replaced require with autoloads
[emacs.git] / src / coding.c
blob250977eb5f2ba639af26f48928bcf01e0429f3d3
1 /* Coding system handler (conversion, detection, and etc).
2 Copyright (C) 1995, 1997, 1998 Electrotechnical Laboratory, JAPAN.
3 Licensed to the Free Software Foundation.
5 This file is part of GNU Emacs.
7 GNU Emacs is free software; you can redistribute it and/or modify
8 it under the terms of the GNU General Public License as published by
9 the Free Software Foundation; either version 2, or (at your option)
10 any later version.
12 GNU Emacs is distributed in the hope that it will be useful,
13 but WITHOUT ANY WARRANTY; without even the implied warranty of
14 MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
15 GNU General Public License for more details.
17 You should have received a copy of the GNU General Public License
18 along with GNU Emacs; see the file COPYING. If not, write to
19 the Free Software Foundation, Inc., 59 Temple Place - Suite 330,
20 Boston, MA 02111-1307, USA. */
22 /*** TABLE OF CONTENTS ***
24 0. General comments
25 1. Preamble
26 2. Emacs' internal format (emacs-mule) handlers
27 3. ISO2022 handlers
28 4. Shift-JIS and BIG5 handlers
29 5. CCL handlers
30 6. End-of-line handlers
31 7. C library functions
32 8. Emacs Lisp library functions
33 9. Post-amble
37 /*** 0. General comments ***/
40 /*** GENERAL NOTE on CODING SYSTEMS ***
42 A coding system is an encoding mechanism for one or more character
43 sets. Here's a list of coding systems which Emacs can handle. When
44 we say "decode", it means converting some other coding system to
45 Emacs' internal format (emacs-mule), and when we say "encode",
46 it means converting the coding system emacs-mule to some other
47 coding system.
49 0. Emacs' internal format (emacs-mule)
51 Emacs itself holds a multi-lingual character in buffers and strings
52 in a special format. Details are described in section 2.
54 1. ISO2022
56 The most famous coding system for multiple character sets. X's
57 Compound Text, various EUCs (Extended Unix Code), and coding
58 systems used in Internet communication such as ISO-2022-JP are
59 all variants of ISO2022. Details are described in section 3.
61 2. SJIS (or Shift-JIS or MS-Kanji-Code)
63 A coding system to encode character sets: ASCII, JISX0201, and
64 JISX0208. Widely used for PC's in Japan. Details are described in
65 section 4.
67 3. BIG5
69 A coding system to encode the character sets ASCII and Big5. Widely
70 used for Chinese (mainly in Taiwan and Hong Kong). Details are
71 described in section 4. In this file, when we write "BIG5"
72 (all uppercase), we mean the coding system, and when we write
73 "Big5" (capitalized), we mean the character set.
75 4. Raw text
77 A coding system for text containing random 8-bit code. Emacs does
78 no code conversion on such text except for end-of-line format.
80 5. Other
82 If a user wants to read/write text encoded in a coding system not
83 listed above, he can supply a decoder and an encoder for it as CCL
84 (Code Conversion Language) programs. Emacs executes the CCL program
85 while reading/writing.
87 Emacs represents a coding system by a Lisp symbol that has a property
88 `coding-system'. But, before actually using the coding system, the
89 information about it is set in a structure of type `struct
90 coding_system' for rapid processing. See section 6 for more details.
94 /*** GENERAL NOTES on END-OF-LINE FORMAT ***
96 How end-of-line of text is encoded depends on the operating system.
97 For instance, Unix's format is just one byte of `line-feed' code,
98 whereas DOS's format is two-byte sequence of `carriage-return' and
99 `line-feed' codes. MacOS's format is usually one byte of
100 `carriage-return'.
102 Since text character encoding and end-of-line encoding are
103 independent, any coding system described above can have any
104 end-of-line format. So Emacs has information about end-of-line
105 format in each coding-system. See section 6 for more details.
109 /*** GENERAL NOTES on `detect_coding_XXX ()' functions ***
111 These functions check if a text between SRC and SRC_END is encoded
112 in the coding system category XXX. Each returns an integer value in
113 which appropriate flag bits for the category XXX are set. The flag
114 bits are defined in macros CODING_CATEGORY_MASK_XXX. Below is the
115 template for these functions. If MULTIBYTEP is nonzero, 8-bit codes
116 of the range 0x80..0x9F are in multibyte form. */
117 #if 0
119 detect_coding_emacs_mule (src, src_end, multibytep)
120 unsigned char *src, *src_end;
121 int multibytep;
125 #endif
127 /*** GENERAL NOTES on `decode_coding_XXX ()' functions ***
129 These functions decode SRC_BYTES length of unibyte text at SOURCE
130 encoded in CODING to Emacs' internal format. The resulting
131 multibyte text goes to a place pointed to by DESTINATION, the length
132 of which should not exceed DST_BYTES.
134 These functions set the information about original and decoded texts
135 in the members `produced', `produced_char', `consumed', and
136 `consumed_char' of the structure *CODING. They also set the member
137 `result' to one of CODING_FINISH_XXX indicating how the decoding
138 finished.
140 DST_BYTES zero means that the source area and destination area are
141 overlapped, which means that we can produce a decoded text until it
142 reaches the head of the not-yet-decoded source text.
144 Below is a template for these functions. */
145 #if 0
146 static void
147 decode_coding_XXX (coding, source, destination, src_bytes, dst_bytes)
148 struct coding_system *coding;
149 unsigned char *source, *destination;
150 int src_bytes, dst_bytes;
154 #endif
156 /*** GENERAL NOTES on `encode_coding_XXX ()' functions ***
158 These functions encode SRC_BYTES length text at SOURCE from Emacs'
159 internal multibyte format to CODING. The resulting unibyte text
160 goes to a place pointed to by DESTINATION, the length of which
161 should not exceed DST_BYTES.
163 These functions set the information about original and encoded texts
164 in the members `produced', `produced_char', `consumed', and
165 `consumed_char' of the structure *CODING. They also set the member
166 `result' to one of CODING_FINISH_XXX indicating how the encoding
167 finished.
169 DST_BYTES zero means that the source area and destination area are
170 overlapped, which means that we can produce encoded text until it
171 reaches at the head of the not-yet-encoded source text.
173 Below is a template for these functions. */
174 #if 0
175 static void
176 encode_coding_XXX (coding, source, destination, src_bytes, dst_bytes)
177 struct coding_system *coding;
178 unsigned char *source, *destination;
179 int src_bytes, dst_bytes;
183 #endif
185 /*** COMMONLY USED MACROS ***/
187 /* The following two macros ONE_MORE_BYTE and TWO_MORE_BYTES safely
188 get one, two, and three bytes from the source text respectively.
189 If there are not enough bytes in the source, they jump to
190 `label_end_of_loop'. The caller should set variables `coding',
191 `src' and `src_end' to appropriate pointer in advance. These
192 macros are called from decoding routines `decode_coding_XXX', thus
193 it is assumed that the source text is unibyte. */
195 #define ONE_MORE_BYTE(c1) \
196 do { \
197 if (src >= src_end) \
199 coding->result = CODING_FINISH_INSUFFICIENT_SRC; \
200 goto label_end_of_loop; \
202 c1 = *src++; \
203 } while (0)
205 #define TWO_MORE_BYTES(c1, c2) \
206 do { \
207 if (src + 1 >= src_end) \
209 coding->result = CODING_FINISH_INSUFFICIENT_SRC; \
210 goto label_end_of_loop; \
212 c1 = *src++; \
213 c2 = *src++; \
214 } while (0)
217 /* Like ONE_MORE_BYTE, but 8-bit bytes of data at SRC are in multibyte
218 form if MULTIBYTEP is nonzero. */
220 #define ONE_MORE_BYTE_CHECK_MULTIBYTE(c1, multibytep) \
221 do { \
222 if (src >= src_end) \
224 coding->result = CODING_FINISH_INSUFFICIENT_SRC; \
225 goto label_end_of_loop; \
227 c1 = *src++; \
228 if (multibytep && c1 == LEADING_CODE_8_BIT_CONTROL) \
229 c1 = *src++ - 0x20; \
230 } while (0)
232 /* Set C to the next character at the source text pointed by `src'.
233 If there are not enough characters in the source, jump to
234 `label_end_of_loop'. The caller should set variables `coding'
235 `src', `src_end', and `translation_table' to appropriate pointers
236 in advance. This macro is used in encoding routines
237 `encode_coding_XXX', thus it assumes that the source text is in
238 multibyte form except for 8-bit characters. 8-bit characters are
239 in multibyte form if coding->src_multibyte is nonzero, else they
240 are represented by a single byte. */
242 #define ONE_MORE_CHAR(c) \
243 do { \
244 int len = src_end - src; \
245 int bytes; \
246 if (len <= 0) \
248 coding->result = CODING_FINISH_INSUFFICIENT_SRC; \
249 goto label_end_of_loop; \
251 if (coding->src_multibyte \
252 || UNIBYTE_STR_AS_MULTIBYTE_P (src, len, bytes)) \
253 c = STRING_CHAR_AND_LENGTH (src, len, bytes); \
254 else \
255 c = *src, bytes = 1; \
256 if (!NILP (translation_table)) \
257 c = translate_char (translation_table, c, -1, 0, 0); \
258 src += bytes; \
259 } while (0)
262 /* Produce a multibyte form of characater C to `dst'. Jump to
263 `label_end_of_loop' if there's not enough space at `dst'.
265 If we are now in the middle of a composition sequence, the decoded
266 character may be ALTCHAR (for the current composition). In that
267 case, the character goes to coding->cmp_data->data instead of
268 `dst'.
270 This macro is used in decoding routines. */
272 #define EMIT_CHAR(c) \
273 do { \
274 if (! COMPOSING_P (coding) \
275 || coding->composing == COMPOSITION_RELATIVE \
276 || coding->composing == COMPOSITION_WITH_RULE) \
278 int bytes = CHAR_BYTES (c); \
279 if ((dst + bytes) > (dst_bytes ? dst_end : src)) \
281 coding->result = CODING_FINISH_INSUFFICIENT_DST; \
282 goto label_end_of_loop; \
284 dst += CHAR_STRING (c, dst); \
285 coding->produced_char++; \
288 if (COMPOSING_P (coding) \
289 && coding->composing != COMPOSITION_RELATIVE) \
291 CODING_ADD_COMPOSITION_COMPONENT (coding, c); \
292 coding->composition_rule_follows \
293 = coding->composing != COMPOSITION_WITH_ALTCHARS; \
295 } while (0)
298 #define EMIT_ONE_BYTE(c) \
299 do { \
300 if (dst >= (dst_bytes ? dst_end : src)) \
302 coding->result = CODING_FINISH_INSUFFICIENT_DST; \
303 goto label_end_of_loop; \
305 *dst++ = c; \
306 } while (0)
308 #define EMIT_TWO_BYTES(c1, c2) \
309 do { \
310 if (dst + 2 > (dst_bytes ? dst_end : src)) \
312 coding->result = CODING_FINISH_INSUFFICIENT_DST; \
313 goto label_end_of_loop; \
315 *dst++ = c1, *dst++ = c2; \
316 } while (0)
318 #define EMIT_BYTES(from, to) \
319 do { \
320 if (dst + (to - from) > (dst_bytes ? dst_end : src)) \
322 coding->result = CODING_FINISH_INSUFFICIENT_DST; \
323 goto label_end_of_loop; \
325 while (from < to) \
326 *dst++ = *from++; \
327 } while (0)
330 /*** 1. Preamble ***/
332 #ifdef emacs
333 #include <config.h>
334 #endif
336 #include <stdio.h>
338 #ifdef emacs
340 #include "lisp.h"
341 #include "buffer.h"
342 #include "charset.h"
343 #include "composite.h"
344 #include "ccl.h"
345 #include "coding.h"
346 #include "window.h"
348 #else /* not emacs */
350 #include "mulelib.h"
352 #endif /* not emacs */
354 Lisp_Object Qcoding_system, Qeol_type;
355 Lisp_Object Qbuffer_file_coding_system;
356 Lisp_Object Qpost_read_conversion, Qpre_write_conversion;
357 Lisp_Object Qno_conversion, Qundecided;
358 Lisp_Object Qcoding_system_history;
359 Lisp_Object Qsafe_chars;
360 Lisp_Object Qvalid_codes;
362 extern Lisp_Object Qinsert_file_contents, Qwrite_region;
363 Lisp_Object Qcall_process, Qcall_process_region, Qprocess_argument;
364 Lisp_Object Qstart_process, Qopen_network_stream;
365 Lisp_Object Qtarget_idx;
367 Lisp_Object Vselect_safe_coding_system_function;
369 /* Mnemonic string for each format of end-of-line. */
370 Lisp_Object eol_mnemonic_unix, eol_mnemonic_dos, eol_mnemonic_mac;
371 /* Mnemonic string to indicate format of end-of-line is not yet
372 decided. */
373 Lisp_Object eol_mnemonic_undecided;
375 /* Format of end-of-line decided by system. This is CODING_EOL_LF on
376 Unix, CODING_EOL_CRLF on DOS/Windows, and CODING_EOL_CR on Mac. */
377 int system_eol_type;
379 #ifdef emacs
381 Lisp_Object Vcoding_system_list, Vcoding_system_alist;
383 Lisp_Object Qcoding_system_p, Qcoding_system_error;
385 /* Coding system emacs-mule and raw-text are for converting only
386 end-of-line format. */
387 Lisp_Object Qemacs_mule, Qraw_text;
389 /* Coding-systems are handed between Emacs Lisp programs and C internal
390 routines by the following three variables. */
391 /* Coding-system for reading files and receiving data from process. */
392 Lisp_Object Vcoding_system_for_read;
393 /* Coding-system for writing files and sending data to process. */
394 Lisp_Object Vcoding_system_for_write;
395 /* Coding-system actually used in the latest I/O. */
396 Lisp_Object Vlast_coding_system_used;
398 /* A vector of length 256 which contains information about special
399 Latin codes (especially for dealing with Microsoft codes). */
400 Lisp_Object Vlatin_extra_code_table;
402 /* Flag to inhibit code conversion of end-of-line format. */
403 int inhibit_eol_conversion;
405 /* Flag to inhibit ISO2022 escape sequence detection. */
406 int inhibit_iso_escape_detection;
408 /* Flag to make buffer-file-coding-system inherit from process-coding. */
409 int inherit_process_coding_system;
411 /* Coding system to be used to encode text for terminal display. */
412 struct coding_system terminal_coding;
414 /* Coding system to be used to encode text for terminal display when
415 terminal coding system is nil. */
416 struct coding_system safe_terminal_coding;
418 /* Coding system of what is sent from terminal keyboard. */
419 struct coding_system keyboard_coding;
421 /* Default coding system to be used to write a file. */
422 struct coding_system default_buffer_file_coding;
424 Lisp_Object Vfile_coding_system_alist;
425 Lisp_Object Vprocess_coding_system_alist;
426 Lisp_Object Vnetwork_coding_system_alist;
428 Lisp_Object Vlocale_coding_system;
430 #endif /* emacs */
432 Lisp_Object Qcoding_category, Qcoding_category_index;
434 /* List of symbols `coding-category-xxx' ordered by priority. */
435 Lisp_Object Vcoding_category_list;
437 /* Table of coding categories (Lisp symbols). */
438 Lisp_Object Vcoding_category_table;
440 /* Table of names of symbol for each coding-category. */
441 char *coding_category_name[CODING_CATEGORY_IDX_MAX] = {
442 "coding-category-emacs-mule",
443 "coding-category-sjis",
444 "coding-category-iso-7",
445 "coding-category-iso-7-tight",
446 "coding-category-iso-8-1",
447 "coding-category-iso-8-2",
448 "coding-category-iso-7-else",
449 "coding-category-iso-8-else",
450 "coding-category-ccl",
451 "coding-category-big5",
452 "coding-category-utf-8",
453 "coding-category-utf-16-be",
454 "coding-category-utf-16-le",
455 "coding-category-raw-text",
456 "coding-category-binary"
459 /* Table of pointers to coding systems corresponding to each coding
460 categories. */
461 struct coding_system *coding_system_table[CODING_CATEGORY_IDX_MAX];
463 /* Table of coding category masks. Nth element is a mask for a coding
464 cateogry of which priority is Nth. */
465 static
466 int coding_priorities[CODING_CATEGORY_IDX_MAX];
468 /* Flag to tell if we look up translation table on character code
469 conversion. */
470 Lisp_Object Venable_character_translation;
471 /* Standard translation table to look up on decoding (reading). */
472 Lisp_Object Vstandard_translation_table_for_decode;
473 /* Standard translation table to look up on encoding (writing). */
474 Lisp_Object Vstandard_translation_table_for_encode;
476 Lisp_Object Qtranslation_table;
477 Lisp_Object Qtranslation_table_id;
478 Lisp_Object Qtranslation_table_for_decode;
479 Lisp_Object Qtranslation_table_for_encode;
481 /* Alist of charsets vs revision number. */
482 Lisp_Object Vcharset_revision_alist;
484 /* Default coding systems used for process I/O. */
485 Lisp_Object Vdefault_process_coding_system;
487 /* Global flag to tell that we can't call post-read-conversion and
488 pre-write-conversion functions. Usually the value is zero, but it
489 is set to 1 temporarily while such functions are running. This is
490 to avoid infinite recursive call. */
491 static int inhibit_pre_post_conversion;
493 /* Char-table containing safe coding systems of each character. */
494 Lisp_Object Vchar_coding_system_table;
495 Lisp_Object Qchar_coding_system;
497 /* Return `safe-chars' property of coding system CODING. Don't check
498 validity of CODING. */
500 Lisp_Object
501 coding_safe_chars (coding)
502 struct coding_system *coding;
504 Lisp_Object coding_spec, plist, safe_chars;
506 coding_spec = Fget (coding->symbol, Qcoding_system);
507 plist = XVECTOR (coding_spec)->contents[3];
508 safe_chars = Fplist_get (XVECTOR (coding_spec)->contents[3], Qsafe_chars);
509 return (CHAR_TABLE_P (safe_chars) ? safe_chars : Qt);
512 #define CODING_SAFE_CHAR_P(safe_chars, c) \
513 (EQ (safe_chars, Qt) || !NILP (CHAR_TABLE_REF (safe_chars, c)))
516 /*** 2. Emacs internal format (emacs-mule) handlers ***/
518 /* Emacs' internal format for representation of multiple character
519 sets is a kind of multi-byte encoding, i.e. characters are
520 represented by variable-length sequences of one-byte codes.
522 ASCII characters and control characters (e.g. `tab', `newline') are
523 represented by one-byte sequences which are their ASCII codes, in
524 the range 0x00 through 0x7F.
526 8-bit characters of the range 0x80..0x9F are represented by
527 two-byte sequences of LEADING_CODE_8_BIT_CONTROL and (their 8-bit
528 code + 0x20).
530 8-bit characters of the range 0xA0..0xFF are represented by
531 one-byte sequences which are their 8-bit code.
533 The other characters are represented by a sequence of `base
534 leading-code', optional `extended leading-code', and one or two
535 `position-code's. The length of the sequence is determined by the
536 base leading-code. Leading-code takes the range 0x81 through 0x9D,
537 whereas extended leading-code and position-code take the range 0xA0
538 through 0xFF. See `charset.h' for more details about leading-code
539 and position-code.
541 --- CODE RANGE of Emacs' internal format ---
542 character set range
543 ------------- -----
544 ascii 0x00..0x7F
545 eight-bit-control LEADING_CODE_8_BIT_CONTROL + 0xA0..0xBF
546 eight-bit-graphic 0xA0..0xBF
547 ELSE 0x81..0x9D + [0xA0..0xFF]+
548 ---------------------------------------------
550 As this is the internal character representation, the format is
551 usually not used externally (i.e. in a file or in a data sent to a
552 process). But, it is possible to have a text externally in this
553 format (i.e. by encoding by the coding system `emacs-mule').
555 In that case, a sequence of one-byte codes has a slightly different
556 form.
558 At first, all characters in eight-bit-control are represented by
559 one-byte sequences which are their 8-bit code.
561 Next, character composition data are represented by the byte
562 sequence of the form: 0x80 METHOD BYTES CHARS COMPONENT ...,
563 where,
564 METHOD is 0xF0 plus one of composition method (enum
565 composition_method),
567 BYTES is 0x20 plus a byte length of this composition data,
569 CHARS is 0x20 plus a number of characters composed by this
570 data,
572 COMPONENTs are characters of multibye form or composition
573 rules encoded by two-byte of ASCII codes.
575 In addition, for backward compatibility, the following formats are
576 also recognized as composition data on decoding.
578 0x80 MSEQ ...
579 0x80 0xFF MSEQ RULE MSEQ RULE ... MSEQ
581 Here,
582 MSEQ is a multibyte form but in these special format:
583 ASCII: 0xA0 ASCII_CODE+0x80,
584 other: LEADING_CODE+0x20 FOLLOWING-BYTE ...,
585 RULE is a one byte code of the range 0xA0..0xF0 that
586 represents a composition rule.
589 enum emacs_code_class_type emacs_code_class[256];
591 /* See the above "GENERAL NOTES on `detect_coding_XXX ()' functions".
