4] is ignored. | |
3369 | ||
cfb43547 | 3370 | Emacs Lisp's coding systems also carry information about format of |
4ed46869 KH |
3371 | end-of-line in a value of property `eol-type'. If the value is |
3372 | integer, 0 means CODING_EOL_LF, 1 means CODING_EOL_CRLF, and 2 | |
3373 | means CODING_EOL_CR. If it is not integer, it should be a vector | |
3374 | of subsidiary coding systems of which property `eol-type' has one | |
cfb43547 | 3375 | of the above values. |
4ed46869 KH |
3376 | |
3377 | */ | |
3378 | ||
3379 | /* Extract information for decoding/encoding from CODING_SYSTEM_SYMBOL | |
3380 | and set it in CODING. If CODING_SYSTEM_SYMBOL is invalid, CODING | |
3381 | is setup so that no conversion is necessary and return -1, else | |
3382 | return 0. */ | |
3383 | ||
3384 | int | |
e0e989f6 KH |
3385 | setup_coding_system (coding_system, coding) |
3386 | Lisp_Object coding_system; | |
4ed46869 KH |
3387 | struct coding_system *coding; |
3388 | { | |
d46c5b12 | 3389 | Lisp_Object coding_spec, coding_type, eol_type, plist; |
4608c386 | 3390 | Lisp_Object val; |
4ed46869 | 3391 | |
c07c8e12 KH |
3392 | /* At first, zero clear all members. */ |
3393 | bzero (coding, sizeof (struct coding_system)); | |
3394 | ||
d46c5b12 | 3395 | /* Initialize some fields required for all kinds of coding systems. */ |
774324d6 | 3396 | coding->symbol = coding_system; |
d46c5b12 KH |
3397 | coding->heading_ascii = -1; |
3398 | coding->post_read_conversion = coding->pre_write_conversion = Qnil; | |
ec6d2bb8 KH |
3399 | coding->composing = COMPOSITION_DISABLED; |
3400 | coding->cmp_data = NULL; | |
1f5dbf34 KH |
3401 | |
3402 | if (NILP (coding_system)) | |
3403 | goto label_invalid_coding_system; | |
3404 | ||
4608c386 | 3405 | coding_spec = Fget (coding_system, Qcoding_system); |
1f5dbf34 | 3406 | |
4608c386 KH |
3407 | if (!VECTORP (coding_spec) |
3408 | || XVECTOR (coding_spec)->size != 5 | |
3409 | || !CONSP (XVECTOR (coding_spec)->contents[3])) | |
4ed46869 | 3410 | goto label_invalid_coding_system; |
4608c386 | 3411 | |
d46c5b12 KH |
3412 | eol_type = inhibit_eol_conversion ? Qnil : Fget (coding_system, Qeol_type); |
3413 | if (VECTORP (eol_type)) | |
3414 | { | |
3415 | coding->eol_type = CODING_EOL_UNDECIDED; | |
3416 | coding->common_flags = CODING_REQUIRE_DETECTION_MASK; | |
3417 | } | |
3418 | else if (XFASTINT (eol_type) == 1) | |
3419 | { | |
3420 | coding->eol_type = CODING_EOL_CRLF; | |
3421 | coding->common_flags | |
3422 | = CODING_REQUIRE_DECODING_MASK | CODING_REQUIRE_ENCODING_MASK; | |
3423 | } | |
3424 | else if (XFASTINT (eol_type) == 2) | |
3425 | { | |
3426 | coding->eol_type = CODING_EOL_CR; | |
3427 | coding->common_flags | |
3428 | = CODING_REQUIRE_DECODING_MASK | CODING_REQUIRE_ENCODING_MASK; | |
3429 | } | |
3430 | else | |
3431 | coding->eol_type = CODING_EOL_LF; | |
3432 | ||
3433 | coding_type = XVECTOR (coding_spec)->contents[0]; | |
3434 | /* Try short cut. */ | |
3435 | if (SYMBOLP (coding_type)) | |
3436 | { | |
3437 | if (EQ (coding_type, Qt)) | |
3438 | { | |
3439 | coding->type = coding_type_undecided; | |
3440 | coding->common_flags |= CODING_REQUIRE_DETECTION_MASK; | |
3441 | } | |
3442 | else | |
3443 | coding->type = coding_type_no_conversion; | |
9b96232f KH |
3444 | /* Initialize this member. Any thing other than |
3445 | CODING_CATEGORY_IDX_UTF_16_BE and | |
3446 | CODING_CATEGORY_IDX_UTF_16_LE are ok because they have | |
3447 | special treatment in detect_eol. */ | |
3448 | coding->category_idx = CODING_CATEGORY_IDX_EMACS_MULE; | |
3449 | ||
d46c5b12 KH |
3450 | return 0; |
3451 | } | |
3452 | ||
d46c5b12 KH |
3453 | /* Get values of coding system properties: |
3454 | `post-read-conversion', `pre-write-conversion', | |
f967223b | 3455 | `translation-table-for-decode', `translation-table-for-encode'. */ |
4608c386 | 3456 | plist = XVECTOR (coding_spec)->contents[3]; |
b843d1ae | 3457 | /* Pre & post conversion functions should be disabled if |
8ca3766a | 3458 | inhibit_eol_conversion is nonzero. This is the case that a code |
b843d1ae KH |
3459 | conversion function is called while those functions are running. */ |
3460 | if (! inhibit_pre_post_conversion) | |
3461 | { | |
3462 | coding->post_read_conversion = Fplist_get (plist, Qpost_read_conversion); | |
3463 | coding->pre_write_conversion = Fplist_get (plist, Qpre_write_conversion); | |
3464 | } | |
f967223b | 3465 | val = Fplist_get (plist, Qtranslation_table_for_decode); |
4608c386 | 3466 | if (SYMBOLP (val)) |
f967223b KH |
3467 | val = Fget (val, Qtranslation_table_for_decode); |
3468 | coding->translation_table_for_decode = CHAR_TABLE_P (val) ? val : Qnil; | |
3469 | val = Fplist_get (plist, Qtranslation_table_for_encode); | |
4608c386 | 3470 | if (SYMBOLP (val)) |
f967223b KH |
3471 | val = Fget (val, Qtranslation_table_for_encode); |
3472 | coding->translation_table_for_encode = CHAR_TABLE_P (val) ? val : Qnil; | |
d46c5b12 KH |
3473 | val = Fplist_get (plist, Qcoding_category); |
3474 | if (!NILP (val)) | |
3475 | { | |
3476 | val = Fget (val, Qcoding_category_index); | |
3477 | if (INTEGERP (val)) | |
3478 | coding->category_idx = XINT (val); | |
3479 | else | |
3480 | goto label_invalid_coding_system; | |
3481 | } | |
3482 | else | |
3483 | goto label_invalid_coding_system; | |
4608c386 | 3484 | |
ec6d2bb8 KH |
3485 | /* If the coding system has non-nil `composition' property, enable |
3486 | composition handling. */ | |
3487 | val = Fplist_get (plist, Qcomposition); | |
3488 | if (!NILP (val)) | |
3489 | coding->composing = COMPOSITION_NO; | |
3490 | ||
d46c5b12 | 3491 | switch (XFASTINT (coding_type)) |
4ed46869 KH |
3492 | { |
3493 | case 0: | |
0ef69138 | 3494 | coding->type = coding_type_emacs_mule; |
aa72b389 KH |
3495 | coding->common_flags |
3496 | |= CODING_REQUIRE_DECODING_MASK | CODING_REQUIRE_ENCODING_MASK; | |
3497 | coding->composing = COMPOSITION_NO; | |
c952af22 KH |
3498 | if (!NILP (coding->post_read_conversion)) |
3499 | coding->common_flags |= CODING_REQUIRE_DECODING_MASK; | |
3500 | if (!NILP (coding->pre_write_conversion)) | |
3501 | coding->common_flags |= CODING_REQUIRE_ENCODING_MASK; | |
4ed46869 KH |
3502 | break; |
3503 | ||
3504 | case 1: | |
3505 | coding->type = coding_type_sjis; | |
c952af22 KH |
3506 | coding->common_flags |
3507 | |= CODING_REQUIRE_DECODING_MASK | CODING_REQUIRE_ENCODING_MASK; | |
4ed46869 KH |
3508 | break; |
3509 | ||
3510 | case 2: | |
3511 | coding->type = coding_type_iso2022; | |
c952af22 KH |
3512 | coding->common_flags |
3513 | |= CODING_REQUIRE_DECODING_MASK | CODING_REQUIRE_ENCODING_MASK; | |
4ed46869 | 3514 | { |
70c22245 | 3515 | Lisp_Object val, temp; |
4ed46869 | 3516 | Lisp_Object *flags; |
d46c5b12 | 3517 | int i, charset, reg_bits = 0; |
4ed46869 | 3518 | |
4608c386 | 3519 | val = XVECTOR (coding_spec)->contents[4]; |
f44d27ce | 3520 | |
4ed46869 KH |
3521 | if (!VECTORP (val) || XVECTOR (val)->size != 32) |
3522 | goto label_invalid_coding_system; | |
3523 | ||
3524 | flags = XVECTOR (val)->contents; | |
3525 | coding->flags | |
3526 | = ((NILP (flags[4]) ? 0 : CODING_FLAG_ISO_SHORT_FORM) | |
3527 | | (NILP (flags[5]) ? 0 : CODING_FLAG_ISO_RESET_AT_EOL) | |
3528 | | (NILP (flags[6]) ? 0 : CODING_FLAG_ISO_RESET_AT_CNTL) | |
3529 | | (NILP (flags[7]) ? 0 : CODING_FLAG_ISO_SEVEN_BITS) | |
3530 | | (NILP (flags[8]) ? 0 : CODING_FLAG_ISO_LOCKING_SHIFT) | |
3531 | | (NILP (flags[9]) ? 0 : CODING_FLAG_ISO_SINGLE_SHIFT) | |
3532 | | (NILP (flags[10]) ? 0 : CODING_FLAG_ISO_USE_ROMAN) | |
3533 | | (NILP (flags[11]) ? 0 : CODING_FLAG_ISO_USE_OLDJIS) | |
e0e989f6 KH |
3534 | | (NILP (flags[12]) ? 0 : CODING_FLAG_ISO_NO_DIRECTION) |
3535 | | (NILP (flags[13]) ? 0 : CODING_FLAG_ISO_INIT_AT_BOL) | |
c4825358 KH |
3536 | | (NILP (flags[14]) ? 0 : CODING_FLAG_ISO_DESIGNATE_AT_BOL) |
3537 | | (NILP (flags[15]) ? 0 : CODING_FLAG_ISO_SAFE) | |
3f003981 | 3538 | | (NILP (flags[16]) ? 0 : CODING_FLAG_ISO_LATIN_EXTRA) |
c4825358 | 3539 | ); |
4ed46869 KH |
3540 | |
3541 | /* Invoke graphic register 0 to plane 0. */ | |
3542 | CODING_SPEC_ISO_INVOCATION (coding, 0) = 0; | |
3543 | /* Invoke graphic register 1 to plane 1 if we can use full 8-bit. */ | |
3544 | CODING_SPEC_ISO_INVOCATION (coding, 1) | |
3545 | = (coding->flags & CODING_FLAG_ISO_SEVEN_BITS ? -1 : 1); | |
3546 | /* Not single shifting at first. */ | |
6e85d753 | 3547 | CODING_SPEC_ISO_SINGLE_SHIFTING (coding) = 0; |
e0e989f6 | 3548 | /* Beginning of buffer should also be regarded as bol. */ |
6e85d753 | 3549 | CODING_SPEC_ISO_BOL (coding) = 1; |
4ed46869 | 3550 | |
70c22245 KH |
3551 | for (charset = 0; charset <= MAX_CHARSET; charset++) |
3552 | CODING_SPEC_ISO_REVISION_NUMBER (coding, charset) = 255; | |
3553 | val = Vcharset_revision_alist; | |
3554 | while (CONSP (val)) | |
3555 | { | |
03699b14 | 3556 | charset = get_charset_id (Fcar_safe (XCAR (val))); |
70c22245 | 3557 | if (charset >= 0 |
03699b14 | 3558 | && (temp = Fcdr_safe (XCAR (val)), INTEGERP (temp)) |
70c22245 KH |
3559 | && (i = XINT (temp), (i >= 0 && (i + '@') < 128))) |
3560 | CODING_SPEC_ISO_REVISION_NUMBER (coding, charset) = i; | |
03699b14 | 3561 | val = XCDR (val); |
70c22245 KH |
3562 | } |
3563 | ||
4ed46869 KH |
3564 | /* Checks FLAGS[REG] (REG = 0, 1, 2 3) and decide designations. |
3565 | FLAGS[REG] can be one of below: | |
3566 | integer CHARSET: CHARSET occupies register I, | |
3567 | t: designate nothing to REG initially, but can be used | |
3568 | by any charsets, | |
3569 | list of integer, nil, or t: designate the first | |
3570 | element (if integer) to REG initially, the remaining | |
3571 | elements (if integer) is designated to REG on request, | |
d46c5b12 | 3572 | if an element is t, REG can be used by any charsets, |
4ed46869 | 3573 | nil: REG is never used. */ |
467e7675 | 3574 | for (charset = 0; charset <= MAX_CHARSET; charset++) |
1ba9e4ab KH |
3575 | CODING_SPEC_ISO_REQUESTED_DESIGNATION (coding, charset) |
3576 | = CODING_SPEC_ISO_NO_REQUESTED_DESIGNATION; | |
4ed46869 KH |
3577 | for (i = 0; i < 4; i++) |
3578 | { | |
3579 | if (INTEGERP (flags[i]) | |
e0e989f6 KH |
3580 | && (charset = XINT (flags[i]), CHARSET_VALID_P (charset)) |
3581 | || (charset = get_charset_id (flags[i])) >= 0) | |
4ed46869 KH |
3582 | { |
3583 | CODING_SPEC_ISO_INITIAL_DESIGNATION (coding, i) = charset; | |
3584 | CODING_SPEC_ISO_REQUESTED_DESIGNATION (coding, charset) = i; | |
3585 | } | |
3586 | else if (EQ (flags[i], Qt)) | |
3587 | { | |
3588 | CODING_SPEC_ISO_INITIAL_DESIGNATION (coding, i) = -1; | |
d46c5b12 KH |
3589 | reg_bits |= 1 << i; |
3590 | coding->flags |= CODING_FLAG_ISO_DESIGNATION; | |
4ed46869 KH |
3591 | } |
3592 | else if (CONSP (flags[i])) | |
3593 | { | |
84d60297 RS |
3594 | Lisp_Object tail; |
3595 | tail = flags[i]; | |
4ed46869 | 3596 | |
d46c5b12 | 3597 | coding->flags |= CODING_FLAG_ISO_DESIGNATION; |
03699b14 KR |
3598 | if (INTEGERP (XCAR (tail)) |
3599 | && (charset = XINT (XCAR (tail)), | |
e0e989f6 | 3600 | CHARSET_VALID_P (charset)) |
03699b14 | 3601 | || (charset = get_charset_id (XCAR (tail))) >= 0) |
4ed46869 KH |
3602 | { |
3603 | CODING_SPEC_ISO_INITIAL_DESIGNATION (coding, i) = charset; | |
3604 | CODING_SPEC_ISO_REQUESTED_DESIGNATION (coding, charset) =i; | |
3605 | } | |
3606 | else | |
3607 | CODING_SPEC_ISO_INITIAL_DESIGNATION (coding, i) = -1; | |
03699b14 | 3608 | tail = XCDR (tail); |
4ed46869 KH |
3609 | while (CONSP (tail)) |
3610 | { | |
03699b14 KR |
3611 | if (INTEGERP (XCAR (tail)) |
3612 | && (charset = XINT (XCAR (tail)), | |
e0e989f6 | 3613 | CHARSET_VALID_P (charset)) |
03699b14 | 3614 | || (charset = get_charset_id (XCAR (tail))) >= 0) |
70c22245 KH |
3615 | CODING_SPEC_ISO_REQUESTED_DESIGNATION (coding, charset) |
3616 | = i; | |
03699b14 | 3617 | else if (EQ (XCAR (tail), Qt)) |
d46c5b12 | 3618 | reg_bits |= 1 << i; |
03699b14 | 3619 | tail = XCDR (tail); |
4ed46869 KH |
3620 | } |
3621 | } | |
3622 | else | |
3623 | CODING_SPEC_ISO_INITIAL_DESIGNATION (coding, i) = -1; | |
3624 | ||
3625 | CODING_SPEC_ISO_DESIGNATION (coding, i) | |
3626 | = CODING_SPEC_ISO_INITIAL_DESIGNATION (coding, i); | |
3627 | } | |
3628 | ||
d46c5b12 | 3629 | if (reg_bits && ! (coding->flags & CODING_FLAG_ISO_LOCKING_SHIFT)) |
4ed46869 KH |
3630 | { |
3631 | /* REG 1 can be used only by locking shift in 7-bit env. */ | |
3632 | if (coding->flags & CODING_FLAG_ISO_SEVEN_BITS) | |
d46c5b12 | 3633 | reg_bits &= ~2; |
4ed46869 KH |
3634 | if (! (coding->flags & CODING_FLAG_ISO_SINGLE_SHIFT)) |
3635 | /* Without any shifting, only REG 0 and 1 can be used. */ | |
d46c5b12 | 3636 | reg_bits &= 3; |
4ed46869 KH |
3637 | } |
3638 | ||
d46c5b12 KH |
3639 | if (reg_bits) |
3640 | for (charset = 0; charset <= MAX_CHARSET; charset++) | |
6e85d753 | 3641 | { |
928a85c1 | 3642 | if (CHARSET_DEFINED_P (charset) |
96148065 KH |
3643 | && (CODING_SPEC_ISO_REQUESTED_DESIGNATION (coding, charset) |
3644 | == CODING_SPEC_ISO_NO_REQUESTED_DESIGNATION)) | |
d46c5b12 KH |
3645 | { |
3646 | /* There exist some default graphic registers to be | |
96148065 | 3647 | used by CHARSET. */ |
d46c5b12 KH |
3648 | |
3649 | /* We had better avoid designating a charset of | |
3650 | CHARS96 to REG 0 as far as possible. */ | |
3651 | if (CHARSET_CHARS (charset) == 96) | |
3652 | CODING_SPEC_ISO_REQUESTED_DESIGNATION (coding, charset) | |
3653 | = (reg_bits & 2 | |
3654 | ? 1 : (reg_bits & 4 ? 2 : (reg_bits & 8 ? 3 : 0))); | |
3655 | else | |
3656 | CODING_SPEC_ISO_REQUESTED_DESIGNATION (coding, charset) | |
3657 | = (reg_bits & 1 | |
3658 | ? 0 : (reg_bits & 2 ? 1 : (reg_bits & 4 ? 2 : 3))); | |
3659 | } | |
6e85d753 | 3660 | } |
4ed46869 | 3661 | } |
c952af22 | 3662 | coding->common_flags |= CODING_REQUIRE_FLUSHING_MASK; |
d46c5b12 | 3663 | coding->spec.iso2022.last_invalid_designation_register = -1; |
4ed46869 KH |
3664 | break; |
3665 | ||
3666 | case 3: | |
3667 | coding->type = coding_type_big5; | |
c952af22 KH |
3668 | coding->common_flags |
3669 | |= CODING_REQUIRE_DECODING_MASK | CODING_REQUIRE_ENCODING_MASK; | |
4ed46869 | 3670 | coding->flags |
4608c386 | 3671 | = (NILP (XVECTOR (coding_spec)->contents[4]) |
4ed46869 KH |
3672 | ? CODING_FLAG_BIG5_HKU |
3673 | : CODING_FLAG_BIG5_ETEN); | |
3674 | break; | |
3675 | ||
3676 | case 4: | |
3677 | coding->type = coding_type_ccl; | |
c952af22 KH |
3678 | coding->common_flags |
3679 | |= CODING_REQUIRE_DECODING_MASK | CODING_REQUIRE_ENCODING_MASK; | |
4ed46869 | 3680 | { |
84d60297 | 3681 | val = XVECTOR (coding_spec)->contents[4]; |
ef4ced28 KH |
3682 | if (! CONSP (val) |
3683 | || setup_ccl_program (&(coding->spec.ccl.decoder), | |
03699b14 | 3684 | XCAR (val)) < 0 |
ef4ced28 | 3685 | || setup_ccl_program (&(coding->spec.ccl.encoder), |
03699b14 | 3686 | XCDR (val)) < 0) |
4ed46869 | 3687 | goto label_invalid_coding_system; |
1397dc18 KH |
3688 | |
3689 | bzero (coding->spec.ccl.valid_codes, 256); | |
3690 | val = Fplist_get (plist, Qvalid_codes); | |
3691 | if (CONSP (val)) | |
3692 | { | |
3693 | Lisp_Object this; | |
3694 | ||
03699b14 | 3695 | for (; CONSP (val); val = XCDR (val)) |
1397dc18 | 3696 | { |
03699b14 | 3697 | this = XCAR (val); |
1397dc18 KH |
3698 | if (INTEGERP (this) |
3699 | && XINT (this) >= 0 && XINT (this) < 256) | |
3700 | coding->spec.ccl.valid_codes[XINT (this)] = 1; | |
3701 | else if (CONSP (this) | |
03699b14 KR |
3702 | && INTEGERP (XCAR (this)) |
3703 | && INTEGERP (XCDR (this))) | |
1397dc18 | 3704 | { |
03699b14 KR |
3705 | int start = XINT (XCAR (this)); |
3706 | int end = XINT (XCDR (this)); | |
1397dc18 KH |
3707 | |
3708 | if (start >= 0 && start <= end && end < 256) | |
e133c8fa | 3709 | while (start <= end) |
1397dc18 KH |
3710 | coding->spec.ccl.valid_codes[start++] = 1; |
3711 | } | |
3712 | } | |
3713 | } | |
4ed46869 | 3714 | } |
c952af22 | 3715 | coding->common_flags |= CODING_REQUIRE_FLUSHING_MASK; |
aaaf0b1e | 3716 | coding->spec.ccl.cr_carryover = 0; |
1c3478b0 | 3717 | coding->spec.ccl.eight_bit_carryover[0] = 0; |
4ed46869 KH |
3718 | break; |
3719 | ||
27901516 KH |
3720 | case 5: |
3721 | coding->type = coding_type_raw_text; | |
3722 | break; | |
3723 | ||
4ed46869 | 3724 | default: |
d46c5b12 | 3725 | goto label_invalid_coding_system; |
4ed46869 KH |
3726 | } |
3727 | return 0; | |
3728 | ||
3729 | label_invalid_coding_system: | |
3730 | coding->type = coding_type_no_conversion; | |
d46c5b12 | 3731 | coding->category_idx = CODING_CATEGORY_IDX_BINARY; |
c952af22 | 3732 | coding->common_flags = 0; |
dec137e5 | 3733 | coding->eol_type = CODING_EOL_LF; |
d46c5b12 | 3734 | coding->pre_write_conversion = coding->post_read_conversion = Qnil; |
4ed46869 KH |
3735 | return -1; |
3736 | } | |
3737 | ||
ec6d2bb8 KH |
3738 | /* Free memory blocks allocated for storing composition information. */ |
3739 | ||
3740 | void | |
3741 | coding_free_composition_data (coding) | |
3742 | struct coding_system *coding; | |
3743 | { | |
3744 | struct composition_data *cmp_data = coding->cmp_data, *next; | |
3745 | ||
3746 | if (!cmp_data) | |
3747 | return; | |
3748 | /* Memory blocks are chained. At first, rewind to the first, then, | |
3749 | free blocks one by one. */ | |
3750 | while (cmp_data->prev) | |
3751 | cmp_data = cmp_data->prev; | |
3752 | while (cmp_data) | |
3753 | { | |
3754 | next = cmp_data->next; | |
3755 | xfree (cmp_data); | |
3756 | cmp_data = next; | |
3757 | } | |
3758 | coding->cmp_data = NULL; | |
3759 | } | |
3760 | ||
3761 | /* Set `char_offset' member of all memory blocks pointed by | |
3762 | coding->cmp_data to POS. */ | |
3763 | ||
3764 | void | |
3765 | coding_adjust_composition_offset (coding, pos) | |
3766 | struct coding_system *coding; | |
3767 | int pos; | |
3768 | { | |
3769 | struct composition_data *cmp_data; | |
3770 | ||
3771 | for (cmp_data = coding->cmp_data; cmp_data; cmp_data = cmp_data->next) | |
3772 | cmp_data->char_offset = pos; | |
3773 | } | |
3774 | ||
54f78171 KH |
3775 | /* Setup raw-text or one of its subsidiaries in the structure |
3776 | coding_system CODING according to the already setup value eol_type | |
3777 | in CODING. CODING should be setup for some coding system in | |
3778 | advance. */ | |
3779 | ||
3780 | void | |
3781 | setup_raw_text_coding_system (coding) | |
3782 | struct coding_system *coding; | |
3783 | { | |
3784 | if (coding->type != coding_type_raw_text) | |
3785 | { | |
3786 | coding->symbol = Qraw_text; | |
3787 | coding->type = coding_type_raw_text; | |
3788 | if (coding->eol_type != CODING_EOL_UNDECIDED) | |
3789 | { | |
84d60297 RS |
3790 | Lisp_Object subsidiaries; |
3791 | subsidiaries = Fget (Qraw_text, Qeol_type); | |
54f78171 KH |
3792 | |
3793 | if (VECTORP (subsidiaries) | |
3794 | && XVECTOR (subsidiaries)->size == 3) | |
3795 | coding->symbol | |
3796 | = XVECTOR (subsidiaries)->contents[coding->eol_type]; | |
3797 | } | |
716e0b0a | 3798 | setup_coding_system (coding->symbol, coding); |
54f78171 KH |
3799 | } |
3800 | return; | |
3801 | } | |
3802 | ||
4ed46869 KH |
3803 | /* Emacs has a mechanism to automatically detect a coding system if it |
3804 | is one of Emacs' internal format, ISO2022, SJIS, and BIG5. But, | |
3805 | it's impossible to distinguish some coding systems accurately | |
3806 | because they use the same range of codes. So, at first, coding | |
3807 | systems are categorized into 7, those are: | |
3808 | ||
0ef69138 | 3809 | o coding-category-emacs-mule |
4ed46869 KH |
3810 | |
3811 | The category for a coding system which has the same code range | |
3812 | as Emacs' internal format. Assigned the coding-system (Lisp | |
0ef69138 | 3813 | symbol) `emacs-mule' by default. |
4ed46869 KH |
3814 | |
3815 | o coding-category-sjis | |
3816 | ||
3817 | The category for a coding system which has the same code range | |
3818 | as SJIS. Assigned the coding-system (Lisp | |
7717c392 | 3819 | symbol) `japanese-shift-jis' by default. |
4ed46869 KH |
3820 | |
3821 | o coding-category-iso-7 | |
3822 | ||
3823 | The category for a coding system which has the same code range | |
7717c392 | 3824 | as ISO2022 of 7-bit environment. This doesn't use any locking |
d46c5b12 KH |
3825 | shift and single shift functions. This can encode/decode all |
3826 | charsets. Assigned the coding-system (Lisp symbol) | |
3827 | `iso-2022-7bit' by default. | |
3828 | ||
3829 | o coding-category-iso-7-tight | |
3830 | ||
3831 | Same as coding-category-iso-7 except that this can | |
3832 | encode/decode only the specified charsets. | |
4ed46869 KH |
3833 | |
3834 | o coding-category-iso-8-1 | |
3835 | ||
3836 | The category for a coding system which has the same code range | |
3837 | as ISO2022 of 8-bit environment and graphic plane 1 used only | |
7717c392 KH |
3838 | for DIMENSION1 charset. This doesn't use any locking shift |
3839 | and single shift functions. Assigned the coding-system (Lisp | |
3840 | symbol) `iso-latin-1' by default. | |
4ed46869 KH |
3841 | |
3842 | o coding-category-iso-8-2 | |
3843 | ||
3844 | The category for a coding system which has the same code range | |
3845 | as ISO2022 of 8-bit environment and graphic plane 1 used only | |
7717c392 KH |
3846 | for DIMENSION2 charset. This doesn't use any locking shift |
3847 | and single shift functions. Assigned the coding-system (Lisp | |
3848 | symbol) `japanese-iso-8bit' by default. | |
4ed46869 | 3849 | |
7717c392 | 3850 | o coding-category-iso-7-else |
4ed46869 KH |
3851 | |
3852 | The category for a coding system which has the same code range | |
8ca3766a | 3853 | as ISO2022 of 7-bit environment but uses locking shift or |
7717c392 KH |
3854 | single shift functions. Assigned the coding-system (Lisp |
3855 | symbol) `iso-2022-7bit-lock' by default. | |
3856 | ||
3857 | o coding-category-iso-8-else | |
3858 | ||
3859 | The category for a coding system which has the same code range | |