592 Check if a text is encoded in Emacs' internal format. If it is,
593 return CODING_CATEGORY_MASK_EMACS_MULE, else return 0. */
595 static int
596 detect_coding_emacs_mule (src, src_end, multibytep)
597 unsigned char *src, *src_end;
598 int multibytep;
600 unsigned char c;
601 int composing = 0;
602 /* Dummy for ONE_MORE_BYTE. */
603 struct coding_system dummy_coding;
604 struct coding_system *coding = &dummy_coding;
606 while (1)
608 ONE_MORE_BYTE_CHECK_MULTIBYTE (c, multibytep);
610 if (composing)
612 if (c < 0xA0)
613 composing = 0;
614 else if (c == 0xA0)
616 ONE_MORE_BYTE_CHECK_MULTIBYTE (c, multibytep);
617 c &= 0x7F;
619 else
620 c -= 0x20;
623 if (c < 0x20)
625 if (c == ISO_CODE_ESC || c == ISO_CODE_SI || c == ISO_CODE_SO)
626 return 0;
628 else if (c >= 0x80 && c < 0xA0)
630 if (c == 0x80)
631 /* Old leading code for a composite character. */
632 composing = 1;
633 else
635 unsigned char *src_base = src - 1;
636 int bytes;
638 if (!UNIBYTE_STR_AS_MULTIBYTE_P (src_base, src_end - src_base,
639 bytes))
640 return 0;
641 src = src_base + bytes;
645 label_end_of_loop:
646 return CODING_CATEGORY_MASK_EMACS_MULE;
650 /* Record the starting position START and METHOD of one composition. */
652 #define CODING_ADD_COMPOSITION_START(coding, start, method) \
653 do { \
654 struct composition_data *cmp_data = coding->cmp_data; \
655 int *data = cmp_data->data + cmp_data->used; \
656 coding->cmp_data_start = cmp_data->used; \
657 data[0] = -1; \
658 data[1] = cmp_data->char_offset + start; \
659 data[3] = (int) method; \
660 cmp_data->used += 4; \
661 } while (0)
663 /* Record the ending position END of the current composition. */
665 #define CODING_ADD_COMPOSITION_END(coding, end) \
666 do { \
667 struct composition_data *cmp_data = coding->cmp_data; \
668 int *data = cmp_data->data + coding->cmp_data_start; \
669 data[0] = cmp_data->used - coding->cmp_data_start; \
670 data[2] = cmp_data->char_offset + end; \
671 } while (0)
673 /* Record one COMPONENT (alternate character or composition rule). */
675 #define CODING_ADD_COMPOSITION_COMPONENT(coding, component) \
676 (coding->cmp_data->data[coding->cmp_data->used++] = component)
679 /* Get one byte from a data pointed by SRC and increment SRC. If SRC
680 is not less than SRC_END, return -1 without inccrementing Src. */
682 #define SAFE_ONE_MORE_BYTE() (src >= src_end ? -1 : *src++)
685 /* Decode a character represented as a component of composition
686 sequence of Emacs 20 style at SRC. Set C to that character, store
687 its multibyte form sequence at P, and set P to the end of that
688 sequence. If no valid character is found, set C to -1. */
690 #define DECODE_EMACS_MULE_COMPOSITION_CHAR(c, p) \
691 do { \
692 int bytes; \
694 c = SAFE_ONE_MORE_BYTE (); \
695 if (c < 0) \
696 break; \
697 if (CHAR_HEAD_P (c)) \
698 c = -1; \
699 else if (c == 0xA0) \
701 c = SAFE_ONE_MORE_BYTE (); \
702 if (c < 0xA0) \
703 c = -1; \
704 else \
706 c -= 0xA0; \
707 *p++ = c; \
710 else if (BASE_LEADING_CODE_P (c - 0x20)) \
712 unsigned char *p0 = p; \
714 c -= 0x20; \
715 *p++ = c; \
716 bytes = BYTES_BY_CHAR_HEAD (c); \
717 while (--bytes) \
719 c = SAFE_ONE_MORE_BYTE (); \
720 if (c < 0) \
721 break; \
722 *p++ = c; \
724 if (UNIBYTE_STR_AS_MULTIBYTE_P (p0, p - p0, bytes)) \
725 c = STRING_CHAR (p0, bytes); \
726 else \
727 c = -1; \
729 else \
730 c = -1; \
731 } while (0)
734 /* Decode a composition rule represented as a component of composition
735 sequence of Emacs 20 style at SRC. Set C to the rule. If not
736 valid rule is found, set C to -1. */
738 #define DECODE_EMACS_MULE_COMPOSITION_RULE(c) \
739 do { \
740 c = SAFE_ONE_MORE_BYTE (); \
741 c -= 0xA0; \
742 if (c < 0 || c >= 81) \
743 c = -1; \
744 else \
746 gref = c / 9, nref = c % 9; \
747 c = COMPOSITION_ENCODE_RULE (gref, nref); \
749 } while (0)
752 /* Decode composition sequence encoded by `emacs-mule' at the source
753 pointed by SRC. SRC_END is the end of source. Store information
754 of the composition in CODING->cmp_data.
756 For backward compatibility, decode also a composition sequence of
757 Emacs 20 style. In that case, the composition sequence contains
758 characters that should be extracted into a buffer or string. Store
759 those characters at *DESTINATION in multibyte form.
761 If we encounter an invalid byte sequence, return 0.
762 If we encounter an insufficient source or destination, or
763 insufficient space in CODING->cmp_data, return 1.
764 Otherwise, return consumed bytes in the source.
767 static INLINE int
768 decode_composition_emacs_mule (coding, src, src_end,
769 destination, dst_end, dst_bytes)
770 struct coding_system *coding;
771 unsigned char *src, *src_end, **destination, *dst_end;
772 int dst_bytes;
774 unsigned char *dst = *destination;
775 int method, data_len, nchars;
776 unsigned char *src_base = src++;
777 /* Store compoments of composition. */
778 int component[COMPOSITION_DATA_MAX_BUNCH_LENGTH];
779 int ncomponent;
780 /* Store multibyte form of characters to be composed. This is for
781 Emacs 20 style composition sequence. */
782 unsigned char buf[MAX_COMPOSITION_COMPONENTS * MAX_MULTIBYTE_LENGTH];
783 unsigned char *bufp = buf;
784 int c, i, gref, nref;
786 if (coding->cmp_data->used + COMPOSITION_DATA_MAX_BUNCH_LENGTH
787 >= COMPOSITION_DATA_SIZE)
789 coding->result = CODING_FINISH_INSUFFICIENT_CMP;
790 return -1;
793 ONE_MORE_BYTE (c);
794 if (c - 0xF0 >= COMPOSITION_RELATIVE
795 && c - 0xF0 <= COMPOSITION_WITH_RULE_ALTCHARS)
797 int with_rule;
799 method = c - 0xF0;
800 with_rule = (method == COMPOSITION_WITH_RULE
801 || method == COMPOSITION_WITH_RULE_ALTCHARS);
802 ONE_MORE_BYTE (c);
803 data_len = c - 0xA0;
804 if (data_len < 4
805 || src_base + data_len > src_end)
806 return 0;
807 ONE_MORE_BYTE (c);
808 nchars = c - 0xA0;
809 if (c < 1)
810 return 0;
811 for (ncomponent = 0; src < src_base + data_len; ncomponent++)
813 if (ncomponent % 2 && with_rule)
815 ONE_MORE_BYTE (gref);
816 gref -= 32;
817 ONE_MORE_BYTE (nref);
818 nref -= 32;
819 c = COMPOSITION_ENCODE_RULE (gref, nref);
821 else
823 int bytes;
824 if (UNIBYTE_STR_AS_MULTIBYTE_P (src, src_end - src, bytes))
825 c = STRING_CHAR (src, bytes);
826 else
827 c = *src, bytes = 1;
828 src += bytes;
830 component[ncomponent] = c;
833 else
835 /* This may be an old Emacs 20 style format. See the comment at
836 the section 2 of this file. */
837 while (src < src_end && !CHAR_HEAD_P (*src)) src++;
838 if (src == src_end
839 && !(coding->mode & CODING_MODE_LAST_BLOCK))
840 goto label_end_of_loop;
842 src_end = src;
843 src = src_base + 1;
844 if (c < 0xC0)
846 method = COMPOSITION_RELATIVE;
847 for (ncomponent = 0; ncomponent < MAX_COMPOSITION_COMPONENTS;)
849 DECODE_EMACS_MULE_COMPOSITION_CHAR (c, bufp);
850 if (c < 0)
851 break;
852 component[ncomponent++] = c;
854 if (ncomponent < 2)
855 return 0;
856 nchars = ncomponent;
858 else if (c == 0xFF)
860 method = COMPOSITION_WITH_RULE;
861 src++;
862 DECODE_EMACS_MULE_COMPOSITION_CHAR (c, bufp);
863 if (c < 0)
864 return 0;
865 component[0] = c;
866 for (ncomponent = 1;
867 ncomponent < MAX_COMPOSITION_COMPONENTS * 2 - 1;)
869 DECODE_EMACS_MULE_COMPOSITION_RULE (c);
870 if (c < 0)
871 break;
872 component[ncomponent++] = c;
873 DECODE_EMACS_MULE_COMPOSITION_CHAR (c, bufp);
874 if (c < 0)
875 break;
876 component[ncomponent++] = c;
878 if (ncomponent < 3)
879 return 0;
880 nchars = (ncomponent + 1) / 2;
882 else
883 return 0;
886 if (buf == bufp || dst + (bufp - buf) <= (dst_bytes ? dst_end : src))
888 CODING_ADD_COMPOSITION_START (coding, coding->produced_char, method);
889 for (i = 0; i < ncomponent; i++)
890 CODING_ADD_COMPOSITION_COMPONENT (coding, component[i]);
891 CODING_ADD_COMPOSITION_END (coding, coding->produced_char + nchars);
892 if (buf < bufp)
894 unsigned char *p = buf;
895 EMIT_BYTES (p, bufp);
896 *destination += bufp - buf;
897 coding->produced_char += nchars;
899 return (src - src_base);
901 label_end_of_loop:
902 return -1;
905 /* See the above "GENERAL NOTES on `decode_coding_XXX ()' functions". */
907 static void
908 decode_coding_emacs_mule (coding, source, destination, src_bytes, dst_bytes)
909 struct coding_system *coding;
910 unsigned char *source, *destination;
911 int src_bytes, dst_bytes;
913 unsigned char *src = source;
914 unsigned char *src_end = source + src_bytes;
915 unsigned char *dst = destination;
916 unsigned char *dst_end = destination + dst_bytes;
917 /* SRC_BASE remembers the start position in source in each loop.
918 The loop will be exited when there's not enough source code, or
919 when there's not enough destination area to produce a
920 character. */
921 unsigned char *src_base;
923 coding->produced_char = 0;
924 while ((src_base = src) < src_end)
926 unsigned char tmp[MAX_MULTIBYTE_LENGTH], *p;
927 int bytes;
929 if (*src == '\r')
931 int c = *src++;
933 if (coding->eol_type == CODING_EOL_CR)
934 c = '\n';
935 else if (coding->eol_type == CODING_EOL_CRLF)
937 ONE_MORE_BYTE (c);
938 if (c != '\n')
940 if (coding->mode & CODING_MODE_INHIBIT_INCONSISTENT_EOL)
942 coding->result = CODING_FINISH_INCONSISTENT_EOL;
943 goto label_end_of_loop;
945 src--;
946 c = '\r';
949 *dst++ = c;
950 coding->produced_char++;
951 continue;
953 else if (*src == '\n')
955 if ((coding->eol_type == CODING_EOL_CR
956 || coding->eol_type == CODING_EOL_CRLF)
957 && coding->mode & CODING_MODE_INHIBIT_INCONSISTENT_EOL)
959 coding->result = CODING_FINISH_INCONSISTENT_EOL;
960 goto label_end_of_loop;
962 *dst++ = *src++;
963 coding->produced_char++;
964 continue;
966 else if (*src == 0x80)
968 /* Start of composition data. */
969 int consumed = decode_composition_emacs_mule (coding, src, src_end,
970 &dst, dst_end,
971 dst_bytes);
972 if (consumed < 0)
973 goto label_end_of_loop;
974 else if (consumed > 0)
976 src += consumed;
977 continue;
979 bytes = CHAR_STRING (*src, tmp);
980 p = tmp;
981 src++;
983 else if (UNIBYTE_STR_AS_MULTIBYTE_P (src, src_end - src, bytes))
985 p = src;
986 src += bytes;
988 else
990 bytes = CHAR_STRING (*src, tmp);
991 p = tmp;
992 src++;
994 if (dst + bytes >= (dst_bytes ? dst_end : src))
996 coding->result = CODING_FINISH_INSUFFICIENT_DST;
997 break;
999 while (bytes--) *dst++ = *p++;
1000 coding->produced_char++;
1002 label_end_of_loop:
1003 coding->consumed = coding->consumed_char = src_base - source;
1004 coding->produced = dst - destination;
1008 /* Encode composition data stored at DATA into a special byte sequence
1009 starting by 0x80. Update CODING->cmp_data_start and maybe
1010 CODING->cmp_data for the next call. */
1012 #define ENCODE_COMPOSITION_EMACS_MULE(coding, data) \
1013 do { \
1014 unsigned char buf[1024], *p0 = buf, *p; \
1015 int len = data[0]; \
1016 int i; \
1018 buf[0] = 0x80; \
1019 buf[1] = 0xF0 + data[3]; /* METHOD */ \
1020 buf[3] = 0xA0 + (data[2] - data[1]); /* COMPOSED-CHARS */ \
1021 p = buf + 4; \
1022 if (data[3] == COMPOSITION_WITH_RULE \
1023 || data[3] == COMPOSITION_WITH_RULE_ALTCHARS) \
1025 p += CHAR_STRING (data[4], p); \
1026 for (i = 5; i < len; i += 2) \
1028 int gref, nref; \
1029 COMPOSITION_DECODE_RULE (data[i], gref, nref); \
1030 *p++ = 0x20 + gref; \
1031 *p++ = 0x20 + nref; \
1032 p += CHAR_STRING (data[i + 1], p); \
1035 else \
1037 for (i = 4; i < len; i++) \
1038 p += CHAR_STRING (data[i], p); \
1040 buf[2] = 0xA0 + (p - buf); /* COMPONENTS-BYTES */ \
1042 if (dst + (p - buf) + 4 > (dst_bytes ? dst_end : src)) \
1044 coding->result = CODING_FINISH_INSUFFICIENT_DST; \
1045 goto label_end_of_loop; \
1047 while (p0 < p) \
1048 *dst++ = *p0++; \
1049 coding->cmp_data_start += data[0]; \
1050 if (coding->cmp_data_start == coding->cmp_data->used \
1051 && coding->cmp_data->next) \
1053 coding->cmp_data = coding->cmp_data->next; \
1054 coding->cmp_data_start = 0; \
1056 } while (0)
1059 static void encode_eol P_ ((struct coding_system *, unsigned char *,
1060 unsigned char *, int, int));
1062 static void
1063 encode_coding_emacs_mule (coding, source, destination, src_bytes, dst_bytes)
1064 struct coding_system *coding;
1065 unsigned char *source, *destination;
1066 int src_bytes, dst_bytes;
1068 unsigned char *src = source;
1069 unsigned char *src_end = source + src_bytes;
1070 unsigned char *dst = destination;
1071 unsigned char *dst_end = destination + dst_bytes;
1072 unsigned char *src_base;
1073 int c;
1074 int char_offset;
1075 int *data;
1077 Lisp_Object translation_table;
1079 translation_table = Qnil;
1081 /* Optimization for the case that there's no composition. */
1082 if (!coding->cmp_data || coding->cmp_data->used == 0)
1084 encode_eol (coding, source, destination, src_bytes, dst_bytes);
1085 return;
1088 char_offset = coding->cmp_data->char_offset;
1089 data = coding->cmp_data->data + coding->cmp_data_start;
1090 while (1)
1092 src_base = src;
1094 /* If SRC starts a composition, encode the information about the
1095 composition in advance. */
1096 if (coding->cmp_data_start < coding->cmp_data->used
1097 && char_offset + coding->consumed_char == data[1])
1099 ENCODE_COMPOSITION_EMACS_MULE (coding, data);
1100 char_offset = coding->cmp_data->char_offset;
1101 data = coding->cmp_data->data + coding->cmp_data_start;
1104 ONE_MORE_CHAR (c);
1105 if (c == '\n' && (coding->eol_type == CODING_EOL_CRLF
1106 || coding->eol_type == CODING_EOL_CR))
1108 if (coding->eol_type == CODING_EOL_CRLF)
1109 EMIT_TWO_BYTES ('\r', c);
1110 else
1111 EMIT_ONE_BYTE ('\r');
1113 else if (SINGLE_BYTE_CHAR_P (c))
1114 EMIT_ONE_BYTE (c);
1115 else
1116 EMIT_BYTES (src_base, src);
1117 coding->consumed_char++;
1119 label_end_of_loop:
1120 coding->consumed = src_base - source;
1121 coding->produced = coding->produced_char = dst - destination;
1122 return;
1126 /*** 3. ISO2022 handlers ***/
1128 /* The following note describes the coding system ISO2022 briefly.
1129 Since the intention of this note is to help understand the
1130 functions in this file, some parts are NOT ACCURATE or are OVERLY
1131 SIMPLIFIED. For thorough understanding, please refer to the
1132 original document of ISO2022. This is equivalent to the standard
1133 ECMA-35, obtainable from <URL:http://www.ecma.ch/> (*).
1135 ISO2022 provides many mechanisms to encode several character sets
1136 in 7-bit and 8-bit environments. For 7-bit environments, all text
1137 is encoded using bytes less than 128. This may make the encoded
1138 text a little bit longer, but the text passes more easily through
1139 several types of gateway, some of which strip off the MSB (Most
1140 Signigant Bit).
1142 There are two kinds of character sets: control character sets and
1143 graphic character sets. The former contain control characters such
1144 as `newline' and `escape' to provide control functions (control
1145 functions are also provided by escape sequences). The latter
1146 contain graphic characters such as 'A' and '-'. Emacs recognizes
1147 two control character sets and many graphic character sets.
1149 Graphic character sets are classified into one of the following
1150 four classes, according to the number of bytes (DIMENSION) and
1151 number of characters in one dimension (CHARS) of the set:
1152 - DIMENSION1_CHARS94
1153 - DIMENSION1_CHARS96
1154 - DIMENSION2_CHARS94
1155 - DIMENSION2_CHARS96
1157 In addition, each character set is assigned an identification tag,
1158 unique for each set, called the "final character" (denoted as <F>
1159 hereafter). The <F> of each character set is decided by ECMA(*)
1160 when it is registered in ISO. The code range of <F> is 0x30..0x7F
1161 (0x30..0x3F are for private use only).
1163 Note (*): ECMA = European Computer Manufacturers Association
1165 Here are examples of graphic character sets [NAME(<F>)]:
1166 o DIMENSION1_CHARS94 -- ASCII('B'), right-half-of-JISX0201('I'), ...
1167 o DIMENSION1_CHARS96 -- right-half-of-ISO8859-1('A'), ...
1168 o DIMENSION2_CHARS94 -- GB2312('A'), JISX0208('B'), ...
1169 o DIMENSION2_CHARS96 -- none for the moment
1171 A code area (1 byte=8 bits) is divided into 4 areas, C0, GL, C1, and GR.
1172 C0 [0x00..0x1F] -- control character plane 0
1173 GL [0x20..0x7F] -- graphic character plane 0
1174 C1 [0x80..0x9F] -- control character plane 1
1175 GR [0xA0..0xFF] -- graphic character plane 1
1177 A control character set is directly designated and invoked to C0 or
1178 C1 by an escape sequence. The most common case is that:
1179 - ISO646's control character set is designated/invoked to C0, and
1180 - ISO6429's control character set is designated/invoked to C1,
1181 and usually these designations/invocations are omitted in encoded
1182 text. In a 7-bit environment, only C0 can be used, and a control
1183 character for C1 is encoded by an appropriate escape sequence to
1184 fit into the environment. All control characters for C1 are
1185 defined to have corresponding escape sequences.
1187 A graphic character set is at first designated to one of four
1188 graphic registers (G0 through G3), then these graphic registers are
1189 invoked to GL or GR. These designations and invocations can be
1190 done independently. The most common case is that G0 is invoked to
1191 GL, G1 is invoked to GR, and ASCII is designated to G0. Usually
1192 these invocations and designations are omitted in encoded text.
1193 In a 7-bit environment, only GL can be used.
1195 When a graphic character set of CHARS94 is invoked to GL, codes
1196 0x20 and 0x7F of the GL area work as control characters SPACE and
1197 DEL respectively, and codes 0xA0 and 0xFF of the GR area should not
1198 be used.
1200 There are two ways of invocation: locking-shift and single-shift.
1201 With locking-shift, the invocation lasts until the next different
1202 invocation, whereas with single-shift, the invocation affects the
1203 following character only and doesn't affect the locking-shift
1204 state. Invocations are done by the following control characters or
1205 escape sequences:
1207 ----------------------------------------------------------------------
1208 abbrev function cntrl escape seq description
1209 ----------------------------------------------------------------------
1210 SI/LS0 (shift-in) 0x0F none invoke G0 into GL
1211 SO/LS1 (shift-out) 0x0E none invoke G1 into GL
1212 LS2 (locking-shift-2) none ESC 'n' invoke G2 into GL
1213 LS3 (locking-shift-3) none ESC 'o' invoke G3 into GL
1214 LS1R (locking-shift-1 right) none ESC '~' invoke G1 into GR (*)
1215 LS2R (locking-shift-2 right) none ESC '}' invoke G2 into GR (*)
1216 LS3R (locking-shift 3 right) none ESC '|' invoke G3 into GR (*)
1217 SS2 (single-shift-2) 0x8E ESC 'N' invoke G2 for one char
1218 SS3 (single-shift-3) 0x8F ESC 'O' invoke G3 for one char
1219 ----------------------------------------------------------------------
1220 (*) These are not used by any known coding system.
1222 Control characters for these functions are defined by macros
1223 ISO_CODE_XXX in `coding.h'.
1225 Designations are done by the following escape sequences:
1226 ----------------------------------------------------------------------
1227 escape sequence description
1228 ----------------------------------------------------------------------
1229 ESC '(' <F> designate DIMENSION1_CHARS94<F> to G0
1230 ESC ')' <F> designate DIMENSION1_CHARS94<F> to G1
1231 ESC '*' <F> designate DIMENSION1_CHARS94<F> to G2
1232 ESC '+' <F> designate DIMENSION1_CHARS94<F> to G3
1233 ESC ',' <F> designate DIMENSION1_CHARS96<F> to G0 (*)
1234 ESC '-' <F> designate DIMENSION1_CHARS96<F> to G1
1235 ESC '.' <F> designate DIMENSION1_CHARS96<F> to G2
1236 ESC '/' <F> designate DIMENSION1_CHARS96<F> to G3
1237 ESC '$' '(' <F> designate DIMENSION2_CHARS94<F> to G0 (**)
1238 ESC '$' ')' <F> designate DIMENSION2_CHARS94<F> to G1
1239 ESC '$' '*' <F> designate DIMENSION2_CHARS94<F> to G2
1240 ESC '$' '+' <F> designate DIMENSION2_CHARS94<F> to G3
1241 ESC '$' ',' <F> designate DIMENSION2_CHARS96<F> to G0 (*)
1242 ESC '$' '-' <F> designate DIMENSION2_CHARS96<F> to G1
1243 ESC '$' '.' <F> designate DIMENSION2_CHARS96<F> to G2
1244 ESC '$' '/' <F> designate DIMENSION2_CHARS96<F> to G3
1245 ----------------------------------------------------------------------
1247 In this list, "DIMENSION1_CHARS94<F>" means a graphic character set
1248 of dimension 1, chars 94, and final character <F>, etc...
1250 Note (*): Although these designations are not allowed in ISO2022,
1251 Emacs accepts them on decoding, and produces them on encoding
1252 CHARS96 character sets in a coding system which is characterized as
1253 7-bit environment, non-locking-shift, and non-single-shift.
1255 Note (**): If <F> is '@', 'A', or 'B', the intermediate character
1256 '(' can be omitted. We refer to this as "short-form" hereafter.
1258 Now you may notice that there are a lot of ways of encoding the
1259 same multilingual text in ISO2022. Actually, there exist many
1260 coding systems such as Compound Text (used in X11's inter client
1261 communication, ISO-2022-JP (used in Japanese internet), ISO-2022-KR
1262 (used in Korean internet), EUC (Extended UNIX Code, used in Asian
1263 localized platforms), and all of these are variants of ISO2022.
1265 In addition to the above, Emacs handles two more kinds of escape
1266 sequences: ISO6429's direction specification and Emacs' private
1267 sequence for specifying character composition.
1269 ISO6429's direction specification takes the following form:
1270 o CSI ']' -- end of the current direction
1271 o CSI '0' ']' -- end of the current direction
1272 o CSI '1' ']' -- start of left-to-right text
1273 o CSI '2' ']' -- start of right-to-left text
1274 The control character CSI (0x9B: control sequence introducer) is
1275 abbreviated to the escape sequence ESC '[' in a 7-bit environment.
1277 Character composition specification takes the following form:
1278 o ESC '0' -- start relative composition
1279 o ESC '1' -- end composition
1280 o ESC '2' -- start rule-base composition (*)
1281 o ESC '3' -- start relative composition with alternate chars (**)
1282 o ESC '4' -- start rule-base composition with alternate chars (**)
1283 Since these are not standard escape sequences of any ISO standard,
1284 the use of them with these meanings is restricted to Emacs only.
1286 (*) This form is used only in Emacs 20.5 and older versions,
1287 but the newer versions can safely decode it.
1288 (**) This form is used only in Emacs 21.1 and newer versions,
1289 and the older versions can't decode it.