8ca3766a | 3860 | as ISO2022 of 8-bit environment but uses locking shift or |
7717c392 KH |
3861 | single shift functions. Assigned the coding-system (Lisp |
3862 | symbol) `iso-2022-8bit-ss2' by default. | |
4ed46869 KH |
3863 | |
3864 | o coding-category-big5 | |
3865 | ||
3866 | The category for a coding system which has the same code range | |
3867 | as BIG5. Assigned the coding-system (Lisp symbol) | |
e0e989f6 | 3868 | `cn-big5' by default. |
4ed46869 | 3869 | |
fa42c37f KH |
3870 | o coding-category-utf-8 |
3871 | ||
3872 | The category for a coding system which has the same code range | |
3873 | as UTF-8 (cf. RFC2279). Assigned the coding-system (Lisp | |
3874 | symbol) `utf-8' by default. | |
3875 | ||
3876 | o coding-category-utf-16-be | |
3877 | ||
3878 | The category for a coding system in which a text has an | |
3879 | Unicode signature (cf. Unicode Standard) in the order of BIG | |
3880 | endian at the head. Assigned the coding-system (Lisp symbol) | |
3881 | `utf-16-be' by default. | |
3882 | ||
3883 | o coding-category-utf-16-le | |
3884 | ||
3885 | The category for a coding system in which a text has an | |
3886 | Unicode signature (cf. Unicode Standard) in the order of | |
3887 | LITTLE endian at the head. Assigned the coding-system (Lisp | |
3888 | symbol) `utf-16-le' by default. | |
3889 | ||
1397dc18 KH |
3890 | o coding-category-ccl |
3891 | ||
3892 | The category for a coding system of which encoder/decoder is | |
3893 | written in CCL programs. The default value is nil, i.e., no | |
3894 | coding system is assigned. | |
3895 | ||
4ed46869 KH |
3896 | o coding-category-binary |
3897 | ||
3898 | The category for a coding system not categorized in any of the | |
3899 | above. Assigned the coding-system (Lisp symbol) | |
e0e989f6 | 3900 | `no-conversion' by default. |
4ed46869 KH |
3901 | |
3902 | Each of them is a Lisp symbol and the value is an actual | |
cfb43547 | 3903 | `coding-system' (this is also a Lisp symbol) assigned by a user. |
4ed46869 KH |
3904 | What Emacs does actually is to detect a category of coding system. |
3905 | Then, it uses a `coding-system' assigned to it. If Emacs can't | |
cfb43547 | 3906 | decide a single possible category, it selects a category of the |
4ed46869 KH |
3907 | highest priority. Priorities of categories are also specified by a |
3908 | user in a Lisp variable `coding-category-list'. | |
3909 | ||
3910 | */ | |
3911 | ||
66cfb530 KH |
3912 | static |
3913 | int ascii_skip_code[256]; | |
3914 | ||
d46c5b12 | 3915 | /* Detect how a text of length SRC_BYTES pointed by SOURCE is encoded. |
4ed46869 KH |
3916 | If it detects possible coding systems, return an integer in which |
3917 | appropriate flag bits are set. Flag bits are defined by macros | |
fa42c37f KH |
3918 | CODING_CATEGORY_MASK_XXX in `coding.h'. If PRIORITIES is non-NULL, |
3919 | it should point the table `coding_priorities'. In that case, only | |
3920 | the flag bit for a coding system of the highest priority is set in | |
0a28aafb KH |
3921 | the returned value. If MULTIBYTEP is nonzero, 8-bit codes of the |
3922 | range 0x80..0x9F are in multibyte form. | |
4ed46869 | 3923 | |
d46c5b12 KH |
3924 | How many ASCII characters are at the head is returned as *SKIP. */ |
3925 | ||
3926 | static int | |
0a28aafb | 3927 | detect_coding_mask (source, src_bytes, priorities, skip, multibytep) |
d46c5b12 KH |
3928 | unsigned char *source; |
3929 | int src_bytes, *priorities, *skip; | |
0a28aafb | 3930 | int multibytep; |
4ed46869 KH |
3931 | { |
3932 | register unsigned char c; | |
d46c5b12 | 3933 | unsigned char *src = source, *src_end = source + src_bytes; |
fa42c37f | 3934 | unsigned int mask, utf16_examined_p, iso2022_examined_p; |
da55a2b7 | 3935 | int i; |
4ed46869 KH |
3936 | |
3937 | /* At first, skip all ASCII characters and control characters except | |
3938 | for three ISO2022 specific control characters. */ | |
66cfb530 KH |
3939 | ascii_skip_code[ISO_CODE_SO] = 0; |
3940 | ascii_skip_code[ISO_CODE_SI] = 0; | |
3941 | ascii_skip_code[ISO_CODE_ESC] = 0; | |
3942 | ||
bcf26d6a | 3943 | label_loop_detect_coding: |
66cfb530 | 3944 | while (src < src_end && ascii_skip_code[*src]) src++; |
d46c5b12 | 3945 | *skip = src - source; |
4ed46869 KH |
3946 | |
3947 | if (src >= src_end) | |
3948 | /* We found nothing other than ASCII. There's nothing to do. */ | |
d46c5b12 | 3949 | return 0; |
4ed46869 | 3950 | |
8a8147d6 | 3951 | c = *src; |
4ed46869 KH |
3952 | /* The text seems to be encoded in some multilingual coding system. |
3953 | Now, try to find in which coding system the text is encoded. */ | |
3954 | if (c < 0x80) | |
bcf26d6a KH |
3955 | { |
3956 | /* i.e. (c == ISO_CODE_ESC || c == ISO_CODE_SI || c == ISO_CODE_SO) */ | |
3957 | /* C is an ISO2022 specific control code of C0. */ | |
0a28aafb | 3958 | mask = detect_coding_iso2022 (src, src_end, multibytep); |
1b2af4b0 | 3959 | if (mask == 0) |
d46c5b12 KH |
3960 | { |
3961 | /* No valid ISO2022 code follows C. Try again. */ | |
3962 | src++; | |
66cfb530 KH |
3963 | if (c == ISO_CODE_ESC) |
3964 | ascii_skip_code[ISO_CODE_ESC] = 1; | |
3965 | else | |
3966 | ascii_skip_code[ISO_CODE_SO] = ascii_skip_code[ISO_CODE_SI] = 1; | |
d46c5b12 KH |
3967 | goto label_loop_detect_coding; |
3968 | } | |
3969 | if (priorities) | |
fa42c37f KH |
3970 | { |
3971 | for (i = 0; i < CODING_CATEGORY_IDX_MAX; i++) | |
3972 | { | |
3973 | if (mask & priorities[i]) | |
3974 | return priorities[i]; | |
3975 | } | |
3976 | return CODING_CATEGORY_MASK_RAW_TEXT; | |
3977 | } | |
bcf26d6a | 3978 | } |
d46c5b12 | 3979 | else |
c4825358 | 3980 | { |
d46c5b12 | 3981 | int try; |
4ed46869 | 3982 | |
0a28aafb | 3983 | if (multibytep && c == LEADING_CODE_8_BIT_CONTROL) |
67091e59 | 3984 | c = src[1] - 0x20; |
0a28aafb | 3985 | |
d46c5b12 KH |
3986 | if (c < 0xA0) |
3987 | { | |
3988 | /* C is the first byte of SJIS character code, | |
fa42c37f KH |
3989 | or a leading-code of Emacs' internal format (emacs-mule), |
3990 | or the first byte of UTF-16. */ | |
3991 | try = (CODING_CATEGORY_MASK_SJIS | |
3992 | | CODING_CATEGORY_MASK_EMACS_MULE | |
3993 | | CODING_CATEGORY_MASK_UTF_16_BE | |
3994 | | CODING_CATEGORY_MASK_UTF_16_LE); | |
d46c5b12 KH |
3995 | |
3996 | /* Or, if C is a special latin extra code, | |
3997 | or is an ISO2022 specific control code of C1 (SS2 or SS3), | |
3998 | or is an ISO2022 control-sequence-introducer (CSI), | |
3999 | we should also consider the possibility of ISO2022 codings. */ | |
4000 | if ((VECTORP (Vlatin_extra_code_table) | |
4001 | && !NILP (XVECTOR (Vlatin_extra_code_table)->contents[c])) | |
4002 | || (c == ISO_CODE_SS2 || c == ISO_CODE_SS3) | |
4003 | || (c == ISO_CODE_CSI | |
4004 | && (src < src_end | |
4005 | && (*src == ']' | |
4006 | || ((*src == '0' || *src == '1' || *src == '2') | |
4007 | && src + 1 < src_end | |
4008 | && src[1] == ']'))))) | |
4009 | try |= (CODING_CATEGORY_MASK_ISO_8_ELSE | |
4010 | | CODING_CATEGORY_MASK_ISO_8BIT); | |
4011 | } | |
c4825358 | 4012 | else |
d46c5b12 KH |
4013 | /* C is a character of ISO2022 in graphic plane right, |
4014 | or a SJIS's 1-byte character code (i.e. JISX0201), | |
fa42c37f KH |
4015 | or the first byte of BIG5's 2-byte code, |
4016 | or the first byte of UTF-8/16. */ | |
d46c5b12 KH |
4017 | try = (CODING_CATEGORY_MASK_ISO_8_ELSE |
4018 | | CODING_CATEGORY_MASK_ISO_8BIT | |
4019 | | CODING_CATEGORY_MASK_SJIS | |
fa42c37f KH |
4020 | | CODING_CATEGORY_MASK_BIG5 |
4021 | | CODING_CATEGORY_MASK_UTF_8 | |
4022 | | CODING_CATEGORY_MASK_UTF_16_BE | |
4023 | | CODING_CATEGORY_MASK_UTF_16_LE); | |
d46c5b12 | 4024 | |
1397dc18 KH |
4025 | /* Or, we may have to consider the possibility of CCL. */ |
4026 | if (coding_system_table[CODING_CATEGORY_IDX_CCL] | |
4027 | && (coding_system_table[CODING_CATEGORY_IDX_CCL] | |
4028 | ->spec.ccl.valid_codes)[c]) | |
4029 | try |= CODING_CATEGORY_MASK_CCL; | |
4030 | ||
d46c5b12 | 4031 | mask = 0; |
fa42c37f | 4032 | utf16_examined_p = iso2022_examined_p = 0; |
d46c5b12 KH |
4033 | if (priorities) |
4034 | { | |
4035 | for (i = 0; i < CODING_CATEGORY_IDX_MAX; i++) | |
4036 | { | |
fa42c37f KH |
4037 | if (!iso2022_examined_p |
4038 | && (priorities[i] & try & CODING_CATEGORY_MASK_ISO)) | |
4039 | { | |
4040 | mask |= detect_coding_iso2022 (src, src_end); | |
4041 | iso2022_examined_p = 1; | |
4042 | } | |
5ab13dd0 | 4043 | else if (priorities[i] & try & CODING_CATEGORY_MASK_SJIS) |
0a28aafb | 4044 | mask |= detect_coding_sjis (src, src_end, multibytep); |
fa42c37f | 4045 | else if (priorities[i] & try & CODING_CATEGORY_MASK_UTF_8) |
0a28aafb | 4046 | mask |= detect_coding_utf_8 (src, src_end, multibytep); |
fa42c37f KH |
4047 | else if (!utf16_examined_p |
4048 | && (priorities[i] & try & | |
4049 | CODING_CATEGORY_MASK_UTF_16_BE_LE)) | |
4050 | { | |
0a28aafb | 4051 | mask |= detect_coding_utf_16 (src, src_end, multibytep); |
fa42c37f KH |
4052 | utf16_examined_p = 1; |
4053 | } | |
5ab13dd0 | 4054 | else if (priorities[i] & try & CODING_CATEGORY_MASK_BIG5) |
0a28aafb | 4055 | mask |= detect_coding_big5 (src, src_end, multibytep); |
5ab13dd0 | 4056 | else if (priorities[i] & try & CODING_CATEGORY_MASK_EMACS_MULE) |
0a28aafb | 4057 | mask |= detect_coding_emacs_mule (src, src_end, multibytep); |
89fa8b36 | 4058 | else if (priorities[i] & try & CODING_CATEGORY_MASK_CCL) |
0a28aafb | 4059 | mask |= detect_coding_ccl (src, src_end, multibytep); |
5ab13dd0 | 4060 | else if (priorities[i] & CODING_CATEGORY_MASK_RAW_TEXT) |
fa42c37f | 4061 | mask |= CODING_CATEGORY_MASK_RAW_TEXT; |
5ab13dd0 | 4062 | else if (priorities[i] & CODING_CATEGORY_MASK_BINARY) |
fa42c37f KH |
4063 | mask |= CODING_CATEGORY_MASK_BINARY; |
4064 | if (mask & priorities[i]) | |
4065 | return priorities[i]; | |
d46c5b12 KH |
4066 | } |
4067 | return CODING_CATEGORY_MASK_RAW_TEXT; | |
4068 | } | |
4069 | if (try & CODING_CATEGORY_MASK_ISO) | |
0a28aafb | 4070 | mask |= detect_coding_iso2022 (src, src_end, multibytep); |
d46c5b12 | 4071 | if (try & CODING_CATEGORY_MASK_SJIS) |
0a28aafb | 4072 | mask |= detect_coding_sjis (src, src_end, multibytep); |
d46c5b12 | 4073 | if (try & CODING_CATEGORY_MASK_BIG5) |
0a28aafb | 4074 | mask |= detect_coding_big5 (src, src_end, multibytep); |
fa42c37f | 4075 | if (try & CODING_CATEGORY_MASK_UTF_8) |
0a28aafb | 4076 | mask |= detect_coding_utf_8 (src, src_end, multibytep); |
fa42c37f | 4077 | if (try & CODING_CATEGORY_MASK_UTF_16_BE_LE) |
0a28aafb | 4078 | mask |= detect_coding_utf_16 (src, src_end, multibytep); |
d46c5b12 | 4079 | if (try & CODING_CATEGORY_MASK_EMACS_MULE) |
0a28aafb | 4080 | mask |= detect_coding_emacs_mule (src, src_end, multibytep); |
1397dc18 | 4081 | if (try & CODING_CATEGORY_MASK_CCL) |
0a28aafb | 4082 | mask |= detect_coding_ccl (src, src_end, multibytep); |
c4825358 | 4083 | } |
5ab13dd0 | 4084 | return (mask | CODING_CATEGORY_MASK_RAW_TEXT | CODING_CATEGORY_MASK_BINARY); |
4ed46869 KH |
4085 | } |
4086 | ||
4087 | /* Detect how a text of length SRC_BYTES pointed by SRC is encoded. | |
4088 | The information of the detected coding system is set in CODING. */ | |
4089 | ||
4090 | void | |
4091 | detect_coding (coding, src, src_bytes) | |
4092 | struct coding_system *coding; | |
4093 | unsigned char *src; | |
4094 | int src_bytes; | |
4095 | { | |
d46c5b12 | 4096 | unsigned int idx; |
da55a2b7 | 4097 | int skip, mask; |
84d60297 | 4098 | Lisp_Object val; |
4ed46869 | 4099 | |
84d60297 | 4100 | val = Vcoding_category_list; |
64c1e55f KH |
4101 | mask = detect_coding_mask (src, src_bytes, coding_priorities, &skip, |
4102 | coding->src_multibyte); | |
d46c5b12 | 4103 | coding->heading_ascii = skip; |
4ed46869 | 4104 | |
d46c5b12 KH |
4105 | if (!mask) return; |
4106 | ||
4107 | /* We found a single coding system of the highest priority in MASK. */ | |
4108 | idx = 0; | |
4109 | while (mask && ! (mask & 1)) mask >>= 1, idx++; | |
4110 | if (! mask) | |
4111 | idx = CODING_CATEGORY_IDX_RAW_TEXT; | |
4ed46869 | 4112 | |
f5c1dd0d | 4113 | val = SYMBOL_VALUE (XVECTOR (Vcoding_category_table)->contents[idx]); |
d46c5b12 KH |
4114 | |
4115 | if (coding->eol_type != CODING_EOL_UNDECIDED) | |
27901516 | 4116 | { |
84d60297 | 4117 | Lisp_Object tmp; |
d46c5b12 | 4118 | |
84d60297 | 4119 | tmp = Fget (val, Qeol_type); |
d46c5b12 KH |
4120 | if (VECTORP (tmp)) |
4121 | val = XVECTOR (tmp)->contents[coding->eol_type]; | |
4ed46869 | 4122 | } |
b73bfc1c KH |
4123 | |
4124 | /* Setup this new coding system while preserving some slots. */ | |
4125 | { | |
4126 | int src_multibyte = coding->src_multibyte; | |
4127 | int dst_multibyte = coding->dst_multibyte; | |
4128 | ||
4129 | setup_coding_system (val, coding); | |
4130 | coding->src_multibyte = src_multibyte; | |
4131 | coding->dst_multibyte = dst_multibyte; | |
4132 | coding->heading_ascii = skip; | |
4133 | } | |
4ed46869 KH |
4134 | } |
4135 | ||
d46c5b12 KH |
4136 | /* Detect how end-of-line of a text of length SRC_BYTES pointed by |
4137 | SOURCE is encoded. Return one of CODING_EOL_LF, CODING_EOL_CRLF, | |
4138 | CODING_EOL_CR, and CODING_EOL_UNDECIDED. | |
4139 | ||
4140 | How many non-eol characters are at the head is returned as *SKIP. */ | |
4ed46869 | 4141 | |
bc4bc72a RS |
4142 | #define MAX_EOL_CHECK_COUNT 3 |
4143 | ||
d46c5b12 KH |
4144 | static int |
4145 | detect_eol_type (source, src_bytes, skip) | |
4146 | unsigned char *source; | |
4147 | int src_bytes, *skip; | |
4ed46869 | 4148 | { |
d46c5b12 | 4149 | unsigned char *src = source, *src_end = src + src_bytes; |
4ed46869 | 4150 | unsigned char c; |
bc4bc72a RS |
4151 | int total = 0; /* How many end-of-lines are found so far. */ |
4152 | int eol_type = CODING_EOL_UNDECIDED; | |
4153 | int this_eol_type; | |
4ed46869 | 4154 | |
d46c5b12 KH |
4155 | *skip = 0; |
4156 | ||
bc4bc72a | 4157 | while (src < src_end && total < MAX_EOL_CHECK_COUNT) |
4ed46869 KH |
4158 | { |
4159 | c = *src++; | |
bc4bc72a | 4160 | if (c == '\n' || c == '\r') |
4ed46869 | 4161 | { |
d46c5b12 KH |
4162 | if (*skip == 0) |
4163 | *skip = src - 1 - source; | |
bc4bc72a RS |
4164 | total++; |
4165 | if (c == '\n') | |
4166 | this_eol_type = CODING_EOL_LF; | |
4167 | else if (src >= src_end || *src != '\n') | |
4168 | this_eol_type = CODING_EOL_CR; | |
4ed46869 | 4169 | else |
bc4bc72a RS |
4170 | this_eol_type = CODING_EOL_CRLF, src++; |
4171 | ||
4172 | if (eol_type == CODING_EOL_UNDECIDED) | |
4173 | /* This is the first end-of-line. */ | |
4174 | eol_type = this_eol_type; | |
4175 | else if (eol_type != this_eol_type) | |
d46c5b12 KH |
4176 | { |
4177 | /* The found type is different from what found before. */ | |
4178 | eol_type = CODING_EOL_INCONSISTENT; | |
4179 | break; | |
4180 | } | |
4ed46869 KH |
4181 | } |
4182 | } | |
bc4bc72a | 4183 | |
d46c5b12 KH |
4184 | if (*skip == 0) |
4185 | *skip = src_end - source; | |
85a02ca4 | 4186 | return eol_type; |
4ed46869 KH |
4187 | } |
4188 | ||
fa42c37f KH |
4189 | /* Like detect_eol_type, but detect EOL type in 2-octet |
4190 | big-endian/little-endian format for coding systems utf-16-be and | |
4191 | utf-16-le. */ | |
4192 | ||
4193 | static int | |
4194 | detect_eol_type_in_2_octet_form (source, src_bytes, skip, big_endian_p) | |
4195 | unsigned char *source; | |
cfb43547 | 4196 | int src_bytes, *skip, big_endian_p; |
fa42c37f KH |
4197 | { |
4198 | unsigned char *src = source, *src_end = src + src_bytes; | |
4199 | unsigned int c1, c2; | |
4200 | int total = 0; /* How many end-of-lines are found so far. */ | |
4201 | int eol_type = CODING_EOL_UNDECIDED; | |
4202 | int this_eol_type; | |
4203 | int msb, lsb; | |
4204 | ||
4205 | if (big_endian_p) | |
4206 | msb = 0, lsb = 1; | |
4207 | else | |
4208 | msb = 1, lsb = 0; | |
4209 | ||
4210 | *skip = 0; | |
4211 | ||
4212 | while ((src + 1) < src_end && total < MAX_EOL_CHECK_COUNT) | |
4213 | { | |
4214 | c1 = (src[msb] << 8) | (src[lsb]); | |
4215 | src += 2; | |
4216 | ||
4217 | if (c1 == '\n' || c1 == '\r') | |
4218 | { | |
4219 | if (*skip == 0) | |
4220 | *skip = src - 2 - source; | |
4221 | total++; | |
4222 | if (c1 == '\n') | |
4223 | { | |
4224 | this_eol_type = CODING_EOL_LF; | |
4225 | } | |
4226 | else | |
4227 | { | |
4228 | if ((src + 1) >= src_end) | |
4229 | { | |
4230 | this_eol_type = CODING_EOL_CR; | |
4231 | } | |
4232 | else | |
4233 | { | |
4234 | c2 = (src[msb] << 8) | (src[lsb]); | |
4235 | if (c2 == '\n') | |
4236 | this_eol_type = CODING_EOL_CRLF, src += 2; | |
4237 | else | |
4238 | this_eol_type = CODING_EOL_CR; | |
4239 | } | |
4240 | } | |
4241 | ||
4242 | if (eol_type == CODING_EOL_UNDECIDED) | |
4243 | /* This is the first end-of-line. */ | |
4244 | eol_type = this_eol_type; | |
4245 | else if (eol_type != this_eol_type) | |
4246 | { | |
4247 | /* The found type is different from what found before. */ | |
4248 | eol_type = CODING_EOL_INCONSISTENT; | |
4249 | break; | |
4250 | } | |
4251 | } | |
4252 | } | |
4253 | ||
4254 | if (*skip == 0) | |
4255 | *skip = src_end - source; | |
4256 | return eol_type; | |
4257 | } | |
4258 | ||
4ed46869 KH |
4259 | /* Detect how end-of-line of a text of length SRC_BYTES pointed by SRC |
4260 | is encoded. If it detects an appropriate format of end-of-line, it | |
4261 | sets the information in *CODING. */ | |
4262 | ||
4263 | void | |
4264 | detect_eol (coding, src, src_bytes) | |
4265 | struct coding_system *coding; | |
4266 | unsigned char *src; | |
4267 | int src_bytes; | |
4268 | { | |
4608c386 | 4269 | Lisp_Object val; |
d46c5b12 | 4270 | int skip; |
fa42c37f KH |
4271 | int eol_type; |
4272 | ||
4273 | switch (coding->category_idx) | |
4274 | { | |
4275 | case CODING_CATEGORY_IDX_UTF_16_BE: | |
4276 | eol_type = detect_eol_type_in_2_octet_form (src, src_bytes, &skip, 1); | |
4277 | break; | |
4278 | case CODING_CATEGORY_IDX_UTF_16_LE: | |
4279 | eol_type = detect_eol_type_in_2_octet_form (src, src_bytes, &skip, 0); | |
4280 | break; | |
4281 | default: | |
4282 | eol_type = detect_eol_type (src, src_bytes, &skip); | |
4283 | break; | |
4284 | } | |
d46c5b12 KH |
4285 | |
4286 | if (coding->heading_ascii > skip) | |
4287 | coding->heading_ascii = skip; | |
4288 | else | |
4289 | skip = coding->heading_ascii; | |
4ed46869 | 4290 | |
0ef69138 | 4291 | if (eol_type == CODING_EOL_UNDECIDED) |
4ed46869 | 4292 | return; |
27901516 KH |
4293 | if (eol_type == CODING_EOL_INCONSISTENT) |
4294 | { | |
4295 | #if 0 | |
4296 | /* This code is suppressed until we find a better way to | |
992f23f2 | 4297 | distinguish raw text file and binary file. */ |
27901516 KH |
4298 | |
4299 | /* If we have already detected that the coding is raw-text, the | |
4300 | coding should actually be no-conversion. */ | |
4301 | if (coding->type == coding_type_raw_text) | |
4302 | { | |
4303 | setup_coding_system (Qno_conversion, coding); | |
4304 | return; | |
4305 | } | |
4306 | /* Else, let's decode only text code anyway. */ | |
4307 | #endif /* 0 */ | |
1b2af4b0 | 4308 | eol_type = CODING_EOL_LF; |
27901516 KH |
4309 | } |
4310 | ||
4608c386 | 4311 | val = Fget (coding->symbol, Qeol_type); |
4ed46869 | 4312 | if (VECTORP (val) && XVECTOR (val)->size == 3) |
d46c5b12 | 4313 | { |
b73bfc1c KH |
4314 | int src_multibyte = coding->src_multibyte; |
4315 | int dst_multibyte = coding->dst_multibyte; | |
4316 | ||
d46c5b12 | 4317 | setup_coding_system (XVECTOR (val)->contents[eol_type], coding); |
b73bfc1c KH |
4318 | coding->src_multibyte = src_multibyte; |
4319 | coding->dst_multibyte = dst_multibyte; | |
d46c5b12 KH |
4320 | coding->heading_ascii = skip; |
4321 | } | |
4322 | } | |
4323 | ||
4324 | #define CONVERSION_BUFFER_EXTRA_ROOM 256 | |
4325 | ||
b73bfc1c KH |
4326 | #define DECODING_BUFFER_MAG(coding) \ |
4327 | (coding->type == coding_type_iso2022 \ | |
4328 | ? 3 \ | |
4329 | : (coding->type == coding_type_ccl \ | |
4330 | ? coding->spec.ccl.decoder.buf_magnification \ | |
4331 | : 2)) | |
d46c5b12 KH |
4332 | |
4333 | /* Return maximum size (bytes) of a buffer enough for decoding | |
4334 | SRC_BYTES of text encoded in CODING. */ | |
4335 | ||
4336 | int | |
4337 | decoding_buffer_size (coding, src_bytes) | |
4338 | struct coding_system *coding; | |
4339 | int src_bytes; | |
4340 | { | |
4341 | return (src_bytes * DECODING_BUFFER_MAG (coding) | |
4342 | + CONVERSION_BUFFER_EXTRA_ROOM); | |
4343 | } | |
4344 | ||
4345 | /* Return maximum size (bytes) of a buffer enough for encoding | |
4346 | SRC_BYTES of text to CODING. */ | |
4347 | ||
4348 | int | |
4349 | encoding_buffer_size (coding, src_bytes) | |
4350 | struct coding_system *coding; | |
4351 | int src_bytes; | |
4352 | { | |
4353 | int magnification; | |
4354 | ||
4355 | if (coding->type == coding_type_ccl) | |
4356 | magnification = coding->spec.ccl.encoder.buf_magnification; | |
b73bfc1c | 4357 | else if (CODING_REQUIRE_ENCODING (coding)) |
d46c5b12 | 4358 | magnification = 3; |
b73bfc1c KH |
4359 | else |
4360 | magnification = 1; | |
d46c5b12 KH |
4361 | |
4362 | return (src_bytes * magnification + CONVERSION_BUFFER_EXTRA_ROOM); | |
4363 | } | |
4364 | ||
73be902c KH |
4365 | /* Working buffer for code conversion. */ |
4366 | struct conversion_buffer | |
4367 | { | |
4368 | int size; /* size of data. */ | |
4369 | int on_stack; /* 1 if allocated by alloca. */ | |
4370 | unsigned char *data; | |
4371 | }; | |
d46c5b12 | 4372 | |
73be902c KH |
4373 | /* Don't use alloca for allocating memory space larger than this, lest |
4374 | we overflow their stack. */ | |
4375 | #define MAX_ALLOCA 16*1024 | |
d46c5b12 | 4376 | |
73be902c KH |
4377 | /* Allocate LEN bytes of memory for BUF (struct conversion_buffer). */ |
4378 | #define allocate_conversion_buffer(buf, len) \ | |
4379 | do { \ | |
4380 | if (len < MAX_ALLOCA) \ | |
4381 | { \ | |
4382 | buf.data = (unsigned char *) alloca (len); \ | |