1291 Here's a list of example usages of these composition escape
1292 sequences (categorized by `enum composition_method').
1294 COMPOSITION_RELATIVE:
1295 ESC 0 CHAR [ CHAR ] ESC 1
1296 COMPOSITOIN_WITH_RULE:
1297 ESC 2 CHAR [ RULE CHAR ] ESC 1
1298 COMPOSITION_WITH_ALTCHARS:
1299 ESC 3 ALTCHAR [ ALTCHAR ] ESC 0 CHAR [ CHAR ] ESC 1
1300 COMPOSITION_WITH_RULE_ALTCHARS:
1301 ESC 4 ALTCHAR [ RULE ALTCHAR ] ESC 0 CHAR [ CHAR ] ESC 1 */
1303 enum iso_code_class_type iso_code_class[256];
1305 #define CHARSET_OK(idx, charset, c) \
1306 (coding_system_table[idx] \
1307 && (charset == CHARSET_ASCII \
1308 || (safe_chars = coding_safe_chars (coding_system_table[idx]), \
1309 CODING_SAFE_CHAR_P (safe_chars, c))) \
1310 && (CODING_SPEC_ISO_REQUESTED_DESIGNATION (coding_system_table[idx], \
1311 charset) \
1312 != CODING_SPEC_ISO_NO_REQUESTED_DESIGNATION))
1314 #define SHIFT_OUT_OK(idx) \
1315 (CODING_SPEC_ISO_INITIAL_DESIGNATION (coding_system_table[idx], 1) >= 0)
1317 /* See the above "GENERAL NOTES on `detect_coding_XXX ()' functions".
1318 Check if a text is encoded in ISO2022. If it is, return an
1319 integer in which appropriate flag bits any of:
1320 CODING_CATEGORY_MASK_ISO_7
1321 CODING_CATEGORY_MASK_ISO_7_TIGHT
1322 CODING_CATEGORY_MASK_ISO_8_1
1323 CODING_CATEGORY_MASK_ISO_8_2
1324 CODING_CATEGORY_MASK_ISO_7_ELSE
1325 CODING_CATEGORY_MASK_ISO_8_ELSE
1326 are set. If a code which should never appear in ISO2022 is found,
1327 returns 0. */
1329 static int
1330 detect_coding_iso2022 (src, src_end, multibytep)
1331 unsigned char *src, *src_end;
1332 int multibytep;
1334 int mask = CODING_CATEGORY_MASK_ISO;
1335 int mask_found = 0;
1336 int reg[4], shift_out = 0, single_shifting = 0;
1337 int c, c1, charset;
1338 /* Dummy for ONE_MORE_BYTE. */
1339 struct coding_system dummy_coding;
1340 struct coding_system *coding = &dummy_coding;
1341 Lisp_Object safe_chars;
1343 reg[0] = CHARSET_ASCII, reg[1] = reg[2] = reg[3] = -1;
1344 while (mask && src < src_end)
1346 ONE_MORE_BYTE_CHECK_MULTIBYTE (c, multibytep);
1347 switch (c)
1349 case ISO_CODE_ESC:
1350 if (inhibit_iso_escape_detection)
1351 break;
1352 single_shifting = 0;
1353 ONE_MORE_BYTE_CHECK_MULTIBYTE (c, multibytep);
1354 if (c >= '(' && c <= '/')
1356 /* Designation sequence for a charset of dimension 1. */
1357 ONE_MORE_BYTE_CHECK_MULTIBYTE (c1, multibytep);
1358 if (c1 < ' ' || c1 >= 0x80
1359 || (charset = iso_charset_table[0][c >= ','][c1]) < 0)
1360 /* Invalid designation sequence. Just ignore. */
1361 break;
1362 reg[(c - '(') % 4] = charset;
1364 else if (c == '$')
1366 /* Designation sequence for a charset of dimension 2. */
1367 ONE_MORE_BYTE_CHECK_MULTIBYTE (c, multibytep);
1368 if (c >= '@' && c <= 'B')
1369 /* Designation for JISX0208.1978, GB2312, or JISX0208. */
1370 reg[0] = charset = iso_charset_table[1][0][c];
1371 else if (c >= '(' && c <= '/')
1373 ONE_MORE_BYTE_CHECK_MULTIBYTE (c1, multibytep);
1374 if (c1 < ' ' || c1 >= 0x80
1375 || (charset = iso_charset_table[1][c >= ','][c1]) < 0)
1376 /* Invalid designation sequence. Just ignore. */
1377 break;
1378 reg[(c - '(') % 4] = charset;
1380 else
1381 /* Invalid designation sequence. Just ignore. */
1382 break;
1384 else if (c == 'N' || c == 'O')
1386 /* ESC <Fe> for SS2 or SS3. */
1387 mask &= CODING_CATEGORY_MASK_ISO_7_ELSE;
1388 break;
1390 else if (c >= '0' && c <= '4')
1392 /* ESC <Fp> for start/end composition. */
1393 mask_found |= CODING_CATEGORY_MASK_ISO;
1394 break;
1396 else
1397 /* Invalid escape sequence. Just ignore. */
1398 break;
1400 /* We found a valid designation sequence for CHARSET. */
1401 mask &= ~CODING_CATEGORY_MASK_ISO_8BIT;
1402 c = MAKE_CHAR (charset, 0, 0);
1403 if (CHARSET_OK (CODING_CATEGORY_IDX_ISO_7, charset, c))
1404 mask_found |= CODING_CATEGORY_MASK_ISO_7;
1405 else
1406 mask &= ~CODING_CATEGORY_MASK_ISO_7;
1407 if (CHARSET_OK (CODING_CATEGORY_IDX_ISO_7_TIGHT, charset, c))
1408 mask_found |= CODING_CATEGORY_MASK_ISO_7_TIGHT;
1409 else
1410 mask &= ~CODING_CATEGORY_MASK_ISO_7_TIGHT;
1411 if (CHARSET_OK (CODING_CATEGORY_IDX_ISO_7_ELSE, charset, c))
1412 mask_found |= CODING_CATEGORY_MASK_ISO_7_ELSE;
1413 else
1414 mask &= ~CODING_CATEGORY_MASK_ISO_7_ELSE;
1415 if (CHARSET_OK (CODING_CATEGORY_IDX_ISO_8_ELSE, charset, c))
1416 mask_found |= CODING_CATEGORY_MASK_ISO_8_ELSE;
1417 else
1418 mask &= ~CODING_CATEGORY_MASK_ISO_8_ELSE;
1419 break;
1421 case ISO_CODE_SO:
1422 if (inhibit_iso_escape_detection)
1423 break;
1424 single_shifting = 0;
1425 if (shift_out == 0
1426 && (reg[1] >= 0
1427 || SHIFT_OUT_OK (CODING_CATEGORY_IDX_ISO_7_ELSE)
1428 || SHIFT_OUT_OK (CODING_CATEGORY_IDX_ISO_8_ELSE)))
1430 /* Locking shift out. */
1431 mask &= ~CODING_CATEGORY_MASK_ISO_7BIT;
1432 mask_found |= CODING_CATEGORY_MASK_ISO_SHIFT;
1434 break;
1436 case ISO_CODE_SI:
1437 if (inhibit_iso_escape_detection)
1438 break;
1439 single_shifting = 0;
1440 if (shift_out == 1)
1442 /* Locking shift in. */
1443 mask &= ~CODING_CATEGORY_MASK_ISO_7BIT;
1444 mask_found |= CODING_CATEGORY_MASK_ISO_SHIFT;
1446 break;
1448 case ISO_CODE_CSI:
1449 single_shifting = 0;
1450 case ISO_CODE_SS2:
1451 case ISO_CODE_SS3:
1453 int newmask = CODING_CATEGORY_MASK_ISO_8_ELSE;
1455 if (inhibit_iso_escape_detection)
1456 break;
1457 if (c != ISO_CODE_CSI)
1459 if (coding_system_table[CODING_CATEGORY_IDX_ISO_8_1]->flags
1460 & CODING_FLAG_ISO_SINGLE_SHIFT)
1461 newmask |= CODING_CATEGORY_MASK_ISO_8_1;
1462 if (coding_system_table[CODING_CATEGORY_IDX_ISO_8_2]->flags
1463 & CODING_FLAG_ISO_SINGLE_SHIFT)
1464 newmask |= CODING_CATEGORY_MASK_ISO_8_2;
1465 single_shifting = 1;
1467 if (VECTORP (Vlatin_extra_code_table)
1468 && !NILP (XVECTOR (Vlatin_extra_code_table)->contents[c]))
1470 if (coding_system_table[CODING_CATEGORY_IDX_ISO_8_1]->flags
1471 & CODING_FLAG_ISO_LATIN_EXTRA)
1472 newmask |= CODING_CATEGORY_MASK_ISO_8_1;
1473 if (coding_system_table[CODING_CATEGORY_IDX_ISO_8_2]->flags
1474 & CODING_FLAG_ISO_LATIN_EXTRA)
1475 newmask |= CODING_CATEGORY_MASK_ISO_8_2;
1477 mask &= newmask;
1478 mask_found |= newmask;
1480 break;
1482 default:
1483 if (c < 0x80)
1485 single_shifting = 0;
1486 break;
1488 else if (c < 0xA0)
1490 single_shifting = 0;
1491 if (VECTORP (Vlatin_extra_code_table)
1492 && !NILP (XVECTOR (Vlatin_extra_code_table)->contents[c]))
1494 int newmask = 0;
1496 if (coding_system_table[CODING_CATEGORY_IDX_ISO_8_1]->flags
1497 & CODING_FLAG_ISO_LATIN_EXTRA)
1498 newmask |= CODING_CATEGORY_MASK_ISO_8_1;
1499 if (coding_system_table[CODING_CATEGORY_IDX_ISO_8_2]->flags
1500 & CODING_FLAG_ISO_LATIN_EXTRA)
1501 newmask |= CODING_CATEGORY_MASK_ISO_8_2;
1502 mask &= newmask;
1503 mask_found |= newmask;
1505 else
1506 return 0;
1508 else
1510 mask &= ~(CODING_CATEGORY_MASK_ISO_7BIT
1511 | CODING_CATEGORY_MASK_ISO_7_ELSE);
1512 mask_found |= CODING_CATEGORY_MASK_ISO_8_1;
1513 /* Check the length of succeeding codes of the range
1514 0xA0..0FF. If the byte length is odd, we exclude
1515 CODING_CATEGORY_MASK_ISO_8_2. We can check this only
1516 when we are not single shifting. */
1517 if (!single_shifting
1518 && mask & CODING_CATEGORY_MASK_ISO_8_2)
1520 int i = 1;
1521 while (src < src_end)
1523 ONE_MORE_BYTE_CHECK_MULTIBYTE (c, multibytep);
1524 if (c < 0xA0)
1525 break;
1526 i++;
1529 if (i & 1 && src < src_end)
1530 mask &= ~CODING_CATEGORY_MASK_ISO_8_2;
1531 else
1532 mask_found |= CODING_CATEGORY_MASK_ISO_8_2;
1535 break;
1538 label_end_of_loop:
1539 return (mask & mask_found);
1542 /* Decode a character of which charset is CHARSET, the 1st position
1543 code is C1, the 2nd position code is C2, and return the decoded
1544 character code. If the variable `translation_table' is non-nil,
1545 returned the translated code. */
1547 #define DECODE_ISO_CHARACTER(charset, c1, c2) \
1548 (NILP (translation_table) \
1549 ? MAKE_CHAR (charset, c1, c2) \
1550 : translate_char (translation_table, -1, charset, c1, c2))
1552 /* Set designation state into CODING. */
1553 #define DECODE_DESIGNATION(reg, dimension, chars, final_char) \
1554 do { \
1555 int charset, c; \
1557 if (final_char < '0' || final_char >= 128) \
1558 goto label_invalid_code; \
1559 charset = ISO_CHARSET_TABLE (make_number (dimension), \
1560 make_number (chars), \
1561 make_number (final_char)); \
1562 c = MAKE_CHAR (charset, 0, 0); \
1563 if (charset >= 0 \
1564 && (CODING_SPEC_ISO_REQUESTED_DESIGNATION (coding, charset) == reg \
1565 || CODING_SAFE_CHAR_P (safe_chars, c))) \
1567 if (coding->spec.iso2022.last_invalid_designation_register == 0 \
1568 && reg == 0 \
1569 && charset == CHARSET_ASCII) \
1571 /* We should insert this designation sequence as is so \
1572 that it is surely written back to a file. */ \
1573 coding->spec.iso2022.last_invalid_designation_register = -1; \
1574 goto label_invalid_code; \
1576 coding->spec.iso2022.last_invalid_designation_register = -1; \
1577 if ((coding->mode & CODING_MODE_DIRECTION) \
1578 && CHARSET_REVERSE_CHARSET (charset) >= 0) \
1579 charset = CHARSET_REVERSE_CHARSET (charset); \
1580 CODING_SPEC_ISO_DESIGNATION (coding, reg) = charset; \
1582 else \
1584 coding->spec.iso2022.last_invalid_designation_register = reg; \
1585 goto label_invalid_code; \
1587 } while (0)
1589 /* Allocate a memory block for storing information about compositions.
1590 The block is chained to the already allocated blocks. */
1592 void
1593 coding_allocate_composition_data (coding, char_offset)
1594 struct coding_system *coding;
1595 int char_offset;
1597 struct composition_data *cmp_data
1598 = (struct composition_data *) xmalloc (sizeof *cmp_data);
1600 cmp_data->char_offset = char_offset;
1601 cmp_data->used = 0;
1602 cmp_data->prev = coding->cmp_data;
1603 cmp_data->next = NULL;
1604 if (coding->cmp_data)
1605 coding->cmp_data->next = cmp_data;
1606 coding->cmp_data = cmp_data;
1607 coding->cmp_data_start = 0;
1610 /* Handle composition start sequence ESC 0, ESC 2, ESC 3, or ESC 4.
1611 ESC 0 : relative composition : ESC 0 CHAR ... ESC 1
1612 ESC 2 : rulebase composition : ESC 2 CHAR RULE CHAR RULE ... CHAR ESC 1
1613 ESC 3 : altchar composition : ESC 3 ALT ... ESC 0 CHAR ... ESC 1
1614 ESC 4 : alt&rule composition : ESC 4 ALT RULE .. ALT ESC 0 CHAR ... ESC 1
1617 #define DECODE_COMPOSITION_START(c1) \
1618 do { \
1619 if (coding->composing == COMPOSITION_DISABLED) \
1621 *dst++ = ISO_CODE_ESC; \
1622 *dst++ = c1 & 0x7f; \
1623 coding->produced_char += 2; \
1625 else if (!COMPOSING_P (coding)) \
1627 /* This is surely the start of a composition. We must be sure \
1628 that coding->cmp_data has enough space to store the \
1629 information about the composition. If not, terminate the \
1630 current decoding loop, allocate one more memory block for \
1631 coding->cmp_data in the calller, then start the decoding \
1632 loop again. We can't allocate memory here directly because \
1633 it may cause buffer/string relocation. */ \
1634 if (!coding->cmp_data \
1635 || (coding->cmp_data->used + COMPOSITION_DATA_MAX_BUNCH_LENGTH \
1636 >= COMPOSITION_DATA_SIZE)) \
1638 coding->result = CODING_FINISH_INSUFFICIENT_CMP; \
1639 goto label_end_of_loop; \
1641 coding->composing = (c1 == '0' ? COMPOSITION_RELATIVE \
1642 : c1 == '2' ? COMPOSITION_WITH_RULE \
1643 : c1 == '3' ? COMPOSITION_WITH_ALTCHARS \
1644 : COMPOSITION_WITH_RULE_ALTCHARS); \
1645 CODING_ADD_COMPOSITION_START (coding, coding->produced_char, \
1646 coding->composing); \
1647 coding->composition_rule_follows = 0; \
1649 else \
1651 /* We are already handling a composition. If the method is \
1652 the following two, the codes following the current escape \
1653 sequence are actual characters stored in a buffer. */ \
1654 if (coding->composing == COMPOSITION_WITH_ALTCHARS \
1655 || coding->composing == COMPOSITION_WITH_RULE_ALTCHARS) \
1657 coding->composing = COMPOSITION_RELATIVE; \
1658 coding->composition_rule_follows = 0; \
1661 } while (0)
1663 /* Handle compositoin end sequence ESC 1. */
1665 #define DECODE_COMPOSITION_END(c1) \
1666 do { \
1667 if (coding->composing == COMPOSITION_DISABLED) \
1669 *dst++ = ISO_CODE_ESC; \
1670 *dst++ = c1; \
1671 coding->produced_char += 2; \
1673 else \
1675 CODING_ADD_COMPOSITION_END (coding, coding->produced_char); \
1676 coding->composing = COMPOSITION_NO; \
1678 } while (0)
1680 /* Decode a composition rule from the byte C1 (and maybe one more byte
1681 from SRC) and store one encoded composition rule in
1682 coding->cmp_data. */
1684 #define DECODE_COMPOSITION_RULE(c1) \
1685 do { \
1686 int rule = 0; \
1687 (c1) -= 32; \
1688 if (c1 < 81) /* old format (before ver.21) */ \
1690 int gref = (c1) / 9; \
1691 int nref = (c1) % 9; \
1692 if (gref == 4) gref = 10; \
1693 if (nref == 4) nref = 10; \
1694 rule = COMPOSITION_ENCODE_RULE (gref, nref); \
1696 else if (c1 < 93) /* new format (after ver.21) */ \
1698 ONE_MORE_BYTE (c2); \
1699 rule = COMPOSITION_ENCODE_RULE (c1 - 81, c2 - 32); \
1701 CODING_ADD_COMPOSITION_COMPONENT (coding, rule); \
1702 coding->composition_rule_follows = 0; \
1703 } while (0)
1706 /* See the above "GENERAL NOTES on `decode_coding_XXX ()' functions". */
1708 static void
1709 decode_coding_iso2022 (coding, source, destination, src_bytes, dst_bytes)
1710 struct coding_system *coding;
1711 unsigned char *source, *destination;
1712 int src_bytes, dst_bytes;
1714 unsigned char *src = source;
1715 unsigned char *src_end = source + src_bytes;
1716 unsigned char *dst = destination;
1717 unsigned char *dst_end = destination + dst_bytes;
1718 /* Charsets invoked to graphic plane 0 and 1 respectively. */
1719 int charset0 = CODING_SPEC_ISO_PLANE_CHARSET (coding, 0);
1720 int charset1 = CODING_SPEC_ISO_PLANE_CHARSET (coding, 1);
1721 /* SRC_BASE remembers the start position in source in each loop.
1722 The loop will be exited when there's not enough source code
1723 (within macro ONE_MORE_BYTE), or when there's not enough
1724 destination area to produce a character (within macro
1725 EMIT_CHAR). */
1726 unsigned char *src_base;
1727 int c, charset;
1728 Lisp_Object translation_table;
1729 Lisp_Object safe_chars;
1731 safe_chars = coding_safe_chars (coding);
1733 if (NILP (Venable_character_translation))
1734 translation_table = Qnil;
1735 else
1737 translation_table = coding->translation_table_for_decode;
1738 if (NILP (translation_table))
1739 translation_table = Vstandard_translation_table_for_decode;
1742 coding->result = CODING_FINISH_NORMAL;
1744 while (1)
1746 int c1, c2;
1748 src_base = src;
1749 ONE_MORE_BYTE (c1);
1751 /* We produce no character or one character. */
1752 switch (iso_code_class [c1])
1754 case ISO_0x20_or_0x7F:
1755 if (COMPOSING_P (coding) && coding->composition_rule_follows)
1757 DECODE_COMPOSITION_RULE (c1);
1758 continue;
1760 if (charset0 < 0 || CHARSET_CHARS (charset0) == 94)
1762 /* This is SPACE or DEL. */
1763 charset = CHARSET_ASCII;
1764 break;
1766 /* This is a graphic character, we fall down ... */
1768 case ISO_graphic_plane_0:
1769 if (COMPOSING_P (coding) && coding->composition_rule_follows)
1771 DECODE_COMPOSITION_RULE (c1);
1772 continue;
1774 charset = charset0;
1775 break;
1777 case ISO_0xA0_or_0xFF:
1778 if (charset1 < 0 || CHARSET_CHARS (charset1) == 94
1779 || coding->flags & CODING_FLAG_ISO_SEVEN_BITS)
1780 goto label_invalid_code;
1781 /* This is a graphic character, we fall down ... */
1783 case ISO_graphic_plane_1:
1784 if (charset1 < 0)
1785 goto label_invalid_code;
1786 charset = charset1;
1787 break;
1789 case ISO_control_0:
1790 if (COMPOSING_P (coding))
1791 DECODE_COMPOSITION_END ('1');
1793 /* All ISO2022 control characters in this class have the
1794 same representation in Emacs internal format. */
1795 if (c1 == '\n'
1796 && (coding->mode & CODING_MODE_INHIBIT_INCONSISTENT_EOL)
1797 && (coding->eol_type == CODING_EOL_CR
1798 || coding->eol_type == CODING_EOL_CRLF))
1800 coding->result = CODING_FINISH_INCONSISTENT_EOL;
1801 goto label_end_of_loop;
1803 charset = CHARSET_ASCII;
1804 break;
1806 case ISO_control_1:
1807 if (COMPOSING_P (coding))
1808 DECODE_COMPOSITION_END ('1');
1809 goto label_invalid_code;
1811 case ISO_carriage_return:
1812 if (COMPOSING_P (coding))
1813 DECODE_COMPOSITION_END ('1');
1815 if (coding->eol_type == CODING_EOL_CR)
1816 c1 = '\n';
1817 else if (coding->eol_type == CODING_EOL_CRLF)
1819 ONE_MORE_BYTE (c1);
1820 if (c1 != ISO_CODE_LF)
1822 if (coding->mode & CODING_MODE_INHIBIT_INCONSISTENT_EOL)
1824 coding->result = CODING_FINISH_INCONSISTENT_EOL;
1825 goto label_end_of_loop;
1827 src--;
1828 c1 = '\r';
1831 charset = CHARSET_ASCII;
1832 break;
1834 case ISO_shift_out:
1835 if (! (coding->flags & CODING_FLAG_ISO_LOCKING_SHIFT)
1836 || CODING_SPEC_ISO_DESIGNATION (coding, 1) < 0)
1837 goto label_invalid_code;
1838 CODING_SPEC_ISO_INVOCATION (coding, 0) = 1;
1839 charset0 = CODING_SPEC_ISO_PLANE_CHARSET (coding, 0);
1840 continue;
1842 case ISO_shift_in:
1843 if (! (coding->flags & CODING_FLAG_ISO_LOCKING_SHIFT))
1844 goto label_invalid_code;
1845 CODING_SPEC_ISO_INVOCATION (coding, 0) = 0;
1846 charset0 = CODING_SPEC_ISO_PLANE_CHARSET (coding, 0);
1847 continue;
1849 case ISO_single_shift_2_7:
1850 case ISO_single_shift_2:
1851 if (! (coding->flags & CODING_FLAG_ISO_SINGLE_SHIFT))
1852 goto label_invalid_code;
1853 /* SS2 is handled as an escape sequence of ESC 'N' */
1854 c1 = 'N';
1855 goto label_escape_sequence;
1857 case ISO_single_shift_3:
1858 if (! (coding->flags & CODING_FLAG_ISO_SINGLE_SHIFT))
1859 goto label_invalid_code;
1860 /* SS2 is handled as an escape sequence of ESC 'O' */
1861 c1 = 'O';
1862 goto label_escape_sequence;
1864 case ISO_control_sequence_introducer:
1865 /* CSI is handled as an escape sequence of ESC '[' ... */
1866 c1 = '[';
1867 goto label_escape_sequence;
1869 case ISO_escape:
1870 ONE_MORE_BYTE (c1);
1871 label_escape_sequence:
1872 /* Escape sequences handled by Emacs are invocation,
1873 designation, direction specification, and character
1874 composition specification. */
1875 switch (c1)
1877 case '&': /* revision of following character set */
1878 ONE_MORE_BYTE (c1);
1879 if (!(c1 >= '@' && c1 <= '~'))
1880 goto label_invalid_code;
1881 ONE_MORE_BYTE (c1);
1882 if (c1 != ISO_CODE_ESC)
1883 goto label_invalid_code;
1884 ONE_MORE_BYTE (c1);
1885 goto label_escape_sequence;
1887 case '$': /* designation of 2-byte character set */
1888 if (! (coding->flags & CODING_FLAG_ISO_DESIGNATION))
1889 goto label_invalid_code;
1890 ONE_MORE_BYTE (c1);
1891 if (c1 >= '@' && c1 <= 'B')
1892 { /* designation of JISX0208.1978, GB2312.1980,
1893 or JISX0208.1980 */
1894 DECODE_DESIGNATION (0, 2, 94, c1);
1896 else if (c1 >= 0x28 && c1 <= 0x2B)
1897 { /* designation of DIMENSION2_CHARS94 character set */
1898 ONE_MORE_BYTE (c2);
1899 DECODE_DESIGNATION (c1 - 0x28, 2, 94, c2);
1901 else if (c1 >= 0x2C && c1 <= 0x2F)
1902 { /* designation of DIMENSION2_CHARS96 character set */
1903 ONE_MORE_BYTE (c2);
1904 DECODE_DESIGNATION (c1 - 0x2C, 2, 96, c2);
1906 else
1907 goto label_invalid_code;
1908 /* We must update these variables now. */
1909 charset0 = CODING_SPEC_ISO_PLANE_CHARSET (coding, 0);
1910 charset1 = CODING_SPEC_ISO_PLANE_CHARSET (coding, 1);
1911 continue;
1913 case 'n': /* invocation of locking-shift-2 */
1914 if (! (coding->flags & CODING_FLAG_ISO_LOCKING_SHIFT)
1915 || CODING_SPEC_ISO_DESIGNATION (coding, 2) < 0)
1916 goto label_invalid_code;
1917 CODING_SPEC_ISO_INVOCATION (coding, 0) = 2;
1918 charset0 = CODING_SPEC_ISO_PLANE_CHARSET (coding, 0);
1919 continue;
1921 case 'o': /* invocation of locking-shift-3 */
1922 if (! (coding->flags & CODING_FLAG_ISO_LOCKING_SHIFT)
1923 || CODING_SPEC_ISO_DESIGNATION (coding, 3) < 0)
1924 goto label_invalid_code;
1925 CODING_SPEC_ISO_INVOCATION (coding, 0) = 3;
1926 charset0 = CODING_SPEC_ISO_PLANE_CHARSET (coding, 0);
1927 continue;
1929 case 'N': /* invocation of single-shift-2 */
1930 if (! (coding->flags & CODING_FLAG_ISO_SINGLE_SHIFT)
1931 || CODING_SPEC_ISO_DESIGNATION (coding, 2) < 0)
1932 goto label_invalid_code;
1933 charset = CODING_SPEC_ISO_DESIGNATION (coding, 2);
1934 ONE_MORE_BYTE (c1);
1935 if (c1 < 0x20 || (c1 >= 0x80 && c1 < 0xA0))
1936 goto label_invalid_code;
1937 break;
1939 case 'O': /* invocation of single-shift-3 */
1940 if (! (coding->flags & CODING_FLAG_ISO_SINGLE_SHIFT)
1941 || CODING_SPEC_ISO_DESIGNATION (coding, 3) < 0)
1942 goto label_invalid_code;
1943 charset = CODING_SPEC_ISO_DESIGNATION (coding, 3);
1944 ONE_MORE_BYTE (c1);
1945 if (c1 < 0x20 || (c1 >= 0x80 && c1 < 0xA0))
1946 goto label_invalid_code;
1947 break;
1949 case '0': case '2': case '3': case '4': /* start composition */
1950 DECODE_COMPOSITION_START (c1);
1951 continue;
1953 case '1': /* end composition */
1954 DECODE_COMPOSITION_END (c1);
1955 continue;
1957 case '[': /* specification of direction */
1958 if (coding->flags & CODING_FLAG_ISO_NO_DIRECTION)
1959 goto label_invalid_code;
1960 /* For the moment, nested direction is not supported.