4383 | buf.on_stack = 1; \ | |
4384 | } \ | |
4385 | else \ | |
4386 | { \ | |
4387 | buf.data = (unsigned char *) xmalloc (len); \ | |
4388 | buf.on_stack = 0; \ | |
4389 | } \ | |
4390 | buf.size = len; \ | |
4391 | } while (0) | |
d46c5b12 | 4392 | |
73be902c KH |
4393 | /* Double the allocated memory for *BUF. */ |
4394 | static void | |
4395 | extend_conversion_buffer (buf) | |
4396 | struct conversion_buffer *buf; | |
d46c5b12 | 4397 | { |
73be902c | 4398 | if (buf->on_stack) |
d46c5b12 | 4399 | { |
73be902c KH |
4400 | unsigned char *save = buf->data; |
4401 | buf->data = (unsigned char *) xmalloc (buf->size * 2); | |
4402 | bcopy (save, buf->data, buf->size); | |
4403 | buf->on_stack = 0; | |
d46c5b12 | 4404 | } |
73be902c KH |
4405 | else |
4406 | { | |
4407 | buf->data = (unsigned char *) xrealloc (buf->data, buf->size * 2); | |
4408 | } | |
4409 | buf->size *= 2; | |
4410 | } | |
4411 | ||
4412 | /* Free the allocated memory for BUF if it is not on stack. */ | |
4413 | static void | |
4414 | free_conversion_buffer (buf) | |
4415 | struct conversion_buffer *buf; | |
4416 | { | |
4417 | if (!buf->on_stack) | |
4418 | xfree (buf->data); | |
d46c5b12 KH |
4419 | } |
4420 | ||
4421 | int | |
4422 | ccl_coding_driver (coding, source, destination, src_bytes, dst_bytes, encodep) | |
4423 | struct coding_system *coding; | |
4424 | unsigned char *source, *destination; | |
4425 | int src_bytes, dst_bytes, encodep; | |
4426 | { | |
4427 | struct ccl_program *ccl | |
4428 | = encodep ? &coding->spec.ccl.encoder : &coding->spec.ccl.decoder; | |
1c3478b0 | 4429 | unsigned char *dst = destination; |
d46c5b12 | 4430 | |
bd64290d | 4431 | ccl->suppress_error = coding->suppress_error; |
ae9ff118 | 4432 | ccl->last_block = coding->mode & CODING_MODE_LAST_BLOCK; |
aaaf0b1e | 4433 | if (encodep) |
80e0ca99 KH |
4434 | { |
4435 | /* On encoding, EOL format is converted within ccl_driver. For | |
4436 | that, setup proper information in the structure CCL. */ | |
4437 | ccl->eol_type = coding->eol_type; | |
4438 | if (ccl->eol_type ==CODING_EOL_UNDECIDED) | |
4439 | ccl->eol_type = CODING_EOL_LF; | |
4440 | ccl->cr_consumed = coding->spec.ccl.cr_carryover; | |
4441 | } | |
7272d75c | 4442 | ccl->multibyte = coding->src_multibyte; |
1c3478b0 KH |
4443 | if (coding->spec.ccl.eight_bit_carryover[0] != 0) |
4444 | { | |
4445 | /* Move carryover bytes to DESTINATION. */ | |
4446 | unsigned char *p = coding->spec.ccl.eight_bit_carryover; | |
4447 | while (*p) | |
4448 | *dst++ = *p++; | |
4449 | coding->spec.ccl.eight_bit_carryover[0] = 0; | |
4450 | if (dst_bytes) | |
4451 | dst_bytes -= dst - destination; | |
4452 | } | |
4453 | ||
4454 | coding->produced = (ccl_driver (ccl, source, dst, src_bytes, dst_bytes, | |
4455 | &(coding->consumed)) | |
4456 | + dst - destination); | |
4457 | ||
b73bfc1c | 4458 | if (encodep) |
80e0ca99 KH |
4459 | { |
4460 | coding->produced_char = coding->produced; | |
4461 | coding->spec.ccl.cr_carryover = ccl->cr_consumed; | |
4462 | } | |
ade8d05e KH |
4463 | else if (!ccl->eight_bit_control) |
4464 | { | |
4465 | /* The produced bytes forms a valid multibyte sequence. */ | |
4466 | coding->produced_char | |
4467 | = multibyte_chars_in_text (destination, coding->produced); | |
4468 | coding->spec.ccl.eight_bit_carryover[0] = 0; | |
4469 | } | |
b73bfc1c KH |
4470 | else |
4471 | { | |
1c3478b0 KH |
4472 | /* On decoding, the destination should always multibyte. But, |
4473 | CCL program might have been generated an invalid multibyte | |
4474 | sequence. Here we make such a sequence valid as | |
4475 | multibyte. */ | |
b73bfc1c KH |
4476 | int bytes |
4477 | = dst_bytes ? dst_bytes : source + coding->consumed - destination; | |
1c3478b0 KH |
4478 | |
4479 | if ((coding->consumed < src_bytes | |
4480 | || !ccl->last_block) | |
4481 | && coding->produced >= 1 | |
4482 | && destination[coding->produced - 1] >= 0x80) | |
4483 | { | |
4484 | /* We should not convert the tailing 8-bit codes to | |
4485 | multibyte form even if they doesn't form a valid | |
4486 | multibyte sequence. They may form a valid sequence in | |
4487 | the next call. */ | |
4488 | int carryover = 0; | |
4489 | ||
4490 | if (destination[coding->produced - 1] < 0xA0) | |
4491 | carryover = 1; | |
4492 | else if (coding->produced >= 2) | |
4493 | { | |
4494 | if (destination[coding->produced - 2] >= 0x80) | |
4495 | { | |
4496 | if (destination[coding->produced - 2] < 0xA0) | |
4497 | carryover = 2; | |
4498 | else if (coding->produced >= 3 | |
4499 | && destination[coding->produced - 3] >= 0x80 | |
4500 | && destination[coding->produced - 3] < 0xA0) | |
4501 | carryover = 3; | |
4502 | } | |
4503 | } | |
4504 | if (carryover > 0) | |
4505 | { | |
4506 | BCOPY_SHORT (destination + coding->produced - carryover, | |
4507 | coding->spec.ccl.eight_bit_carryover, | |
4508 | carryover); | |
4509 | coding->spec.ccl.eight_bit_carryover[carryover] = 0; | |
4510 | coding->produced -= carryover; | |
4511 | } | |
4512 | } | |
b73bfc1c KH |
4513 | coding->produced = str_as_multibyte (destination, bytes, |
4514 | coding->produced, | |
4515 | &(coding->produced_char)); | |
4516 | } | |
69f76525 | 4517 | |
d46c5b12 KH |
4518 | switch (ccl->status) |
4519 | { | |
4520 | case CCL_STAT_SUSPEND_BY_SRC: | |
73be902c | 4521 | coding->result = CODING_FINISH_INSUFFICIENT_SRC; |
d46c5b12 KH |
4522 | break; |
4523 | case CCL_STAT_SUSPEND_BY_DST: | |
73be902c | 4524 | coding->result = CODING_FINISH_INSUFFICIENT_DST; |
d46c5b12 | 4525 | break; |
9864ebce KH |
4526 | case CCL_STAT_QUIT: |
4527 | case CCL_STAT_INVALID_CMD: | |
73be902c | 4528 | coding->result = CODING_FINISH_INTERRUPT; |
9864ebce | 4529 | break; |
d46c5b12 | 4530 | default: |
73be902c | 4531 | coding->result = CODING_FINISH_NORMAL; |
d46c5b12 KH |
4532 | break; |
4533 | } | |
73be902c | 4534 | return coding->result; |
4ed46869 KH |
4535 | } |
4536 | ||
aaaf0b1e KH |
4537 | /* Decode EOL format of the text at PTR of BYTES length destructively |
4538 | according to CODING->eol_type. This is called after the CCL | |
4539 | program produced a decoded text at PTR. If we do CRLF->LF | |
4540 | conversion, update CODING->produced and CODING->produced_char. */ | |
4541 | ||
4542 | static void | |
4543 | decode_eol_post_ccl (coding, ptr, bytes) | |
4544 | struct coding_system *coding; | |
4545 | unsigned char *ptr; | |
4546 | int bytes; | |
4547 | { | |
4548 | Lisp_Object val, saved_coding_symbol; | |
4549 | unsigned char *pend = ptr + bytes; | |
4550 | int dummy; | |
4551 | ||
4552 | /* Remember the current coding system symbol. We set it back when | |
4553 | an inconsistent EOL is found so that `last-coding-system-used' is | |
4554 | set to the coding system that doesn't specify EOL conversion. */ | |
4555 | saved_coding_symbol = coding->symbol; | |
4556 | ||
4557 | coding->spec.ccl.cr_carryover = 0; | |
4558 | if (coding->eol_type == CODING_EOL_UNDECIDED) | |
4559 | { | |
4560 | /* Here, to avoid the call of setup_coding_system, we directly | |
4561 | call detect_eol_type. */ | |
4562 | coding->eol_type = detect_eol_type (ptr, bytes, &dummy); | |
74b01b80 EZ |
4563 | if (coding->eol_type == CODING_EOL_INCONSISTENT) |
4564 | coding->eol_type = CODING_EOL_LF; | |
4565 | if (coding->eol_type != CODING_EOL_UNDECIDED) | |
4566 | { | |
4567 | val = Fget (coding->symbol, Qeol_type); | |
4568 | if (VECTORP (val) && XVECTOR (val)->size == 3) | |
4569 | coding->symbol = XVECTOR (val)->contents[coding->eol_type]; | |
4570 | } | |
aaaf0b1e KH |
4571 | coding->mode |= CODING_MODE_INHIBIT_INCONSISTENT_EOL; |
4572 | } | |
4573 | ||
74b01b80 EZ |
4574 | if (coding->eol_type == CODING_EOL_LF |
4575 | || coding->eol_type == CODING_EOL_UNDECIDED) | |
aaaf0b1e KH |
4576 | { |
4577 | /* We have nothing to do. */ | |
4578 | ptr = pend; | |
4579 | } | |
4580 | else if (coding->eol_type == CODING_EOL_CRLF) | |
4581 | { | |
4582 | unsigned char *pstart = ptr, *p = ptr; | |
4583 | ||
4584 | if (! (coding->mode & CODING_MODE_LAST_BLOCK) | |
4585 | && *(pend - 1) == '\r') | |
4586 | { | |
4587 | /* If the last character is CR, we can't handle it here | |
4588 | because LF will be in the not-yet-decoded source text. | |
4589 | Recorded that the CR is not yet processed. */ | |
4590 | coding->spec.ccl.cr_carryover = 1; | |
4591 | coding->produced--; | |
4592 | coding->produced_char--; | |
4593 | pend--; | |
4594 | } | |
4595 | while (ptr < pend) | |
4596 | { | |
4597 | if (*ptr == '\r') | |
4598 | { | |
4599 | if (ptr + 1 < pend && *(ptr + 1) == '\n') | |
4600 | { | |
4601 | *p++ = '\n'; | |
4602 | ptr += 2; | |
4603 | } | |
4604 | else | |
4605 | { | |
4606 | if (coding->mode & CODING_MODE_INHIBIT_INCONSISTENT_EOL) | |
4607 | goto undo_eol_conversion; | |
4608 | *p++ = *ptr++; | |
4609 | } | |
4610 | } | |
4611 | else if (*ptr == '\n' | |
4612 | && coding->mode & CODING_MODE_INHIBIT_INCONSISTENT_EOL) | |
4613 | goto undo_eol_conversion; | |
4614 | else | |
4615 | *p++ = *ptr++; | |
4616 | continue; | |
4617 | ||
4618 | undo_eol_conversion: | |
4619 | /* We have faced with inconsistent EOL format at PTR. | |
4620 | Convert all LFs before PTR back to CRLFs. */ | |
4621 | for (p--, ptr--; p >= pstart; p--) | |
4622 | { | |
4623 | if (*p == '\n') | |
4624 | *ptr-- = '\n', *ptr-- = '\r'; | |
4625 | else | |
4626 | *ptr-- = *p; | |
4627 | } | |
4628 | /* If carryover is recorded, cancel it because we don't | |
4629 | convert CRLF anymore. */ | |
4630 | if (coding->spec.ccl.cr_carryover) | |
4631 | { | |
4632 | coding->spec.ccl.cr_carryover = 0; | |
4633 | coding->produced++; | |
4634 | coding->produced_char++; | |
4635 | pend++; | |
4636 | } | |
4637 | p = ptr = pend; | |
4638 | coding->eol_type = CODING_EOL_LF; | |
4639 | coding->symbol = saved_coding_symbol; | |
4640 | } | |
4641 | if (p < pend) | |
4642 | { | |
4643 | /* As each two-byte sequence CRLF was converted to LF, (PEND | |
4644 | - P) is the number of deleted characters. */ | |
4645 | coding->produced -= pend - p; | |
4646 | coding->produced_char -= pend - p; | |
4647 | } | |
4648 | } | |
4649 | else /* i.e. coding->eol_type == CODING_EOL_CR */ | |
4650 | { | |
4651 | unsigned char *p = ptr; | |
4652 | ||
4653 | for (; ptr < pend; ptr++) | |
4654 | { | |
4655 | if (*ptr == '\r') | |
4656 | *ptr = '\n'; | |
4657 | else if (*ptr == '\n' | |
4658 | && coding->mode & CODING_MODE_INHIBIT_INCONSISTENT_EOL) | |
4659 | { | |
4660 | for (; p < ptr; p++) | |
4661 | { | |
4662 | if (*p == '\n') | |
4663 | *p = '\r'; | |
4664 | } | |
4665 | ptr = pend; | |
4666 | coding->eol_type = CODING_EOL_LF; | |
4667 | coding->symbol = saved_coding_symbol; | |
4668 | } | |
4669 | } | |
4670 | } | |
4671 | } | |
4672 | ||
4ed46869 KH |
4673 | /* See "GENERAL NOTES about `decode_coding_XXX ()' functions". Before |
4674 | decoding, it may detect coding system and format of end-of-line if | |
b73bfc1c KH |
4675 | those are not yet decided. The source should be unibyte, the |
4676 | result is multibyte if CODING->dst_multibyte is nonzero, else | |
4677 | unibyte. */ | |
4ed46869 KH |
4678 | |
4679 | int | |
d46c5b12 | 4680 | decode_coding (coding, source, destination, src_bytes, dst_bytes) |
4ed46869 KH |
4681 | struct coding_system *coding; |
4682 | unsigned char *source, *destination; | |
4683 | int src_bytes, dst_bytes; | |
4ed46869 | 4684 | { |
0ef69138 | 4685 | if (coding->type == coding_type_undecided) |
4ed46869 KH |
4686 | detect_coding (coding, source, src_bytes); |
4687 | ||
aaaf0b1e KH |
4688 | if (coding->eol_type == CODING_EOL_UNDECIDED |
4689 | && coding->type != coding_type_ccl) | |
8844fa83 KH |
4690 | { |
4691 | detect_eol (coding, source, src_bytes); | |
4692 | /* We had better recover the original eol format if we | |
8ca3766a | 4693 | encounter an inconsistent eol format while decoding. */ |
8844fa83 KH |
4694 | coding->mode |= CODING_MODE_INHIBIT_INCONSISTENT_EOL; |
4695 | } | |
4ed46869 | 4696 | |
b73bfc1c KH |
4697 | coding->produced = coding->produced_char = 0; |
4698 | coding->consumed = coding->consumed_char = 0; | |
4699 | coding->errors = 0; | |
4700 | coding->result = CODING_FINISH_NORMAL; | |
4701 | ||
4ed46869 KH |
4702 | switch (coding->type) |
4703 | { | |
4ed46869 | 4704 | case coding_type_sjis: |
b73bfc1c KH |
4705 | decode_coding_sjis_big5 (coding, source, destination, |
4706 | src_bytes, dst_bytes, 1); | |
4ed46869 KH |
4707 | break; |
4708 | ||
4709 | case coding_type_iso2022: | |
b73bfc1c KH |
4710 | decode_coding_iso2022 (coding, source, destination, |
4711 | src_bytes, dst_bytes); | |
4ed46869 KH |
4712 | break; |
4713 | ||
4714 | case coding_type_big5: | |
b73bfc1c KH |
4715 | decode_coding_sjis_big5 (coding, source, destination, |
4716 | src_bytes, dst_bytes, 0); | |
4717 | break; | |
4718 | ||
4719 | case coding_type_emacs_mule: | |
4720 | decode_coding_emacs_mule (coding, source, destination, | |
4721 | src_bytes, dst_bytes); | |
4ed46869 KH |
4722 | break; |
4723 | ||
4724 | case coding_type_ccl: | |
aaaf0b1e KH |
4725 | if (coding->spec.ccl.cr_carryover) |
4726 | { | |
4727 | /* Set the CR which is not processed by the previous call of | |
4728 | decode_eol_post_ccl in DESTINATION. */ | |
4729 | *destination = '\r'; | |
4730 | coding->produced++; | |
4731 | coding->produced_char++; | |
4732 | dst_bytes--; | |
4733 | } | |
4734 | ccl_coding_driver (coding, source, | |
4735 | destination + coding->spec.ccl.cr_carryover, | |
b73bfc1c | 4736 | src_bytes, dst_bytes, 0); |
aaaf0b1e KH |
4737 | if (coding->eol_type != CODING_EOL_LF) |
4738 | decode_eol_post_ccl (coding, destination, coding->produced); | |
d46c5b12 KH |
4739 | break; |
4740 | ||
b73bfc1c KH |
4741 | default: |
4742 | decode_eol (coding, source, destination, src_bytes, dst_bytes); | |
4743 | } | |
4744 | ||
4745 | if (coding->result == CODING_FINISH_INSUFFICIENT_SRC | |
e7c9eef9 | 4746 | && coding->mode & CODING_MODE_LAST_BLOCK |
b73bfc1c KH |
4747 | && coding->consumed == src_bytes) |
4748 | coding->result = CODING_FINISH_NORMAL; | |
4749 | ||
4750 | if (coding->mode & CODING_MODE_LAST_BLOCK | |
4751 | && coding->result == CODING_FINISH_INSUFFICIENT_SRC) | |
4752 | { | |
4753 | unsigned char *src = source + coding->consumed; | |
4754 | unsigned char *dst = destination + coding->produced; | |
4755 | ||
4756 | src_bytes -= coding->consumed; | |
bb10be8b | 4757 | coding->errors++; |
b73bfc1c KH |
4758 | if (COMPOSING_P (coding)) |
4759 | DECODE_COMPOSITION_END ('1'); | |
4760 | while (src_bytes--) | |
d46c5b12 | 4761 | { |
b73bfc1c KH |
4762 | int c = *src++; |
4763 | dst += CHAR_STRING (c, dst); | |
4764 | coding->produced_char++; | |
d46c5b12 | 4765 | } |
b73bfc1c KH |
4766 | coding->consumed = coding->consumed_char = src - source; |
4767 | coding->produced = dst - destination; | |
73be902c | 4768 | coding->result = CODING_FINISH_NORMAL; |
4ed46869 KH |
4769 | } |
4770 | ||
b73bfc1c KH |
4771 | if (!coding->dst_multibyte) |
4772 | { | |
4773 | coding->produced = str_as_unibyte (destination, coding->produced); | |
4774 | coding->produced_char = coding->produced; | |
4775 | } | |
4ed46869 | 4776 | |
b73bfc1c KH |
4777 | return coding->result; |
4778 | } | |
52d41803 | 4779 | |
b73bfc1c KH |
4780 | /* See "GENERAL NOTES about `encode_coding_XXX ()' functions". The |
4781 | multibyteness of the source is CODING->src_multibyte, the | |
4782 | multibyteness of the result is always unibyte. */ | |
4ed46869 KH |
4783 | |
4784 | int | |
d46c5b12 | 4785 | encode_coding (coding, source, destination, src_bytes, dst_bytes) |
4ed46869 KH |
4786 | struct coding_system *coding; |
4787 | unsigned char *source, *destination; | |
4788 | int src_bytes, dst_bytes; | |
4ed46869 | 4789 | { |
b73bfc1c KH |
4790 | coding->produced = coding->produced_char = 0; |
4791 | coding->consumed = coding->consumed_char = 0; | |
4792 | coding->errors = 0; | |
4793 | coding->result = CODING_FINISH_NORMAL; | |
4ed46869 | 4794 | |
d46c5b12 KH |
4795 | switch (coding->type) |
4796 | { | |
4ed46869 | 4797 | case coding_type_sjis: |
b73bfc1c KH |
4798 | encode_coding_sjis_big5 (coding, source, destination, |
4799 | src_bytes, dst_bytes, 1); | |
4ed46869 KH |
4800 | break; |
4801 | ||
4802 | case coding_type_iso2022: | |
b73bfc1c KH |
4803 | encode_coding_iso2022 (coding, source, destination, |
4804 | src_bytes, dst_bytes); | |
4ed46869 KH |
4805 | break; |
4806 | ||
4807 | case coding_type_big5: | |
b73bfc1c KH |
4808 | encode_coding_sjis_big5 (coding, source, destination, |
4809 | src_bytes, dst_bytes, 0); | |
4810 | break; | |
4811 | ||
4812 | case coding_type_emacs_mule: | |
4813 | encode_coding_emacs_mule (coding, source, destination, | |
4814 | src_bytes, dst_bytes); | |
4ed46869 KH |
4815 | break; |
4816 | ||
4817 | case coding_type_ccl: | |
b73bfc1c KH |
4818 | ccl_coding_driver (coding, source, destination, |
4819 | src_bytes, dst_bytes, 1); | |
d46c5b12 KH |
4820 | break; |
4821 | ||
b73bfc1c KH |
4822 | default: |
4823 | encode_eol (coding, source, destination, src_bytes, dst_bytes); | |
4824 | } | |
4825 | ||
73be902c KH |
4826 | if (coding->mode & CODING_MODE_LAST_BLOCK |
4827 | && coding->result == CODING_FINISH_INSUFFICIENT_SRC) | |
b73bfc1c KH |
4828 | { |
4829 | unsigned char *src = source + coding->consumed; | |
b73bfc1c KH |
4830 | unsigned char *dst = destination + coding->produced; |
4831 | ||
4832 | if (coding->type == coding_type_iso2022) | |
4833 | ENCODE_RESET_PLANE_AND_REGISTER; | |
4834 | if (COMPOSING_P (coding)) | |
4835 | *dst++ = ISO_CODE_ESC, *dst++ = '1'; | |
4836 | if (coding->consumed < src_bytes) | |
d46c5b12 | 4837 | { |
b73bfc1c KH |
4838 | int len = src_bytes - coding->consumed; |
4839 | ||
fabf4a91 | 4840 | BCOPY_SHORT (src, dst, len); |
b73bfc1c KH |
4841 | if (coding->src_multibyte) |
4842 | len = str_as_unibyte (dst, len); | |
4843 | dst += len; | |
4844 | coding->consumed = src_bytes; | |
d46c5b12 | 4845 | } |
b73bfc1c | 4846 | coding->produced = coding->produced_char = dst - destination; |
73be902c | 4847 | coding->result = CODING_FINISH_NORMAL; |
4ed46869 KH |
4848 | } |
4849 | ||
bb10be8b KH |
4850 | if (coding->result == CODING_FINISH_INSUFFICIENT_SRC |
4851 | && coding->consumed == src_bytes) | |
4852 | coding->result = CODING_FINISH_NORMAL; | |
4853 | ||
b73bfc1c | 4854 | return coding->result; |
4ed46869 KH |
4855 | } |
4856 | ||
fb88bf2d KH |
4857 | /* Scan text in the region between *BEG and *END (byte positions), |
4858 | skip characters which we don't have to decode by coding system | |
4859 | CODING at the head and tail, then set *BEG and *END to the region | |
4860 | of the text we actually have to convert. The caller should move | |
b73bfc1c KH |
4861 | the gap out of the region in advance if the region is from a |
4862 | buffer. | |
4ed46869 | 4863 | |
d46c5b12 KH |
4864 | If STR is not NULL, *BEG and *END are indices into STR. */ |
4865 | ||
4866 | static void | |
4867 | shrink_decoding_region (beg, end, coding, str) | |
4868 | int *beg, *end; | |
4869 | struct coding_system *coding; | |
4870 | unsigned char *str; | |
4871 | { | |
fb88bf2d | 4872 | unsigned char *begp_orig, *begp, *endp_orig, *endp, c; |
d46c5b12 | 4873 | int eol_conversion; |
88993dfd | 4874 | Lisp_Object translation_table; |
d46c5b12 KH |
4875 | |
4876 | if (coding->type == coding_type_ccl | |
4877 | || coding->type == coding_type_undecided | |
b73bfc1c KH |
4878 | || coding->eol_type != CODING_EOL_LF |
4879 | || !NILP (coding->post_read_conversion) | |
4880 | || coding->composing != COMPOSITION_DISABLED) | |
d46c5b12 KH |
4881 | { |
4882 | /* We can't skip any data. */ | |
4883 | return; | |
4884 | } | |
b73bfc1c KH |
4885 | if (coding->type == coding_type_no_conversion |
4886 | || coding->type == coding_type_raw_text | |
4887 | || coding->type == coding_type_emacs_mule) | |
d46c5b12 | 4888 | { |
fb88bf2d KH |
4889 | /* We need no conversion, but don't have to skip any data here. |
4890 | Decoding routine handles them effectively anyway. */ | |
d46c5b12 KH |
4891 | return; |
4892 | } | |
4893 | ||
88993dfd KH |
4894 | translation_table = coding->translation_table_for_decode; |
4895 | if (NILP (translation_table) && !NILP (Venable_character_translation)) | |
4896 | translation_table = Vstandard_translation_table_for_decode; | |
4897 | if (CHAR_TABLE_P (translation_table)) | |
4898 | { | |
4899 | int i; | |
4900 | for (i = 0; i < 128; i++) | |
4901 | if (!NILP (CHAR_TABLE_REF (translation_table, i))) | |
4902 | break; | |
4903 | if (i < 128) | |
fa46990e | 4904 | /* Some ASCII character should be translated. We give up |
88993dfd KH |
4905 | shrinking. */ |
4906 | return; | |
4907 | } | |
4908 | ||
b73bfc1c | 4909 | if (coding->heading_ascii >= 0) |
d46c5b12 KH |
4910 | /* Detection routine has already found how much we can skip at the |
4911 | head. */ | |
4912 | *beg += coding->heading_ascii; | |
4913 | ||
4914 | if (str) | |
4915 | { | |
4916 | begp_orig = begp = str + *beg; | |
4917 | endp_orig = endp = str + *end; | |
4918 | } | |
4919 | else | |
4920 | { | |
fb88bf2d | 4921 | begp_orig = begp = BYTE_POS_ADDR (*beg); |
d46c5b12 KH |
4922 | endp_orig = endp = begp + *end - *beg; |
4923 | } | |
4924 | ||
fa46990e DL |
4925 | eol_conversion = (coding->eol_type == CODING_EOL_CR |
4926 | || coding->eol_type == CODING_EOL_CRLF); | |
4927 | ||
d46c5b12 KH |
4928 | switch (coding->type) |
4929 | { | |
d46c5b12 KH |
4930 | case coding_type_sjis: |
4931 | case coding_type_big5: | |
4932 | /* We can skip all ASCII characters at the head. */ | |
4933 | if (coding->heading_ascii < 0) | |
4934 | { | |
4935 | if (eol_conversion) | |
de9d083c | 4936 | while (begp < endp && *begp < 0x80 && *begp != '\r') begp++; |
d46c5b12 KH |
4937 | else |
4938 | while (begp < endp && *begp < 0x80) begp++; | |
4939 | } | |
4940 | /* We can skip all ASCII characters at the tail except for the | |
4941 | second byte of SJIS or BIG5 code. */ | |
4942 | if (eol_conversion) | |
de9d083c | 4943 | while (begp < endp && endp[-1] < 0x80 && endp[-1] != '\r') endp--; |
d46c5b12 KH |
4944 | else |
4945 | while (begp < endp && endp[-1] < 0x80) endp--; | |
ee59c65f RS |
4946 | /* Do not consider LF as ascii if preceded by CR, since that |
4947 | confuses eol decoding. */ | |
4948 | if (begp < endp && endp < endp_orig && endp[-1] == '\r' && endp[0] == '\n') | |
4949 | endp++; | |
d46c5b12 KH |
4950 | if (begp < endp && endp < endp_orig && endp[-1] >= 0x80) |
4951 | endp++; | |
4952 | break; | |
4953 | ||
b73bfc1c | 4954 | case coding_type_iso2022: |
622fece5 KH |
4955 | if (CODING_SPEC_ISO_INITIAL_DESIGNATION (coding, 0) != CHARSET_ASCII) |
4956 | /* We can't skip any data. */ | |
4957 | break; | |
d46c5b12 KH |
4958 | if (coding->heading_ascii < 0) |
4959 | { | |
d46c5b12 KH |
4960 | /* We can skip all ASCII characters at the head except for a |
4961 | few control codes. */ | |
4962 | while (begp < endp && (c = *begp) < 0x80 | |
4963 | && c != ISO_CODE_CR && c != ISO_CODE_SO | |
4964 | && c != ISO_CODE_SI && c != ISO_CODE_ESC | |
4965 | && (!eol_conversion || c != ISO_CODE_LF)) | |
4966 | begp++; | |
4967 | } | |
4968 | switch (coding->category_idx) | |
4969 | { | |
4970 | case CODING_CATEGORY_IDX_ISO_8_1: | |
4971 | case CODING_CATEGORY_IDX_ISO_8_2: | |
4972 | /* We can skip all ASCII characters at the tail. */ | |
4973 | if (eol_conversion) | |
de9d083c | 4974 | while (begp < endp && (c = endp[-1]) < 0x80 && c != '\r') endp--; |
d46c5b12 KH |
4975 | else |
4976 | while (begp < endp && endp[-1] < 0x80) endp--; | |
ee59c65f RS |
4977 | /* Do not consider LF as ascii if preceded by CR, since that |
4978 | confuses eol decoding. */ | |
4979 | if (begp < endp && endp < endp_orig && endp[-1] == '\r' && endp[0] == '\n') | |
4980 | endp++; | |
d46c5b12 KH |
4981 | break; |
4982 | ||
4983 | case CODING_CATEGORY_IDX_ISO_7: | |
4984 | case CODING_CATEGORY_IDX_ISO_7_TIGHT: | |
de79a6a5 | 4985 | { |
8ca3766a | 4986 | /* We can skip all characters at the tail except for 8-bit |
de79a6a5 KH |
4987 | codes and ESC and the following 2-byte at the tail. */ |
4988 | unsigned char *eight_bit = NULL; | |
4989 | ||
4990 | if (eol_conversion) | |
4991 | while (begp < endp | |
4992 | && (c = endp[-1]) != ISO_CODE_ESC && c != '\r') | |
4993 | { | |
4994 | if (!eight_bit && c & 0x80) eight_bit = endp; | |
4995 | endp--; | |
4996 | } | |
4997 | else | |
4998 | while (begp < endp | |
4999 | && (c = endp[-1]) != ISO_CODE_ESC) | |
5000 | { | |
5001 | if (!eight_bit && c & 0x80) eight_bit = endp; | |
5002 | endp--; | |
5003 | } | |
5004 | /* Do not consider LF as ascii if preceded by CR, since that | |
5005 | confuses eol decoding. */ | |
5006 | if (begp < endp && endp < endp_orig | |
5007 | && endp[-1] == '\r' && endp[0] == '\n') | |
5008 | endp++; | |
5009 | if (begp < endp && endp[-1] == ISO_CODE_ESC) | |
5010 | { | |
5011 | if (endp + 1 < endp_orig && end[0] == '(' && end[1] == 'B') | |
5012 | /* This is an ASCII designation sequence. We can | |
5013 | surely skip the tail. But, if we have | |
5014 | encountered an 8-bit code, skip only the codes | |
5015 | after that. */ | |
5016 | endp = eight_bit ? eight_bit : endp + 2; | |
5017 | else | |
5018 | /* Hmmm, we can't skip the tail. */ | |
5019 | endp = endp_orig; | |
5020 | } | |
5021 | else if (eight_bit) | |
5022 | endp = eight_bit; | |
5023 | } | |
d46c5b12 | 5024 | } |
b73bfc1c KH |
5025 | break; |
5026 | ||
5027 | default: | |
5028 | abort (); | |
d46c5b12 KH |
5029 | } |
5030 | *beg += begp - begp_orig; | |
5031 | *end += endp - endp_orig; | |
5032 | return; | |
5033 | } | |
5034 | ||
5035 | /* Like shrink_decoding_region but for encoding. */ | |
5036 | ||
5037 | static void | |
5038 | shrink_encoding_region (beg, end, coding, str) | |
5039 | int *beg, *end; | |
5040 | struct coding_system *coding; | |
5041 | unsigned char *str; | |
5042 | { | |
5043 | unsigned char *begp_orig, *begp, *endp_orig, *endp; | |
5044 | int eol_conversion; | |
88993dfd | 5045 | Lisp_Object translation_table; |
d46c5b12 | 5046 | |
b73bfc1c KH |
5047 | if (coding->type == coding_type_ccl |
5048 | || coding->eol_type == CODING_EOL_CRLF | |
5049 | || coding->eol_type == CODING_EOL_CR | |
5050 | || coding->cmp_data && coding->cmp_data->used > 0) | |
d46c5b12 | 5051 | { |
b73bfc1c KH |
5052 | /* We can't skip any data. */ |
5053 | return; | |
5054 | } | |
5055 | if (coding->type == coding_type_no_conversion | |
5056 | || coding->type == coding_type_raw_text | |
5057 | || coding->type == coding_type_emacs_mule | |
5058 | || coding->type == coding_type_undecided) | |
5059 | { | |
5060 | /* We need no conversion, but don't have to skip any data here. | |
5061 | Encoding routine handles them effectively anyway. */ | |
d46c5b12 KH |
5062 | return; |
5063 | } | |
5064 | ||
88993dfd KH |
5065 | translation_table = coding->translation_table_for_encode; |
5066 | if (NILP (translation_table) && !NILP (Venable_character_translation)) | |
5067 | translation_table = Vstandard_translation_table_for_encode; | |
5068 | if (CHAR_TABLE_P (translation_table)) | |
5069 | { | |
5070 | int i; | |
5071 | for (i = 0; i < 128; i++) | |
5072 | if (!NILP (CHAR_TABLE_REF (translation_table, i))) | |
5073 | break; | |
5074 | if (i < 128) | |
8ca3766a | 5075 | /* Some ASCII character should be translated. We give up |
88993dfd KH |
5076 | shrinking. */ |
5077 | return; | |
5078 | } | |
5079 | ||
d46c5b12 KH |
5080 | if (str) |
5081 | { | |
5082 | begp_orig = begp = str + *beg; | |
5083 | endp_orig = endp = str + *end; | |
5084 | } | |
5085 | else | |
5086 | { | |
fb88bf2d | 5087 | begp_orig = begp = BYTE_POS_ADDR (*beg); |
d46c5b12 KH |
5088 | endp_orig = endp = begp + *end - *beg; |
5089 | } | |
5090 | ||
5091 | eol_conversion = (coding->eol_type == CODING_EOL_CR | |
5092 | || coding->eol_type == CODING_EOL_CRLF); | |
5093 | ||
5094 | /* Here, we don't have to check coding->pre_write_conversion because | |
5095 | the caller is expected to have handled it already. */ | |
5096 | switch (coding->type) | |
5097 | { | |
d46c5b12 | 5098 | case coding_type_iso2022: |
622fece5 KH |
5099 | if (CODING_SPEC_ISO_INITIAL_DESIGNATION (coding, 0) != CHARSET_ASCII) |
5100 | /* We can't skip any data. */ | |
5101 | break; | |
d46c5b12 KH |
5102 | if (coding->flags & CODING_FLAG_ISO_DESIGNATE_AT_BOL) |
5103 | { | |
5104 | unsigned char *bol = begp; | |
5105 | while (begp < endp && *begp < 0x80) | |
5106 | { | |
5107 | begp++; | |
5108 | if (begp[-1] == '\n') | |
5109 | bol = begp; | |
5110 | } | |
5111 | begp = bol; | |
5112 | goto label_skip_tail; | |
5113 | } | |
5114 | /* fall down ... */ | |
5115 | ||
b73bfc1c KH |
5116 | case coding_type_sjis: |
5117 | case coding_type_big5: | |
d46c5b12 KH |
5118 | /* We can skip all ASCII characters at the head and tail. */ |
5119 | if (eol_conversion) | |
5120 | while (begp < endp && *begp < 0x80 && *begp != '\n') begp++; | |
5121 | else | |
5122 | while (begp < endp && *begp < 0x80) begp++; | |
5123 | label_skip_tail: | |
5124 | if (eol_conversion) | |
5125 | while (begp < endp && endp[-1] < 0x80 && endp[-1] != '\n') endp--; | |
5126 | else | |
5127 | while (begp < endp && *(endp - 1) < 0x80) endp--; | |
5128 | break; | |
b73bfc1c KH |
5129 | |
5130 | default: | |
5131 | abort (); | |
d46c5b12 KH |
5132 | } |
5133 | ||
5134 | *beg += begp - begp_orig; | |
5135 | *end += endp - endp_orig; | |
5136 | return; | |
5137 | } | |
5138 | ||
88993dfd KH |
5139 | /* As shrinking conversion region requires some overhead, we don't try |
5140 | shrinking if the length of conversion region is less than this | |
5141 | value. */ | |
5142 | static int shrink_conversion_region_threshhold = 1024; | |
5143 | ||
5144 | #define SHRINK_CONVERSION_REGION(beg, end, coding, str, encodep) \ | |
5145 | do { \ | |
5146 | if (*(end) - *(beg) > shrink_conversion_region_threshhold) \ | |
5147 | { \ | |
5148 | if (encodep) shrink_encoding_region (beg, end, coding, str); \ | |
5149 | else shrink_decoding_region (beg, end, coding, str); \ | |
5150 | } \ | |
5151 | } while (0) | |
5152 | ||
b843d1ae KH |
5153 | static Lisp_Object |
5154 | code_convert_region_unwind (dummy) | |
5155 | Lisp_Object dummy; | |
5156 | { | |
5157 | inhibit_pre_post_conversion = 0; | |
5158 | return Qnil; | |
5159 | } | |
5160 | ||
ec6d2bb8 KH |
5161 | /* Store information about all compositions in the range FROM and TO |
5162 | of OBJ in memory blocks pointed by CODING->cmp_data. OBJ is a | |
5163 | buffer or a string, defaults to the current buffer. */ | |
5164 | ||
5165 | void | |
5166 | coding_save_composition (coding, from, to, obj) | |
5167 | struct coding_system *coding; | |
5168 | int from, to; | |
5169 | Lisp_Object obj; | |
5170 | { | |
5171 | Lisp_Object prop; | |
5172 | int start, end; | |
5173 | ||
91bee881 KH |
5174 | if (coding->composing == COMPOSITION_DISABLED) |
5175 | return; | |
5176 | if (!coding->cmp_data) | |
5177 | coding_allocate_composition_data (coding, from); | |
ec6d2bb8 KH |
5178 | if (!find_composition (from, to, &start, &end, &prop, obj) |
5179 | || end > to) | |
5180 | return; | |
5181 | if (start < from | |
5182 | && (!find_composition (end, to, &start, &end, &prop, obj) | |
5183 | || end > to)) | |
5184 | return; | |
5185 | coding->composing = COMPOSITION_NO; | |
ec6d2bb8 KH |
5186 | do |
5187 | { | |
5188 | if (COMPOSITION_VALID_P (start, end, prop)) | |
5189 | { | |
5190 | enum composition_method method = COMPOSITION_METHOD (prop); | |
5191 | if (coding->cmp_data->used + COMPOSITION_DATA_MAX_BUNCH_LENGTH | |
5192 | >= COMPOSITION_DATA_SIZE) | |
5193 | coding_allocate_composition_data (coding, from); | |
5194 | /* For relative composition, we remember start and end | |
5195 | positions, for the other compositions, we also remember | |
5196 | components. */ | |
5197 | CODING_ADD_COMPOSITION_START (coding, start - from, method); | |
5198 | if (method != COMPOSITION_RELATIVE) | |
5199 | { | |
5200 | /* We must store a*/ | |
5201 | Lisp_Object val, ch; | |
5202 | ||
5203 | val = COMPOSITION_COMPONENTS (prop); | |
5204 | if (CONSP (val)) | |
5205 | while (CONSP (val)) | |
5206 | { | |
5207 | ch = XCAR (val), val = XCDR (val); | |
5208 | CODING_ADD_COMPOSITION_COMPONENT (coding, XINT (ch)); | |
5209 | } | |
5210 | else if (VECTORP (val) || STRINGP (val)) | |
5211 | { | |
5212 | int len = (VECTORP (val) | |
5213 | ? XVECTOR (val)->size : XSTRING (val)->size); | |
5214 | int i; | |
5215 | for (i = 0; i < len; i++) | |
5216 | { | |
5217 | ch = (STRINGP (val) | |
5218 | ? Faref (val, make_number (i)) | |
5219 | : XVECTOR (val)->contents[i]); | |
5220 | CODING_ADD_COMPOSITION_COMPONENT (coding, XINT (ch)); | |
5221 | } | |
5222 | } | |
5223 | else /* INTEGERP (val) */ | |
5224 | CODING_ADD_COMPOSITION_COMPONENT (coding, XINT (val)); | |
5225 | } | |
5226 | CODING_ADD_COMPOSITION_END (coding, end - from); | |
5227 | } | |
5228 | start = end; | |
5229 | } | |
5230 | while (start < to | |
5231 | && find_composition (start, to, &start, &end, &prop, obj) | |
5232 | && end <= to); | |
5233 | ||
5234 | /* Make coding->cmp_data point to the first memory block. */ | |
5235 | while (coding->cmp_data->prev) | |
5236 | coding->cmp_data = coding->cmp_data->prev; | |
5237 | coding->cmp_data_start = 0; | |
5238 | } | |
5239 | ||
5240 | /* Reflect the saved information about compositions to OBJ. | |
8ca3766a | 5241 | CODING->cmp_data points to a memory block for the information. OBJ |
ec6d2bb8 KH |
5242 | is a buffer or a string, defaults to the current buffer. */ |
5243 | ||
33fb63eb | 5244 | void |
ec6d2bb8 KH |
5245 | coding_restore_composition (coding, obj) |
5246 | struct coding_system *coding; | |
5247 | Lisp_Object obj; | |
5248 | { | |
5249 | struct composition_data *cmp_data = coding->cmp_data; | |
5250 | ||
5251 | if (!cmp_data) | |
5252 | return; | |
5253 | ||
5254 | while (cmp_data->prev) | |
5255 | cmp_data = cmp_data->prev; | |
5256 | ||
5257 | while (cmp_data) | |
5258 | { | |
5259 | int i; | |
5260 | ||
78108bcd KH |
5261 | for (i = 0; i < cmp_data->used && cmp_data->data[i] > 0; |
5262 | i += cmp_data->data[i]) | |
ec6d2bb8 KH |
5263 | { |
5264 | int *data = cmp_data->data + i; | |
5265 | enum composition_method method = (enum composition_method) data[3]; | |
5266 | Lisp_Object components; | |
5267 | ||
5268 | if (method == COMPOSITION_RELATIVE) | |
5269 | components = Qnil; | |
5270 | else | |
5271 | { | |
5272 | int len = data[0] - 4, j; | |
5273 | Lisp_Object args[MAX_COMPOSITION_COMPONENTS * 2 - 1]; | |
5274 | ||
5275 | for (j = 0; j < len; j++) | |
5276 | args[j] = make_number (data[4 + j]); | |
5277 | components = (method == COMPOSITION_WITH_ALTCHARS | |
5278 | ? Fstring (len, args) : Fvector (len, args)); | |
5279 | } | |
5280 | compose_text (data[1], data[2], components, Qnil, obj); | |
5281 | } | |
5282 | cmp_data = cmp_data->next; | |
5283 | } | |
5284 | } | |
5285 | ||
d46c5b12 | 5286 | /* Decode (if ENCODEP is zero) or encode (if ENCODEP is nonzero) the |
fb88bf2d KH |
5287 | text from FROM to TO (byte positions are FROM_BYTE and TO_BYTE) by |
5288 | coding system CODING, and return the status code of code conversion | |
5289 | (currently, this value has no meaning). | |
5290 | ||
5291 | How many characters (and bytes) are converted to how many | |
5292 | characters (and bytes) are recorded in members of the structure | |
5293 | CODING. | |
d46c5b12 | 5294 | |
6e44253b | 5295 | If REPLACE is nonzero, we do various things as if the original text |
d46c5b12 | 5296 | is deleted and a new text is inserted. See the comments in |
b73bfc1c KH |
5297 | replace_range (insdel.c) to know what we are doing. |
5298 | ||
5299 | If REPLACE is zero, it is assumed that the source text is unibyte. | |
8ca3766a | 5300 | Otherwise, it is assumed that the source text is multibyte. */ |
4ed46869 KH |
5301 | |
5302 | int | |
6e44253b KH |
5303 | code_convert_region (from, from_byte, to, to_byte, coding, encodep, replace) |
5304 | int from, from_byte, to, to_byte, encodep, replace; | |
4ed46869 | 5305 | struct coding_system *coding; |
4ed46869 | 5306 | { |
fb88bf2d KH |
5307 | int len = to - from, len_byte = to_byte - from_byte; |
5308 | int require, inserted, inserted_byte; | |
4b39528c | 5309 | int head_skip, tail_skip, total_skip = 0; |
84d60297 | 5310 | Lisp_Object saved_coding_symbol; |
fb88bf2d | 5311 | int first = 1; |
fb88bf2d | 5312 | unsigned char *src, *dst; |
84d60297 | 5313 | Lisp_Object deletion; |
e133c8fa | 5314 | int orig_point = PT, orig_len = len; |
6abb9bd9 | 5315 | int prev_Z; |
b73bfc1c KH |
5316 | int multibyte_p = !NILP (current_buffer->enable_multibyte_characters); |
5317 | ||
84d60297 | 5318 | deletion = Qnil; |
8844fa83 | 5319 | saved_coding_symbol = coding->symbol; |
d46c5b12 | 5320 | |
83fa074f | 5321 | if (from < PT && PT < to) |
e133c8fa KH |
5322 | { |
5323 | TEMP_SET_PT_BOTH (from, from_byte); | |
5324 | orig_point = from; | |
5325 | } | |
83fa074f | 5326 | |
6e44253b | 5327 | if (replace) |
d46c5b12 | 5328 | { |
fb88bf2d | 5329 | int saved_from = from; |
e077cc80 | 5330 | int saved_inhibit_modification_hooks; |
fb88bf2d | 5331 | |
d46c5b12 | 5332 | prepare_to_modify_buffer (from, to, &from); |
fb88bf2d KH |
5333 | if (saved_from != from) |
5334 | { | |
5335 | to = from + len; | |
b73bfc1c | 5336 | from_byte = CHAR_TO_BYTE (from), to_byte = CHAR_TO_BYTE (to); |
fb88bf2d KH |
5337 | len_byte = to_byte - from_byte; |
5338 | } | |
e077cc80 KH |
5339 | |
5340 | /* The code conversion routine can not preserve text properties | |
5341 | for now. So, we must remove all text properties in the | |
5342 | region. Here, we must suppress all modification hooks. */ | |
5343 | saved_inhibit_modification_hooks = inhibit_modification_hooks; | |
5344 | inhibit_modification_hooks = 1; | |
5345 | Fset_text_properties (make_number (from), make_number (to), Qnil, Qnil); | |
5346 | inhibit_modification_hooks = saved_inhibit_modification_hooks; | |
d46c5b12 | 5347 | } |
d46c5b12 KH |
5348 | |
5349 | if (! encodep && CODING_REQUIRE_DETECTION (coding)) | |
5350 | { | |
12410ef1 | 5351 | /* We must detect encoding of text and eol format. */ |
d46c5b12 KH |
5352 | |
5353 | if (from < GPT && to > GPT) | |
5354 | move_gap_both (from, from_byte); | |
5355 | if (coding->type == coding_type_undecided) | |
5356 | { | |
fb88bf2d | 5357 | detect_coding (coding, BYTE_POS_ADDR (from_byte), len_byte); |
d46c5b12 | 5358 | if (coding->type == coding_type_undecided) |
62b3ef1d KH |
5359 | { |
5360 | /* It seems that the text contains only ASCII, but we | |
d9aef30f | 5361 | should not leave it undecided because the deeper |
62b3ef1d KH |
5362 | decoding routine (decode_coding) tries to detect the |
5363 | encodings again in vain. */ | |
5364 | coding->type = coding_type_emacs_mule; | |
5365 | coding->category_idx = CODING_CATEGORY_IDX_EMACS_MULE; | |
d280ccb6 KH |
5366 | /* As emacs-mule decoder will handle composition, we |
5367 | need this setting to allocate coding->cmp_data | |
5368 | later. */ | |
5369 | coding->composing = COMPOSITION_NO; | |
62b3ef1d | 5370 | } |
d46c5b12 | 5371 | } |
aaaf0b1e KH |
5372 | if (coding->eol_type == CODING_EOL_UNDECIDED |
5373 | && coding->type != coding_type_ccl) | |
d46c5b12 | 5374 | { |
d46c5b12 KH |
5375 | detect_eol (coding, BYTE_POS_ADDR (from_byte), len_byte); |
5376 | if (coding->eol_type == CODING_EOL_UNDECIDED) | |
5377 | coding->eol_type = CODING_EOL_LF; | |
5378 | /* We had better recover the original eol format if we | |
8ca3766a | 5379 | encounter an inconsistent eol format while decoding. */ |
d46c5b12 KH |
5380 | coding->mode |= CODING_MODE_INHIBIT_INCONSISTENT_EOL; |
5381 | } | |
5382 | } | |
5383 | ||
d46c5b12 KH |
5384 | /* Now we convert the text. */ |
5385 | ||
5386 | /* For encoding, we must process pre-write-conversion in advance. */ | |
b73bfc1c KH |
5387 | if (! inhibit_pre_post_conversion |
5388 | && encodep | |
d46c5b12 KH |
5389 | && SYMBOLP (coding->pre_write_conversion) |
5390 | && ! NILP (Ffboundp (coding->pre_write_conversion))) | |
5391 | { | |
2b4f9037 KH |
5392 | /* The function in pre-write-conversion may put a new text in a |
5393 | new buffer. */ | |
0007bdd0 KH |
5394 | struct buffer *prev = current_buffer; |
5395 | Lisp_Object new; | |
d46c5b12 | 5396 | |
b843d1ae KH |
5397 | record_unwind_protect (code_convert_region_unwind, Qnil); |
5398 | /* We should not call any more pre-write/post-read-conversion | |
5399 | functions while this pre-write-conversion is running. */ | |
5400 | inhibit_pre_post_conversion = 1; | |
b39f748c AS |
5401 | call2 (coding->pre_write_conversion, |
5402 | make_number (from), make_number (to)); | |
b843d1ae KH |
5403 | inhibit_pre_post_conversion = 0; |
5404 | /* Discard the unwind protect. */ | |
5405 | specpdl_ptr--; | |
5406 | ||
d46c5b12 KH |
5407 | if (current_buffer != prev) |
5408 | { | |
5409 | len = ZV - BEGV; | |
0007bdd0 | 5410 | new = Fcurrent_buffer (); |
d46c5b12 | 5411 | set_buffer_internal_1 (prev); |
7dae4502 | 5412 | del_range_2 (from, from_byte, to, to_byte, 0); |
e133c8fa | 5413 | TEMP_SET_PT_BOTH (from, from_byte); |
0007bdd0 KH |
5414 | insert_from_buffer (XBUFFER (new), 1, len, 0); |
5415 | Fkill_buffer (new); | |
e133c8fa KH |
5416 | if (orig_point >= to) |
5417 | orig_point += len - orig_len; | |
5418 | else if (orig_point > from) | |
5419 | orig_point = from; | |
5420 | orig_len = len; | |
d46c5b12 | 5421 | to = from + len; |
b73bfc1c KH |
5422 | from_byte = CHAR_TO_BYTE (from); |
5423 | to_byte = CHAR_TO_BYTE (to); | |
d46c5b12 | 5424 | len_byte = to_byte - from_byte; |
e133c8fa | 5425 | TEMP_SET_PT_BOTH (from, from_byte); |
d46c5b12 KH |
5426 | } |
5427 | } | |
5428 | ||
12410ef1 KH |
5429 | if (replace) |
5430 | deletion = make_buffer_string_both (from, from_byte, to, to_byte, 1); | |
5431 | ||
ec6d2bb8 KH |
5432 | if (coding->composing != COMPOSITION_DISABLED) |
5433 | { | |
5434 | if (encodep) | |
5435 | coding_save_composition (coding, from, to, Fcurrent_buffer ()); | |
5436 | else | |
5437 | coding_allocate_composition_data (coding, from); | |
5438 | } | |
fb88bf2d | 5439 | |
b73bfc1c | 5440 | /* Try to skip the heading and tailing ASCIIs. */ |
4956c225 KH |
5441 | if (coding->type != coding_type_ccl) |
5442 | { | |
5443 | int from_byte_orig = from_byte, to_byte_orig = to_byte; | |
ec6d2bb8 | 5444 | |
4956c225 KH |
5445 | if (from < GPT && GPT < to) |
5446 | move_gap_both (from, from_byte); | |
5447 | SHRINK_CONVERSION_REGION (&from_byte, &to_byte, coding, NULL, encodep); | |
5448 | if (from_byte == to_byte | |
5449 | && (encodep || NILP (coding->post_read_conversion)) | |
5450 | && ! CODING_REQUIRE_FLUSHING (coding)) | |
5451 | { | |
5452 | coding->produced = len_byte; | |
5453 | coding->produced_char = len; | |
5454 | if (!replace) | |
5455 | /* We must record and adjust for this new text now. */ | |
5456 | adjust_after_insert (from, from_byte_orig, to, to_byte_orig, len); | |
5457 | return 0; | |
5458 | } | |
5459 | ||
5460 | head_skip = from_byte - from_byte_orig; | |
5461 | tail_skip = to_byte_orig - to_byte; | |
5462 | total_skip = head_skip + tail_skip; | |
5463 | from += head_skip; | |
5464 | to -= tail_skip; | |
5465 | len -= total_skip; len_byte -= total_skip; | |
5466 | } | |
d46c5b12 | 5467 | |
8ca3766a | 5468 | /* For conversion, we must put the gap before the text in addition to |
fb88bf2d KH |
5469 | making the gap larger for efficient decoding. The required gap |
5470 | size starts from 2000 which is the magic number used in make_gap. | |
5471 | But, after one batch of conversion, it will be incremented if we | |
5472 | find that it is not enough . */ | |
d46c5b12 KH |
5473 | require = 2000; |
5474 | ||
5475 | if (GAP_SIZE < require) | |
5476 | make_gap (require - GAP_SIZE); | |
5477 | move_gap_both (from, from_byte); | |