1961 So, `coding->mode & CODING_MODE_DIRECTION' zero means
1962 left-to-right, and nozero means right-to-left. */
1963 ONE_MORE_BYTE (c1);
1964 switch (c1)
1966 case ']': /* end of the current direction */
1967 coding->mode &= ~CODING_MODE_DIRECTION;
1969 case '0': /* end of the current direction */
1970 case '1': /* start of left-to-right direction */
1971 ONE_MORE_BYTE (c1);
1972 if (c1 == ']')
1973 coding->mode &= ~CODING_MODE_DIRECTION;
1974 else
1975 goto label_invalid_code;
1976 break;
1978 case '2': /* start of right-to-left direction */
1979 ONE_MORE_BYTE (c1);
1980 if (c1 == ']')
1981 coding->mode |= CODING_MODE_DIRECTION;
1982 else
1983 goto label_invalid_code;
1984 break;
1986 default:
1987 goto label_invalid_code;
1989 continue;
1991 default:
1992 if (! (coding->flags & CODING_FLAG_ISO_DESIGNATION))
1993 goto label_invalid_code;
1994 if (c1 >= 0x28 && c1 <= 0x2B)
1995 { /* designation of DIMENSION1_CHARS94 character set */
1996 ONE_MORE_BYTE (c2);
1997 DECODE_DESIGNATION (c1 - 0x28, 1, 94, c2);
1999 else if (c1 >= 0x2C && c1 <= 0x2F)
2000 { /* designation of DIMENSION1_CHARS96 character set */
2001 ONE_MORE_BYTE (c2);
2002 DECODE_DESIGNATION (c1 - 0x2C, 1, 96, c2);
2004 else
2005 goto label_invalid_code;
2006 /* We must update these variables now. */
2007 charset0 = CODING_SPEC_ISO_PLANE_CHARSET (coding, 0);
2008 charset1 = CODING_SPEC_ISO_PLANE_CHARSET (coding, 1);
2009 continue;
2013 /* Now we know CHARSET and 1st position code C1 of a character.
2014 Produce a multibyte sequence for that character while getting
2015 2nd position code C2 if necessary. */
2016 if (CHARSET_DIMENSION (charset) == 2)
2018 ONE_MORE_BYTE (c2);
2019 if (c1 < 0x80 ? c2 < 0x20 || c2 >= 0x80 : c2 < 0xA0)
2020 /* C2 is not in a valid range. */
2021 goto label_invalid_code;
2023 c = DECODE_ISO_CHARACTER (charset, c1, c2);
2024 EMIT_CHAR (c);
2025 continue;
2027 label_invalid_code:
2028 coding->errors++;
2029 if (COMPOSING_P (coding))
2030 DECODE_COMPOSITION_END ('1');
2031 src = src_base;
2032 c = *src++;
2033 EMIT_CHAR (c);
2036 label_end_of_loop:
2037 coding->consumed = coding->consumed_char = src_base - source;
2038 coding->produced = dst - destination;
2039 return;
2043 /* ISO2022 encoding stuff. */
2046 It is not enough to say just "ISO2022" on encoding, we have to
2047 specify more details. In Emacs, each ISO2022 coding system
2048 variant has the following specifications:
2049 1. Initial designation to G0 thru G3.
2050 2. Allows short-form designation?
2051 3. ASCII should be designated to G0 before control characters?
2052 4. ASCII should be designated to G0 at end of line?
2053 5. 7-bit environment or 8-bit environment?
2054 6. Use locking-shift?
2055 7. Use Single-shift?
2056 And the following two are only for Japanese:
2057 8. Use ASCII in place of JIS0201-1976-Roman?
2058 9. Use JISX0208-1983 in place of JISX0208-1978?
2059 These specifications are encoded in `coding->flags' as flag bits
2060 defined by macros CODING_FLAG_ISO_XXX. See `coding.h' for more
2061 details.
2064 /* Produce codes (escape sequence) for designating CHARSET to graphic
2065 register REG at DST, and increment DST. If <final-char> of CHARSET is
2066 '@', 'A', or 'B' and the coding system CODING allows, produce
2067 designation sequence of short-form. */
2069 #define ENCODE_DESIGNATION(charset, reg, coding) \
2070 do { \
2071 unsigned char final_char = CHARSET_ISO_FINAL_CHAR (charset); \
2072 char *intermediate_char_94 = "()*+"; \
2073 char *intermediate_char_96 = ",-./"; \
2074 int revision = CODING_SPEC_ISO_REVISION_NUMBER(coding, charset); \
2076 if (revision < 255) \
2078 *dst++ = ISO_CODE_ESC; \
2079 *dst++ = '&'; \
2080 *dst++ = '@' + revision; \
2082 *dst++ = ISO_CODE_ESC; \
2083 if (CHARSET_DIMENSION (charset) == 1) \
2085 if (CHARSET_CHARS (charset) == 94) \
2086 *dst++ = (unsigned char) (intermediate_char_94[reg]); \
2087 else \
2088 *dst++ = (unsigned char) (intermediate_char_96[reg]); \
2090 else \
2092 *dst++ = '$'; \
2093 if (CHARSET_CHARS (charset) == 94) \
2095 if (! (coding->flags & CODING_FLAG_ISO_SHORT_FORM) \
2096 || reg != 0 \
2097 || final_char < '@' || final_char > 'B') \
2098 *dst++ = (unsigned char) (intermediate_char_94[reg]); \
2100 else \
2101 *dst++ = (unsigned char) (intermediate_char_96[reg]); \
2103 *dst++ = final_char; \
2104 CODING_SPEC_ISO_DESIGNATION (coding, reg) = charset; \
2105 } while (0)
2107 /* The following two macros produce codes (control character or escape
2108 sequence) for ISO2022 single-shift functions (single-shift-2 and
2109 single-shift-3). */
2111 #define ENCODE_SINGLE_SHIFT_2 \
2112 do { \
2113 if (coding->flags & CODING_FLAG_ISO_SEVEN_BITS) \
2114 *dst++ = ISO_CODE_ESC, *dst++ = 'N'; \
2115 else \
2116 *dst++ = ISO_CODE_SS2; \
2117 CODING_SPEC_ISO_SINGLE_SHIFTING (coding) = 1; \
2118 } while (0)
2120 #define ENCODE_SINGLE_SHIFT_3 \
2121 do { \
2122 if (coding->flags & CODING_FLAG_ISO_SEVEN_BITS) \
2123 *dst++ = ISO_CODE_ESC, *dst++ = 'O'; \
2124 else \
2125 *dst++ = ISO_CODE_SS3; \
2126 CODING_SPEC_ISO_SINGLE_SHIFTING (coding) = 1; \
2127 } while (0)
2129 /* The following four macros produce codes (control character or
2130 escape sequence) for ISO2022 locking-shift functions (shift-in,
2131 shift-out, locking-shift-2, and locking-shift-3). */
2133 #define ENCODE_SHIFT_IN \
2134 do { \
2135 *dst++ = ISO_CODE_SI; \
2136 CODING_SPEC_ISO_INVOCATION (coding, 0) = 0; \
2137 } while (0)
2139 #define ENCODE_SHIFT_OUT \
2140 do { \
2141 *dst++ = ISO_CODE_SO; \
2142 CODING_SPEC_ISO_INVOCATION (coding, 0) = 1; \
2143 } while (0)
2145 #define ENCODE_LOCKING_SHIFT_2 \
2146 do { \
2147 *dst++ = ISO_CODE_ESC, *dst++ = 'n'; \
2148 CODING_SPEC_ISO_INVOCATION (coding, 0) = 2; \
2149 } while (0)
2151 #define ENCODE_LOCKING_SHIFT_3 \
2152 do { \
2153 *dst++ = ISO_CODE_ESC, *dst++ = 'o'; \
2154 CODING_SPEC_ISO_INVOCATION (coding, 0) = 3; \
2155 } while (0)
2157 /* Produce codes for a DIMENSION1 character whose character set is
2158 CHARSET and whose position-code is C1. Designation and invocation
2159 sequences are also produced in advance if necessary. */
2161 #define ENCODE_ISO_CHARACTER_DIMENSION1(charset, c1) \
2162 do { \
2163 if (CODING_SPEC_ISO_SINGLE_SHIFTING (coding)) \
2165 if (coding->flags & CODING_FLAG_ISO_SEVEN_BITS) \
2166 *dst++ = c1 & 0x7F; \
2167 else \
2168 *dst++ = c1 | 0x80; \
2169 CODING_SPEC_ISO_SINGLE_SHIFTING (coding) = 0; \
2170 break; \
2172 else if (charset == CODING_SPEC_ISO_PLANE_CHARSET (coding, 0)) \
2174 *dst++ = c1 & 0x7F; \
2175 break; \
2177 else if (charset == CODING_SPEC_ISO_PLANE_CHARSET (coding, 1)) \
2179 *dst++ = c1 | 0x80; \
2180 break; \
2182 else \
2183 /* Since CHARSET is not yet invoked to any graphic planes, we \
2184 must invoke it, or, at first, designate it to some graphic \
2185 register. Then repeat the loop to actually produce the \
2186 character. */ \
2187 dst = encode_invocation_designation (charset, coding, dst); \
2188 } while (1)
2190 /* Produce codes for a DIMENSION2 character whose character set is
2191 CHARSET and whose position-codes are C1 and C2. Designation and
2192 invocation codes are also produced in advance if necessary. */
2194 #define ENCODE_ISO_CHARACTER_DIMENSION2(charset, c1, c2) \
2195 do { \
2196 if (CODING_SPEC_ISO_SINGLE_SHIFTING (coding)) \
2198 if (coding->flags & CODING_FLAG_ISO_SEVEN_BITS) \
2199 *dst++ = c1 & 0x7F, *dst++ = c2 & 0x7F; \
2200 else \
2201 *dst++ = c1 | 0x80, *dst++ = c2 | 0x80; \
2202 CODING_SPEC_ISO_SINGLE_SHIFTING (coding) = 0; \
2203 break; \
2205 else if (charset == CODING_SPEC_ISO_PLANE_CHARSET (coding, 0)) \
2207 *dst++ = c1 & 0x7F, *dst++= c2 & 0x7F; \
2208 break; \
2210 else if (charset == CODING_SPEC_ISO_PLANE_CHARSET (coding, 1)) \
2212 *dst++ = c1 | 0x80, *dst++= c2 | 0x80; \
2213 break; \
2215 else \
2216 /* Since CHARSET is not yet invoked to any graphic planes, we \
2217 must invoke it, or, at first, designate it to some graphic \
2218 register. Then repeat the loop to actually produce the \
2219 character. */ \
2220 dst = encode_invocation_designation (charset, coding, dst); \
2221 } while (1)
2223 #define ENCODE_ISO_CHARACTER(c) \
2224 do { \
2225 int charset, c1, c2; \
2227 SPLIT_CHAR (c, charset, c1, c2); \
2228 if (CHARSET_DEFINED_P (charset)) \
2230 if (CHARSET_DIMENSION (charset) == 1) \
2232 if (charset == CHARSET_ASCII \
2233 && coding->flags & CODING_FLAG_ISO_USE_ROMAN) \
2234 charset = charset_latin_jisx0201; \
2235 ENCODE_ISO_CHARACTER_DIMENSION1 (charset, c1); \
2237 else \
2239 if (charset == charset_jisx0208 \
2240 && coding->flags & CODING_FLAG_ISO_USE_OLDJIS) \
2241 charset = charset_jisx0208_1978; \
2242 ENCODE_ISO_CHARACTER_DIMENSION2 (charset, c1, c2); \
2245 else \
2247 *dst++ = c1; \
2248 if (c2 >= 0) \
2249 *dst++ = c2; \
2251 } while (0)
2254 /* Instead of encoding character C, produce one or two `?'s. */
2256 #define ENCODE_UNSAFE_CHARACTER(c) \
2257 do { \
2258 ENCODE_ISO_CHARACTER (CODING_INHIBIT_CHARACTER_SUBSTITUTION); \
2259 if (CHARSET_WIDTH (CHAR_CHARSET (c)) > 1) \
2260 ENCODE_ISO_CHARACTER (CODING_INHIBIT_CHARACTER_SUBSTITUTION); \
2261 } while (0)
2264 /* Produce designation and invocation codes at a place pointed by DST
2265 to use CHARSET. The element `spec.iso2022' of *CODING is updated.
2266 Return new DST. */
2268 unsigned char *
2269 encode_invocation_designation (charset, coding, dst)
2270 int charset;
2271 struct coding_system *coding;
2272 unsigned char *dst;
2274 int reg; /* graphic register number */
2276 /* At first, check designations. */
2277 for (reg = 0; reg < 4; reg++)
2278 if (charset == CODING_SPEC_ISO_DESIGNATION (coding, reg))
2279 break;
2281 if (reg >= 4)
2283 /* CHARSET is not yet designated to any graphic registers. */
2284 /* At first check the requested designation. */
2285 reg = CODING_SPEC_ISO_REQUESTED_DESIGNATION (coding, charset);
2286 if (reg == CODING_SPEC_ISO_NO_REQUESTED_DESIGNATION)
2287 /* Since CHARSET requests no special designation, designate it
2288 to graphic register 0. */
2289 reg = 0;
2291 ENCODE_DESIGNATION (charset, reg, coding);
2294 if (CODING_SPEC_ISO_INVOCATION (coding, 0) != reg
2295 && CODING_SPEC_ISO_INVOCATION (coding, 1) != reg)
2297 /* Since the graphic register REG is not invoked to any graphic
2298 planes, invoke it to graphic plane 0. */
2299 switch (reg)
2301 case 0: /* graphic register 0 */
2302 ENCODE_SHIFT_IN;
2303 break;
2305 case 1: /* graphic register 1 */
2306 ENCODE_SHIFT_OUT;
2307 break;
2309 case 2: /* graphic register 2 */
2310 if (coding->flags & CODING_FLAG_ISO_SINGLE_SHIFT)
2311 ENCODE_SINGLE_SHIFT_2;
2312 else
2313 ENCODE_LOCKING_SHIFT_2;
2314 break;
2316 case 3: /* graphic register 3 */
2317 if (coding->flags & CODING_FLAG_ISO_SINGLE_SHIFT)
2318 ENCODE_SINGLE_SHIFT_3;
2319 else
2320 ENCODE_LOCKING_SHIFT_3;
2321 break;
2325 return dst;
2328 /* Produce 2-byte codes for encoded composition rule RULE. */
2330 #define ENCODE_COMPOSITION_RULE(rule) \
2331 do { \
2332 int gref, nref; \
2333 COMPOSITION_DECODE_RULE (rule, gref, nref); \
2334 *dst++ = 32 + 81 + gref; \
2335 *dst++ = 32 + nref; \
2336 } while (0)
2338 /* Produce codes for indicating the start of a composition sequence
2339 (ESC 0, ESC 3, or ESC 4). DATA points to an array of integers
2340 which specify information about the composition. See the comment
2341 in coding.h for the format of DATA. */
2343 #define ENCODE_COMPOSITION_START(coding, data) \
2344 do { \
2345 coding->composing = data[3]; \
2346 *dst++ = ISO_CODE_ESC; \
2347 if (coding->composing == COMPOSITION_RELATIVE) \
2348 *dst++ = '0'; \
2349 else \
2351 *dst++ = (coding->composing == COMPOSITION_WITH_ALTCHARS \
2352 ? '3' : '4'); \
2353 coding->cmp_data_index = coding->cmp_data_start + 4; \
2354 coding->composition_rule_follows = 0; \
2356 } while (0)
2358 /* Produce codes for indicating the end of the current composition. */
2360 #define ENCODE_COMPOSITION_END(coding, data) \
2361 do { \
2362 *dst++ = ISO_CODE_ESC; \
2363 *dst++ = '1'; \
2364 coding->cmp_data_start += data[0]; \
2365 coding->composing = COMPOSITION_NO; \
2366 if (coding->cmp_data_start == coding->cmp_data->used \
2367 && coding->cmp_data->next) \
2369 coding->cmp_data = coding->cmp_data->next; \
2370 coding->cmp_data_start = 0; \
2372 } while (0)
2374 /* Produce composition start sequence ESC 0. Here, this sequence
2375 doesn't mean the start of a new composition but means that we have
2376 just produced components (alternate chars and composition rules) of
2377 the composition and the actual text follows in SRC. */
2379 #define ENCODE_COMPOSITION_FAKE_START(coding) \
2380 do { \
2381 *dst++ = ISO_CODE_ESC; \
2382 *dst++ = '0'; \
2383 coding->composing = COMPOSITION_RELATIVE; \
2384 } while (0)
2386 /* The following three macros produce codes for indicating direction
2387 of text. */
2388 #define ENCODE_CONTROL_SEQUENCE_INTRODUCER \
2389 do { \
2390 if (coding->flags == CODING_FLAG_ISO_SEVEN_BITS) \
2391 *dst++ = ISO_CODE_ESC, *dst++ = '['; \
2392 else \
2393 *dst++ = ISO_CODE_CSI; \
2394 } while (0)
2396 #define ENCODE_DIRECTION_R2L \
2397 ENCODE_CONTROL_SEQUENCE_INTRODUCER (dst), *dst++ = '2', *dst++ = ']'
2399 #define ENCODE_DIRECTION_L2R \
2400 ENCODE_CONTROL_SEQUENCE_INTRODUCER (dst), *dst++ = '0', *dst++ = ']'
2402 /* Produce codes for designation and invocation to reset the graphic
2403 planes and registers to initial state. */
2404 #define ENCODE_RESET_PLANE_AND_REGISTER \
2405 do { \
2406 int reg; \
2407 if (CODING_SPEC_ISO_INVOCATION (coding, 0) != 0) \
2408 ENCODE_SHIFT_IN; \
2409 for (reg = 0; reg < 4; reg++) \
2410 if (CODING_SPEC_ISO_INITIAL_DESIGNATION (coding, reg) >= 0 \
2411 && (CODING_SPEC_ISO_DESIGNATION (coding, reg) \
2412 != CODING_SPEC_ISO_INITIAL_DESIGNATION (coding, reg))) \
2413 ENCODE_DESIGNATION \
2414 (CODING_SPEC_ISO_INITIAL_DESIGNATION (coding, reg), reg, coding); \
2415 } while (0)
2417 /* Produce designation sequences of charsets in the line started from
2418 SRC to a place pointed by DST, and return updated DST.
2420 If the current block ends before any end-of-line, we may fail to
2421 find all the necessary designations. */
2423 static unsigned char *
2424 encode_designation_at_bol (coding, translation_table, src, src_end, dst)
2425 struct coding_system *coding;
2426 Lisp_Object translation_table;
2427 unsigned char *src, *src_end, *dst;
2429 int charset, c, found = 0, reg;
2430 /* Table of charsets to be designated to each graphic register. */
2431 int r[4];
2433 for (reg = 0; reg < 4; reg++)
2434 r[reg] = -1;
2436 while (found < 4)
2438 ONE_MORE_CHAR (c);
2439 if (c == '\n')
2440 break;
2442 charset = CHAR_CHARSET (c);
2443 reg = CODING_SPEC_ISO_REQUESTED_DESIGNATION (coding, charset);
2444 if (reg != CODING_SPEC_ISO_NO_REQUESTED_DESIGNATION && r[reg] < 0)
2446 found++;
2447 r[reg] = charset;
2451 label_end_of_loop:
2452 if (found)
2454 for (reg = 0; reg < 4; reg++)
2455 if (r[reg] >= 0
2456 && CODING_SPEC_ISO_DESIGNATION (coding, reg) != r[reg])
2457 ENCODE_DESIGNATION (r[reg], reg, coding);
2460 return dst;
2463 /* See the above "GENERAL NOTES on `encode_coding_XXX ()' functions". */
2465 static void
2466 encode_coding_iso2022 (coding, source, destination, src_bytes, dst_bytes)
2467 struct coding_system *coding;
2468 unsigned char *source, *destination;
2469 int src_bytes, dst_bytes;
2471 unsigned char *src = source;
2472 unsigned char *src_end = source + src_bytes;
2473 unsigned char *dst = destination;
2474 unsigned char *dst_end = destination + dst_bytes;
2475 /* Since the maximum bytes produced by each loop is 20, we subtract 19
2476 from DST_END to assure overflow checking is necessary only at the
2477 head of loop. */
2478 unsigned char *adjusted_dst_end = dst_end - 19;
2479 /* SRC_BASE remembers the start position in source in each loop.
2480 The loop will be exited when there's not enough source text to
2481 analyze multi-byte codes (within macro ONE_MORE_CHAR), or when
2482 there's not enough destination area to produce encoded codes
2483 (within macro EMIT_BYTES). */
2484 unsigned char *src_base;
2485 int c;
2486 Lisp_Object translation_table;
2487 Lisp_Object safe_chars;
2489 safe_chars = coding_safe_chars (coding);
2491 if (NILP (Venable_character_translation))
2492 translation_table = Qnil;
2493 else
2495 translation_table = coding->translation_table_for_encode;
2496 if (NILP (translation_table))
2497 translation_table = Vstandard_translation_table_for_encode;
2500 coding->consumed_char = 0;
2501 coding->errors = 0;
2502 while (1)
2504 src_base = src;
2506 if (dst >= (dst_bytes ? adjusted_dst_end : (src - 19)))
2508 coding->result = CODING_FINISH_INSUFFICIENT_DST;
2509 break;
2512 if (coding->flags & CODING_FLAG_ISO_DESIGNATE_AT_BOL
2513 && CODING_SPEC_ISO_BOL (coding))
2515 /* We have to produce designation sequences if any now. */
2516 dst = encode_designation_at_bol (coding, translation_table,
2517 src, src_end, dst);
2518 CODING_SPEC_ISO_BOL (coding) = 0;
2521 /* Check composition start and end. */
2522 if (coding->composing != COMPOSITION_DISABLED
2523 && coding->cmp_data_start < coding->cmp_data->used)
2525 struct composition_data *cmp_data = coding->cmp_data;
2526 int *data = cmp_data->data + coding->cmp_data_start;
2527 int this_pos = cmp_data->char_offset + coding->consumed_char;
2529 if (coding->composing == COMPOSITION_RELATIVE)
2531 if (this_pos == data[2])
2533 ENCODE_COMPOSITION_END (coding, data);
2534 cmp_data = coding->cmp_data;
2535 data = cmp_data->data + coding->cmp_data_start;
2538 else if (COMPOSING_P (coding))
2540 /* COMPOSITION_WITH_ALTCHARS or COMPOSITION_WITH_RULE_ALTCHAR */
2541 if (coding->cmp_data_index == coding->cmp_data_start + data[0])
2542 /* We have consumed components of the composition.
2543 What follows in SRC is the compositions's base
2544 text. */
2545 ENCODE_COMPOSITION_FAKE_START (coding);
2546 else
2548 int c = cmp_data->data[coding->cmp_data_index++];
2549 if (coding->composition_rule_follows)
2551 ENCODE_COMPOSITION_RULE (c);
2552 coding->composition_rule_follows = 0;
2554 else
2556 if (coding->flags & CODING_FLAG_ISO_SAFE
2557 && ! CODING_SAFE_CHAR_P (safe_chars, c))
2558 ENCODE_UNSAFE_CHARACTER (c);
2559 else
2560 ENCODE_ISO_CHARACTER (c);
2561 if (coding->composing == COMPOSITION_WITH_RULE_ALTCHARS)
2562 coding->composition_rule_follows = 1;
2564 continue;
2567 if (!COMPOSING_P (coding))
2569 if (this_pos == data[1])
2571 ENCODE_COMPOSITION_START (coding, data);
2572 continue;
2577 ONE_MORE_CHAR (c);
2579 /* Now encode the character C. */
2580 if (c < 0x20 || c == 0x7F)
2582 if (c == '\r')
2584 if (! (coding->mode & CODING_MODE_SELECTIVE_DISPLAY))
2586 if (coding->flags & CODING_FLAG_ISO_RESET_AT_CNTL)
2587 ENCODE_RESET_PLANE_AND_REGISTER;
2588 *dst++ = c;
2589 continue;
2591 /* fall down to treat '\r' as '\n' ... */
2592 c = '\n';
2594 if (c == '\n')
2596 if (coding->flags & CODING_FLAG_ISO_RESET_AT_EOL)
2597 ENCODE_RESET_PLANE_AND_REGISTER;
2598 if (coding->flags & CODING_FLAG_ISO_INIT_AT_BOL)
2599 bcopy (coding->spec.iso2022.initial_designation,
2600 coding->spec.iso2022.current_designation,
2601 sizeof coding->spec.iso2022.initial_designation);
2602 if (coding->eol_type == CODING_EOL_LF
2603 || coding->eol_type == CODING_EOL_UNDECIDED)
2604 *dst++ = ISO_CODE_LF;
2605 else if (coding->eol_type == CODING_EOL_CRLF)
2606 *dst++ = ISO_CODE_CR, *dst++ = ISO_CODE_LF;
2607 else
2608 *dst++ = ISO_CODE_CR;
2609 CODING_SPEC_ISO_BOL (coding) = 1;
2611 else
2613 if (coding->flags & CODING_FLAG_ISO_RESET_AT_CNTL)
2614 ENCODE_RESET_PLANE_AND_REGISTER;
2615 *dst++ = c;
2618 else if (ASCII_BYTE_P (c))
2619 ENCODE_ISO_CHARACTER (c);
2620 else if (SINGLE_BYTE_CHAR_P (c))
2622 *dst++ = c;
2623 coding->errors++;
2625 else if (coding->flags & CODING_FLAG_ISO_SAFE
2626 && ! CODING_SAFE_CHAR_P (safe_chars, c))
2627 ENCODE_UNSAFE_CHARACTER (c);
2628 else
2629 ENCODE_ISO_CHARACTER (c);
2631 coding->consumed_char++;
2634 label_end_of_loop:
2635 coding->consumed = src_base - source;
2636 coding->produced = coding->produced_char = dst - destination;
2640 /*** 4. SJIS and BIG5 handlers ***/
2642 /* Although SJIS and BIG5 are not ISO coding systems, they are used
2643 quite widely. So, for the moment, Emacs supports them in the bare
2644 C code. But, in the future, they may be supported only by CCL. */
2646 /* SJIS is a coding system encoding three character sets: ASCII, right
2647 half of JISX0201-Kana, and JISX0208. An ASCII character is encoded
2648 as is. A character of charset katakana-jisx0201 is encoded by
2649 "position-code + 0x80". A character of charset japanese-jisx0208
2650 is encoded in 2-byte but two position-codes are divided and shifted
2651 so that it fits in the range below.
2653 --- CODE RANGE of SJIS ---
2654 (character set) (range)
2655 ASCII 0x00 .. 0x7F
2656 KATAKANA-JISX0201 0xA0 .. 0xDF
2657 JISX0208 (1st byte) 0x81 .. 0x9F and 0xE0 .. 0xEF
2658 (2nd byte) 0x40 .. 0x7E and 0x80 .. 0xFC
2659 -------------------------------
2663 /* BIG5 is a coding system encoding two character sets: ASCII and
2664 Big5. An ASCII character is encoded as is. Big5 is a two-byte
2665 character set and is encoded in two bytes.
2667 --- CODE RANGE of BIG5 ---
2668 (character set) (range)
2669 ASCII 0x00 .. 0x7F
2670 Big5 (1st byte) 0xA1 .. 0xFE
2671 (2nd byte) 0x40 .. 0x7E and 0xA1 .. 0xFE
2672 --------------------------
2674 Since the number of characters in Big5 is larger than maximum
2675 characters in Emacs' charset (96x96), it can't be handled as one
2676 charset. So, in Emacs, Big5 is divided into two: `charset-big5-1'
2677 and `charset-big5-2'. Both are DIMENSION2 and CHARS94. The former
2678 contains frequently used characters and the latter contains less
2679 frequently used characters. */
2681 /* Macros to decode or encode a character of Big5 in BIG5. B1 and B2
2682 are the 1st and 2nd position-codes of Big5 in BIG5 coding system.
2683 C1 and C2 are the 1st and 2nd position-codes of of Emacs' internal
2684 format. CHARSET is `charset_big5_1' or `charset_big5_2'. */
2686 /* Number of Big5 characters which have the same code in 1st byte. */
2687 #define BIG5_SAME_ROW (0xFF - 0xA1 + 0x7F - 0x40)
2689 #define DECODE_BIG5(b1, b2, charset, c1, c2) \
2690 do { \
2691 unsigned int temp \
2692 = (b1 - 0xA1) * BIG5_SAME_ROW + b2 - (b2 < 0x7F ? 0x40 : 0x62); \
2693 if (b1 < 0xC9) \
2694 charset = charset_big5_1; \
2695 else \
2697 charset = charset_big5_2; \
2698 temp -= (0xC9 - 0xA1) * BIG5_SAME_ROW; \
2700 c1 = temp / (0xFF - 0xA1) + 0x21; \
2701 c2 = temp % (0xFF - 0xA1) + 0x21; \
2702 } while (0)
2704 #define ENCODE_BIG5(charset, c1, c2, b1, b2) \
2705 do { \
2706 unsigned int temp = (c1 - 0x21) * (0xFF - 0xA1) + (c2 - 0x21); \
2707 if (charset == charset_big5_2) \
2708 temp += BIG5_SAME_ROW * (0xC9 - 0xA1); \
2709 b1 = temp / BIG5_SAME_ROW + 0xA1; \
2710 b2 = temp % BIG5_SAME_ROW; \
2711 b2 += b2 < 0x3F ? 0x40 : 0x62; \
2712 } while (0)
2714 /* See the above "GENERAL NOTES on `detect_coding_XXX ()' functions".
2715 Check if a text is encoded in SJIS. If it is, return
2716 CODING_CATEGORY_MASK_SJIS, else return 0. */
2718 static int
2719 detect_coding_sjis (src, src_end, multibytep)
2720 unsigned char *src, *src_end;
2721 int multibytep;
2723 int c;
2724 /* Dummy for ONE_MORE_BYTE. */
2725 struct coding_system dummy_coding;
2726 struct coding_system *coding = &dummy_coding;
2728 while (1)
2730 ONE_MORE_BYTE_CHECK_MULTIBYTE (c, multibytep);
2731 if (c >= 0x81)
2733 if (c <= 0x9F || (c >= 0xE0 && c <= 0xEF))
2735 ONE_MORE_BYTE_CHECK_MULTIBYTE (c, multibytep);
2736 if (c < 0x40 || c == 0x7F || c > 0xFC)
2737 return 0;
2739 else if (c > 0xDF)
2740 return 0;
2743 label_end_of_loop:
2744 return CODING_CATEGORY_MASK_SJIS;
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. */
2751 static int
2752 detect_coding_big5 (src, src_end, multibytep)
2753 unsigned char *src, *src_end;
2754 int multibytep;
2756 int c;
2757 /* Dummy for ONE_MORE_BYTE. */
2758 struct coding_system dummy_coding;
2759 struct coding_system *coding = &dummy_coding;
2761 while (1)
2763 ONE_MORE_BYTE_CHECK_MULTIBYTE (c, multibytep);
2764 if (c >= 0xA1)
2766 ONE_MORE_BYTE_CHECK_MULTIBYTE (c, multibytep);
2767 if (c < 0x40 || (c >= 0x7F && c <= 0xA0))
2768 return 0;
2771 label_end_of_loop:
2772 return CODING_CATEGORY_MASK_BIG5;
2775 /* See the above "GENERAL NOTES on `detect_coding_XXX ()' functions".
2776 Check if a text is encoded in UTF-8. If it is, return
2777 CODING_CATEGORY_MASK_UTF_8, else return 0. */
2779 #define UTF_8_1_OCTET_P(c) ((c) < 0x80)
2780 #define UTF_8_EXTRA_OCTET_P(c) (((c) & 0xC0) == 0x80)
2781 #define UTF_8_2_OCTET_LEADING_P(c) (((c) & 0xE0) == 0xC0)
2782 #define UTF_8_3_OCTET_LEADING_P(c) (((c) & 0xF0) == 0xE0)
2783 #define UTF_8_4_OCTET_LEADING_P(c) (((c) & 0xF8) == 0xF0)
2784 #define UTF_8_5_OCTET_LEADING_P(c) (((c) & 0xFC) == 0xF8)
2785 #define UTF_8_6_OCTET_LEADING_P(c) (((c) & 0xFE) == 0xFC)
2787 static int
2788 detect_coding_utf_8 (src, src_end, multibytep)
2789 unsigned char *src, *src_end;
2790 int multibytep;
2792 unsigned char c;
2793 int seq_maybe_bytes;
2794 /* Dummy for ONE_MORE_BYTE. */
2795 struct coding_system dummy_coding;
2796 struct coding_system *coding = &dummy_coding;
2798 while (1)
2800 ONE_MORE_BYTE_CHECK_MULTIBYTE (c, multibytep);
2801 if (UTF_8_1_OCTET_P (c))
2802 continue;
2803 else if (UTF_8_2_OCTET_LEADING_P (c))
2804 seq_maybe_bytes = 1;
2805 else if (UTF_8_3_OCTET_LEADING_P (c))
2806 seq_maybe_bytes = 2;
2807 else if (UTF_8_4_OCTET_LEADING_P (c))
2808 seq_maybe_bytes = 3;
2809 else if (UTF_8_5_OCTET_LEADING_P (c))
2810 seq_maybe_bytes = 4;
2811 else if (UTF_8_6_OCTET_LEADING_P (c))
2812 seq_maybe_bytes = 5;
2813 else
2814 return 0;
2818 ONE_MORE_BYTE_CHECK_MULTIBYTE (c, multibytep);
2819 if (!UTF_8_EXTRA_OCTET_P (c))
2820 return 0;
2821 seq_maybe_bytes--;
2823 while (seq_maybe_bytes > 0);
2826 label_end_of_loop:
2827 return CODING_CATEGORY_MASK_UTF_8;
2830 /* See the above "GENERAL NOTES on `detect_coding_XXX ()' functions".
2831 Check if a text is encoded in UTF-16 Big Endian (endian == 1) or
2832 Little Endian (otherwise). If it is, return
2833 CODING_CATEGORY_MASK_UTF_16_BE or CODING_CATEGORY_MASK_UTF_16_LE,
2834 else return 0. */
2836 #define UTF_16_INVALID_P(val) \
2837 (((val) == 0xFFFE) \
2838 || ((val) == 0xFFFF))
2840 #define UTF_16_HIGH_SURROGATE_P(val) \
2841 (((val) & 0xD800) == 0xD800)
2843 #define UTF_16_LOW_SURROGATE_P(val) \
2844 (((val) & 0xDC00) == 0xDC00)
2846 static int
2847 detect_coding_utf_16 (src, src_end, multibytep)
2848 unsigned char *src, *src_end;
2849 int multibytep;
2851 unsigned char c1, c2;
2852 /* Dummy for TWO_MORE_BYTES. */
2853 struct coding_system dummy_coding;
2854 struct coding_system *coding = &dummy_coding;
2856 ONE_MORE_BYTE_CHECK_MULTIBYTE (c1, multibytep);
2857 ONE_MORE_BYTE_CHECK_MULTIBYTE (c2, multibytep);
2859 if ((c1 == 0xFF) && (c2 == 0xFE))
2860 return CODING_CATEGORY_MASK_UTF_16_LE;
2861 else if ((c1 == 0xFE) && (c2 == 0xFF))
2862 return CODING_CATEGORY_MASK_UTF_16_BE;
2864 label_end_of_loop:
2865 return 0;
2868 /* See the above "GENERAL NOTES on `decode_coding_XXX ()' functions".
2869 If SJIS_P is 1, decode SJIS text, else decode BIG5 test. */
2871 static void
2872 decode_coding_sjis_big5 (coding, source, destination,
2873 src_bytes, dst_bytes, sjis_p)
2874 struct coding_system *coding;
2875 unsigned char *source, *destination;
2876 int src_bytes, dst_bytes;
2877 int sjis_p;
2879 unsigned char *src = source;
2880 unsigned char *src_end = source + src_bytes;
2881 unsigned char *dst = destination;
2882 unsigned char *dst_end = destination + dst_bytes;
2883 /* SRC_BASE remembers the start position in source in each loop.
2884 The loop will be exited when there's not enough source code
2885 (within macro ONE_MORE_BYTE), or when there's not enough
2886 destination area to produce a character (within macro
2887 EMIT_CHAR). */
2888 unsigned char *src_base;
2889 Lisp_Object translation_table;
2891 if (NILP (Venable_character_translation))
2892 translation_table = Qnil;
2893 else
2895 translation_table = coding->translation_table_for_decode;
2896 if (NILP (translation_table))
2897 translation_table = Vstandard_translation_table_for_decode;
2900 coding->produced_char = 0;
2901 while (1)
2903 int c, charset, c1, c2;
2905 src_base = src;
2906 ONE_MORE_BYTE (c1);
2908 if (c1 < 0x80)
2910 charset = CHARSET_ASCII;
2911 if (c1 < 0x20)
2913 if (c1 == '\r')
2915 if (coding->eol_type == CODING_EOL_CRLF)
2917 ONE_MORE_BYTE (c2);
2918 if (c2 == '\n')
2919 c1 = c2;
2920 else if (coding->mode
2921 & CODING_MODE_INHIBIT_INCONSISTENT_EOL)
2923 coding->result = CODING_FINISH_INCONSISTENT_EOL;
2924 goto label_end_of_loop;
2926 else
2927 /* To process C2 again, SRC is subtracted by 1. */
2928 src--;
2930 else if (coding->eol_type == CODING_EOL_CR)
2931 c1 = '\n';
2933 else if (c1 == '\n'
2934 && (coding->mode & CODING_MODE_INHIBIT_INCONSISTENT_EOL)
2935 && (coding->eol_type == CODING_EOL_CR
2936 || coding->eol_type == CODING_EOL_CRLF))
2938 coding->result = CODING_FINISH_INCONSISTENT_EOL;
2939 goto label_end_of_loop;
2943 else
2945 if (sjis_p)
2947 if (c1 >= 0xF0)
2948 goto label_invalid_code;
2949 if (c1 < 0xA0 || c1 >= 0xE0)
2951 /* SJIS -> JISX0208 */
2952 ONE_MORE_BYTE (c2);
2953 if (c2 < 0x40 || c2 == 0x7F || c2 > 0xFC)
2954 goto label_invalid_code;
2955 DECODE_SJIS (c1, c2, c1, c2);
2956 charset = charset_jisx0208;
2958 else
2959 /* SJIS -> JISX0201-Kana */
2960 charset = charset_katakana_jisx0201;
2962 else
2964 /* BIG5 -> Big5 */
2965 if (c1 < 0xA1 || c1 > 0xFE)
2966 goto label_invalid_code;
2967 ONE_MORE_BYTE (c2);
2968 if (c2 < 0x40 || (c2 > 0x7E && c2 < 0xA1) || c2 > 0xFE)
2969 goto label_invalid_code;
2970 DECODE_BIG5 (c1, c2, charset, c1, c2);
2974 c = DECODE_ISO_CHARACTER (charset, c1, c2);
2975 EMIT_CHAR (c);
2976 continue;
2978 label_invalid_code:
2979 coding->errors++;
2980 src = src_base;
2981 c = *src++;
2982 EMIT_CHAR (c);
2985 label_end_of_loop:
2986 coding->consumed = coding->consumed_char = src_base - source;
2987 coding->produced = dst - destination;
2988 return;
2991 /* See the above "GENERAL NOTES on `encode_coding_XXX ()' functions".
2992 This function can encode charsets `ascii', `katakana-jisx0201',
2993 `japanese-jisx0208', `chinese-big5-1', and `chinese-big5-2'. We
2994 are sure that all these charsets are registered as official charset
2995 (i.e. do not have extended leading-codes). Characters of other
2996 charsets are produced without any encoding. If SJIS_P is 1, encode
2997 SJIS text, else encode BIG5 text. */
2999 static void
3000 encode_coding_sjis_big5 (coding, source, destination,
3001 src_bytes, dst_bytes, sjis_p)
3002 struct coding_system *coding;
3003 unsigned char *source, *destination;
3004 int src_bytes, dst_bytes;
3005 int sjis_p;
3007 unsigned char *src = source;
3008 unsigned char *src_end = source + src_bytes;
3009 unsigned char *dst = destination;
3010 unsigned char *dst_end = destination + dst_bytes;
3011 /* SRC_BASE remembers the start position in source in each loop.
3012 The loop will be exited when there's not enough source text to
3013 analyze multi-byte codes (within macro ONE_MORE_CHAR), or when
3014 there's not enough destination area to produce encoded codes
3015 (within macro EMIT_BYTES). */
3016 unsigned char *src_base;
3017 Lisp_Object translation_table;
3019 if (NILP (Venable_character_translation))
3020 translation_table = Qnil;
3021 else
3023 translation_table = coding->translation_table_for_encode;
3024 if (NILP (translation_table))
3025 translation_table = Vstandard_translation_table_for_encode;
3028 while (1)
3030 int c, charset, c1, c2;
3032 src_base = src;
3033 ONE_MORE_CHAR (c);
3035 /* Now encode the character C. */
3036 if (SINGLE_BYTE_CHAR_P (c))
3038 switch (c)
3040 case '\r':
3041 if (!coding->mode & CODING_MODE_SELECTIVE_DISPLAY)
3043 EMIT_ONE_BYTE (c);
3044 break;
3046 c = '\n';
3047 case '\n':
3048 if (coding->eol_type == CODING_EOL_CRLF)
3050 EMIT_TWO_BYTES ('\r', c);
3051 break;
3053 else if (coding->eol_type == CODING_EOL_CR)
3054 c = '\r';
3055 default:
3056 EMIT_ONE_BYTE (c);
3059 else
3061 SPLIT_CHAR (c, charset, c1, c2);
3062 if (sjis_p)
3064 if (charset == charset_jisx0208
3065 || charset == charset_jisx0208_1978)
3067 ENCODE_SJIS (c1, c2, c1, c2);
3068 EMIT_TWO_BYTES (c1, c2);
3070 else if (charset == charset_katakana_jisx0201)
3071 EMIT_ONE_BYTE (c1 | 0x80);
3072 else if (charset == charset_latin_jisx0201)
3073 EMIT_ONE_BYTE (c1);
3074 else
3075 /* There's no way other than producing the internal
3076 codes as is. */
3077 EMIT_BYTES (src_base, src);
3079 else
3081 if (charset == charset_big5_1 || charset == charset_big5_2)
3083 ENCODE_BIG5 (charset, c1, c2, c1, c2);
3084 EMIT_TWO_BYTES (c1, c2);
3086 else
3087 /* There's no way other than producing the internal
3088 codes as is. */
3089 EMIT_BYTES (src_base, src);
3092 coding->consumed_char++;
3095 label_end_of_loop:
3096 coding->consumed = src_base - source;
3097 coding->produced = coding->produced_char = dst - destination;
3101 /*** 5. CCL handlers ***/
3103 /* See the above "GENERAL NOTES on `detect_coding_XXX ()' functions".