5478 | ||
d46c5b12 | 5479 | inserted = inserted_byte = 0; |
fb88bf2d KH |
5480 | |
5481 | GAP_SIZE += len_byte; | |
5482 | ZV -= len; | |
5483 | Z -= len; | |
5484 | ZV_BYTE -= len_byte; | |
5485 | Z_BYTE -= len_byte; | |
5486 | ||
d9f9a1bc GM |
5487 | if (GPT - BEG < BEG_UNCHANGED) |
5488 | BEG_UNCHANGED = GPT - BEG; | |
5489 | if (Z - GPT < END_UNCHANGED) | |
5490 | END_UNCHANGED = Z - GPT; | |
f2558efd | 5491 | |
b73bfc1c KH |
5492 | if (!encodep && coding->src_multibyte) |
5493 | { | |
5494 | /* Decoding routines expects that the source text is unibyte. | |
5495 | We must convert 8-bit characters of multibyte form to | |
5496 | unibyte. */ | |
5497 | int len_byte_orig = len_byte; | |
5498 | len_byte = str_as_unibyte (GAP_END_ADDR - len_byte, len_byte); | |
5499 | if (len_byte < len_byte_orig) | |
5500 | safe_bcopy (GAP_END_ADDR - len_byte_orig, GAP_END_ADDR - len_byte, | |
5501 | len_byte); | |
5502 | coding->src_multibyte = 0; | |
5503 | } | |
5504 | ||
d46c5b12 KH |
5505 | for (;;) |
5506 | { | |
fb88bf2d | 5507 | int result; |
d46c5b12 | 5508 | |
ec6d2bb8 | 5509 | /* The buffer memory is now: |
b73bfc1c KH |
5510 | +--------+converted-text+---------+-------original-text-------+---+ |
5511 | |<-from->|<--inserted-->|---------|<--------len_byte--------->|---| | |
5512 | |<---------------------- GAP ----------------------->| */ | |
ec6d2bb8 KH |
5513 | src = GAP_END_ADDR - len_byte; |
5514 | dst = GPT_ADDR + inserted_byte; | |
5515 | ||
d46c5b12 | 5516 | if (encodep) |
fb88bf2d | 5517 | result = encode_coding (coding, src, dst, len_byte, 0); |
d46c5b12 | 5518 | else |
fb88bf2d | 5519 | result = decode_coding (coding, src, dst, len_byte, 0); |
ec6d2bb8 KH |
5520 | |
5521 | /* The buffer memory is now: | |
b73bfc1c KH |
5522 | +--------+-------converted-text----+--+------original-text----+---+ |
5523 | |<-from->|<-inserted->|<-produced->|--|<-(len_byte-consumed)->|---| | |
5524 | |<---------------------- GAP ----------------------->| */ | |
ec6d2bb8 | 5525 | |
d46c5b12 KH |
5526 | inserted += coding->produced_char; |
5527 | inserted_byte += coding->produced; | |
d46c5b12 | 5528 | len_byte -= coding->consumed; |
ec6d2bb8 KH |
5529 | |
5530 | if (result == CODING_FINISH_INSUFFICIENT_CMP) | |
5531 | { | |
5532 | coding_allocate_composition_data (coding, from + inserted); | |
5533 | continue; | |
5534 | } | |
5535 | ||
fb88bf2d | 5536 | src += coding->consumed; |
3636f7a3 | 5537 | dst += coding->produced; |
d46c5b12 | 5538 | |
9864ebce KH |
5539 | if (result == CODING_FINISH_NORMAL) |
5540 | { | |
5541 | src += len_byte; | |
5542 | break; | |
5543 | } | |
d46c5b12 KH |
5544 | if (! encodep && result == CODING_FINISH_INCONSISTENT_EOL) |
5545 | { | |
fb88bf2d | 5546 | unsigned char *pend = dst, *p = pend - inserted_byte; |
38edf7d4 | 5547 | Lisp_Object eol_type; |
d46c5b12 KH |
5548 | |
5549 | /* Encode LFs back to the original eol format (CR or CRLF). */ | |
5550 | if (coding->eol_type == CODING_EOL_CR) | |
5551 | { | |
5552 | while (p < pend) if (*p++ == '\n') p[-1] = '\r'; | |
5553 | } | |
5554 | else | |
5555 | { | |
d46c5b12 KH |
5556 | int count = 0; |
5557 | ||
fb88bf2d KH |
5558 | while (p < pend) if (*p++ == '\n') count++; |
5559 | if (src - dst < count) | |
d46c5b12 | 5560 | { |
38edf7d4 | 5561 | /* We don't have sufficient room for encoding LFs |
fb88bf2d KH |
5562 | back to CRLF. We must record converted and |
5563 | not-yet-converted text back to the buffer | |
5564 | content, enlarge the gap, then record them out of | |
5565 | the buffer contents again. */ | |
5566 | int add = len_byte + inserted_byte; | |
5567 | ||
5568 | GAP_SIZE -= add; | |
5569 | ZV += add; Z += add; ZV_BYTE += add; Z_BYTE += add; | |
5570 | GPT += inserted_byte; GPT_BYTE += inserted_byte; | |
5571 | make_gap (count - GAP_SIZE); | |
5572 | GAP_SIZE += add; | |
5573 | ZV -= add; Z -= add; ZV_BYTE -= add; Z_BYTE -= add; | |
5574 | GPT -= inserted_byte; GPT_BYTE -= inserted_byte; | |
5575 | /* Don't forget to update SRC, DST, and PEND. */ | |
5576 | src = GAP_END_ADDR - len_byte; | |
5577 | dst = GPT_ADDR + inserted_byte; | |
5578 | pend = dst; | |
d46c5b12 | 5579 | } |
d46c5b12 KH |
5580 | inserted += count; |
5581 | inserted_byte += count; | |
fb88bf2d KH |
5582 | coding->produced += count; |
5583 | p = dst = pend + count; | |
5584 | while (count) | |
5585 | { | |
5586 | *--p = *--pend; | |
5587 | if (*p == '\n') count--, *--p = '\r'; | |
5588 | } | |
d46c5b12 KH |
5589 | } |
5590 | ||
5591 | /* Suppress eol-format conversion in the further conversion. */ | |
5592 | coding->eol_type = CODING_EOL_LF; | |
5593 | ||
38edf7d4 KH |
5594 | /* Set the coding system symbol to that for Unix-like EOL. */ |
5595 | eol_type = Fget (saved_coding_symbol, Qeol_type); | |
5596 | if (VECTORP (eol_type) | |
5597 | && XVECTOR (eol_type)->size == 3 | |
5598 | && SYMBOLP (XVECTOR (eol_type)->contents[CODING_EOL_LF])) | |
5599 | coding->symbol = XVECTOR (eol_type)->contents[CODING_EOL_LF]; | |
5600 | else | |
5601 | coding->symbol = saved_coding_symbol; | |
fb88bf2d KH |
5602 | |
5603 | continue; | |
d46c5b12 KH |
5604 | } |
5605 | if (len_byte <= 0) | |
944bd420 KH |
5606 | { |
5607 | if (coding->type != coding_type_ccl | |
5608 | || coding->mode & CODING_MODE_LAST_BLOCK) | |
5609 | break; | |
5610 | coding->mode |= CODING_MODE_LAST_BLOCK; | |
5611 | continue; | |
5612 | } | |
d46c5b12 KH |
5613 | if (result == CODING_FINISH_INSUFFICIENT_SRC) |
5614 | { | |
5615 | /* The source text ends in invalid codes. Let's just | |
5616 | make them valid buffer contents, and finish conversion. */ | |
70ad9fc4 GM |
5617 | if (multibyte_p) |
5618 | { | |
5619 | unsigned char *start = dst; | |
5620 | ||
5621 | inserted += len_byte; | |
5622 | while (len_byte--) | |
5623 | { | |
5624 | int c = *src++; | |
5625 | dst += CHAR_STRING (c, dst); | |
5626 | } | |
5627 | ||
5628 | inserted_byte += dst - start; | |
5629 | } | |
5630 | else | |
5631 | { | |
5632 | inserted += len_byte; | |
5633 | inserted_byte += len_byte; | |
5634 | while (len_byte--) | |
5635 | *dst++ = *src++; | |
5636 | } | |
d46c5b12 KH |
5637 | break; |
5638 | } | |
9864ebce KH |
5639 | if (result == CODING_FINISH_INTERRUPT) |
5640 | { | |
5641 | /* The conversion procedure was interrupted by a user. */ | |
9864ebce KH |
5642 | break; |
5643 | } | |
5644 | /* Now RESULT == CODING_FINISH_INSUFFICIENT_DST */ | |
5645 | if (coding->consumed < 1) | |
5646 | { | |
5647 | /* It's quite strange to require more memory without | |
5648 | consuming any bytes. Perhaps CCL program bug. */ | |
9864ebce KH |
5649 | break; |
5650 | } | |
fb88bf2d KH |
5651 | if (first) |
5652 | { | |
5653 | /* We have just done the first batch of conversion which was | |
8ca3766a | 5654 | stopped because of insufficient gap. Let's reconsider the |
fb88bf2d KH |
5655 | required gap size (i.e. SRT - DST) now. |
5656 | ||
5657 | We have converted ORIG bytes (== coding->consumed) into | |
5658 | NEW bytes (coding->produced). To convert the remaining | |
5659 | LEN bytes, we may need REQUIRE bytes of gap, where: | |
5660 | REQUIRE + LEN_BYTE = LEN_BYTE * (NEW / ORIG) | |
5661 | REQUIRE = LEN_BYTE * (NEW - ORIG) / ORIG | |
5662 | Here, we are sure that NEW >= ORIG. */ | |
6e44253b KH |
5663 | float ratio = coding->produced - coding->consumed; |
5664 | ratio /= coding->consumed; | |
5665 | require = len_byte * ratio; | |
fb88bf2d KH |
5666 | first = 0; |
5667 | } | |
5668 | if ((src - dst) < (require + 2000)) | |
5669 | { | |
5670 | /* See the comment above the previous call of make_gap. */ | |
5671 | int add = len_byte + inserted_byte; | |
5672 | ||
5673 | GAP_SIZE -= add; | |
5674 | ZV += add; Z += add; ZV_BYTE += add; Z_BYTE += add; | |
5675 | GPT += inserted_byte; GPT_BYTE += inserted_byte; | |
5676 | make_gap (require + 2000); | |
5677 | GAP_SIZE += add; | |
5678 | ZV -= add; Z -= add; ZV_BYTE -= add; Z_BYTE -= add; | |
5679 | GPT -= inserted_byte; GPT_BYTE -= inserted_byte; | |
fb88bf2d | 5680 | } |
d46c5b12 | 5681 | } |
fb88bf2d KH |
5682 | if (src - dst > 0) *dst = 0; /* Put an anchor. */ |
5683 | ||
b73bfc1c KH |
5684 | if (encodep && coding->dst_multibyte) |
5685 | { | |
5686 | /* The output is unibyte. We must convert 8-bit characters to | |
5687 | multibyte form. */ | |
5688 | if (inserted_byte * 2 > GAP_SIZE) | |
5689 | { | |
5690 | GAP_SIZE -= inserted_byte; | |
5691 | ZV += inserted_byte; Z += inserted_byte; | |
5692 | ZV_BYTE += inserted_byte; Z_BYTE += inserted_byte; | |
5693 | GPT += inserted_byte; GPT_BYTE += inserted_byte; | |
5694 | make_gap (inserted_byte - GAP_SIZE); | |
5695 | GAP_SIZE += inserted_byte; | |
5696 | ZV -= inserted_byte; Z -= inserted_byte; | |
5697 | ZV_BYTE -= inserted_byte; Z_BYTE -= inserted_byte; | |
5698 | GPT -= inserted_byte; GPT_BYTE -= inserted_byte; | |
5699 | } | |
5700 | inserted_byte = str_to_multibyte (GPT_ADDR, GAP_SIZE, inserted_byte); | |
5701 | } | |
7553d0e1 | 5702 | |
8ca3766a | 5703 | /* If we shrank the conversion area, adjust it now. */ |
12410ef1 KH |
5704 | if (total_skip > 0) |
5705 | { | |
5706 | if (tail_skip > 0) | |
5707 | safe_bcopy (GAP_END_ADDR, GPT_ADDR + inserted_byte, tail_skip); | |
5708 | inserted += total_skip; inserted_byte += total_skip; | |
5709 | GAP_SIZE += total_skip; | |
5710 | GPT -= head_skip; GPT_BYTE -= head_skip; | |
5711 | ZV -= total_skip; ZV_BYTE -= total_skip; | |
5712 | Z -= total_skip; Z_BYTE -= total_skip; | |
5713 | from -= head_skip; from_byte -= head_skip; | |
5714 | to += tail_skip; to_byte += tail_skip; | |
5715 | } | |
5716 | ||
6abb9bd9 | 5717 | prev_Z = Z; |
12410ef1 | 5718 | adjust_after_replace (from, from_byte, deletion, inserted, inserted_byte); |
6abb9bd9 | 5719 | inserted = Z - prev_Z; |
4ed46869 | 5720 | |
ec6d2bb8 KH |
5721 | if (!encodep && coding->cmp_data && coding->cmp_data->used) |
5722 | coding_restore_composition (coding, Fcurrent_buffer ()); | |
5723 | coding_free_composition_data (coding); | |
5724 | ||
b73bfc1c KH |
5725 | if (! inhibit_pre_post_conversion |
5726 | && ! encodep && ! NILP (coding->post_read_conversion)) | |
d46c5b12 | 5727 | { |
2b4f9037 | 5728 | Lisp_Object val; |
4ed46869 | 5729 | |
e133c8fa KH |
5730 | if (from != PT) |
5731 | TEMP_SET_PT_BOTH (from, from_byte); | |
6abb9bd9 | 5732 | prev_Z = Z; |
b843d1ae KH |
5733 | record_unwind_protect (code_convert_region_unwind, Qnil); |
5734 | /* We should not call any more pre-write/post-read-conversion | |
5735 | functions while this post-read-conversion is running. */ | |
5736 | inhibit_pre_post_conversion = 1; | |
2b4f9037 | 5737 | val = call1 (coding->post_read_conversion, make_number (inserted)); |
b843d1ae KH |
5738 | inhibit_pre_post_conversion = 0; |
5739 | /* Discard the unwind protect. */ | |
5740 | specpdl_ptr--; | |
b7826503 | 5741 | CHECK_NUMBER (val); |
944bd420 | 5742 | inserted += Z - prev_Z; |
e133c8fa KH |
5743 | } |
5744 | ||
5745 | if (orig_point >= from) | |
5746 | { | |
5747 | if (orig_point >= from + orig_len) | |
5748 | orig_point += inserted - orig_len; | |
5749 | else | |
5750 | orig_point = from; | |
5751 | TEMP_SET_PT (orig_point); | |
d46c5b12 | 5752 | } |
4ed46869 | 5753 | |
ec6d2bb8 KH |
5754 | if (replace) |
5755 | { | |
5756 | signal_after_change (from, to - from, inserted); | |
e19539f1 | 5757 | update_compositions (from, from + inserted, CHECK_BORDER); |
ec6d2bb8 | 5758 | } |
2b4f9037 | 5759 | |
fb88bf2d | 5760 | { |
12410ef1 KH |
5761 | coding->consumed = to_byte - from_byte; |
5762 | coding->consumed_char = to - from; | |
5763 | coding->produced = inserted_byte; | |
5764 | coding->produced_char = inserted; | |
fb88bf2d | 5765 | } |
7553d0e1 | 5766 | |
fb88bf2d | 5767 | return 0; |
d46c5b12 KH |
5768 | } |
5769 | ||
5770 | Lisp_Object | |
b73bfc1c KH |
5771 | run_pre_post_conversion_on_str (str, coding, encodep) |
5772 | Lisp_Object str; | |
5773 | struct coding_system *coding; | |
5774 | int encodep; | |
5775 | { | |
5776 | int count = specpdl_ptr - specpdl; | |
5777 | struct gcpro gcpro1; | |
b73bfc1c KH |
5778 | int multibyte = STRING_MULTIBYTE (str); |
5779 | ||
5780 | record_unwind_protect (Fset_buffer, Fcurrent_buffer ()); | |
5781 | record_unwind_protect (code_convert_region_unwind, Qnil); | |
5782 | GCPRO1 (str); | |
5783 | temp_output_buffer_setup (" *code-converting-work*"); | |
5784 | set_buffer_internal (XBUFFER (Vstandard_output)); | |
5785 | /* We must insert the contents of STR as is without | |
5786 | unibyte<->multibyte conversion. For that, we adjust the | |
5787 | multibyteness of the working buffer to that of STR. */ | |
5788 | Ferase_buffer (); | |
5789 | current_buffer->enable_multibyte_characters = multibyte ? Qt : Qnil; | |
5790 | insert_from_string (str, 0, 0, | |
5791 | XSTRING (str)->size, STRING_BYTES (XSTRING (str)), 0); | |
5792 | UNGCPRO; | |
5793 | inhibit_pre_post_conversion = 1; | |
5794 | if (encodep) | |
5795 | call2 (coding->pre_write_conversion, make_number (BEG), make_number (Z)); | |
5796 | else | |
6bac5b12 KH |
5797 | { |
5798 | TEMP_SET_PT_BOTH (BEG, BEG_BYTE); | |
5799 | call1 (coding->post_read_conversion, make_number (Z - BEG)); | |
5800 | } | |
b73bfc1c | 5801 | inhibit_pre_post_conversion = 0; |
78108bcd | 5802 | str = make_buffer_string (BEG, Z, 1); |
b73bfc1c KH |
5803 | return unbind_to (count, str); |
5804 | } | |
5805 | ||
5806 | Lisp_Object | |
5807 | decode_coding_string (str, coding, nocopy) | |
d46c5b12 | 5808 | Lisp_Object str; |
4ed46869 | 5809 | struct coding_system *coding; |
b73bfc1c | 5810 | int nocopy; |
4ed46869 | 5811 | { |
d46c5b12 | 5812 | int len; |
73be902c | 5813 | struct conversion_buffer buf; |
da55a2b7 | 5814 | int from, to_byte; |
d46c5b12 | 5815 | struct gcpro gcpro1; |
84d60297 | 5816 | Lisp_Object saved_coding_symbol; |
d46c5b12 | 5817 | int result; |
78108bcd | 5818 | int require_decoding; |
73be902c KH |
5819 | int shrinked_bytes = 0; |
5820 | Lisp_Object newstr; | |
2391eaa4 | 5821 | int consumed, consumed_char, produced, produced_char; |
4ed46869 | 5822 | |
b73bfc1c | 5823 | from = 0; |
b73bfc1c | 5824 | to_byte = STRING_BYTES (XSTRING (str)); |
4ed46869 | 5825 | |
8844fa83 | 5826 | saved_coding_symbol = coding->symbol; |
764ca8da KH |
5827 | coding->src_multibyte = STRING_MULTIBYTE (str); |
5828 | coding->dst_multibyte = 1; | |
b73bfc1c | 5829 | if (CODING_REQUIRE_DETECTION (coding)) |
d46c5b12 KH |
5830 | { |
5831 | /* See the comments in code_convert_region. */ | |
5832 | if (coding->type == coding_type_undecided) | |
5833 | { | |
5834 | detect_coding (coding, XSTRING (str)->data, to_byte); | |
5835 | if (coding->type == coding_type_undecided) | |
d280ccb6 KH |
5836 | { |
5837 | coding->type = coding_type_emacs_mule; | |
5838 | coding->category_idx = CODING_CATEGORY_IDX_EMACS_MULE; | |
5839 | /* As emacs-mule decoder will handle composition, we | |
5840 | need this setting to allocate coding->cmp_data | |
5841 | later. */ | |
5842 | coding->composing = COMPOSITION_NO; | |
5843 | } | |
d46c5b12 | 5844 | } |
aaaf0b1e KH |
5845 | if (coding->eol_type == CODING_EOL_UNDECIDED |
5846 | && coding->type != coding_type_ccl) | |
d46c5b12 KH |
5847 | { |
5848 | saved_coding_symbol = coding->symbol; | |
5849 | detect_eol (coding, XSTRING (str)->data, to_byte); | |
5850 | if (coding->eol_type == CODING_EOL_UNDECIDED) | |
5851 | coding->eol_type = CODING_EOL_LF; | |
5852 | /* We had better recover the original eol format if we | |
8ca3766a | 5853 | encounter an inconsistent eol format while decoding. */ |
d46c5b12 KH |
5854 | coding->mode |= CODING_MODE_INHIBIT_INCONSISTENT_EOL; |
5855 | } | |
5856 | } | |
4ed46869 | 5857 | |
764ca8da KH |
5858 | if (coding->type == coding_type_no_conversion |
5859 | || coding->type == coding_type_raw_text) | |
5860 | coding->dst_multibyte = 0; | |
5861 | ||
78108bcd | 5862 | require_decoding = CODING_REQUIRE_DECODING (coding); |
ec6d2bb8 | 5863 | |
b73bfc1c | 5864 | if (STRING_MULTIBYTE (str)) |
d46c5b12 | 5865 | { |
b73bfc1c KH |
5866 | /* Decoding routines expect the source text to be unibyte. */ |
5867 | str = Fstring_as_unibyte (str); | |
86af83a9 | 5868 | to_byte = STRING_BYTES (XSTRING (str)); |
b73bfc1c | 5869 | nocopy = 1; |
764ca8da | 5870 | coding->src_multibyte = 0; |
b73bfc1c | 5871 | } |
ec6d2bb8 | 5872 | |
b73bfc1c | 5873 | /* Try to skip the heading and tailing ASCIIs. */ |
78108bcd | 5874 | if (require_decoding && coding->type != coding_type_ccl) |
4956c225 | 5875 | { |
4956c225 KH |
5876 | SHRINK_CONVERSION_REGION (&from, &to_byte, coding, XSTRING (str)->data, |
5877 | 0); | |
5878 | if (from == to_byte) | |
78108bcd | 5879 | require_decoding = 0; |
73be902c | 5880 | shrinked_bytes = from + (STRING_BYTES (XSTRING (str)) - to_byte); |
4956c225 | 5881 | } |
b73bfc1c | 5882 | |
78108bcd KH |
5883 | if (!require_decoding) |
5884 | { | |
5885 | coding->consumed = STRING_BYTES (XSTRING (str)); | |
5886 | coding->consumed_char = XSTRING (str)->size; | |
5887 | if (coding->dst_multibyte) | |
5888 | { | |
5889 | str = Fstring_as_multibyte (str); | |
5890 | nocopy = 1; | |
5891 | } | |
5892 | coding->produced = STRING_BYTES (XSTRING (str)); | |
5893 | coding->produced_char = XSTRING (str)->size; | |
5894 | return (nocopy ? str : Fcopy_sequence (str)); | |
5895 | } | |
5896 | ||
5897 | if (coding->composing != COMPOSITION_DISABLED) | |
5898 | coding_allocate_composition_data (coding, from); | |
b73bfc1c | 5899 | len = decoding_buffer_size (coding, to_byte - from); |
73be902c | 5900 | allocate_conversion_buffer (buf, len); |
4ed46869 | 5901 | |
2391eaa4 | 5902 | consumed = consumed_char = produced = produced_char = 0; |
73be902c | 5903 | while (1) |
4ed46869 | 5904 | { |
73be902c KH |
5905 | result = decode_coding (coding, XSTRING (str)->data + from + consumed, |
5906 | buf.data + produced, to_byte - from - consumed, | |
5907 | buf.size - produced); | |
5908 | consumed += coding->consumed; | |
2391eaa4 | 5909 | consumed_char += coding->consumed_char; |
73be902c KH |
5910 | produced += coding->produced; |
5911 | produced_char += coding->produced_char; | |
2391eaa4 KH |
5912 | if (result == CODING_FINISH_NORMAL |
5913 | || (result == CODING_FINISH_INSUFFICIENT_SRC | |
5914 | && coding->consumed == 0)) | |
73be902c KH |
5915 | break; |
5916 | if (result == CODING_FINISH_INSUFFICIENT_CMP) | |
5917 | coding_allocate_composition_data (coding, from + produced_char); | |
5918 | else if (result == CODING_FINISH_INSUFFICIENT_DST) | |
5919 | extend_conversion_buffer (&buf); | |
5920 | else if (result == CODING_FINISH_INCONSISTENT_EOL) | |
5921 | { | |
8844fa83 KH |
5922 | Lisp_Object eol_type; |
5923 | ||
73be902c KH |
5924 | /* Recover the original EOL format. */ |
5925 | if (coding->eol_type == CODING_EOL_CR) | |
5926 | { | |
5927 | unsigned char *p; | |
5928 | for (p = buf.data; p < buf.data + produced; p++) | |
5929 | if (*p == '\n') *p = '\r'; | |
5930 | } | |
5931 | else if (coding->eol_type == CODING_EOL_CRLF) | |
5932 | { | |
5933 | int num_eol = 0; | |
5934 | unsigned char *p0, *p1; | |
5935 | for (p0 = buf.data, p1 = p0 + produced; p0 < p1; p0++) | |
5936 | if (*p0 == '\n') num_eol++; | |
5937 | if (produced + num_eol >= buf.size) | |
5938 | extend_conversion_buffer (&buf); | |
5939 | for (p0 = buf.data + produced, p1 = p0 + num_eol; p0 > buf.data;) | |
5940 | { | |
5941 | *--p1 = *--p0; | |
5942 | if (*p0 == '\n') *--p1 = '\r'; | |
5943 | } | |
5944 | produced += num_eol; | |
5945 | produced_char += num_eol; | |
5946 | } | |
8844fa83 | 5947 | /* Suppress eol-format conversion in the further conversion. */ |
73be902c | 5948 | coding->eol_type = CODING_EOL_LF; |
8844fa83 KH |
5949 | |
5950 | /* Set the coding system symbol to that for Unix-like EOL. */ | |
5951 | eol_type = Fget (saved_coding_symbol, Qeol_type); | |
5952 | if (VECTORP (eol_type) | |
5953 | && XVECTOR (eol_type)->size == 3 | |
5954 | && SYMBOLP (XVECTOR (eol_type)->contents[CODING_EOL_LF])) | |
5955 | coding->symbol = XVECTOR (eol_type)->contents[CODING_EOL_LF]; | |
5956 | else | |
5957 | coding->symbol = saved_coding_symbol; | |
5958 | ||
5959 | ||
73be902c | 5960 | } |
4ed46869 | 5961 | } |
d46c5b12 | 5962 | |
2391eaa4 KH |
5963 | coding->consumed = consumed; |
5964 | coding->consumed_char = consumed_char; | |
5965 | coding->produced = produced; | |
5966 | coding->produced_char = produced_char; | |
5967 | ||
78108bcd | 5968 | if (coding->dst_multibyte) |
73be902c KH |
5969 | newstr = make_uninit_multibyte_string (produced_char + shrinked_bytes, |
5970 | produced + shrinked_bytes); | |
78108bcd | 5971 | else |
73be902c KH |
5972 | newstr = make_uninit_string (produced + shrinked_bytes); |
5973 | if (from > 0) | |
5974 | bcopy (XSTRING (str)->data, XSTRING (newstr)->data, from); | |
5975 | bcopy (buf.data, XSTRING (newstr)->data + from, produced); | |
5976 | if (shrinked_bytes > from) | |
5977 | bcopy (XSTRING (str)->data + to_byte, | |
5978 | XSTRING (newstr)->data + from + produced, | |
5979 | shrinked_bytes - from); | |
5980 | free_conversion_buffer (&buf); | |
b73bfc1c KH |
5981 | |
5982 | if (coding->cmp_data && coding->cmp_data->used) | |
73be902c | 5983 | coding_restore_composition (coding, newstr); |
b73bfc1c KH |
5984 | coding_free_composition_data (coding); |
5985 | ||
5986 | if (SYMBOLP (coding->post_read_conversion) | |
5987 | && !NILP (Ffboundp (coding->post_read_conversion))) | |
73be902c | 5988 | newstr = run_pre_post_conversion_on_str (newstr, coding, 0); |
b73bfc1c | 5989 | |
73be902c | 5990 | return newstr; |
b73bfc1c KH |
5991 | } |
5992 | ||
5993 | Lisp_Object | |
5994 | encode_coding_string (str, coding, nocopy) | |
5995 | Lisp_Object str; | |
5996 | struct coding_system *coding; | |
5997 | int nocopy; | |
5998 | { | |
5999 | int len; | |
73be902c | 6000 | struct conversion_buffer buf; |
b73bfc1c | 6001 | int from, to, to_byte; |
b73bfc1c | 6002 | int result; |
73be902c KH |