3104 Check if a text is encoded in a coding system of which
3105 encoder/decoder are written in CCL program. If it is, return
3106 CODING_CATEGORY_MASK_CCL, else return 0. */
3108 static int
3109 detect_coding_ccl (src, src_end, multibytep)
3110 unsigned char *src, *src_end;
3111 int multibytep;
3113 unsigned char *valid;
3114 int c;
3115 /* Dummy for ONE_MORE_BYTE. */
3116 struct coding_system dummy_coding;
3117 struct coding_system *coding = &dummy_coding;
3119 /* No coding system is assigned to coding-category-ccl. */
3120 if (!coding_system_table[CODING_CATEGORY_IDX_CCL])
3121 return 0;
3123 valid = coding_system_table[CODING_CATEGORY_IDX_CCL]->spec.ccl.valid_codes;
3124 while (1)
3126 ONE_MORE_BYTE_CHECK_MULTIBYTE (c, multibytep);
3127 if (! valid[c])
3128 return 0;
3130 label_end_of_loop:
3131 return CODING_CATEGORY_MASK_CCL;
3135 /*** 6. End-of-line handlers ***/
3137 /* See the above "GENERAL NOTES on `decode_coding_XXX ()' functions". */
3139 static void
3140 decode_eol (coding, source, destination, src_bytes, dst_bytes)
3141 struct coding_system *coding;
3142 unsigned char *source, *destination;
3143 int src_bytes, dst_bytes;
3145 unsigned char *src = source;
3146 unsigned char *dst = destination;
3147 unsigned char *src_end = src + src_bytes;
3148 unsigned char *dst_end = dst + dst_bytes;
3149 Lisp_Object translation_table;
3150 /* SRC_BASE remembers the start position in source in each loop.
3151 The loop will be exited when there's not enough source code
3152 (within macro ONE_MORE_BYTE), or when there's not enough
3153 destination area to produce a character (within macro
3154 EMIT_CHAR). */
3155 unsigned char *src_base;
3156 int c;
3158 translation_table = Qnil;
3159 switch (coding->eol_type)
3161 case CODING_EOL_CRLF:
3162 while (1)
3164 src_base = src;
3165 ONE_MORE_BYTE (c);
3166 if (c == '\r')
3168 ONE_MORE_BYTE (c);
3169 if (c != '\n')
3171 if (coding->mode & CODING_MODE_INHIBIT_INCONSISTENT_EOL)
3173 coding->result = CODING_FINISH_INCONSISTENT_EOL;
3174 goto label_end_of_loop;
3176 src--;
3177 c = '\r';
3180 else if (c == '\n'
3181 && (coding->mode & CODING_MODE_INHIBIT_INCONSISTENT_EOL))
3183 coding->result = CODING_FINISH_INCONSISTENT_EOL;
3184 goto label_end_of_loop;
3186 EMIT_CHAR (c);
3188 break;
3190 case CODING_EOL_CR:
3191 while (1)
3193 src_base = src;
3194 ONE_MORE_BYTE (c);
3195 if (c == '\n')
3197 if (coding->mode & CODING_MODE_INHIBIT_INCONSISTENT_EOL)
3199 coding->result = CODING_FINISH_INCONSISTENT_EOL;
3200 goto label_end_of_loop;
3203 else if (c == '\r')
3204 c = '\n';
3205 EMIT_CHAR (c);
3207 break;
3209 default: /* no need for EOL handling */
3210 while (1)
3212 src_base = src;
3213 ONE_MORE_BYTE (c);
3214 EMIT_CHAR (c);
3218 label_end_of_loop:
3219 coding->consumed = coding->consumed_char = src_base - source;
3220 coding->produced = dst - destination;
3221 return;
3224 /* See "GENERAL NOTES about `encode_coding_XXX ()' functions". Encode
3225 format of end-of-line according to `coding->eol_type'. It also
3226 convert multibyte form 8-bit characers to unibyte if
3227 CODING->src_multibyte is nonzero. If `coding->mode &
3228 CODING_MODE_SELECTIVE_DISPLAY' is nonzero, code '\r' in source text
3229 also means end-of-line. */
3231 static void
3232 encode_eol (coding, source, destination, src_bytes, dst_bytes)
3233 struct coding_system *coding;
3234 unsigned char *source, *destination;
3235 int src_bytes, dst_bytes;
3237 unsigned char *src = source;
3238 unsigned char *dst = destination;
3239 unsigned char *src_end = src + src_bytes;
3240 unsigned char *dst_end = dst + dst_bytes;
3241 Lisp_Object translation_table;
3242 /* SRC_BASE remembers the start position in source in each loop.
3243 The loop will be exited when there's not enough source text to
3244 analyze multi-byte codes (within macro ONE_MORE_CHAR), or when
3245 there's not enough destination area to produce encoded codes
3246 (within macro EMIT_BYTES). */
3247 unsigned char *src_base;
3248 int c;
3249 int selective_display = coding->mode & CODING_MODE_SELECTIVE_DISPLAY;
3251 translation_table = Qnil;
3252 if (coding->src_multibyte
3253 && *(src_end - 1) == LEADING_CODE_8_BIT_CONTROL)
3255 src_end--;
3256 src_bytes--;
3257 coding->result = CODING_FINISH_INSUFFICIENT_SRC;
3260 if (coding->eol_type == CODING_EOL_CRLF)
3262 while (src < src_end)
3264 src_base = src;
3265 c = *src++;
3266 if (c >= 0x20)
3267 EMIT_ONE_BYTE (c);
3268 else if (c == '\n' || (c == '\r' && selective_display))
3269 EMIT_TWO_BYTES ('\r', '\n');
3270 else
3271 EMIT_ONE_BYTE (c);
3273 src_base = src;
3274 label_end_of_loop:
3277 else
3279 if (!dst_bytes || src_bytes <= dst_bytes)
3281 safe_bcopy (src, dst, src_bytes);
3282 src_base = src_end;
3283 dst += src_bytes;
3285 else
3287 if (coding->src_multibyte
3288 && *(src + dst_bytes - 1) == LEADING_CODE_8_BIT_CONTROL)
3289 dst_bytes--;
3290 safe_bcopy (src, dst, dst_bytes);
3291 src_base = src + dst_bytes;
3292 dst = destination + dst_bytes;
3293 coding->result = CODING_FINISH_INSUFFICIENT_DST;
3295 if (coding->eol_type == CODING_EOL_CR)
3297 for (src = destination; src < dst; src++)
3298 if (*src == '\n') *src = '\r';
3300 else if (selective_display)
3302 for (src = destination; src < dst; src++)
3303 if (*src == '\r') *src = '\n';
3306 if (coding->src_multibyte)
3307 dst = destination + str_as_unibyte (destination, dst - destination);
3309 coding->consumed = src_base - source;
3310 coding->produced = dst - destination;
3311 coding->produced_char = coding->produced;
3315 /*** 7. C library functions ***/
3317 /* In Emacs Lisp, a coding system is represented by a Lisp symbol which
3318 has a property `coding-system'. The value of this property is a
3319 vector of length 5 (called the coding-vector). Among elements of
3320 this vector, the first (element[0]) and the fifth (element[4])
3321 carry important information for decoding/encoding. Before
3322 decoding/encoding, this information should be set in fields of a
3323 structure of type `coding_system'.
3325 The value of the property `coding-system' can be a symbol of another
3326 subsidiary coding-system. In that case, Emacs gets coding-vector
3327 from that symbol.
3329 `element[0]' contains information to be set in `coding->type'. The
3330 value and its meaning is as follows:
3332 0 -- coding_type_emacs_mule
3333 1 -- coding_type_sjis
3334 2 -- coding_type_iso2022
3335 3 -- coding_type_big5
3336 4 -- coding_type_ccl encoder/decoder written in CCL
3337 nil -- coding_type_no_conversion
3338 t -- coding_type_undecided (automatic conversion on decoding,
3339 no-conversion on encoding)
3341 `element[4]' contains information to be set in `coding->flags' and
3342 `coding->spec'. The meaning varies by `coding->type'.
3344 If `coding->type' is `coding_type_iso2022', element[4] is a vector
3345 of length 32 (of which the first 13 sub-elements are used now).
3346 Meanings of these sub-elements are:
3348 sub-element[N] where N is 0 through 3: to be set in `coding->spec.iso2022'
3349 If the value is an integer of valid charset, the charset is
3350 assumed to be designated to graphic register N initially.
3352 If the value is minus, it is a minus value of charset which
3353 reserves graphic register N, which means that the charset is
3354 not designated initially but should be designated to graphic
3355 register N just before encoding a character in that charset.
3357 If the value is nil, graphic register N is never used on
3358 encoding.
3360 sub-element[N] where N is 4 through 11: to be set in `coding->flags'
3361 Each value takes t or nil. See the section ISO2022 of
3362 `coding.h' for more information.
3364 If `coding->type' is `coding_type_big5', element[4] is t to denote
3365 BIG5-ETen or nil to denote BIG5-HKU.
3367 If `coding->type' takes the other value, element[4] is ignored.
3369 Emacs Lisp's coding systems also carry information about format of
3370 end-of-line in a value of property `eol-type'. If the value is
3371 integer, 0 means CODING_EOL_LF, 1 means CODING_EOL_CRLF, and 2
3372 means CODING_EOL_CR. If it is not integer, it should be a vector
3373 of subsidiary coding systems of which property `eol-type' has one
3374 of the above values.
3378 /* Extract information for decoding/encoding from CODING_SYSTEM_SYMBOL
3379 and set it in CODING. If CODING_SYSTEM_SYMBOL is invalid, CODING
3380 is setup so that no conversion is necessary and return -1, else
3381 return 0. */
3384 setup_coding_system (coding_system, coding)
3385 Lisp_Object coding_system;
3386 struct coding_system *coding;
3388 Lisp_Object coding_spec, coding_type, eol_type, plist;
3389 Lisp_Object val;
3391 /* At first, zero clear all members. */
3392 bzero (coding, sizeof (struct coding_system));
3394 /* Initialize some fields required for all kinds of coding systems. */
3395 coding->symbol = coding_system;
3396 coding->heading_ascii = -1;
3397 coding->post_read_conversion = coding->pre_write_conversion = Qnil;
3398 coding->composing = COMPOSITION_DISABLED;
3399 coding->cmp_data = NULL;
3401 if (NILP (coding_system))
3402 goto label_invalid_coding_system;
3404 coding_spec = Fget (coding_system, Qcoding_system);
3406 if (!VECTORP (coding_spec)
3407 || XVECTOR (coding_spec)->size != 5
3408 || !CONSP (XVECTOR (coding_spec)->contents[3]))
3409 goto label_invalid_coding_system;
3411 eol_type = inhibit_eol_conversion ? Qnil : Fget (coding_system, Qeol_type);
3412 if (VECTORP (eol_type))
3414 coding->eol_type = CODING_EOL_UNDECIDED;
3415 coding->common_flags = CODING_REQUIRE_DETECTION_MASK;
3417 else if (XFASTINT (eol_type) == 1)
3419 coding->eol_type = CODING_EOL_CRLF;
3420 coding->common_flags
3421 = CODING_REQUIRE_DECODING_MASK | CODING_REQUIRE_ENCODING_MASK;
3423 else if (XFASTINT (eol_type) == 2)
3425 coding->eol_type = CODING_EOL_CR;
3426 coding->common_flags
3427 = CODING_REQUIRE_DECODING_MASK | CODING_REQUIRE_ENCODING_MASK;
3429 else
3430 coding->eol_type = CODING_EOL_LF;
3432 coding_type = XVECTOR (coding_spec)->contents[0];
3433 /* Try short cut. */
3434 if (SYMBOLP (coding_type))
3436 if (EQ (coding_type, Qt))
3438 coding->type = coding_type_undecided;
3439 coding->common_flags |= CODING_REQUIRE_DETECTION_MASK;
3441 else
3442 coding->type = coding_type_no_conversion;
3443 /* Initialize this member. Any thing other than
3444 CODING_CATEGORY_IDX_UTF_16_BE and
3445 CODING_CATEGORY_IDX_UTF_16_LE are ok because they have
3446 special treatment in detect_eol. */
3447 coding->category_idx = CODING_CATEGORY_IDX_EMACS_MULE;
3449 return 0;
3452 /* Get values of coding system properties:
3453 `post-read-conversion', `pre-write-conversion',
3454 `translation-table-for-decode', `translation-table-for-encode'. */
3455 plist = XVECTOR (coding_spec)->contents[3];
3456 /* Pre & post conversion functions should be disabled if
3457 inhibit_eol_conversion is nozero. This is the case that a code
3458 conversion function is called while those functions are running. */
3459 if (! inhibit_pre_post_conversion)
3461 coding->post_read_conversion = Fplist_get (plist, Qpost_read_conversion);
3462 coding->pre_write_conversion = Fplist_get (plist, Qpre_write_conversion);
3464 val = Fplist_get (plist, Qtranslation_table_for_decode);
3465 if (SYMBOLP (val))
3466 val = Fget (val, Qtranslation_table_for_decode);
3467 coding->translation_table_for_decode = CHAR_TABLE_P (val) ? val : Qnil;
3468 val = Fplist_get (plist, Qtranslation_table_for_encode);
3469 if (SYMBOLP (val))
3470 val = Fget (val, Qtranslation_table_for_encode);
3471 coding->translation_table_for_encode = CHAR_TABLE_P (val) ? val : Qnil;
3472 val = Fplist_get (plist, Qcoding_category);
3473 if (!NILP (val))
3475 val = Fget (val, Qcoding_category_index);
3476 if (INTEGERP (val))
3477 coding->category_idx = XINT (val);
3478 else
3479 goto label_invalid_coding_system;
3481 else
3482 goto label_invalid_coding_system;
3484 /* If the coding system has non-nil `composition' property, enable
3485 composition handling. */
3486 val = Fplist_get (plist, Qcomposition);
3487 if (!NILP (val))
3488 coding->composing = COMPOSITION_NO;
3490 switch (XFASTINT (coding_type))
3492 case 0:
3493 coding->type = coding_type_emacs_mule;
3494 coding->common_flags
3495 |= CODING_REQUIRE_DECODING_MASK | CODING_REQUIRE_ENCODING_MASK;
3496 coding->composing = COMPOSITION_NO;
3497 if (!NILP (coding->post_read_conversion))
3498 coding->common_flags |= CODING_REQUIRE_DECODING_MASK;
3499 if (!NILP (coding->pre_write_conversion))
3500 coding->common_flags |= CODING_REQUIRE_ENCODING_MASK;
3501 break;
3503 case 1:
3504 coding->type = coding_type_sjis;
3505 coding->common_flags
3506 |= CODING_REQUIRE_DECODING_MASK | CODING_REQUIRE_ENCODING_MASK;
3507 break;
3509 case 2:
3510 coding->type = coding_type_iso2022;
3511 coding->common_flags
3512 |= CODING_REQUIRE_DECODING_MASK | CODING_REQUIRE_ENCODING_MASK;
3514 Lisp_Object val, temp;
3515 Lisp_Object *flags;
3516 int i, charset, reg_bits = 0;
3518 val = XVECTOR (coding_spec)->contents[4];
3520 if (!VECTORP (val) || XVECTOR (val)->size != 32)
3521 goto label_invalid_coding_system;
3523 flags = XVECTOR (val)->contents;
3524 coding->flags
3525 = ((NILP (flags[4]) ? 0 : CODING_FLAG_ISO_SHORT_FORM)
3526 | (NILP (flags[5]) ? 0 : CODING_FLAG_ISO_RESET_AT_EOL)
3527 | (NILP (flags[6]) ? 0 : CODING_FLAG_ISO_RESET_AT_CNTL)
3528 | (NILP (flags[7]) ? 0 : CODING_FLAG_ISO_SEVEN_BITS)
3529 | (NILP (flags[8]) ? 0 : CODING_FLAG_ISO_LOCKING_SHIFT)
3530 | (NILP (flags[9]) ? 0 : CODING_FLAG_ISO_SINGLE_SHIFT)
3531 | (NILP (flags[10]) ? 0 : CODING_FLAG_ISO_USE_ROMAN)
3532 | (NILP (flags[11]) ? 0 : CODING_FLAG_ISO_USE_OLDJIS)
3533 | (NILP (flags[12]) ? 0 : CODING_FLAG_ISO_NO_DIRECTION)
3534 | (NILP (flags[13]) ? 0 : CODING_FLAG_ISO_INIT_AT_BOL)
3535 | (NILP (flags[14]) ? 0 : CODING_FLAG_ISO_DESIGNATE_AT_BOL)
3536 | (NILP (flags[15]) ? 0 : CODING_FLAG_ISO_SAFE)
3537 | (NILP (flags[16]) ? 0 : CODING_FLAG_ISO_LATIN_EXTRA)
3540 /* Invoke graphic register 0 to plane 0. */
3541 CODING_SPEC_ISO_INVOCATION (coding, 0) = 0;
3542 /* Invoke graphic register 1 to plane 1 if we can use full 8-bit. */
3543 CODING_SPEC_ISO_INVOCATION (coding, 1)
3544 = (coding->flags & CODING_FLAG_ISO_SEVEN_BITS ? -1 : 1);
3545 /* Not single shifting at first. */
3546 CODING_SPEC_ISO_SINGLE_SHIFTING (coding) = 0;
3547 /* Beginning of buffer should also be regarded as bol. */
3548 CODING_SPEC_ISO_BOL (coding) = 1;
3550 for (charset = 0; charset <= MAX_CHARSET; charset++)
3551 CODING_SPEC_ISO_REVISION_NUMBER (coding, charset) = 255;
3552 val = Vcharset_revision_alist;
3553 while (CONSP (val))
3555 charset = get_charset_id (Fcar_safe (XCAR (val)));
3556 if (charset >= 0
3557 && (temp = Fcdr_safe (XCAR (val)), INTEGERP (temp))
3558 && (i = XINT (temp), (i >= 0 && (i + '@') < 128)))
3559 CODING_SPEC_ISO_REVISION_NUMBER (coding, charset) = i;
3560 val = XCDR (val);
3563 /* Checks FLAGS[REG] (REG = 0, 1, 2 3) and decide designations.