6003 | int shrinked_bytes = 0; |
6004 | Lisp_Object newstr; | |
2391eaa4 | 6005 | int consumed, consumed_char, produced, produced_char; |
b73bfc1c KH |
6006 | |
6007 | if (SYMBOLP (coding->pre_write_conversion) | |
6008 | && !NILP (Ffboundp (coding->pre_write_conversion))) | |
6bac5b12 | 6009 | str = run_pre_post_conversion_on_str (str, coding, 1); |
b73bfc1c KH |
6010 | |
6011 | from = 0; | |
6012 | to = XSTRING (str)->size; | |
6013 | to_byte = STRING_BYTES (XSTRING (str)); | |
6014 | ||
e2c06b17 KH |
6015 | /* Encoding routines determine the multibyteness of the source text |
6016 | by coding->src_multibyte. */ | |
6017 | coding->src_multibyte = STRING_MULTIBYTE (str); | |
6018 | coding->dst_multibyte = 0; | |
b73bfc1c | 6019 | if (! CODING_REQUIRE_ENCODING (coding)) |
826bfb8b | 6020 | { |
2391eaa4 KH |
6021 | coding->consumed = STRING_BYTES (XSTRING (str)); |
6022 | coding->consumed_char = XSTRING (str)->size; | |
b73bfc1c KH |
6023 | if (STRING_MULTIBYTE (str)) |
6024 | { | |
6025 | str = Fstring_as_unibyte (str); | |
6026 | nocopy = 1; | |
6027 | } | |
2391eaa4 KH |
6028 | coding->produced = STRING_BYTES (XSTRING (str)); |
6029 | coding->produced_char = XSTRING (str)->size; | |
b73bfc1c | 6030 | return (nocopy ? str : Fcopy_sequence (str)); |
826bfb8b KH |
6031 | } |
6032 | ||
b73bfc1c KH |
6033 | if (coding->composing != COMPOSITION_DISABLED) |
6034 | coding_save_composition (coding, from, to, str); | |
ec6d2bb8 | 6035 | |
b73bfc1c | 6036 | /* Try to skip the heading and tailing ASCIIs. */ |
4956c225 KH |
6037 | if (coding->type != coding_type_ccl) |
6038 | { | |
4956c225 KH |
6039 | SHRINK_CONVERSION_REGION (&from, &to_byte, coding, XSTRING (str)->data, |
6040 | 1); | |
6041 | if (from == to_byte) | |
6042 | return (nocopy ? str : Fcopy_sequence (str)); | |
73be902c | 6043 | shrinked_bytes = from + (STRING_BYTES (XSTRING (str)) - to_byte); |
4956c225 | 6044 | } |
b73bfc1c KH |
6045 | |
6046 | len = encoding_buffer_size (coding, to_byte - from); | |
73be902c KH |
6047 | allocate_conversion_buffer (buf, len); |
6048 | ||
2391eaa4 | 6049 | consumed = consumed_char = produced = produced_char = 0; |
73be902c KH |
6050 | while (1) |
6051 | { | |
6052 | result = encode_coding (coding, XSTRING (str)->data + from + consumed, | |
6053 | buf.data + produced, to_byte - from - consumed, | |
6054 | buf.size - produced); | |
6055 | consumed += coding->consumed; | |
2391eaa4 | 6056 | consumed_char += coding->consumed_char; |
13004bef | 6057 | produced += coding->produced; |
2391eaa4 KH |
6058 | produced_char += coding->produced_char; |
6059 | if (result == CODING_FINISH_NORMAL | |
6060 | || (result == CODING_FINISH_INSUFFICIENT_SRC | |
6061 | && coding->consumed == 0)) | |
73be902c KH |
6062 | break; |
6063 | /* Now result should be CODING_FINISH_INSUFFICIENT_DST. */ | |
6064 | extend_conversion_buffer (&buf); | |
6065 | } | |
6066 | ||
2391eaa4 KH |
6067 | coding->consumed = consumed; |
6068 | coding->consumed_char = consumed_char; | |
6069 | coding->produced = produced; | |
6070 | coding->produced_char = produced_char; | |
6071 | ||
73be902c | 6072 | newstr = make_uninit_string (produced + shrinked_bytes); |
b73bfc1c | 6073 | if (from > 0) |
73be902c KH |
6074 | bcopy (XSTRING (str)->data, XSTRING (newstr)->data, from); |
6075 | bcopy (buf.data, XSTRING (newstr)->data + from, produced); | |
6076 | if (shrinked_bytes > from) | |
6077 | bcopy (XSTRING (str)->data + to_byte, | |
6078 | XSTRING (newstr)->data + from + produced, | |
6079 | shrinked_bytes - from); | |
6080 | ||
6081 | free_conversion_buffer (&buf); | |
ec6d2bb8 | 6082 | coding_free_composition_data (coding); |
b73bfc1c | 6083 | |
73be902c | 6084 | return newstr; |
4ed46869 KH |
6085 | } |
6086 | ||
6087 | \f | |
6088 | #ifdef emacs | |
1397dc18 | 6089 | /*** 8. Emacs Lisp library functions ***/ |
4ed46869 | 6090 | |
4ed46869 | 6091 | DEFUN ("coding-system-p", Fcoding_system_p, Scoding_system_p, 1, 1, 0, |
48b0f3ae PJ |
6092 | doc: /* Return t if OBJECT is nil or a coding-system. |
6093 | See the documentation of `make-coding-system' for information | |
6094 | about coding-system objects. */) | |
6095 | (obj) | |
4ed46869 KH |
6096 | Lisp_Object obj; |
6097 | { | |
4608c386 KH |
6098 | if (NILP (obj)) |
6099 | return Qt; | |
6100 | if (!SYMBOLP (obj)) | |
6101 | return Qnil; | |
6102 | /* Get coding-spec vector for OBJ. */ | |
6103 | obj = Fget (obj, Qcoding_system); | |
6104 | return ((VECTORP (obj) && XVECTOR (obj)->size == 5) | |
6105 | ? Qt : Qnil); | |
4ed46869 KH |
6106 | } |
6107 | ||
9d991de8 RS |
6108 | DEFUN ("read-non-nil-coding-system", Fread_non_nil_coding_system, |
6109 | Sread_non_nil_coding_system, 1, 1, 0, | |
48b0f3ae PJ |
6110 | doc: /* Read a coding system from the minibuffer, prompting with string PROMPT. */) |
6111 | (prompt) | |
4ed46869 KH |
6112 | Lisp_Object prompt; |
6113 | { | |
e0e989f6 | 6114 | Lisp_Object val; |
9d991de8 RS |
6115 | do |
6116 | { | |
4608c386 KH |
6117 | val = Fcompleting_read (prompt, Vcoding_system_alist, Qnil, |
6118 | Qt, Qnil, Qcoding_system_history, Qnil, Qnil); | |
9d991de8 RS |
6119 | } |
6120 | while (XSTRING (val)->size == 0); | |
e0e989f6 | 6121 | return (Fintern (val, Qnil)); |
4ed46869 KH |
6122 | } |
6123 | ||
9b787f3e | 6124 | DEFUN ("read-coding-system", Fread_coding_system, Sread_coding_system, 1, 2, 0, |
48b0f3ae PJ |
6125 | doc: /* Read a coding system from the minibuffer, prompting with string PROMPT. |
6126 | If the user enters null input, return second argument DEFAULT-CODING-SYSTEM. */) | |
6127 | (prompt, default_coding_system) | |
9b787f3e | 6128 | Lisp_Object prompt, default_coding_system; |
4ed46869 | 6129 | { |
f44d27ce | 6130 | Lisp_Object val; |
9b787f3e RS |
6131 | if (SYMBOLP (default_coding_system)) |
6132 | XSETSTRING (default_coding_system, XSYMBOL (default_coding_system)->name); | |
4608c386 | 6133 | val = Fcompleting_read (prompt, Vcoding_system_alist, Qnil, |
9b787f3e RS |
6134 | Qt, Qnil, Qcoding_system_history, |
6135 | default_coding_system, Qnil); | |
e0e989f6 | 6136 | return (XSTRING (val)->size == 0 ? Qnil : Fintern (val, Qnil)); |
4ed46869 KH |
6137 | } |
6138 | ||
6139 | DEFUN ("check-coding-system", Fcheck_coding_system, Scheck_coding_system, | |
6140 | 1, 1, 0, | |
48b0f3ae PJ |
6141 | doc: /* Check validity of CODING-SYSTEM. |
6142 | If valid, return CODING-SYSTEM, else signal a `coding-system-error' error. | |
6143 | It is valid if it is a symbol with a non-nil `coding-system' property. | |
6144 | The value of property should be a vector of length 5. */) | |
6145 | (coding_system) | |
4ed46869 KH |
6146 | Lisp_Object coding_system; |
6147 | { | |
b7826503 | 6148 | CHECK_SYMBOL (coding_system); |
4ed46869 KH |
6149 | if (!NILP (Fcoding_system_p (coding_system))) |
6150 | return coding_system; | |
6151 | while (1) | |
02ba4723 | 6152 | Fsignal (Qcoding_system_error, Fcons (coding_system, Qnil)); |
4ed46869 | 6153 | } |
3a73fa5d | 6154 | \f |
d46c5b12 | 6155 | Lisp_Object |
0a28aafb | 6156 | detect_coding_system (src, src_bytes, highest, multibytep) |
d46c5b12 KH |
6157 | unsigned char *src; |
6158 | int src_bytes, highest; | |
0a28aafb | 6159 | int multibytep; |
4ed46869 KH |
6160 | { |
6161 | int coding_mask, eol_type; | |
d46c5b12 KH |
6162 | Lisp_Object val, tmp; |
6163 | int dummy; | |
4ed46869 | 6164 | |
0a28aafb | 6165 | coding_mask = detect_coding_mask (src, src_bytes, NULL, &dummy, multibytep); |
d46c5b12 KH |
6166 | eol_type = detect_eol_type (src, src_bytes, &dummy); |
6167 | if (eol_type == CODING_EOL_INCONSISTENT) | |
25b02698 | 6168 | eol_type = CODING_EOL_UNDECIDED; |
4ed46869 | 6169 | |
d46c5b12 | 6170 | if (!coding_mask) |
4ed46869 | 6171 | { |
27901516 | 6172 | val = Qundecided; |
d46c5b12 | 6173 | if (eol_type != CODING_EOL_UNDECIDED) |
4ed46869 | 6174 | { |
f44d27ce RS |
6175 | Lisp_Object val2; |
6176 | val2 = Fget (Qundecided, Qeol_type); | |
4ed46869 KH |
6177 | if (VECTORP (val2)) |
6178 | val = XVECTOR (val2)->contents[eol_type]; | |
6179 | } | |
80e803b4 | 6180 | return (highest ? val : Fcons (val, Qnil)); |
4ed46869 | 6181 | } |
4ed46869 | 6182 | |
d46c5b12 KH |
6183 | /* At first, gather possible coding systems in VAL. */ |
6184 | val = Qnil; | |
fa42c37f | 6185 | for (tmp = Vcoding_category_list; CONSP (tmp); tmp = XCDR (tmp)) |
4ed46869 | 6186 | { |
fa42c37f KH |
6187 | Lisp_Object category_val, category_index; |
6188 | ||
6189 | category_index = Fget (XCAR (tmp), Qcoding_category_index); | |
6190 | category_val = Fsymbol_value (XCAR (tmp)); | |
6191 | if (!NILP (category_val) | |
6192 | && NATNUMP (category_index) | |
6193 | && (coding_mask & (1 << XFASTINT (category_index)))) | |
4ed46869 | 6194 | { |
fa42c37f | 6195 | val = Fcons (category_val, val); |
d46c5b12 KH |
6196 | if (highest) |
6197 | break; | |
4ed46869 KH |
6198 | } |
6199 | } | |
d46c5b12 KH |
6200 | if (!highest) |
6201 | val = Fnreverse (val); | |
4ed46869 | 6202 | |
65059037 | 6203 | /* Then, replace the elements with subsidiary coding systems. */ |
fa42c37f | 6204 | for (tmp = val; CONSP (tmp); tmp = XCDR (tmp)) |
4ed46869 | 6205 | { |
65059037 RS |
6206 | if (eol_type != CODING_EOL_UNDECIDED |
6207 | && eol_type != CODING_EOL_INCONSISTENT) | |
4ed46869 | 6208 | { |
d46c5b12 | 6209 | Lisp_Object eol; |
03699b14 | 6210 | eol = Fget (XCAR (tmp), Qeol_type); |
d46c5b12 | 6211 | if (VECTORP (eol)) |
f3fbd155 | 6212 | XSETCAR (tmp, XVECTOR (eol)->contents[eol_type]); |
4ed46869 KH |
6213 | } |
6214 | } | |
03699b14 | 6215 | return (highest ? XCAR (val) : val); |
d46c5b12 | 6216 | } |
4ed46869 | 6217 | |
d46c5b12 KH |
6218 | DEFUN ("detect-coding-region", Fdetect_coding_region, Sdetect_coding_region, |
6219 | 2, 3, 0, | |
48b0f3ae PJ |
6220 | doc: /* Detect coding system of the text in the region between START and END. |
6221 | Return a list of possible coding systems ordered by priority. | |
6222 | ||
6223 | If only ASCII characters are found, it returns a list of single element | |
6224 | `undecided' or its subsidiary coding system according to a detected | |
6225 | end-of-line format. | |
6226 | ||
6227 | If optional argument HIGHEST is non-nil, return the coding system of | |
6228 | highest priority. */) | |
6229 | (start, end, highest) | |
d46c5b12 KH |
6230 | Lisp_Object start, end, highest; |
6231 | { | |
6232 | int from, to; | |
6233 | int from_byte, to_byte; | |
682169fe | 6234 | int include_anchor_byte = 0; |
6289dd10 | 6235 | |
b7826503 PJ |
6236 | CHECK_NUMBER_COERCE_MARKER (start); |
6237 | CHECK_NUMBER_COERCE_MARKER (end); | |
4ed46869 | 6238 | |
d46c5b12 KH |
6239 | validate_region (&start, &end); |
6240 | from = XINT (start), to = XINT (end); | |
6241 | from_byte = CHAR_TO_BYTE (from); | |
6242 | to_byte = CHAR_TO_BYTE (to); | |
6289dd10 | 6243 | |
d46c5b12 KH |
6244 | if (from < GPT && to >= GPT) |
6245 | move_gap_both (to, to_byte); | |
c210f766 KH |
6246 | /* If we an anchor byte `\0' follows the region, we include it in |
6247 | the detecting source. Then code detectors can handle the tailing | |
6248 | byte sequence more accurately. | |
6249 | ||
6250 | Fix me: This is not an perfect solution. It is better that we | |
6251 | add one more argument, say LAST_BLOCK, to all detect_coding_XXX. | |
6252 | */ | |
682169fe KH |
6253 | if (to == Z || (to == GPT && GAP_SIZE > 0)) |
6254 | include_anchor_byte = 1; | |
d46c5b12 | 6255 | return detect_coding_system (BYTE_POS_ADDR (from_byte), |
682169fe | 6256 | to_byte - from_byte + include_anchor_byte, |
0a28aafb KH |
6257 | !NILP (highest), |
6258 | !NILP (current_buffer | |
6259 | ->enable_multibyte_characters)); | |
d46c5b12 | 6260 | } |
6289dd10 | 6261 | |
d46c5b12 KH |
6262 | DEFUN ("detect-coding-string", Fdetect_coding_string, Sdetect_coding_string, |
6263 | 1, 2, 0, | |
48b0f3ae PJ |
6264 | doc: /* Detect coding system of the text in STRING. |
6265 | Return a list of possible coding systems ordered by priority. | |
6266 | ||
6267 | If only ASCII characters are found, it returns a list of single element | |
6268 | `undecided' or its subsidiary coding system according to a detected | |
6269 | end-of-line format. | |
6270 | ||
6271 | If optional argument HIGHEST is non-nil, return the coding system of | |
6272 | highest priority. */) | |
6273 | (string, highest) | |
d46c5b12 KH |
6274 | Lisp_Object string, highest; |
6275 | { | |
b7826503 | 6276 | CHECK_STRING (string); |
4ed46869 | 6277 | |
d46c5b12 | 6278 | return detect_coding_system (XSTRING (string)->data, |
682169fe KH |
6279 | /* "+ 1" is to include the anchor byte |
6280 | `\0'. With this, code detectors can | |
c210f766 KH |
6281 | handle the tailing bytes more |
6282 | accurately. */ | |
682169fe | 6283 | STRING_BYTES (XSTRING (string)) + 1, |
0a28aafb KH |
6284 | !NILP (highest), |
6285 | STRING_MULTIBYTE (string)); | |
4ed46869 KH |
6286 | } |
6287 | ||
05e6f5dc KH |
6288 | /* Return an intersection of lists L1 and L2. */ |
6289 | ||
6290 | static Lisp_Object | |
6291 | intersection (l1, l2) | |
6292 | Lisp_Object l1, l2; | |
6293 | { | |
6294 | Lisp_Object val; | |
6295 | ||
6296 | for (val = Qnil; CONSP (l1); l1 = XCDR (l1)) | |
6297 | { | |
6298 | if (!NILP (Fmemq (XCAR (l1), l2))) | |
6299 | val = Fcons (XCAR (l1), val); | |
6300 | } | |
6301 | return val; | |
6302 | } | |
6303 | ||
6304 | ||
6305 | /* Subroutine for Fsafe_coding_systems_region_internal. | |
6306 | ||
6307 | Return a list of coding systems that safely encode the multibyte | |
6308 | text between P and PEND. SAFE_CODINGS, if non-nil, is a list of | |
6309 | possible coding systems. If it is nil, it means that we have not | |
6310 | yet found any coding systems. | |
6311 | ||
6312 | WORK_TABLE is a copy of the char-table Vchar_coding_system_table. An | |
6313 | element of WORK_TABLE is set to t once the element is looked up. | |
6314 | ||
6315 | If a non-ASCII single byte char is found, set | |
6316 | *single_byte_char_found to 1. */ | |
6317 | ||
6318 | static Lisp_Object | |
6319 | find_safe_codings (p, pend, safe_codings, work_table, single_byte_char_found) | |
6320 | unsigned char *p, *pend; | |
6321 | Lisp_Object safe_codings, work_table; | |
6322 | int *single_byte_char_found; | |
6323 | { | |
6324 | int c, len, idx; | |
6325 | Lisp_Object val; | |
6326 | ||
6327 | while (p < pend) | |
6328 | { | |
6329 | c = STRING_CHAR_AND_LENGTH (p, pend - p, len); | |
6330 | p += len; | |
6331 | if (ASCII_BYTE_P (c)) | |
6332 | /* We can ignore ASCII characters here. */ | |
6333 | continue; | |
6334 | if (SINGLE_BYTE_CHAR_P (c)) | |
6335 | *single_byte_char_found = 1; | |
6336 | if (NILP (safe_codings)) | |
6337 | continue; | |
6338 | /* Check the safe coding systems for C. */ | |
6339 | val = char_table_ref_and_index (work_table, c, &idx); | |
6340 | if (EQ (val, Qt)) | |
6341 | /* This element was already checked. Ignore it. */ | |
6342 | continue; | |
6343 | /* Remember that we checked this element. */ | |
975f250a | 6344 | CHAR_TABLE_SET (work_table, make_number (idx), Qt); |
05e6f5dc KH |
6345 | |
6346 | /* If there are some safe coding systems for C and we have | |
6347 | already found the other set of coding systems for the | |
6348 | different characters, get the intersection of them. */ | |
6349 | if (!EQ (safe_codings, Qt) && !NILP (val)) | |
6350 | val = intersection (safe_codings, val); | |
6351 | safe_codings = val; | |
6352 | } | |
6353 | return safe_codings; | |
6354 | } | |
6355 | ||
6356 | ||
6357 | /* Return a list of coding systems that safely encode the text between | |
6358 | START and END. If the text contains only ASCII or is unibyte, | |
6359 | return t. */ | |
6360 | ||
6361 | DEFUN ("find-coding-systems-region-internal", | |
6362 | Ffind_coding_systems_region_internal, | |
6363 | Sfind_coding_systems_region_internal, 2, 2, 0, | |
48b0f3ae PJ |
6364 | doc: /* Internal use only. */) |
6365 | (start, end) | |
05e6f5dc KH |
6366 | Lisp_Object start, end; |
6367 | { | |
6368 | Lisp_Object work_table, safe_codings; | |
6369 | int non_ascii_p = 0; | |
6370 | int single_byte_char_found = 0; | |
6371 | unsigned char *p1, *p1end, *p2, *p2end, *p; | |
05e6f5dc KH |
6372 | |
6373 | if (STRINGP (start)) | |
6374 | { | |
6375 | if (!STRING_MULTIBYTE (start)) | |
6376 | return Qt; | |
6377 | p1 = XSTRING (start)->data, p1end = p1 + STRING_BYTES (XSTRING (start)); | |
6378 | p2 = p2end = p1end; | |
6379 | if (XSTRING (start)->size != STRING_BYTES (XSTRING (start))) | |
6380 | non_ascii_p = 1; | |
6381 | } | |
6382 | else | |
6383 | { | |
6384 | int from, to, stop; | |
6385 | ||
b7826503 PJ |
6386 | CHECK_NUMBER_COERCE_MARKER (start); |
6387 | CHECK_NUMBER_COERCE_MARKER (end); | |
05e6f5dc KH |
6388 | if (XINT (start) < BEG || XINT (end) > Z || XINT (start) > XINT (end)) |
6389 | args_out_of_range (start, end); | |
6390 | if (NILP (current_buffer->enable_multibyte_characters)) | |
6391 | return Qt; | |
6392 | from = CHAR_TO_BYTE (XINT (start)); | |
6393 | to = CHAR_TO_BYTE (XINT (end)); | |
6394 | stop = from < GPT_BYTE && GPT_BYTE < to ? GPT_BYTE : to; | |
6395 | p1 = BYTE_POS_ADDR (from), p1end = p1 + (stop - from); | |
6396 | if (stop == to) | |
6397 | p2 = p2end = p1end; | |
6398 | else | |
6399 | p2 = BYTE_POS_ADDR (stop), p2end = p2 + (to - stop); | |
6400 | if (XINT (end) - XINT (start) != to - from) | |
6401 | non_ascii_p = 1; | |
6402 | } | |
6403 | ||
6404 | if (!non_ascii_p) | |
6405 | { | |
6406 | /* We are sure that the text contains no multibyte character. | |
6407 | Check if it contains eight-bit-graphic. */ | |
6408 | p = p1; | |
6409 | for (p = p1; p < p1end && ASCII_BYTE_P (*p); p++); | |
6410 | if (p == p1end) | |
6411 | { | |
6412 | for (p = p2; p < p2end && ASCII_BYTE_P (*p); p++); | |
6413 | if (p == p2end) | |
6414 | return Qt; | |
6415 | } | |
6416 | } | |
6417 | ||
6418 | /* The text contains non-ASCII characters. */ | |
6419 | work_table = Fcopy_sequence (Vchar_coding_system_table); | |
6420 | safe_codings = find_safe_codings (p1, p1end, Qt, work_table, | |
6421 | &single_byte_char_found); | |
6422 | if (p2 < p2end) | |
6423 | safe_codings = find_safe_codings (p2, p2end, safe_codings, work_table, | |
6424 | &single_byte_char_found); | |
6425 | ||
176c92e6 SM |
6426 | if (EQ (safe_codings, Qt)) |
6427 | ; /* Nothing to be done. */ | |
6428 | else if (!single_byte_char_found) | |
05e6f5dc KH |
6429 | { |
6430 | /* Append generic coding systems. */ | |
6431 | Lisp_Object args[2]; | |
6432 | args[0] = safe_codings; | |
6433 | args[1] = Fchar_table_extra_slot (Vchar_coding_system_table, | |
6434 | make_number (0)); | |
975f250a | 6435 | safe_codings = Fappend (2, args); |
05e6f5dc KH |
6436 | } |
6437 | else | |
109a5acb KH |
6438 | safe_codings = Fcons (Qraw_text, |
6439 | Fcons (Qemacs_mule, | |
6440 | Fcons (Qno_conversion, safe_codings))); | |
05e6f5dc KH |
6441 | return safe_codings; |
6442 | } | |
6443 | ||
6444 | ||
4031e2bf KH |
6445 | Lisp_Object |
6446 | code_convert_region1 (start, end, coding_system, encodep) | |
d46c5b12 | 6447 | Lisp_Object start, end, coding_system; |
4031e2bf | 6448 | int encodep; |
3a73fa5d RS |
6449 | { |
6450 | struct coding_system coding; | |
da55a2b7 | 6451 | int from, to; |
3a73fa5d | 6452 | |
b7826503 PJ |
6453 | CHECK_NUMBER_COERCE_MARKER (start); |
6454 | CHECK_NUMBER_COERCE_MARKER (end); | |
6455 | CHECK_SYMBOL (coding_system); | |
3a73fa5d | 6456 | |
d46c5b12 KH |
6457 | validate_region (&start, &end); |
6458 | from = XFASTINT (start); | |
6459 | to = XFASTINT (end); | |
6460 | ||
3a73fa5d | 6461 | if (NILP (coding_system)) |
d46c5b12 KH |
6462 | return make_number (to - from); |
6463 | ||
3a73fa5d | 6464 | if (setup_coding_system (Fcheck_coding_system (coding_system), &coding) < 0) |
d46c5b12 | 6465 | error ("Invalid coding system: %s", XSYMBOL (coding_system)->name->data); |
3a73fa5d | 6466 | |
d46c5b12 | 6467 | coding.mode |= CODING_MODE_LAST_BLOCK; |
b73bfc1c KH |
6468 | coding.src_multibyte = coding.dst_multibyte |
6469 | = !NILP (current_buffer->enable_multibyte_characters); | |
fb88bf2d KH |
6470 | code_convert_region (from, CHAR_TO_BYTE (from), to, CHAR_TO_BYTE (to), |
6471 | &coding, encodep, 1); | |
f072a3e8 | 6472 | Vlast_coding_system_used = coding.symbol; |
fb88bf2d | 6473 | return make_number (coding.produced_char); |
4031e2bf KH |
6474 | } |
6475 | ||
6476 | DEFUN ("decode-coding-region", Fdecode_coding_region, Sdecode_coding_region, | |
6477 | 3, 3, "r\nzCoding system: ", | |
48b0f3ae PJ |
6478 | doc: /* Decode the current region from the specified coding system. |
6479 | When called from a program, takes three arguments: | |
6480 | START, END, and CODING-SYSTEM. START and END are buffer positions. | |
6481 | This function sets `last-coding-system-used' to the precise coding system | |
6482 | used (which may be different from CODING-SYSTEM if CODING-SYSTEM is | |
6483 | not fully specified.) | |
6484 | It returns the length of the decoded text. */) | |
6485 | (start, end, coding_system) | |
4031e2bf KH |
6486 | Lisp_Object start, end, coding_system; |
6487 | { | |
6488 | return code_convert_region1 (start, end, coding_system, 0); | |
3a73fa5d RS |
6489 | } |
6490 | ||
6491 | DEFUN ("encode-coding-region", Fencode_coding_region, Sencode_coding_region, | |
6492 | 3, 3, "r\nzCoding system: ", | |
48b0f3ae PJ |
6493 | doc: /* Encode the current region into the specified coding system. |
6494 | When called from a program, takes three arguments: | |
6495 | START, END, and CODING-SYSTEM. START and END are buffer positions. | |
6496 | This function sets `last-coding-system-used' to the precise coding system | |
6497 | used (which may be different from CODING-SYSTEM if CODING-SYSTEM is | |
6498 | not fully specified.) | |
6499 | It returns the length of the encoded text. */) | |
6500 | (start, end, coding_system) | |
d46c5b12 | 6501 | Lisp_Object start, end, coding_system; |