3564 FLAGS[REG] can be one of below:
3565 integer CHARSET: CHARSET occupies register I,
3566 t: designate nothing to REG initially, but can be used
3567 by any charsets,
3568 list of integer, nil, or t: designate the first
3569 element (if integer) to REG initially, the remaining
3570 elements (if integer) is designated to REG on request,
3571 if an element is t, REG can be used by any charsets,
3572 nil: REG is never used. */
3573 for (charset = 0; charset <= MAX_CHARSET; charset++)
3574 CODING_SPEC_ISO_REQUESTED_DESIGNATION (coding, charset)
3575 = CODING_SPEC_ISO_NO_REQUESTED_DESIGNATION;
3576 for (i = 0; i < 4; i++)
3578 if (INTEGERP (flags[i])
3579 && (charset = XINT (flags[i]), CHARSET_VALID_P (charset))
3580 || (charset = get_charset_id (flags[i])) >= 0)
3582 CODING_SPEC_ISO_INITIAL_DESIGNATION (coding, i) = charset;
3583 CODING_SPEC_ISO_REQUESTED_DESIGNATION (coding, charset) = i;
3585 else if (EQ (flags[i], Qt))
3587 CODING_SPEC_ISO_INITIAL_DESIGNATION (coding, i) = -1;
3588 reg_bits |= 1 << i;
3589 coding->flags |= CODING_FLAG_ISO_DESIGNATION;
3591 else if (CONSP (flags[i]))
3593 Lisp_Object tail;
3594 tail = flags[i];
3596 coding->flags |= CODING_FLAG_ISO_DESIGNATION;
3597 if (INTEGERP (XCAR (tail))
3598 && (charset = XINT (XCAR (tail)),
3599 CHARSET_VALID_P (charset))
3600 || (charset = get_charset_id (XCAR (tail))) >= 0)
3602 CODING_SPEC_ISO_INITIAL_DESIGNATION (coding, i) = charset;
3603 CODING_SPEC_ISO_REQUESTED_DESIGNATION (coding, charset) =i;
3605 else
3606 CODING_SPEC_ISO_INITIAL_DESIGNATION (coding, i) = -1;
3607 tail = XCDR (tail);
3608 while (CONSP (tail))
3610 if (INTEGERP (XCAR (tail))
3611 && (charset = XINT (XCAR (tail)),
3612 CHARSET_VALID_P (charset))
3613 || (charset = get_charset_id (XCAR (tail))) >= 0)
3614 CODING_SPEC_ISO_REQUESTED_DESIGNATION (coding, charset)
3615 = i;
3616 else if (EQ (XCAR (tail), Qt))
3617 reg_bits |= 1 << i;
3618 tail = XCDR (tail);
3621 else
3622 CODING_SPEC_ISO_INITIAL_DESIGNATION (coding, i) = -1;
3624 CODING_SPEC_ISO_DESIGNATION (coding, i)
3625 = CODING_SPEC_ISO_INITIAL_DESIGNATION (coding, i);
3628 if (reg_bits && ! (coding->flags & CODING_FLAG_ISO_LOCKING_SHIFT))
3630 /* REG 1 can be used only by locking shift in 7-bit env. */
3631 if (coding->flags & CODING_FLAG_ISO_SEVEN_BITS)
3632 reg_bits &= ~2;
3633 if (! (coding->flags & CODING_FLAG_ISO_SINGLE_SHIFT))
3634 /* Without any shifting, only REG 0 and 1 can be used. */
3635 reg_bits &= 3;
3638 if (reg_bits)
3639 for (charset = 0; charset <= MAX_CHARSET; charset++)
3641 if (CHARSET_VALID_P (charset)
3642 && (CODING_SPEC_ISO_REQUESTED_DESIGNATION (coding, charset)
3643 == CODING_SPEC_ISO_NO_REQUESTED_DESIGNATION))
3645 /* There exist some default graphic registers to be
3646 used by CHARSET. */
3648 /* We had better avoid designating a charset of
3649 CHARS96 to REG 0 as far as possible. */
3650 if (CHARSET_CHARS (charset) == 96)
3651 CODING_SPEC_ISO_REQUESTED_DESIGNATION (coding, charset)
3652 = (reg_bits & 2
3653 ? 1 : (reg_bits & 4 ? 2 : (reg_bits & 8 ? 3 : 0)));
3654 else
3655 CODING_SPEC_ISO_REQUESTED_DESIGNATION (coding, charset)
3656 = (reg_bits & 1
3657 ? 0 : (reg_bits & 2 ? 1 : (reg_bits & 4 ? 2 : 3)));
3661 coding->common_flags |= CODING_REQUIRE_FLUSHING_MASK;
3662 coding->spec.iso2022.last_invalid_designation_register = -1;
3663 break;
3665 case 3:
3666 coding->type = coding_type_big5;
3667 coding->common_flags
3668 |= CODING_REQUIRE_DECODING_MASK | CODING_REQUIRE_ENCODING_MASK;
3669 coding->flags
3670 = (NILP (XVECTOR (coding_spec)->contents[4])
3671 ? CODING_FLAG_BIG5_HKU
3672 : CODING_FLAG_BIG5_ETEN);
3673 break;
3675 case 4:
3676 coding->type = coding_type_ccl;
3677 coding->common_flags
3678 |= CODING_REQUIRE_DECODING_MASK | CODING_REQUIRE_ENCODING_MASK;
3680 val = XVECTOR (coding_spec)->contents[4];
3681 if (! CONSP (val)
3682 || setup_ccl_program (&(coding->spec.ccl.decoder),
3683 XCAR (val)) < 0
3684 || setup_ccl_program (&(coding->spec.ccl.encoder),
3685 XCDR (val)) < 0)
3686 goto label_invalid_coding_system;
3688 bzero (coding->spec.ccl.valid_codes, 256);
3689 val = Fplist_get (plist, Qvalid_codes);
3690 if (CONSP (val))
3692 Lisp_Object this;
3694 for (; CONSP (val); val = XCDR (val))
3696 this = XCAR (val);
3697 if (INTEGERP (this)
3698 && XINT (this) >= 0 && XINT (this) < 256)
3699 coding->spec.ccl.valid_codes[XINT (this)] = 1;
3700 else if (CONSP (this)
3701 && INTEGERP (XCAR (this))
3702 && INTEGERP (XCDR (this)))
3704 int start = XINT (XCAR (this));
3705 int end = XINT (XCDR (this));
3707 if (start >= 0 && start <= end && end < 256)
3708 while (start <= end)
3709 coding->spec.ccl.valid_codes[start++] = 1;
3714 coding->common_flags |= CODING_REQUIRE_FLUSHING_MASK;
3715 coding->spec.ccl.cr_carryover = 0;
3716 coding->spec.ccl.eight_bit_carryover[0] = 0;
3717 break;
3719 case 5:
3720 coding->type = coding_type_raw_text;
3721 break;
3723 default:
3724 goto label_invalid_coding_system;
3726 return 0;
3728 label_invalid_coding_system:
3729 coding->type = coding_type_no_conversion;
3730 coding->category_idx = CODING_CATEGORY_IDX_BINARY;
3731 coding->common_flags = 0;
3732 coding->eol_type = CODING_EOL_LF;
3733 coding->pre_write_conversion = coding->post_read_conversion = Qnil;
3734 return -1;
3737 /* Free memory blocks allocated for storing composition information. */
3739 void
3740 coding_free_composition_data (coding)
3741 struct coding_system *coding;
3743 struct composition_data *cmp_data = coding->cmp_data, *next;
3745 if (!cmp_data)
3746 return;
3747 /* Memory blocks are chained. At first, rewind to the first, then,
3748 free blocks one by one. */
3749 while (cmp_data->prev)
3750 cmp_data = cmp_data->prev;
3751 while (cmp_data)
3753 next = cmp_data->next;
3754 xfree (cmp_data);
3755 cmp_data = next;
3757 coding->cmp_data = NULL;
3760 /* Set `char_offset' member of all memory blocks pointed by
3761 coding->cmp_data to POS. */
3763 void
3764 coding_adjust_composition_offset (coding, pos)
3765 struct coding_system *coding;
3766 int pos;
3768 struct composition_data *cmp_data;
3770 for (cmp_data = coding->cmp_data; cmp_data; cmp_data = cmp_data->next)
3771 cmp_data->char_offset = pos;
3774 /* Setup raw-text or one of its subsidiaries in the structure
3775 coding_system CODING according to the already setup value eol_type
3776 in CODING. CODING should be setup for some coding system in
3777 advance. */
3779 void
3780 setup_raw_text_coding_system (coding)
3781 struct coding_system *coding;
3783 if (coding->type != coding_type_raw_text)
3785 coding->symbol = Qraw_text;
3786 coding->type = coding_type_raw_text;
3787 if (coding->eol_type != CODING_EOL_UNDECIDED)
3789 Lisp_Object subsidiaries;
3790 subsidiaries = Fget (Qraw_text, Qeol_type);
3792 if (VECTORP (subsidiaries)
3793 && XVECTOR (subsidiaries)->size == 3)
3794 coding->symbol
3795 = XVECTOR (subsidiaries)->contents[coding->eol_type];
3797 setup_coding_system (coding->symbol, coding);
3799 return;
3802 /* Emacs has a mechanism to automatically detect a coding system if it
3803 is one of Emacs' internal format, ISO2022, SJIS, and BIG5. But,
3804 it's impossible to distinguish some coding systems accurately
3805 because they use the same range of codes. So, at first, coding
3806 systems are categorized into 7, those are:
3808 o coding-category-emacs-mule
3810 The category for a coding system which has the same code range
3811 as Emacs' internal format. Assigned the coding-system (Lisp
3812 symbol) `emacs-mule' by default.
3814 o coding-category-sjis
3816 The category for a coding system which has the same code range
3817 as SJIS. Assigned the coding-system (Lisp
3818 symbol) `japanese-shift-jis' by default.
3820 o coding-category-iso-7
3822 The category for a coding system which has the same code range
3823 as ISO2022 of 7-bit environment. This doesn't use any locking
3824 shift and single shift functions. This can encode/decode all
3825 charsets. Assigned the coding-system (Lisp symbol)
3826 `iso-2022-7bit' by default.
3828 o coding-category-iso-7-tight
3830 Same as coding-category-iso-7 except that this can
3831 encode/decode only the specified charsets.
3833 o coding-category-iso-8-1
3835 The category for a coding system which has the same code range
3836 as ISO2022 of 8-bit environment and graphic plane 1 used only
3837 for DIMENSION1 charset. This doesn't use any locking shift
3838 and single shift functions. Assigned the coding-system (Lisp
3839 symbol) `iso-latin-1' by default.
3841 o coding-category-iso-8-2
3843 The category for a coding system which has the same code range
3844 as ISO2022 of 8-bit environment and graphic plane 1 used only
3845 for DIMENSION2 charset. This doesn't use any locking shift
3846 and single shift functions. Assigned the coding-system (Lisp
3847 symbol) `japanese-iso-8bit' by default.
3849 o coding-category-iso-7-else
3851 The category for a coding system which has the same code range
3852 as ISO2022 of 7-bit environemnt but uses locking shift or
3853 single shift functions. Assigned the coding-system (Lisp
3854 symbol) `iso-2022-7bit-lock' by default.
3856 o coding-category-iso-8-else
3858 The category for a coding system which has the same code range
3859 as ISO2022 of 8-bit environemnt but uses locking shift or
3860 single shift functions. Assigned the coding-system (Lisp
3861 symbol) `iso-2022-8bit-ss2' by default.
3863 o coding-category-big5
3865 The category for a coding system which has the same code range
3866 as BIG5. Assigned the coding-system (Lisp symbol)
3867 `cn-big5' by default.
3869 o coding-category-utf-8
3871 The category for a coding system which has the same code range
3872 as UTF-8 (cf. RFC2279). Assigned the coding-system (Lisp
3873 symbol) `utf-8' by default.
3875 o coding-category-utf-16-be
3877 The category for a coding system in which a text has an
3878 Unicode signature (cf. Unicode Standard) in the order of BIG
3879 endian at the head. Assigned the coding-system (Lisp symbol)
3880 `utf-16-be' by default.
3882 o coding-category-utf-16-le
3884 The category for a coding system in which a text has an
3885 Unicode signature (cf. Unicode Standard) in the order of
3886 LITTLE endian at the head. Assigned the coding-system (Lisp
3887 symbol) `utf-16-le' by default.
3889 o coding-category-ccl
3891 The category for a coding system of which encoder/decoder is
3892 written in CCL programs. The default value is nil, i.e., no
3893 coding system is assigned.
3895 o coding-category-binary
3897 The category for a coding system not categorized in any of the
3898 above. Assigned the coding-system (Lisp symbol)
3899 `no-conversion' by default.
3901 Each of them is a Lisp symbol and the value is an actual
3902 `coding-system' (this is also a Lisp symbol) assigned by a user.
3903 What Emacs does actually is to detect a category of coding system.
3904 Then, it uses a `coding-system' assigned to it. If Emacs can't
3905 decide a single possible category, it selects a category of the
3906 highest priority. Priorities of categories are also specified by a
3907 user in a Lisp variable `coding-category-list'.
3911 static
3912 int ascii_skip_code[256];
3914 /* Detect how a text of length SRC_BYTES pointed by SOURCE is encoded.
3915 If it detects possible coding systems, return an integer in which
3916 appropriate flag bits are set. Flag bits are defined by macros
3917 CODING_CATEGORY_MASK_XXX in `coding.h'. If PRIORITIES is non-NULL,
3918 it should point the table `coding_priorities'. In that case, only
3919 the flag bit for a coding system of the highest priority is set in
3920 the returned value. If MULTIBYTEP is nonzero, 8-bit codes of the
3921 range 0x80..0x9F are in multibyte form.
3923 How many ASCII characters are at the head is returned as *SKIP. */
3925 static int
3926 detect_coding_mask (source, src_bytes, priorities, skip, multibytep)
3927 unsigned char *source;
3928 int src_bytes, *priorities, *skip;
3929 int multibytep;
3931 register unsigned char c;
3932 unsigned char *src = source, *src_end = source + src_bytes;
3933 unsigned int mask, utf16_examined_p, iso2022_examined_p;
3934 int i;
3936 /* At first, skip all ASCII characters and control characters except
3937 for three ISO2022 specific control characters. */
3938 ascii_skip_code[ISO_CODE_SO] = 0;
3939 ascii_skip_code[ISO_CODE_SI] = 0;
3940 ascii_skip_code[ISO_CODE_ESC] = 0;
3942 label_loop_detect_coding:
3943 while (src < src_end && ascii_skip_code[*src]) src++;
3944 *skip = src - source;
3946 if (src >= src_end)
3947 /* We found nothing other than ASCII. There's nothing to do. */
3948 return 0;
3950 c = *src;
3951 /* The text seems to be encoded in some multilingual coding system.
3952 Now, try to find in which coding system the text is encoded. */
3953 if (c < 0x80)
3955 /* i.e. (c == ISO_CODE_ESC || c == ISO_CODE_SI || c == ISO_CODE_SO) */
3956 /* C is an ISO2022 specific control code of C0. */
3957 mask = detect_coding_iso2022 (src, src_end, multibytep);
3958 if (mask == 0)
3960 /* No valid ISO2022 code follows C. Try again. */
3961 src++;
3962 if (c == ISO_CODE_ESC)
3963 ascii_skip_code[ISO_CODE_ESC] = 1;
3964 else
3965 ascii_skip_code[ISO_CODE_SO] = ascii_skip_code[ISO_CODE_SI] = 1;
3966 goto label_loop_detect_coding;
3968 if (priorities)
3970 for (i = 0; i < CODING_CATEGORY_IDX_MAX; i++)
3972 if (mask & priorities[i])
3973 return priorities[i];
3975 return CODING_CATEGORY_MASK_RAW_TEXT;
3978 else
3980 int try;
3982 if (multibytep && c == LEADING_CODE_8_BIT_CONTROL)
3983 c = *src++ - 0x20;
3985 if (c < 0xA0)
3987 /* C is the first byte of SJIS character code,
3988 or a leading-code of Emacs' internal format (emacs-mule),
3989 or the first byte of UTF-16. */
3990 try = (CODING_CATEGORY_MASK_SJIS
3991 | CODING_CATEGORY_MASK_EMACS_MULE
3992 | CODING_CATEGORY_MASK_UTF_16_BE
3993 | CODING_CATEGORY_MASK_UTF_16_LE);
3995 /* Or, if C is a special latin extra code,
3996 or is an ISO2022 specific control code of C1 (SS2 or SS3),
3997 or is an ISO2022 control-sequence-introducer (CSI),
3998 we should also consider the possibility of ISO2022 codings. */
3999 if ((VECTORP (Vlatin_extra_code_table)
4000 && !NILP (XVECTOR (Vlatin_extra_code_table)->contents[c]))
4001 || (c == ISO_CODE_SS2 || c == ISO_CODE_SS3)
4002 || (c == ISO_CODE_CSI
4003 && (src < src_end
4004 && (*src == ']'
4005 || ((*src == '0' || *src == '1' || *src == '2')
4006 && src + 1 < src_end
4007 && src[1] == ']')))))
4008 try |= (CODING_CATEGORY_MASK_ISO_8_ELSE
4009 | CODING_CATEGORY_MASK_ISO_8BIT);
4011 else
4012 /* C is a character of ISO2022 in graphic plane right,
4013 or a SJIS's 1-byte character code (i.e. JISX0201),
4014 or the first byte of BIG5's 2-byte code,
4015 or the first byte of UTF-8/16. */
4016 try = (CODING_CATEGORY_MASK_ISO_8_ELSE
4017 | CODING_CATEGORY_MASK_ISO_8BIT
4018 | CODING_CATEGORY_MASK_SJIS
4019 | CODING_CATEGORY_MASK_BIG5
4020 | CODING_CATEGORY_MASK_UTF_8
4021 | CODING_CATEGORY_MASK_UTF_16_BE
4022 | CODING_CATEGORY_MASK_UTF_16_LE);
4024 /* Or, we may have to consider the possibility of CCL. */
4025 if (coding_system_table[CODING_CATEGORY_IDX_CCL]
4026 && (coding_system_table[CODING_CATEGORY_IDX_CCL]
4027 ->spec.ccl.valid_codes)[c])
4028 try |= CODING_CATEGORY_MASK_CCL;
4030 mask = 0;
4031 utf16_examined_p = iso2022_examined_p = 0;
4032 if (priorities)
4034 for (i = 0; i < CODING_CATEGORY_IDX_MAX; i++)
4036 if (!iso2022_examined_p
4037 && (priorities[i] & try & CODING_CATEGORY_MASK_ISO))
4039 mask |= detect_coding_iso2022 (src, src_end);
4040 iso2022_examined_p = 1;
4042 else if (priorities[i] & try & CODING_CATEGORY_MASK_SJIS)
4043 mask |= detect_coding_sjis (src, src_end, multibytep);
4044 else if (priorities[i] & try & CODING_CATEGORY_MASK_UTF_8)
4045 mask |= detect_coding_utf_8 (src, src_end, multibytep);
4046 else if (!utf16_examined_p
4047 && (priorities[i] & try &
4048 CODING_CATEGORY_MASK_UTF_16_BE_LE))
4050 mask |= detect_coding_utf_16 (src, src_end, multibytep);
4051 utf16_examined_p = 1;
4053 else if (priorities[i] & try & CODING_CATEGORY_MASK_BIG5)
4054 mask |= detect_coding_big5 (src, src_end, multibytep);
4055 else if (priorities[i] & try & CODING_CATEGORY_MASK_EMACS_MULE)
4056 mask |= detect_coding_emacs_mule (src, src_end, multibytep);
4057 else if (priorities[i] & try & CODING_CATEGORY_MASK_CCL)
4058 mask |= detect_coding_ccl (src, src_end, multibytep);
4059 else if (priorities[i] & CODING_CATEGORY_MASK_RAW_TEXT)
4060 mask |= CODING_CATEGORY_MASK_RAW_TEXT;
4061 else if (priorities[i] & CODING_CATEGORY_MASK_BINARY)
4062 mask |= CODING_CATEGORY_MASK_BINARY;
4063 if (mask & priorities[i])
4064 return priorities[i];
4066 return CODING_CATEGORY_MASK_RAW_TEXT;
4068 if (try & CODING_CATEGORY_MASK_ISO)
4069 mask |= detect_coding_iso2022 (src, src_end, multibytep);
4070 if (try & CODING_CATEGORY_MASK_SJIS)
4071 mask |= detect_coding_sjis (src, src_end, multibytep);
4072 if (try & CODING_CATEGORY_MASK_BIG5)
4073 mask |= detect_coding_big5 (src, src_end, multibytep);
4074 if (try & CODING_CATEGORY_MASK_UTF_8)
4075 mask |= detect_coding_utf_8 (src, src_end, multibytep);
4076 if (try & CODING_CATEGORY_MASK_UTF_16_BE_LE)
4077 mask |= detect_coding_utf_16 (src, src_end, multibytep);
4078 if (try & CODING_CATEGORY_MASK_EMACS_MULE)
4079 mask |= detect_coding_emacs_mule (src, src_end, multibytep);
4080 if (try & CODING_CATEGORY_MASK_CCL)
4081 mask |= detect_coding_ccl (src, src_end, multibytep);
4083 return (mask | CODING_CATEGORY_MASK_RAW_TEXT | CODING_CATEGORY_MASK_BINARY);
4086 /* Detect how a text of length SRC_BYTES pointed by SRC is encoded.
4087 The information of the detected coding system is set in CODING. */
4089 void
4090 detect_coding (coding, src, src_bytes)
4091 struct coding_system *coding;
4092 unsigned char *src;
4093 int src_bytes;
4095 unsigned int idx;
4096 int skip, mask;
4097 Lisp_Object val;
4099 val = Vcoding_category_list;
4100 mask = detect_coding_mask (src, src_bytes, coding_priorities, &skip,
4101 coding->src_multibyte);
4102 coding->heading_ascii = skip;
4104 if (!mask) return;
4106 /* We found a single coding system of the highest priority in MASK. */
4107 idx = 0;
4108 while (mask && ! (mask & 1)) mask >>= 1, idx++;
4109 if (! mask)
4110 idx = CODING_CATEGORY_IDX_RAW_TEXT;
4112 val = XSYMBOL (XVECTOR (Vcoding_category_table)->contents[idx])->value;
4114 if (coding->eol_type != CODING_EOL_UNDECIDED)
4116 Lisp_Object tmp;
4118 tmp = Fget (val, Qeol_type);
4119 if (VECTORP (tmp))
4120 val = XVECTOR (tmp)->contents[coding->eol_type];
4123 /* Setup this new coding system while preserving some slots. */
4125 int src_multibyte = coding->src_multibyte;
4126 int dst_multibyte = coding->dst_multibyte;
4128 setup_coding_system (val, coding);
4129 coding->src_multibyte = src_multibyte;
4130 coding->dst_multibyte = dst_multibyte;
4131 coding->heading_ascii = skip;