3a73fa5d | 6502 | { |
4031e2bf KH |
6503 | return code_convert_region1 (start, end, coding_system, 1); |
6504 | } | |
3a73fa5d | 6505 | |
4031e2bf KH |
6506 | Lisp_Object |
6507 | code_convert_string1 (string, coding_system, nocopy, encodep) | |
6508 | Lisp_Object string, coding_system, nocopy; | |
6509 | int encodep; | |
6510 | { | |
6511 | struct coding_system coding; | |
3a73fa5d | 6512 | |
b7826503 PJ |
6513 | CHECK_STRING (string); |
6514 | CHECK_SYMBOL (coding_system); | |
4ed46869 | 6515 | |
d46c5b12 | 6516 | if (NILP (coding_system)) |
4031e2bf | 6517 | return (NILP (nocopy) ? Fcopy_sequence (string) : string); |
4ed46869 | 6518 | |
d46c5b12 KH |
6519 | if (setup_coding_system (Fcheck_coding_system (coding_system), &coding) < 0) |
6520 | error ("Invalid coding system: %s", XSYMBOL (coding_system)->name->data); | |
5f1cd180 | 6521 | |
d46c5b12 | 6522 | coding.mode |= CODING_MODE_LAST_BLOCK; |
b73bfc1c KH |
6523 | string = (encodep |
6524 | ? encode_coding_string (string, &coding, !NILP (nocopy)) | |
6525 | : decode_coding_string (string, &coding, !NILP (nocopy))); | |
f072a3e8 | 6526 | Vlast_coding_system_used = coding.symbol; |
ec6d2bb8 KH |
6527 | |
6528 | return string; | |
4ed46869 KH |
6529 | } |
6530 | ||
4ed46869 | 6531 | DEFUN ("decode-coding-string", Fdecode_coding_string, Sdecode_coding_string, |
e0e989f6 | 6532 | 2, 3, 0, |
48b0f3ae PJ |
6533 | doc: /* Decode STRING which is encoded in CODING-SYSTEM, and return the result. |
6534 | Optional arg NOCOPY non-nil means it is OK to return STRING itself | |
6535 | if the decoding operation is trivial. | |
6536 | This function sets `last-coding-system-used' to the precise coding system | |
6537 | used (which may be different from CODING-SYSTEM if CODING-SYSTEM is | |
6538 | not fully specified.) */) | |
6539 | (string, coding_system, nocopy) | |
e0e989f6 | 6540 | Lisp_Object string, coding_system, nocopy; |
4ed46869 | 6541 | { |
f072a3e8 | 6542 | return code_convert_string1 (string, coding_system, nocopy, 0); |
4ed46869 KH |
6543 | } |
6544 | ||
6545 | DEFUN ("encode-coding-string", Fencode_coding_string, Sencode_coding_string, | |
e0e989f6 | 6546 | 2, 3, 0, |
48b0f3ae PJ |
6547 | doc: /* Encode STRING to CODING-SYSTEM, and return the result. |
6548 | Optional arg NOCOPY non-nil means it is OK to return STRING itself | |
6549 | if the encoding operation is trivial. | |
6550 | This function sets `last-coding-system-used' to the precise coding system | |
6551 | used (which may be different from CODING-SYSTEM if CODING-SYSTEM is | |
6552 | not fully specified.) */) | |
6553 | (string, coding_system, nocopy) | |
e0e989f6 | 6554 | Lisp_Object string, coding_system, nocopy; |
4ed46869 | 6555 | { |
f072a3e8 | 6556 | return code_convert_string1 (string, coding_system, nocopy, 1); |
4ed46869 | 6557 | } |
4031e2bf | 6558 | |
ecec61c1 | 6559 | /* Encode or decode STRING according to CODING_SYSTEM. |
ec6d2bb8 KH |
6560 | Do not set Vlast_coding_system_used. |
6561 | ||
6562 | This function is called only from macros DECODE_FILE and | |
6563 | ENCODE_FILE, thus we ignore character composition. */ | |
ecec61c1 KH |
6564 | |
6565 | Lisp_Object | |
6566 | code_convert_string_norecord (string, coding_system, encodep) | |
6567 | Lisp_Object string, coding_system; | |
6568 | int encodep; | |
6569 | { | |
6570 | struct coding_system coding; | |
6571 | ||
b7826503 PJ |
6572 | CHECK_STRING (string); |
6573 | CHECK_SYMBOL (coding_system); | |
ecec61c1 KH |
6574 | |
6575 | if (NILP (coding_system)) | |
6576 | return string; | |
6577 | ||
6578 | if (setup_coding_system (Fcheck_coding_system (coding_system), &coding) < 0) | |
6579 | error ("Invalid coding system: %s", XSYMBOL (coding_system)->name->data); | |
6580 | ||
ec6d2bb8 | 6581 | coding.composing = COMPOSITION_DISABLED; |
ecec61c1 | 6582 | coding.mode |= CODING_MODE_LAST_BLOCK; |
b73bfc1c KH |
6583 | return (encodep |
6584 | ? encode_coding_string (string, &coding, 1) | |
6585 | : decode_coding_string (string, &coding, 1)); | |
ecec61c1 | 6586 | } |
3a73fa5d | 6587 | \f |
4ed46869 | 6588 | DEFUN ("decode-sjis-char", Fdecode_sjis_char, Sdecode_sjis_char, 1, 1, 0, |
48b0f3ae PJ |
6589 | doc: /* Decode a Japanese character which has CODE in shift_jis encoding. |
6590 | Return the corresponding character. */) | |
6591 | (code) | |
4ed46869 KH |
6592 | Lisp_Object code; |
6593 | { | |
6594 | unsigned char c1, c2, s1, s2; | |
6595 | Lisp_Object val; | |
6596 | ||
b7826503 | 6597 | CHECK_NUMBER (code); |
4ed46869 | 6598 | s1 = (XFASTINT (code)) >> 8, s2 = (XFASTINT (code)) & 0xFF; |
55ab7be3 KH |
6599 | if (s1 == 0) |
6600 | { | |
c28a9453 KH |
6601 | if (s2 < 0x80) |
6602 | XSETFASTINT (val, s2); | |
6603 | else if (s2 >= 0xA0 || s2 <= 0xDF) | |
b73bfc1c | 6604 | XSETFASTINT (val, MAKE_CHAR (charset_katakana_jisx0201, s2, 0)); |
c28a9453 | 6605 | else |
9da8350f | 6606 | error ("Invalid Shift JIS code: %x", XFASTINT (code)); |
55ab7be3 KH |
6607 | } |
6608 | else | |
6609 | { | |
6610 | if ((s1 < 0x80 || s1 > 0x9F && s1 < 0xE0 || s1 > 0xEF) | |
6611 | || (s2 < 0x40 || s2 == 0x7F || s2 > 0xFC)) | |
9da8350f | 6612 | error ("Invalid Shift JIS code: %x", XFASTINT (code)); |
55ab7be3 | 6613 | DECODE_SJIS (s1, s2, c1, c2); |
b73bfc1c | 6614 | XSETFASTINT (val, MAKE_CHAR (charset_jisx0208, c1, c2)); |
55ab7be3 | 6615 | } |
4ed46869 KH |
6616 | return val; |
6617 | } | |
6618 | ||
6619 | DEFUN ("encode-sjis-char", Fencode_sjis_char, Sencode_sjis_char, 1, 1, 0, | |
48b0f3ae PJ |
6620 | doc: /* Encode a Japanese character CHAR to shift_jis encoding. |
6621 | Return the corresponding code in SJIS. */) | |
6622 | (ch) | |
4ed46869 KH |
6623 | Lisp_Object ch; |
6624 | { | |
bcf26d6a | 6625 | int charset, c1, c2, s1, s2; |
4ed46869 KH |
6626 | Lisp_Object val; |
6627 | ||
b7826503 | 6628 | CHECK_NUMBER (ch); |
4ed46869 | 6629 | SPLIT_CHAR (XFASTINT (ch), charset, c1, c2); |
c28a9453 KH |
6630 | if (charset == CHARSET_ASCII) |
6631 | { | |
6632 | val = ch; | |
6633 | } | |
6634 | else if (charset == charset_jisx0208 | |
6635 | && c1 > 0x20 && c1 < 0x7F && c2 > 0x20 && c2 < 0x7F) | |
4ed46869 KH |
6636 | { |
6637 | ENCODE_SJIS (c1, c2, s1, s2); | |
bcf26d6a | 6638 | XSETFASTINT (val, (s1 << 8) | s2); |
4ed46869 | 6639 | } |
55ab7be3 KH |
6640 | else if (charset == charset_katakana_jisx0201 |
6641 | && c1 > 0x20 && c2 < 0xE0) | |
6642 | { | |
6643 | XSETFASTINT (val, c1 | 0x80); | |
6644 | } | |
4ed46869 | 6645 | else |
55ab7be3 | 6646 | error ("Can't encode to shift_jis: %d", XFASTINT (ch)); |
4ed46869 KH |
6647 | return val; |
6648 | } | |
6649 | ||
6650 | DEFUN ("decode-big5-char", Fdecode_big5_char, Sdecode_big5_char, 1, 1, 0, | |
48b0f3ae PJ |
6651 | doc: /* Decode a Big5 character which has CODE in BIG5 coding system. |
6652 | Return the corresponding character. */) | |
6653 | (code) | |
4ed46869 KH |
6654 | Lisp_Object code; |
6655 | { | |
6656 | int charset; | |
6657 | unsigned char b1, b2, c1, c2; | |
6658 | Lisp_Object val; | |
6659 | ||
b7826503 | 6660 | CHECK_NUMBER (code); |
4ed46869 | 6661 | b1 = (XFASTINT (code)) >> 8, b2 = (XFASTINT (code)) & 0xFF; |
c28a9453 KH |
6662 | if (b1 == 0) |
6663 | { | |
6664 | if (b2 >= 0x80) | |
9da8350f | 6665 | error ("Invalid BIG5 code: %x", XFASTINT (code)); |
c28a9453 KH |
6666 | val = code; |
6667 | } | |
6668 | else | |
6669 | { | |
6670 | if ((b1 < 0xA1 || b1 > 0xFE) | |
6671 | || (b2 < 0x40 || (b2 > 0x7E && b2 < 0xA1) || b2 > 0xFE)) | |
9da8350f | 6672 | error ("Invalid BIG5 code: %x", XFASTINT (code)); |
c28a9453 | 6673 | DECODE_BIG5 (b1, b2, charset, c1, c2); |
b73bfc1c | 6674 | XSETFASTINT (val, MAKE_CHAR (charset, c1, c2)); |
c28a9453 | 6675 | } |
4ed46869 KH |
6676 | return val; |
6677 | } | |
6678 | ||
6679 | DEFUN ("encode-big5-char", Fencode_big5_char, Sencode_big5_char, 1, 1, 0, | |
48b0f3ae PJ |
6680 | doc: /* Encode the Big5 character CHAR to BIG5 coding system. |
6681 | Return the corresponding character code in Big5. */) | |
6682 | (ch) | |
4ed46869 KH |
6683 | Lisp_Object ch; |
6684 | { | |
bcf26d6a | 6685 | int charset, c1, c2, b1, b2; |
4ed46869 KH |
6686 | Lisp_Object val; |
6687 | ||
b7826503 | 6688 | CHECK_NUMBER (ch); |
4ed46869 | 6689 | SPLIT_CHAR (XFASTINT (ch), charset, c1, c2); |
c28a9453 KH |
6690 | if (charset == CHARSET_ASCII) |
6691 | { | |
6692 | val = ch; | |
6693 | } | |
6694 | else if ((charset == charset_big5_1 | |
6695 | && (XFASTINT (ch) >= 0x250a1 && XFASTINT (ch) <= 0x271ec)) | |
6696 | || (charset == charset_big5_2 | |
6697 | && XFASTINT (ch) >= 0x290a1 && XFASTINT (ch) <= 0x2bdb2)) | |
4ed46869 KH |
6698 | { |
6699 | ENCODE_BIG5 (charset, c1, c2, b1, b2); | |
bcf26d6a | 6700 | XSETFASTINT (val, (b1 << 8) | b2); |
4ed46869 KH |
6701 | } |
6702 | else | |
c28a9453 | 6703 | error ("Can't encode to Big5: %d", XFASTINT (ch)); |
4ed46869 KH |
6704 | return val; |
6705 | } | |
3a73fa5d | 6706 | \f |
1ba9e4ab KH |
6707 | DEFUN ("set-terminal-coding-system-internal", |
6708 | Fset_terminal_coding_system_internal, | |
48b0f3ae PJ |
6709 | Sset_terminal_coding_system_internal, 1, 1, 0, |
6710 | doc: /* Internal use only. */) | |
6711 | (coding_system) | |
4ed46869 KH |
6712 | Lisp_Object coding_system; |
6713 | { | |
b7826503 | 6714 | CHECK_SYMBOL (coding_system); |
4ed46869 | 6715 | setup_coding_system (Fcheck_coding_system (coding_system), &terminal_coding); |
70c22245 | 6716 | /* We had better not send unsafe characters to terminal. */ |
6e85d753 | 6717 | terminal_coding.flags |= CODING_FLAG_ISO_SAFE; |
8ca3766a | 6718 | /* Character composition should be disabled. */ |
ec6d2bb8 | 6719 | terminal_coding.composing = COMPOSITION_DISABLED; |
bd64290d KH |
6720 | /* Error notification should be suppressed. */ |
6721 | terminal_coding.suppress_error = 1; | |
b73bfc1c KH |
6722 | terminal_coding.src_multibyte = 1; |
6723 | terminal_coding.dst_multibyte = 0; | |
4ed46869 KH |
6724 | return Qnil; |
6725 | } | |
6726 | ||
c4825358 KH |
6727 | DEFUN ("set-safe-terminal-coding-system-internal", |
6728 | Fset_safe_terminal_coding_system_internal, | |
48b0f3ae PJ |
6729 | Sset_safe_terminal_coding_system_internal, 1, 1, 0, |
6730 | doc: /* Internal use only. */) | |
6731 | (coding_system) | |
c4825358 KH |
6732 | Lisp_Object coding_system; |
6733 | { | |
b7826503 | 6734 | CHECK_SYMBOL (coding_system); |
c4825358 KH |
6735 | setup_coding_system (Fcheck_coding_system (coding_system), |
6736 | &safe_terminal_coding); | |
8ca3766a | 6737 | /* Character composition should be disabled. */ |
ec6d2bb8 | 6738 | safe_terminal_coding.composing = COMPOSITION_DISABLED; |
bd64290d KH |
6739 | /* Error notification should be suppressed. */ |
6740 | terminal_coding.suppress_error = 1; | |
b73bfc1c KH |
6741 | safe_terminal_coding.src_multibyte = 1; |
6742 | safe_terminal_coding.dst_multibyte = 0; | |
c4825358 KH |
6743 | return Qnil; |
6744 | } | |
6745 | ||
4ed46869 KH |
6746 | DEFUN ("terminal-coding-system", |
6747 | Fterminal_coding_system, Sterminal_coding_system, 0, 0, 0, | |
48b0f3ae PJ |
6748 | doc: /* Return coding system specified for terminal output. */) |
6749 | () | |
4ed46869 KH |
6750 | { |
6751 | return terminal_coding.symbol; | |
6752 | } | |
6753 | ||
1ba9e4ab KH |
6754 | DEFUN ("set-keyboard-coding-system-internal", |
6755 | Fset_keyboard_coding_system_internal, | |
48b0f3ae PJ |
6756 | Sset_keyboard_coding_system_internal, 1, 1, 0, |
6757 | doc: /* Internal use only. */) | |
6758 | (coding_system) | |
4ed46869 KH |
6759 | Lisp_Object coding_system; |
6760 | { | |
b7826503 | 6761 | CHECK_SYMBOL (coding_system); |
4ed46869 | 6762 | setup_coding_system (Fcheck_coding_system (coding_system), &keyboard_coding); |
8ca3766a | 6763 | /* Character composition should be disabled. */ |
ec6d2bb8 | 6764 | keyboard_coding.composing = COMPOSITION_DISABLED; |
4ed46869 KH |
6765 | return Qnil; |
6766 | } | |
6767 | ||
6768 | DEFUN ("keyboard-coding-system", | |
6769 | Fkeyboard_coding_system, Skeyboard_coding_system, 0, 0, 0, | |
48b0f3ae PJ |
6770 | doc: /* Return coding system specified for decoding keyboard input. */) |
6771 | () | |
4ed46869 KH |
6772 | { |
6773 | return keyboard_coding.symbol; | |
6774 | } | |
6775 | ||
6776 | \f | |
a5d301df KH |
6777 | DEFUN ("find-operation-coding-system", Ffind_operation_coding_system, |
6778 | Sfind_operation_coding_system, 1, MANY, 0, | |
48b0f3ae PJ |
6779 | doc: /* Choose a coding system for an operation based on the target name. |
6780 | The value names a pair of coding systems: (DECODING-SYSTEM . ENCODING-SYSTEM). | |
6781 | DECODING-SYSTEM is the coding system to use for decoding | |
6782 | \(in case OPERATION does decoding), and ENCODING-SYSTEM is the coding system | |
6783 | for encoding (in case OPERATION does encoding). | |
6784 | ||
6785 | The first argument OPERATION specifies an I/O primitive: | |
6786 | For file I/O, `insert-file-contents' or `write-region'. | |
6787 | For process I/O, `call-process', `call-process-region', or `start-process'. | |
6788 | For network I/O, `open-network-stream'. | |
6789 | ||
6790 | The remaining arguments should be the same arguments that were passed | |
6791 | to the primitive. Depending on which primitive, one of those arguments | |
6792 | is selected as the TARGET. For example, if OPERATION does file I/O, | |
6793 | whichever argument specifies the file name is TARGET. | |
6794 | ||
6795 | TARGET has a meaning which depends on OPERATION: | |
6796 | For file I/O, TARGET is a file name. | |
6797 | For process I/O, TARGET is a process name. | |
6798 | For network I/O, TARGET is a service name or a port number | |
6799 | ||
6800 | This function looks up what specified for TARGET in, | |
6801 | `file-coding-system-alist', `process-coding-system-alist', | |
6802 | or `network-coding-system-alist' depending on OPERATION. | |
6803 | They may specify a coding system, a cons of coding systems, | |
6804 | or a function symbol to call. | |
6805 | In the last case, we call the function with one argument, | |
6806 | which is a list of all the arguments given to this function. | |
6807 | ||
6808 | usage: (find-operation-coding-system OPERATION ARGUMENTS ...) */) | |
6809 | (nargs, args) | |
4ed46869 KH |
6810 | int nargs; |
6811 | Lisp_Object *args; | |
6812 | { | |
6813 | Lisp_Object operation, target_idx, target, val; | |
6814 | register Lisp_Object chain; | |
6815 | ||
6816 | if (nargs < 2) | |
6817 | error ("Too few arguments"); | |
6818 | operation = args[0]; | |
6819 | if (!SYMBOLP (operation) | |
6820 | || !INTEGERP (target_idx = Fget (operation, Qtarget_idx))) | |
8ca3766a | 6821 | error ("Invalid first argument"); |
4ed46869 KH |
6822 | if (nargs < 1 + XINT (target_idx)) |
6823 | error ("Too few arguments for operation: %s", | |
6824 | XSYMBOL (operation)->name->data); | |
6825 | target = args[XINT (target_idx) + 1]; | |
6826 | if (!(STRINGP (target) | |
6827 | || (EQ (operation, Qopen_network_stream) && INTEGERP (target)))) | |
8ca3766a | 6828 | error ("Invalid argument %d", XINT (target_idx) + 1); |
4ed46869 | 6829 | |
2e34157c RS |
6830 | chain = ((EQ (operation, Qinsert_file_contents) |
6831 | || EQ (operation, Qwrite_region)) | |
02ba4723 | 6832 | ? Vfile_coding_system_alist |
2e34157c | 6833 | : (EQ (operation, Qopen_network_stream) |
02ba4723 KH |
6834 | ? Vnetwork_coding_system_alist |
6835 | : Vprocess_coding_system_alist)); | |
4ed46869 KH |
6836 | if (NILP (chain)) |
6837 | return Qnil; | |
6838 | ||
03699b14 | 6839 | for (; CONSP (chain); chain = XCDR (chain)) |
4ed46869 | 6840 | { |
f44d27ce | 6841 | Lisp_Object elt; |
03699b14 | 6842 | elt = XCAR (chain); |
4ed46869 KH |
6843 | |
6844 | if (CONSP (elt) | |
6845 | && ((STRINGP (target) | |
03699b14 KR |
6846 | && STRINGP (XCAR (elt)) |
6847 | && fast_string_match (XCAR (elt), target) >= 0) | |
6848 | || (INTEGERP (target) && EQ (target, XCAR (elt))))) | |
02ba4723 | 6849 | { |
03699b14 | 6850 | val = XCDR (elt); |
b19fd4c5 KH |
6851 | /* Here, if VAL is both a valid coding system and a valid |
6852 | function symbol, we return VAL as a coding system. */ | |
02ba4723 KH |
6853 | if (CONSP (val)) |
6854 | return val; | |
6855 | if (! SYMBOLP (val)) | |
6856 | return Qnil; | |
6857 | if (! NILP (Fcoding_system_p (val))) | |
6858 | return Fcons (val, val); | |
b19fd4c5 KH |
6859 | if (! NILP (Ffboundp (val))) |
6860 | { | |
6861 | val = call1 (val, Flist (nargs, args)); | |
6862 | if (CONSP (val)) | |
6863 | return val; | |
6864 | if (SYMBOLP (val) && ! NILP (Fcoding_system_p (val))) | |
6865 | return Fcons (val, val); | |
6866 | } | |
02ba4723 KH |
6867 | return Qnil; |
6868 | } | |
4ed46869 KH |
6869 | } |
6870 | return Qnil; | |
6871 | } | |
6872 | ||
1397dc18 KH |
6873 | DEFUN ("update-coding-systems-internal", Fupdate_coding_systems_internal, |
6874 | Supdate_coding_systems_internal, 0, 0, 0, | |
48b0f3ae PJ |
6875 | doc: /* Update internal database for ISO2022 and CCL based coding systems. |
6876 | When values of any coding categories are changed, you must | |
6877 | call this function. */) | |
6878 | () | |
d46c5b12 KH |
6879 | { |
6880 | int i; | |
6881 | ||
fa42c37f | 6882 | for (i = CODING_CATEGORY_IDX_EMACS_MULE; i < CODING_CATEGORY_IDX_MAX; i++) |
d46c5b12 | 6883 | { |
1397dc18 KH |
6884 | Lisp_Object val; |
6885 | ||
f5c1dd0d | 6886 | val = SYMBOL_VALUE (XVECTOR (Vcoding_category_table)->contents[i]); |
1397dc18 KH |
6887 | if (!NILP (val)) |
6888 | { | |
6889 | if (! coding_system_table[i]) | |
6890 | coding_system_table[i] = ((struct coding_system *) | |
6891 | xmalloc (sizeof (struct coding_system))); | |
6892 | setup_coding_system (val, coding_system_table[i]); | |
6893 | } | |
6894 | else if (coding_system_table[i]) | |
6895 | { | |
6896 | xfree (coding_system_table[i]); | |
6897 | coding_system_table[i] = NULL; | |
6898 | } | |
d46c5b12 | 6899 | } |
1397dc18 | 6900 | |
d46c5b12 KH |
6901 | return Qnil; |
6902 | } | |
6903 | ||
66cfb530 KH |
6904 | DEFUN ("set-coding-priority-internal", Fset_coding_priority_internal, |
6905 | Sset_coding_priority_internal, 0, 0, 0, | |
48b0f3ae PJ |
6906 | doc: /* Update internal database for the current value of `coding-category-list'. |
6907 | This function is internal use only. */) | |
6908 | () | |
66cfb530 KH |
6909 | { |
6910 | int i = 0, idx; | |
84d60297 RS |
6911 | Lisp_Object val; |
6912 | ||
6913 | val = Vcoding_category_list; | |
66cfb530 KH |
6914 | |
6915 | while (CONSP (val) && i < CODING_CATEGORY_IDX_MAX) | |
6916 | { | |
03699b14 | 6917 | if (! SYMBOLP (XCAR (val))) |
66cfb530 | 6918 | break; |
03699b14 | 6919 | idx = XFASTINT (Fget (XCAR (val), Qcoding_category_index)); |
66cfb530 KH |
6920 | if (idx >= CODING_CATEGORY_IDX_MAX) |
6921 | break; | |
6922 | coding_priorities[i++] = (1 << idx); | |
03699b14 | 6923 | val = XCDR (val); |
66cfb530 KH |
6924 | } |
6925 | /* If coding-category-list is valid and contains all coding | |
6926 | categories, `i' should be CODING_CATEGORY_IDX_MAX now. If not, | |
fa42c37f | 6927 | the following code saves Emacs from crashing. */ |
66cfb530 KH |
6928 | while (i < CODING_CATEGORY_IDX_MAX) |
6929 | coding_priorities[i++] = CODING_CATEGORY_MASK_RAW_TEXT; | |
6930 | ||
6931 | return Qnil; | |
6932 | } | |
6933 | ||
4ed46869 KH |
6934 | #endif /* emacs */ |
6935 | ||
6936 | \f | |
1397dc18 | 6937 | /*** 9. Post-amble ***/ |
4ed46869 | 6938 | |
dfcf069d | 6939 | void |
4ed46869 KH |
6940 | init_coding_once () |
6941 | { | |
6942 | int i; | |
6943 | ||
0ef69138 | 6944 | /* Emacs' internal format specific initialize routine. */ |
4ed46869 KH |
6945 | for (i = 0; i <= 0x20; i++) |
6946 | emacs_code_class[i] = EMACS_control_code; | |
6947 | emacs_code_class[0x0A] = EMACS_linefeed_code; | |
6948 | emacs_code_class[0x0D] = EMACS_carriage_return_code; | |
6949 | for (i = 0x21 ; i < 0x7F; i++) | |
6950 | emacs_code_class[i] = EMACS_ascii_code; | |
6951 | emacs_code_class[0x7F] = EMACS_control_code; | |
ec6d2bb8 | 6952 | for (i = 0x80; i < 0xFF; i++) |
4ed46869 KH |
6953 | emacs_code_class[i] = EMACS_invalid_code; |
6954 | emacs_code_class[LEADING_CODE_PRIVATE_11] = EMACS_leading_code_3; | |
6955 | emacs_code_class[LEADING_CODE_PRIVATE_12] = EMACS_leading_code_3; | |
6956 | emacs_code_class[LEADING_CODE_PRIVATE_21] = EMACS_leading_code_4; | |
6957 | emacs_code_class[LEADING_CODE_PRIVATE_22] = EMACS_leading_code_4; | |
6958 | ||
6959 | /* ISO2022 specific initialize routine. */ | |
6960 | for (i = 0; i < 0x20; i++) | |
b73bfc1c | 6961 | iso_code_class[i] = ISO_control_0; |
4ed46869 KH |
6962 | for (i = 0x21; i < 0x7F; i++) |
6963 | iso_code_class[i] = ISO_graphic_plane_0; | |
6964 | for (i = 0x80; i < 0xA0; i++) | |
b73bfc1c | 6965 | iso_code_class[i] = ISO_control_1; |
4ed46869 KH |
6966 | for (i = 0xA1; i < 0xFF; i++) |
6967 | iso_code_class[i] = ISO_graphic_plane_1; | |
6968 | iso_code_class[0x20] = iso_code_class[0x7F] = ISO_0x20_or_0x7F; | |
6969 | iso_code_class[0xA0] = iso_code_class[0xFF] = ISO_0xA0_or_0xFF; | |
6970 | iso_code_class[ISO_CODE_CR] = ISO_carriage_return; | |
6971 | iso_code_class[ISO_CODE_SO] = ISO_shift_out; | |
6972 | iso_code_class[ISO_CODE_SI] = ISO_shift_in; | |
6973 | iso_code_class[ISO_CODE_SS2_7] = ISO_single_shift_2_7; | |
6974 | iso_code_class[ISO_CODE_ESC] = ISO_escape; | |
6975 | iso_code_class[ISO_CODE_SS2] = ISO_single_shift_2; | |
6976 | iso_code_class[ISO_CODE_SS3] = ISO_single_shift_3; | |
6977 | iso_code_class[ISO_CODE_CSI] = ISO_control_sequence_introducer; | |
6978 | ||
e0e989f6 KH |
6979 | setup_coding_system (Qnil, &keyboard_coding); |
6980 | setup_coding_system (Qnil, &terminal_coding); | |
c4825358 | 6981 | setup_coding_system (Qnil, &safe_terminal_coding); |
6bc51348 | 6982 | setup_coding_system (Qnil, &default_buffer_file_coding); |
9ce27fde | 6983 | |
d46c5b12 KH |
6984 | bzero (coding_system_table, sizeof coding_system_table); |
6985 | ||
66cfb530 KH |
6986 | bzero (ascii_skip_code, sizeof ascii_skip_code); |
6987 | for (i = 0; i < 128; i++) | |
6988 | ascii_skip_code[i] = 1; | |
6989 | ||
9ce27fde KH |
6990 | #if defined (MSDOS) || defined (WINDOWSNT) |
6991 | system_eol_type = CODING_EOL_CRLF; | |
6992 | #else | |
6993 | system_eol_type = CODING_EOL_LF; | |
6994 | #endif | |
b843d1ae KH |
6995 | |
6996 | inhibit_pre_post_conversion = 0; | |
e0e989f6 KH |
6997 | } |
6998 | ||
6999 | #ifdef emacs | |
7000 | ||
dfcf069d | 7001 | void |
e0e989f6 KH |
7002 | syms_of_coding () |
7003 | { | |
7004 | Qtarget_idx = intern ("target-idx"); | |
7005 | staticpro (&Qtarget_idx); | |
7006 | ||
bb0115a2 RS |
7007 | Qcoding_system_history = intern ("coding-system-history"); |
7008 | staticpro (&Qcoding_system_history); | |
7009 | Fset (Qcoding_system_history, Qnil); | |
7010 | ||
9ce27fde | 7011 | /* Target FILENAME is the first argument. */ |
e0e989f6 | 7012 | Fput (Qinsert_file_contents, Qtarget_idx, make_number (0)); |
9ce27fde | 7013 | /* Target FILENAME is the third argument. */ |
e0e989f6 KH |
7014 | Fput (Qwrite_region, Qtarget_idx, make_number (2)); |
7015 | ||
7016 | Qcall_process = intern ("call-process"); | |
7017 | staticpro (&Qcall_process); | |
9ce27fde | 7018 | /* Target PROGRAM is the first argument. */ |
e0e989f6 KH |
7019 | Fput (Qcall_process, Qtarget_idx, make_number (0)); |
7020 | ||
7021 | Qcall_process_region = intern ("call-process-region"); | |
7022 | staticpro (&Qcall_process_region); | |
9ce27fde | 7023 | /* Target PROGRAM is the third argument. */ |
e0e989f6 KH |
7024 | Fput (Qcall_process_region, Qtarget_idx, make_number (2)); |
7025 | ||
7026 | Qstart_process = intern ("start-process"); | |
7027 | staticpro (&Qstart_process); | |
9ce27fde | 7028 | /* Target PROGRAM is the third argument. */ |
e0e989f6 KH |
7029 | Fput (Qstart_process, Qtarget_idx, make_number (2)); |
7030 | ||
7031 | Qopen_network_stream = intern ("open-network-stream"); | |
7032 | staticpro (&Qopen_network_stream); | |
9ce27fde | 7033 | /* Target SERVICE is the fourth argument. */ |
e0e989f6 KH |
7034 | Fput (Qopen_network_stream, Qtarget_idx, make_number (3)); |
7035 | ||
4ed46869 KH |
7036 | Qcoding_system = intern ("coding-system"); |
7037 | staticpro (&Qcoding_system); | |
7038 | ||
7039 | Qeol_type = intern ("eol-type"); | |
7040 | staticpro (&Qeol_type); | |
7041 | ||
7042 | Qbuffer_file_coding_system = intern ("buffer-file-coding-system"); | |
7043 | staticpro (&Qbuffer_file_coding_system); | |
7044 | ||
7045 | Qpost_read_conversion = intern ("post-read-conversion"); | |
7046 | staticpro (&Qpost_read_conversion); | |
7047 | ||
7048 | Qpre_write_conversion = intern ("pre-write-conversion"); | |
7049 | staticpro (&Qpre_write_conversion); | |
7050 | ||
27901516 KH |
7051 | Qno_conversion = intern ("no-conversion"); |
7052 | staticpro (&Qno_conversion); | |
7053 | ||
7054 | Qundecided = intern ("undecided"); | |
7055 | staticpro (&Qundecided); | |
7056 | ||
4ed46869 KH |
7057 | Qcoding_system_p = intern ("coding-system-p"); |
7058 | staticpro (&Qcoding_system_p); | |
7059 | ||
7060 | Qcoding_system_error = intern ("coding-system-error"); | |
7061 | staticpro (&Qcoding_system_error); | |
7062 | ||
7063 | Fput (Qcoding_system_error, Qerror_conditions, | |
7064 | Fcons (Qcoding_system_error, Fcons (Qerror, Qnil))); | |
7065 | Fput (Qcoding_system_error, Qerror_message, | |
9ce27fde | 7066 | build_string ("Invalid coding system")); |
4ed46869 | 7067 | |
d46c5b12 KH |
7068 | Qcoding_category = intern ("coding-category"); |
7069 | staticpro (&Qcoding_category); | |
4ed46869 KH |
7070 | Qcoding_category_index = intern ("coding-category-index"); |
7071 | staticpro (&Qcoding_category_index); | |
7072 | ||
d46c5b12 KH |
7073 | Vcoding_category_table |
7074 | = Fmake_vector (make_number (CODING_CATEGORY_IDX_MAX), Qnil); | |
7075 | staticpro (&Vcoding_category_table); | |
4ed46869 KH |
7076 | { |
7077 | int i; | |
7078 | for (i = 0; i < CODING_CATEGORY_IDX_MAX; i++) | |
7079 | { | |
d46c5b12 KH |
7080 | XVECTOR (Vcoding_category_table)->contents[i] |
7081 | = intern (coding_category_name[i]); | |
7082 | Fput (XVECTOR (Vcoding_category_table)->contents[i], | |
7083 | Qcoding_category_index, make_number (i)); | |
4ed46869 KH |
7084 | } |
7085 | } | |
7086 | ||
f967223b KH |
7087 | Qtranslation_table = intern ("translation-table"); |
7088 | staticpro (&Qtranslation_table); | |
1397dc18 | 7089 | Fput (Qtranslation_table, Qchar_table_extra_slots, make_number (1)); |
bdd9fb48 | 7090 | |
f967223b KH |
7091 | Qtranslation_table_id = intern ("translation-table-id"); |
7092 | staticpro (&Qtranslation_table_id); | |
84fbb8a0 | 7093 | |
f967223b KH |
7094 | Qtranslation_table_for_decode = intern ("translation-table-for-decode"); |
7095 | staticpro (&Qtranslation_table_for_decode); | |
a5d301df | 7096 | |
f967223b KH |
7097 | Qtranslation_table_for_encode = intern ("translation-table-for-encode"); |
7098 | staticpro (&Qtranslation_table_for_encode); | |
a5d301df | 7099 | |
05e6f5dc KH |
7100 | Qsafe_chars = intern ("safe-chars"); |
7101 | staticpro (&Qsafe_chars); | |
7102 | ||
7103 | Qchar_coding_system = intern ("char-coding-system"); | |
7104 | staticpro (&Qchar_coding_system); | |
7105 | ||
7106 | /* Intern this now in case it isn't already done. | |
7107 | Setting this variable twice is harmless. | |
7108 | But don't staticpro it here--that is done in alloc.c. */ | |
7109 | Qchar_table_extra_slots = intern ("char-table-extra-slots"); | |
7110 | Fput (Qsafe_chars, Qchar_table_extra_slots, make_number (0)); | |
7111 | Fput (Qchar_coding_system, Qchar_table_extra_slots, make_number (1)); | |
70c22245 | 7112 | |
1397dc18 KH |
7113 | Qvalid_codes = intern ("valid-codes"); |
7114 | staticpro (&Qvalid_codes); | |
7115 | ||
9ce27fde KH |
7116 | Qemacs_mule = intern ("emacs-mule"); |
7117 | staticpro (&Qemacs_mule); | |
7118 | ||
d46c5b12 KH |
7119 | Qraw_text = intern ("raw-text"); |
7120 | staticpro (&Qraw_text); | |
7121 | ||
4ed46869 KH |
7122 | defsubr (&Scoding_system_p); |
7123 | defsubr (&Sread_coding_system); | |
7124 | defsubr (&Sread_non_nil_coding_system); | |
7125 | defsubr (&Scheck_coding_system); | |
7126 | defsubr (&Sdetect_coding_region); | |
d46c5b12 | 7127 | defsubr (&Sdetect_coding_string); |
05e6f5dc | 7128 | defsubr (&Sfind_coding_systems_region_internal); |
4ed46869 KH |
7129 | defsubr (&Sdecode_coding_region); |
7130 | defsubr (&Sencode_coding_region); | |
7131 | defsubr (&Sdecode_coding_string); | |
7132 | defsubr (&Sencode_coding_string); | |
7133 | defsubr (&Sdecode_sjis_char); | |
7134 | defsubr (&Sencode_sjis_char); | |
7135 | defsubr (&Sdecode_big5_char); | |
7136 | defsubr (&Sencode_big5_char); | |
1ba9e4ab | 7137 | defsubr (&Sset_terminal_coding_system_internal); |
c4825358 | 7138 | defsubr (&Sset_safe_terminal_coding_system_internal); |
4ed46869 | 7139 | defsubr (&Sterminal_coding_system); |
1ba9e4ab | 7140 | defsubr (&Sset_keyboard_coding_system_internal); |
4ed46869 | 7141 | defsubr (&Skeyboard_coding_system); |
a5d301df | 7142 | defsubr (&Sfind_operation_coding_system); |
1397dc18 | 7143 | defsubr (&Supdate_coding_systems_internal); |
66cfb530 | 7144 | defsubr (&Sset_coding_priority_internal); |
4ed46869 | 7145 | |
4608c386 | 7146 | DEFVAR_LISP ("coding-system-list", &Vcoding_system_list, |
48b0f3ae PJ |
7147 | doc: /* List of coding systems. |
7148 | ||
7149 | Do not alter the value of this variable manually. This variable should be | |
7150 | updated by the functions `make-coding-system' and | |
7151 | `define-coding-system-alias'. */); | |
4608c386 KH |
7152 | Vcoding_system_list = Qnil; |
7153 | ||
7154 | DEFVAR_LISP ("coding-system-alist", &Vcoding_system_alist, | |
48b0f3ae PJ |
7155 | doc: /* Alist of coding system names. |
7156 | Each element is one element list of coding system name. | |
7157 | This variable is given to `completing-read' as TABLE argument. | |
7158 | ||
7159 | Do not alter the value of this variable manually. This variable should be | |
7160 | updated by the functions `make-coding-system' and | |
7161 | `define-coding-system-alias'. */); | |
4608c386 KH |
7162 | Vcoding_system_alist = Qnil; |
7163 | ||
4ed46869 | 7164 | DEFVAR_LISP ("coding-category-list", &Vcoding_category_list, |
48b0f3ae PJ |
7165 | doc: /* List of coding-categories (symbols) ordered by priority. |
7166 | ||
7167 | On detecting a coding system, Emacs tries code detection algorithms | |
7168 | associated with each coding-category one by one in this order. When | |
7169 | one algorithm agrees with a byte sequence of source text, the coding | |
7170 | system bound to the corresponding coding-category is selected. */); | |
4ed46869 KH |
7171 | { |
7172 | int i; | |
7173 | ||
7174 | Vcoding_category_list = Qnil; | |
7175 | for (i = CODING_CATEGORY_IDX_MAX - 1; i >= 0; i--) | |
7176 | Vcoding_category_list | |
d46c5b12 KH |
7177 | = Fcons (XVECTOR (Vcoding_category_table)->contents[i], |
7178 | Vcoding_category_list); | |
4ed46869 KH |
7179 | } |
7180 | ||
7181 | DEFVAR_LISP ("coding-system-for-read", &Vcoding_system_for_read, | |
48b0f3ae PJ |
7182 | doc: /* Specify the coding system for read operations. |
7183 | It is useful to bind this variable with `let', but do not set it globally. | |
7184 | If the value is a coding system, it is used for decoding on read operation. | |
7185 | If not, an appropriate element is used from one of the coding system alists: | |
7186 | There are three such tables, `file-coding-system-alist', | |
7187 | `process-coding-system-alist', and `network-coding-system-alist'. */); | |
4ed46869 KH |
7188 | Vcoding_system_for_read = Qnil; |
7189 | ||
7190 | DEFVAR_LISP ("coding-system-for-write", &Vcoding_system_for_write, | |
48b0f3ae PJ |
7191 | doc: /* Specify the coding system for write operations. |
7192 | Programs bind this variable with `let', but you should not set it globally. | |
7193 | If the value is a coding system, it is used for encoding of output, | |
7194 | when writing it to a file and when sending it to a file or subprocess. | |
7195 | ||
7196 | If this does not specify a coding system, an appropriate element | |
7197 | is used from one of the coding system alists: | |
7198 | There are three such tables, `file-coding-system-alist', | |
7199 | `process-coding-system-alist', and `network-coding-system-alist'. | |
7200 | For output to files, if the above procedure does not specify a coding system, | |
7201 | the value of `buffer-file-coding-system' is used. */); | |
4ed46869 KH |
7202 | Vcoding_system_for_write = Qnil; |
7203 | ||
7204 | DEFVAR_LISP ("last-coding-system-used", &Vlast_coding_system_used, | |
48b0f3ae | 7205 | doc: /* Coding system used in the latest file or process I/O. */); |
4ed46869 KH |
7206 | Vlast_coding_system_used = Qnil; |
7207 | ||
9ce27fde | 7208 | DEFVAR_BOOL ("inhibit-eol-conversion", &inhibit_eol_conversion, |
48b0f3ae PJ |
7209 | doc: /* *Non-nil means always inhibit code conversion of end-of-line format. |
7210 | See info node `Coding Systems' and info node `Text and Binary' concerning | |
7211 | such conversion. */); | |
9ce27fde KH |
7212 | inhibit_eol_conversion = 0; |
7213 | ||
ed29121d | 7214 | DEFVAR_BOOL ("inherit-process-coding-system", &inherit_process_coding_system, |
48b0f3ae PJ |
7215 | doc: /* Non-nil means process buffer inherits coding system of process output. |
7216 | Bind it to t if the process output is to be treated as if it were a file | |
7217 | read from some filesystem. */); | |
ed29121d EZ |
7218 | inherit_process_coding_system = 0; |
7219 | ||
02ba4723 | 7220 | DEFVAR_LISP ("file-coding-system-alist", &Vfile_coding_system_alist, |
48b0f3ae PJ |
7221 | doc: /* Alist to decide a coding system to use for a file I/O operation. |
7222 | The format is ((PATTERN . VAL) ...), | |
7223 | where PATTERN is a regular expression matching a file name, | |
7224 | VAL is a coding system, a cons of coding systems, or a function symbol. | |
7225 | If VAL is a coding system, it is used for both decoding and encoding | |
7226 | the file contents. | |
7227 | If VAL is a cons of coding systems, the car part is used for decoding, | |
7228 | and the cdr part is used for encoding. | |
7229 | If VAL is a function symbol, the function must return a coding system | |
7230 | or a cons of coding systems which are used as above. | |
7231 | ||
7232 | See also the function `find-operation-coding-system' | |
7233 | and the variable `auto-coding-alist'. */); | |
02ba4723 KH |
7234 | Vfile_coding_system_alist = Qnil; |
7235 | ||
7236 | DEFVAR_LISP ("process-coding-system-alist", &Vprocess_coding_system_alist, | |
48b0f3ae PJ |
7237 | doc: /* Alist to decide a coding system to use for a process I/O operation. |
7238 | The format is ((PATTERN . VAL) ...), | |
7239 | where PATTERN is a regular expression matching a program name, | |
7240 | VAL is a coding system, a cons of coding systems, or a function symbol. | |
7241 | If VAL is a coding system, it is used for both decoding what received | |
7242 | from the program and encoding what sent to the program. | |
7243 | If VAL is a cons of coding systems, the car part is used for decoding, | |
7244 | and the cdr part is used for encoding. | |
7245 | If VAL is a function symbol, the function must return a coding system | |
7246 | or a cons of coding systems which are used as above. | |
7247 | ||
7248 | See also the function `find-operation-coding-system'. */); | |
02ba4723 KH |
7249 | Vprocess_coding_system_alist = Qnil; |
7250 | ||
7251 | DEFVAR_LISP ("network-coding-system-alist", &Vnetwork_coding_system_alist, | |
48b0f3ae PJ |
7252 | doc: /* Alist to decide a coding system to use for a network I/O operation. |
7253 | The format is ((PATTERN . VAL) ...), | |
7254 | where PATTERN is a regular expression matching a network service name | |
7255 | or is a port number to connect to, | |
7256 | VAL is a coding system, a cons of coding systems, or a function symbol. | |
7257 | If VAL is a coding system, it is used for both decoding what received | |
7258 | from the network stream and encoding what sent to the network stream. | |
7259 | If VAL is a cons of coding systems, the car part is used for decoding, | |
7260 | and the cdr part is used for encoding. | |
7261 | If VAL is a function symbol, the function must return a coding system | |
7262 | or a cons of coding systems which are used as above. | |
7263 | ||
7264 | See also the function `find-operation-coding-system'. */); | |
02ba4723 | 7265 | Vnetwork_coding_system_alist = Qnil; |
4ed46869 | 7266 | |
68c45bf0 | 7267 | DEFVAR_LISP ("locale-coding-system", &Vlocale_coding_system, |
48b0f3ae PJ |
7268 | doc: /* Coding system to use with system messages. Also used for decoding |
7269 | keyboard input on X Window system. */); | |
68c45bf0 PE |
7270 | Vlocale_coding_system = Qnil; |
7271 | ||
005f0d35 | 7272 | /* The eol mnemonics are reset in startup.el system-dependently. */ |
7722baf9 | 7273 | DEFVAR_LISP ("eol-mnemonic-unix", &eol_mnemonic_unix, |
48b0f3ae | 7274 | doc: /* *String displayed in mode line for UNIX-like (LF) end-of-line format. */); |
7722baf9 | 7275 | eol_mnemonic_unix = build_string (":"); |
4ed46869 | 7276 | |
7722baf9 | 7277 | DEFVAR_LISP ("eol-mnemonic-dos", &eol_mnemonic_dos, |
48b0f3ae | 7278 | doc: /* *String displayed in mode line for DOS-like (CRLF) end-of-line format. */); |
7722baf9 | 7279 | eol_mnemonic_dos = build_string ("\\"); |
4ed46869 | 7280 | |
7722baf9 | 7281 | DEFVAR_LISP ("eol-mnemonic-mac", &eol_mnemonic_mac, |
48b0f3ae | 7282 | doc: /* *String displayed in mode line for MAC-like (CR) end-of-line format. */); |
7722baf9 | 7283 | eol_mnemonic_mac = build_string ("/"); |
4ed46869 | 7284 | |
7722baf9 | 7285 | DEFVAR_LISP ("eol-mnemonic-undecided", &eol_mnemonic_undecided, |
48b0f3ae | 7286 | doc: /* *String displayed in mode line when end-of-line format is not yet determined. */); |
7722baf9 | 7287 | eol_mnemonic_undecided = build_string (":"); |
4ed46869 | 7288 | |
84fbb8a0 | 7289 | DEFVAR_LISP ("enable-character-translation", &Venable_character_translation, |
48b0f3ae | 7290 | doc: /* *Non-nil enables character translation while encoding and decoding. */); |
84fbb8a0 | 7291 | Venable_character_translation = Qt; |
bdd9fb48 | 7292 | |
f967223b | 7293 | DEFVAR_LISP ("standard-translation-table-for-decode", |
48b0f3ae PJ |
7294 | &Vstandard_translation_table_for_decode, |
7295 | doc: /* Table for translating characters while decoding. */); | |
f967223b | 7296 | Vstandard_translation_table_for_decode = Qnil; |
bdd9fb48 | 7297 | |
f967223b | 7298 | DEFVAR_LISP ("standard-translation-table-for-encode", |
48b0f3ae PJ |
7299 | &Vstandard_translation_table_for_encode, |
7300 | doc: /* Table for translating characters while encoding. */); | |
f967223b | 7301 | Vstandard_translation_table_for_encode = Qnil; |
4ed46869 KH |
7302 | |
7303 | DEFVAR_LISP ("charset-revision-table", &Vcharset_revision_alist, | |
48b0f3ae PJ |
7304 | doc: /* Alist of charsets vs revision numbers. |
7305 | While encoding, if a charset (car part of an element) is found, | |
7306 | designate it with the escape sequence identifying revision (cdr part of the element). */); | |
4ed46869 | 7307 | Vcharset_revision_alist = Qnil; |
02ba4723 KH |
7308 | |
7309 | DEFVAR_LISP ("default-process-coding-system", | |
7310 | &Vdefault_process_coding_system, | |
48b0f3ae PJ |
7311 | doc: /* Cons of coding systems used for process I/O by default. |
7312 | The car part is used for decoding a process output, | |
7313 | the cdr part is used for encoding a text to be sent to a process. */); | |
02ba4723 | 7314 | Vdefault_process_coding_system = Qnil; |
c4825358 | 7315 | |
3f003981 | 7316 | DEFVAR_LISP ("latin-extra-code-table", &Vlatin_extra_code_table, |
48b0f3ae PJ |
7317 | doc: /* Table of extra Latin codes in the range 128..159 (inclusive). |
7318 | This is a vector of length 256. | |
7319 | If Nth element is non-nil, the existence of code N in a file | |
7320 | \(or output of subprocess) doesn't prevent it to be detected as | |
7321 | a coding system of ISO 2022 variant which has a flag | |
7322 | `accept-latin-extra-code' t (e.g. iso-latin-1) on reading a file | |
7323 | or reading output of a subprocess. | |
7324 | Only 128th through 159th elements has a meaning. */); | |
3f003981 | 7325 | Vlatin_extra_code_table = Fmake_vector (make_number (256), Qnil); |
d46c5b12 KH |
7326 | |
7327 | DEFVAR_LISP ("select-safe-coding-system-function", | |
7328 | &Vselect_safe_coding_system_function, | |
48b0f3ae PJ |
7329 | doc: /* Function to call to select safe coding system for encoding a text. |
7330 | ||
7331 | If set, this function is called to force a user to select a proper | |
7332 | coding system which can encode the text in the case that a default | |
7333 | coding system used in each operation can't encode the text. | |
7334 | ||
7335 | The default value is `select-safe-coding-system' (which see). */); | |
d46c5b12 KH |
7336 | Vselect_safe_coding_system_function = Qnil; |
7337 | ||
05e6f5dc | 7338 | DEFVAR_LISP ("char-coding-system-table", &Vchar_coding_system_table, |
48b0f3ae PJ |
7339 | doc: /* Char-table containing safe coding systems of each characters. |
7340 | Each element doesn't include such generic coding systems that can | |
7341 | encode any characters. They are in the first extra slot. */); | |
05e6f5dc KH |
7342 | Vchar_coding_system_table = Fmake_char_table (Qchar_coding_system, Qnil); |
7343 | ||
22ab2303 | 7344 | DEFVAR_BOOL ("inhibit-iso-escape-detection", |
74383408 | 7345 | &inhibit_iso_escape_detection, |
48b0f3ae PJ |
7346 | doc: /* If non-nil, Emacs ignores ISO2022's escape sequence on code detection. |
7347 | ||
7348 | By default, on reading a file, Emacs tries to detect how the text is | |
7349 | encoded. This code detection is sensitive to escape sequences. If | |
7350 | the sequence is valid as ISO2022, the code is determined as one of | |
7351 | the ISO2022 encodings, and the file is decoded by the corresponding | |
7352 | coding system (e.g. `iso-2022-7bit'). | |
7353 | ||
7354 | However, there may be a case that you want to read escape sequences in | |
7355 | a file as is. In such a case, you can set this variable to non-nil. | |
7356 | Then, as the code detection ignores any escape sequences, no file is | |
7357 | detected as encoded in some ISO2022 encoding. The result is that all | |
7358 | escape sequences become visible in a buffer. | |
7359 | ||
7360 | The default value is nil, and it is strongly recommended not to change | |
7361 | it. That is because many Emacs Lisp source files that contain | |
7362 | non-ASCII characters are encoded by the coding system `iso-2022-7bit' | |
7363 | in Emacs's distribution, and they won't be decoded correctly on | |
7364 | reading if you suppress escape sequence detection. | |
7365 | ||
7366 | The other way to read escape sequences in a file without decoding is | |
7367 | to explicitly specify some coding system that doesn't use ISO2022's | |
7368 | escape sequence (e.g `latin-1') on reading by \\[universal-coding-system-argument]. */); | |
74383408 | 7369 | inhibit_iso_escape_detection = 0; |
4ed46869 KH |
7370 | } |
7371 | ||
68c45bf0 PE |
7372 | char * |
7373 | emacs_strerror (error_number) | |
7374 | int error_number; | |
7375 | { | |
7376 | char *str; | |
7377 | ||
ca9c0567 | 7378 | synchronize_system_messages_locale (); |
68c45bf0 PE |
7379 | str = strerror (error_number); |
7380 | ||
7381 | if (! NILP (Vlocale_coding_system)) | |
7382 | { | |
7383 | Lisp_Object dec = code_convert_string_norecord (build_string (str), | |
7384 | Vlocale_coding_system, | |
7385 | 0); | |
7386 | str = (char *) XSTRING (dec)->data; | |
7387 | } | |
7388 | ||
7389 | return str; | |
7390 | } | |
7391 | ||
4ed46869 | 7392 | #endif /* emacs */ |
c2f94ebc | 7393 |