4135 /* Detect how end-of-line of a text of length SRC_BYTES pointed by
4136 SOURCE is encoded. Return one of CODING_EOL_LF, CODING_EOL_CRLF,
4137 CODING_EOL_CR, and CODING_EOL_UNDECIDED.
4139 How many non-eol characters are at the head is returned as *SKIP. */
4141 #define MAX_EOL_CHECK_COUNT 3
4143 static int
4144 detect_eol_type (source, src_bytes, skip)
4145 unsigned char *source;
4146 int src_bytes, *skip;
4148 unsigned char *src = source, *src_end = src + src_bytes;
4149 unsigned char c;
4150 int total = 0; /* How many end-of-lines are found so far. */
4151 int eol_type = CODING_EOL_UNDECIDED;
4152 int this_eol_type;
4154 *skip = 0;
4156 while (src < src_end && total < MAX_EOL_CHECK_COUNT)
4158 c = *src++;
4159 if (c == '\n' || c == '\r')
4161 if (*skip == 0)
4162 *skip = src - 1 - source;
4163 total++;
4164 if (c == '\n')
4165 this_eol_type = CODING_EOL_LF;
4166 else if (src >= src_end || *src != '\n')
4167 this_eol_type = CODING_EOL_CR;
4168 else
4169 this_eol_type = CODING_EOL_CRLF, src++;
4171 if (eol_type == CODING_EOL_UNDECIDED)
4172 /* This is the first end-of-line. */
4173 eol_type = this_eol_type;
4174 else if (eol_type != this_eol_type)
4176 /* The found type is different from what found before. */
4177 eol_type = CODING_EOL_INCONSISTENT;
4178 break;
4183 if (*skip == 0)
4184 *skip = src_end - source;
4185 return eol_type;
4188 /* Like detect_eol_type, but detect EOL type in 2-octet
4189 big-endian/little-endian format for coding systems utf-16-be and
4190 utf-16-le. */
4192 static int
4193 detect_eol_type_in_2_octet_form (source, src_bytes, skip, big_endian_p)
4194 unsigned char *source;
4195 int src_bytes, *skip, big_endian_p;
4197 unsigned char *src = source, *src_end = src + src_bytes;
4198 unsigned int c1, c2;
4199 int total = 0; /* How many end-of-lines are found so far. */
4200 int eol_type = CODING_EOL_UNDECIDED;
4201 int this_eol_type;
4202 int msb, lsb;
4204 if (big_endian_p)
4205 msb = 0, lsb = 1;
4206 else
4207 msb = 1, lsb = 0;
4209 *skip = 0;
4211 while ((src + 1) < src_end && total < MAX_EOL_CHECK_COUNT)
4213 c1 = (src[msb] << 8) | (src[lsb]);
4214 src += 2;
4216 if (c1 == '\n' || c1 == '\r')
4218 if (*skip == 0)
4219 *skip = src - 2 - source;
4220 total++;
4221 if (c1 == '\n')
4223 this_eol_type = CODING_EOL_LF;
4225 else
4227 if ((src + 1) >= src_end)
4229 this_eol_type = CODING_EOL_CR;
4231 else
4233 c2 = (src[msb] << 8) | (src[lsb]);
4234 if (c2 == '\n')
4235 this_eol_type = CODING_EOL_CRLF, src += 2;
4236 else
4237 this_eol_type = CODING_EOL_CR;
4241 if (eol_type == CODING_EOL_UNDECIDED)
4242 /* This is the first end-of-line. */
4243 eol_type = this_eol_type;
4244 else if (eol_type != this_eol_type)
4246 /* The found type is different from what found before. */
4247 eol_type = CODING_EOL_INCONSISTENT;
4248 break;
4253 if (*skip == 0)
4254 *skip = src_end - source;
4255 return eol_type;
4258 /* Detect how end-of-line of a text of length SRC_BYTES pointed by SRC
4259 is encoded. If it detects an appropriate format of end-of-line, it
4260 sets the information in *CODING. */
4262 void
4263 detect_eol (coding, src, src_bytes)
4264 struct coding_system *coding;
4265 unsigned char *src;
4266 int src_bytes;
4268 Lisp_Object val;
4269 int skip;
4270 int eol_type;
4272 switch (coding->category_idx)
4274 case CODING_CATEGORY_IDX_UTF_16_BE:
4275 eol_type = detect_eol_type_in_2_octet_form (src, src_bytes, &skip, 1);
4276 break;
4277 case CODING_CATEGORY_IDX_UTF_16_LE:
4278 eol_type = detect_eol_type_in_2_octet_form (src, src_bytes, &skip, 0);
4279 break;
4280 default:
4281 eol_type = detect_eol_type (src, src_bytes, &skip);
4282 break;
4285 if (coding->heading_ascii > skip)
4286 coding->heading_ascii = skip;
4287 else
4288 skip = coding->heading_ascii;
4290 if (eol_type == CODING_EOL_UNDECIDED)
4291 return;
4292 if (eol_type == CODING_EOL_INCONSISTENT)
4294 #if 0
4295 /* This code is suppressed until we find a better way to
4296 distinguish raw text file and binary file. */
4298 /* If we have already detected that the coding is raw-text, the
4299 coding should actually be no-conversion. */
4300 if (coding->type == coding_type_raw_text)
4302 setup_coding_system (Qno_conversion, coding);
4303 return;
4305 /* Else, let's decode only text code anyway. */
4306 #endif /* 0 */
4307 eol_type = CODING_EOL_LF;
4310 val = Fget (coding->symbol, Qeol_type);
4311 if (VECTORP (val) && XVECTOR (val)->size == 3)
4313 int src_multibyte = coding->src_multibyte;
4314 int dst_multibyte = coding->dst_multibyte;
4316 setup_coding_system (XVECTOR (val)->contents[eol_type], coding);
4317 coding->src_multibyte = src_multibyte;
4318 coding->dst_multibyte = dst_multibyte;
4319 coding->heading_ascii = skip;
4323 #define CONVERSION_BUFFER_EXTRA_ROOM 256
4325 #define DECODING_BUFFER_MAG(coding) \
4326 (coding->type == coding_type_iso2022 \
4327 ? 3 \
4328 : (coding->type == coding_type_ccl \
4329 ? coding->spec.ccl.decoder.buf_magnification \
4330 : 2))
4332 /* Return maximum size (bytes) of a buffer enough for decoding
4333 SRC_BYTES of text encoded in CODING. */
4336 decoding_buffer_size (coding, src_bytes)
4337 struct coding_system *coding;
4338 int src_bytes;
4340 return (src_bytes * DECODING_BUFFER_MAG (coding)
4341 + CONVERSION_BUFFER_EXTRA_ROOM);
4344 /* Return maximum size (bytes) of a buffer enough for encoding
4345 SRC_BYTES of text to CODING. */
4348 encoding_buffer_size (coding, src_bytes)
4349 struct coding_system *coding;
4350 int src_bytes;
4352 int magnification;
4354 if (coding->type == coding_type_ccl)
4355 magnification = coding->spec.ccl.encoder.buf_magnification;
4356 else if (CODING_REQUIRE_ENCODING (coding))
4357 magnification = 3;
4358 else
4359 magnification = 1;
4361 return (src_bytes * magnification + CONVERSION_BUFFER_EXTRA_ROOM);
4364 /* Working buffer for code conversion. */
4365 struct conversion_buffer
4367 int size; /* size of data. */
4368 int on_stack; /* 1 if allocated by alloca. */
4369 unsigned char *data;
4372 /* Don't use alloca for allocating memory space larger than this, lest
4373 we overflow their stack. */
4374 #define MAX_ALLOCA 16*1024
4376 /* Allocate LEN bytes of memory for BUF (struct conversion_buffer). */
4377 #define allocate_conversion_buffer(buf, len) \
4378 do { \
4379 if (len < MAX_ALLOCA) \
4381 buf.data = (unsigned char *) alloca (len); \
4382 buf.on_stack = 1; \
4384 else \
4386 buf.data = (unsigned char *) xmalloc (len); \
4387 buf.on_stack = 0; \
4389 buf.size = len; \
4390 } while (0)
4392 /* Double the allocated memory for *BUF. */
4393 static void
4394 extend_conversion_buffer (buf)
4395 struct conversion_buffer *buf;
4397 if (buf->on_stack)
4399 unsigned char *save = buf->data;
4400 buf->data = (unsigned char *) xmalloc (buf->size * 2);
4401 bcopy (save, buf->data, buf->size);
4402 buf->on_stack = 0;
4404 else
4406 buf->data = (unsigned char *) xrealloc (buf->data, buf->size * 2);
4408 buf->size *= 2;
4411 /* Free the allocated memory for BUF if it is not on stack. */
4412 static void
4413 free_conversion_buffer (buf)
4414 struct conversion_buffer *buf;
4416 if (!buf->on_stack)
4417 xfree (buf->data);
4421 ccl_coding_driver (coding, source, destination, src_bytes, dst_bytes, encodep)
4422 struct coding_system *coding;
4423 unsigned char *source, *destination;
4424 int src_bytes, dst_bytes, encodep;
4426 struct ccl_program *ccl
4427 = encodep ? &coding->spec.ccl.encoder : &coding->spec.ccl.decoder;
4428 unsigned char *dst = destination;
4430 ccl->suppress_error = coding->suppress_error;
4431 ccl->last_block = coding->mode & CODING_MODE_LAST_BLOCK;
4432 if (encodep)
4434 /* On encoding, EOL format is converted within ccl_driver. For
4435 that, setup proper information in the structure CCL. */
4436 ccl->eol_type = coding->eol_type;
4437 if (ccl->eol_type ==CODING_EOL_UNDECIDED)
4438 ccl->eol_type = CODING_EOL_LF;
4439 ccl->cr_consumed = coding->spec.ccl.cr_carryover;
4441 ccl->multibyte = coding->src_multibyte;
4442 if (coding->spec.ccl.eight_bit_carryover[0] != 0)
4444 /* Move carryover bytes to DESTINATION. */
4445 unsigned char *p = coding->spec.ccl.eight_bit_carryover;
4446 while (*p)
4447 *dst++ = *p++;
4448 coding->spec.ccl.eight_bit_carryover[0] = 0;
4449 if (dst_bytes)
4450 dst_bytes -= dst - destination;
4453 coding->produced = (ccl_driver (ccl, source, dst, src_bytes, dst_bytes,
4454 &(coding->consumed))
4455 + dst - destination);
4457 if (encodep)
4459 coding->produced_char = coding->produced;
4460 coding->spec.ccl.cr_carryover = ccl->cr_consumed;
4462 else
4464 /* On decoding, the destination should always multibyte. But,
4465 CCL program might have been generated an invalid multibyte
4466 sequence. Here we make such a sequence valid as
4467 multibyte. */
4468 int bytes
4469 = dst_bytes ? dst_bytes : source + coding->consumed - destination;
4471 if ((coding->consumed < src_bytes
4472 || !ccl->last_block)
4473 && coding->produced >= 1
4474 && destination[coding->produced - 1] >= 0x80)
4476 /* We should not convert the tailing 8-bit codes to
4477 multibyte form even if they doesn't form a valid
4478 multibyte sequence. They may form a valid sequence in
4479 the next call. */
4480 int carryover = 0;
4482 if (destination[coding->produced - 1] < 0xA0)
4483 carryover = 1;
4484 else if (coding->produced >= 2)
4486 if (destination[coding->produced - 2] >= 0x80)
4488 if (destination[coding->produced - 2] < 0xA0)
4489 carryover = 2;
4490 else if (coding->produced >= 3
4491 && destination[coding->produced - 3] >= 0x80
4492 && destination[coding->produced - 3] < 0xA0)
4493 carryover = 3;
4496 if (carryover > 0)
4498 BCOPY_SHORT (destination + coding->produced - carryover,
4499 coding->spec.ccl.eight_bit_carryover,
4500 carryover);
4501 coding->spec.ccl.eight_bit_carryover[carryover] = 0;
4502 coding->produced -= carryover;
4505 coding->produced = str_as_multibyte (destination, bytes,
4506 coding->produced,
4507 &(coding->produced_char));
4510 switch (ccl->status)
4512 case CCL_STAT_SUSPEND_BY_SRC:
4513 coding->result = CODING_FINISH_INSUFFICIENT_SRC;
4514 break;
4515 case CCL_STAT_SUSPEND_BY_DST:
4516 coding->result = CODING_FINISH_INSUFFICIENT_DST;
4517 break;
4518 case CCL_STAT_QUIT:
4519 case CCL_STAT_INVALID_CMD:
4520 coding->result = CODING_FINISH_INTERRUPT;
4521 break;
4522 default:
4523 coding->result = CODING_FINISH_NORMAL;
4524 break;
4526 return coding->result;
4529 /* Decode EOL format of the text at PTR of BYTES length destructively
4530 according to CODING->eol_type. This is called after the CCL
4531 program produced a decoded text at PTR. If we do CRLF->LF
4532 conversion, update CODING->produced and CODING->produced_char. */
4534 static void
4535 decode_eol_post_ccl (coding, ptr, bytes)
4536 struct coding_system *coding;
4537 unsigned char *ptr;
4538 int bytes;
4540 Lisp_Object val, saved_coding_symbol;
4541 unsigned char *pend = ptr + bytes;
4542 int dummy;
4544 /* Remember the current coding system symbol. We set it back when
4545 an inconsistent EOL is found so that `last-coding-system-used' is
4546 set to the coding system that doesn't specify EOL conversion. */
4547 saved_coding_symbol = coding->symbol;
4549 coding->spec.ccl.cr_carryover = 0;
4550 if (coding->eol_type == CODING_EOL_UNDECIDED)
4552 /* Here, to avoid the call of setup_coding_system, we directly
4553 call detect_eol_type. */
4554 coding->eol_type = detect_eol_type (ptr, bytes, &dummy);
4555 if (coding->eol_type == CODING_EOL_INCONSISTENT)
4556 coding->eol_type = CODING_EOL_LF;
4557 if (coding->eol_type != CODING_EOL_UNDECIDED)
4559 val = Fget (coding->symbol, Qeol_type);
4560 if (VECTORP (val) && XVECTOR (val)->size == 3)
4561 coding->symbol = XVECTOR (val)->contents[coding->eol_type];
4563 coding->mode |= CODING_MODE_INHIBIT_INCONSISTENT_EOL;
4566 if (coding->eol_type == CODING_EOL_LF
4567 || coding->eol_type == CODING_EOL_UNDECIDED)
4569 /* We have nothing to do. */
4570 ptr = pend;
4572 else if (coding->eol_type == CODING_EOL_CRLF)
4574 unsigned char *pstart = ptr, *p = ptr;
4576 if (! (coding->mode & CODING_MODE_LAST_BLOCK)
4577 && *(pend - 1) == '\r')
4579 /* If the last character is CR, we can't handle it here
4580 because LF will be in the not-yet-decoded source text.
4581 Recorded that the CR is not yet processed. */
4582 coding->spec.ccl.cr_carryover = 1;
4583 coding->produced--;
4584 coding->produced_char--;
4585 pend--;
4587 while (ptr < pend)
4589 if (*ptr == '\r')
4591 if (ptr + 1 < pend && *(ptr + 1) == '\n')
4593 *p++ = '\n';
4594 ptr += 2;
4596 else
4598 if (coding->mode & CODING_MODE_INHIBIT_INCONSISTENT_EOL)
4599 goto undo_eol_conversion;
4600 *p++ = *ptr++;
4603 else if (*ptr == '\n'
4604 && coding->mode & CODING_MODE_INHIBIT_INCONSISTENT_EOL)
4605 goto undo_eol_conversion;
4606 else
4607 *p++ = *ptr++;
4608 continue;
4610 undo_eol_conversion:
4611 /* We have faced with inconsistent EOL format at PTR.
4612 Convert all LFs before PTR back to CRLFs. */
4613 for (p--, ptr--; p >= pstart; p--)
4615 if (*p == '\n')
4616 *ptr-- = '\n', *ptr-- = '\r';
4617 else
4618 *ptr-- = *p;
4620 /* If carryover is recorded, cancel it because we don't
4621 convert CRLF anymore. */
4622 if (coding->spec.ccl.cr_carryover)
4624 coding->spec.ccl.cr_carryover = 0;
4625 coding->produced++;
4626 coding->produced_char++;
4627 pend++;
4629 p = ptr = pend;
4630 coding->eol_type = CODING_EOL_LF;
4631 coding->symbol = saved_coding_symbol;
4633 if (p < pend)
4635 /* As each two-byte sequence CRLF was converted to LF, (PEND
4636 - P) is the number of deleted characters. */
4637 coding->produced -= pend - p;
4638 coding->produced_char -= pend - p;
4641 else /* i.e. coding->eol_type == CODING_EOL_CR */
4643 unsigned char *p = ptr;
4645 for (; ptr < pend; ptr++)
4647 if (*ptr == '\r')
4648 *ptr = '\n';
4649 else if (*ptr == '\n'
4650 && coding->mode & CODING_MODE_INHIBIT_INCONSISTENT_EOL)
4652 for (; p < ptr; p++)
4654 if (*p == '\n')
4655 *p = '\r';
4657 ptr = pend;
4658 coding->eol_type = CODING_EOL_LF;
4659 coding->symbol = saved_coding_symbol;
4665 /* See "GENERAL NOTES about `decode_coding_XXX ()' functions". Before
4666 decoding, it may detect coding system and format of end-of-line if
4667 those are not yet decided. The source should be unibyte, the
4668 result is multibyte if CODING->dst_multibyte is nonzero, else
4669 unibyte. */
4672 decode_coding (coding, source, destination, src_bytes, dst_bytes)
4673 struct coding_system *coding;
4674 unsigned char *source, *destination;
4675 int src_bytes, dst_bytes;
4677 if (coding->type == coding_type_undecided)
4678 detect_coding (coding, source, src_bytes);
4680 if (coding->eol_type == CODING_EOL_UNDECIDED
4681 && coding->type != coding_type_ccl)
4683 detect_eol (coding, source, src_bytes);
4684 /* We had better recover the original eol format if we
4685 encounter an inconsitent eol format while decoding. */
4686 coding->mode |= CODING_MODE_INHIBIT_INCONSISTENT_EOL;
4689 coding->produced = coding->produced_char = 0;
4690 coding->consumed = coding->consumed_char = 0;
4691 coding->errors = 0;
4692 coding->result = CODING_FINISH_NORMAL;
4694 switch (coding->type)
4696 case coding_type_sjis:
4697 decode_coding_sjis_big5 (coding, source, destination,
4698 src_bytes, dst_bytes, 1);
4699 break;
4701 case coding_type_iso2022:
4702 decode_coding_iso2022 (coding, source, destination,
4703 src_bytes, dst_bytes);
4704 break;
4706 case coding_type_big5:
4707 decode_coding_sjis_big5 (coding, source, destination,
4708 src_bytes, dst_bytes, 0);
4709 break;
4711 case coding_type_emacs_mule:
4712 decode_coding_emacs_mule (coding, source, destination,
4713 src_bytes, dst_bytes);
4714 break;
4716 case coding_type_ccl:
4717 if (coding->spec.ccl.cr_carryover)
4719 /* Set the CR which is not processed by the previous call of
4720 decode_eol_post_ccl in DESTINATION. */
4721 *destination = '\r';
4722 coding->produced++;
4723 coding->produced_char++;
4724 dst_bytes--;
4726 ccl_coding_driver (coding, source,
4727 destination + coding->spec.ccl.cr_carryover,
4728 src_bytes, dst_bytes, 0);
4729 if (coding->eol_type != CODING_EOL_LF)
4730 decode_eol_post_ccl (coding, destination, coding->produced);
4731 break;
4733 default:
4734 decode_eol (coding, source, destination, src_bytes, dst_bytes);
4737 if (coding->result == CODING_FINISH_INSUFFICIENT_SRC
4738 && coding->mode & CODING_MODE_LAST_BLOCK
4739 && coding->consumed == src_bytes)
4740 coding->result = CODING_FINISH_NORMAL;
4742 if (coding->mode & CODING_MODE_LAST_BLOCK
4743 && coding->result == CODING_FINISH_INSUFFICIENT_SRC)
4745 unsigned char *src = source + coding->consumed;
4746 unsigned char *dst = destination + coding->produced;
4748 src_bytes -= coding->consumed;
4749 coding->errors++;
4750 if (COMPOSING_P (coding))
4751 DECODE_COMPOSITION_END ('1');
4752 while (src_bytes--)
4754 int c = *src++;
4755 dst += CHAR_STRING (c, dst);
4756 coding->produced_char++;
4758 coding->consumed = coding->consumed_char = src - source;
4759 coding->produced = dst - destination;
4760 coding->result = CODING_FINISH_NORMAL;
4763 if (!coding->dst_multibyte)
4765 coding->produced = str_as_unibyte (destination, coding->produced);
4766 coding->produced_char = coding->produced;
4769 return coding->result;
4772 /* See "GENERAL NOTES about `encode_coding_XXX ()' functions". The
4773 multibyteness of the source is CODING->src_multibyte, the
4774 multibyteness of the result is always unibyte. */
4777 encode_coding (coding, source, destination, src_bytes, dst_bytes)
4778 struct coding_system *coding;
4779 unsigned char *source, *destination;
4780 int src_bytes, dst_bytes;
4782 coding->produced = coding->produced_char = 0;
4783 coding->consumed = coding->consumed_char = 0;
4784 coding->errors = 0;
4785 coding->result = CODING_FINISH_NORMAL;
4787 switch (coding->type)
4789 case coding_type_sjis:
4790 encode_coding_sjis_big5 (coding, source, destination,
4791 src_bytes, dst_bytes, 1);
4792 break;
4794 case coding_type_iso2022:
4795 encode_coding_iso2022 (coding, source, destination,
4796 src_bytes, dst_bytes);
4797 break;
4799 case coding_type_big5:
4800 encode_coding_sjis_big5 (coding, source, destination,
4801 src_bytes, dst_bytes, 0);
4802 break;
4804 case coding_type_emacs_mule:
4805 encode_coding_emacs_mule (coding, source, destination,
4806 src_bytes, dst_bytes);
4807 break;
4809 case coding_type_ccl:
4810 ccl_coding_driver (coding, source, destination,
4811 src_bytes, dst_bytes, 1);
4812 break;
4814 default:
4815 encode_eol (coding, source, destination, src_bytes, dst_bytes);
4818 if (coding->mode & CODING_MODE_LAST_BLOCK
4819 && coding->result == CODING_FINISH_INSUFFICIENT_SRC)
4821 unsigned char *src = source + coding->consumed;
4822 unsigned char *src_end = src + src_bytes;
4823 unsigned char *dst = destination + coding->produced;
4825 if (coding->type == coding_type_iso2022)
4826 ENCODE_RESET_PLANE_AND_REGISTER;
4827 if (COMPOSING_P (coding))
4828 *dst++ = ISO_CODE_ESC, *dst++ = '1';
4829 if (coding->consumed < src_bytes)
4831 int len = src_bytes - coding->consumed;
4833 BCOPY_SHORT (source + coding->consumed, dst, len);
4834 if (coding->src_multibyte)
4835 len = str_as_unibyte (dst, len);
4836 dst += len;
4837 coding->consumed = src_bytes;
4839 coding->produced = coding->produced_char = dst - destination;
4840 coding->result = CODING_FINISH_NORMAL;
4843 if (coding->result == CODING_FINISH_INSUFFICIENT_SRC
4844 && coding->consumed == src_bytes)
4845 coding->result = CODING_FINISH_NORMAL;
4847 return coding->result;
4850 /* Scan text in the region between *BEG and *END (byte positions),
4851 skip characters which we don't have to decode by coding system
4852 CODING at the head and tail, then set *BEG and *END to the region
4853 of the text we actually have to convert. The caller should move
4854 the gap out of the region in advance if the region is from a
4855 buffer.
4857 If STR is not NULL, *BEG and *END are indices into STR. */
4859 static void
4860 shrink_decoding_region (beg, end, coding, str)
4861 int *beg, *end;
4862 struct coding_system *coding;
4863 unsigned char *str;
4865 unsigned char *begp_orig, *begp, *endp_orig, *endp, c;
4866 int eol_conversion;
4867 Lisp_Object translation_table;
4869 if (coding->type == coding_type_ccl
4870 || coding->type == coding_type_undecided
4871 || coding->eol_type != CODING_EOL_LF
4872 || !NILP (coding->post_read_conversion)
4873 || coding->composing != COMPOSITION_DISABLED)
4875 /* We can't skip any data. */
4876 return;
4878 if (coding->type == coding_type_no_conversion
4879 || coding->type == coding_type_raw_text
4880 || coding->type == coding_type_emacs_mule)
4882 /* We need no conversion, but don't have to skip any data here.
4883 Decoding routine handles them effectively anyway. */
4884 return;
4887 translation_table = coding->translation_table_for_decode;
4888 if (NILP (translation_table) && !NILP (Venable_character_translation))
4889 translation_table = Vstandard_translation_table_for_decode;
4890 if (CHAR_TABLE_P (translation_table))
4892 int i;
4893 for (i = 0; i < 128; i++)
4894 if (!NILP (CHAR_TABLE_REF (translation_table, i)))
4895 break;
4896 if (i < 128)
4897 /* Some ASCII character should be translated. We give up
4898 shrinking. */
4899 return;
4902 if (coding->heading_ascii >= 0)
4903 /* Detection routine has already found how much we can skip at the
4904 head. */
4905 *beg += coding->heading_ascii;
4907 if (str)
4909 begp_orig = begp = str + *beg;
4910 endp_orig = endp = str + *end;
4912 else
4914 begp_orig = begp = BYTE_POS_ADDR (*beg);
4915 endp_orig = endp = begp + *end - *beg;
4918 eol_conversion = (coding->eol_type == CODING_EOL_CR
4919 || coding->eol_type == CODING_EOL_CRLF);
4921 switch (coding->type)
4923 case coding_type_sjis:
4924 case coding_type_big5:
4925 /* We can skip all ASCII characters at the head. */
4926 if (coding->heading_ascii < 0)
4928 if (eol_conversion)
4929 while (begp < endp && *begp < 0x80 && *begp != '\r') begp++;
4930 else
4931 while (begp < endp && *begp < 0x80) begp++;
4933 /* We can skip all ASCII characters at the tail except for the
4934 second byte of SJIS or BIG5 code. */
4935 if (eol_conversion)
4936 while (begp < endp && endp[-1] < 0x80 && endp[-1] != '\r') endp--;
4937 else
4938 while (begp < endp && endp[-1] < 0x80) endp--;
4939 /* Do not consider LF as ascii if preceded by CR, since that
4940 confuses eol decoding. */
4941 if (begp < endp && endp < endp_orig && endp[-1] == '\r' && endp[0] == '\n')
4942 endp++;
4943 if (begp < endp && endp < endp_orig && endp[-1] >= 0x80)
4944 endp++;
4945 break;
4947 case coding_type_iso2022:
4948 if (CODING_SPEC_ISO_INITIAL_DESIGNATION (coding, 0) != CHARSET_ASCII)
4949 /* We can't skip any data. */
4950 break;
4951 if (coding->heading_ascii < 0)
4953 /* We can skip all ASCII characters at the head except for a
4954 few control codes. */
4955 while (begp < endp && (c = *begp) < 0x80
4956 && c != ISO_CODE_CR && c != ISO_CODE_SO
4957 && c != ISO_CODE_SI && c != ISO_CODE_ESC
4958 && (!eol_conversion || c != ISO_CODE_LF))
4959 begp++;
4961 switch (coding->category_idx)
4963 case CODING_CATEGORY_IDX_ISO_8_1:
4964 case CODING_CATEGORY_IDX_ISO_8_2:
4965 /* We can skip all ASCII characters at the tail. */
4966 if (eol_conversion)
4967 while (begp < endp && (c = endp[-1]) < 0x80 && c != '\r') endp--;
4968 else
4969 while (begp < endp && endp[-1] < 0x80) endp--;
4970 /* Do not consider LF as ascii if preceded by CR, since that
4971 confuses eol decoding. */
4972 if (begp < endp && endp < endp_orig && endp[-1] == '\r' && endp[0] == '\n')
4973 endp++;
4974 break;
4976 case CODING_CATEGORY_IDX_ISO_7:
4977 case CODING_CATEGORY_IDX_ISO_7_TIGHT:
4979 /* We can skip all charactes at the tail except for 8-bit
4980 codes and ESC and the following 2-byte at the tail. */
4981 unsigned char *eight_bit = NULL;
4983 if (eol_conversion)
4984 while (begp < endp
4985 && (c = endp[-1]) != ISO_CODE_ESC && c != '\r')
4987 if (!eight_bit && c & 0x80) eight_bit = endp;
4988 endp--;
4990 else
4991 while (begp < endp
4992 && (c = endp[-1]) != ISO_CODE_ESC)
4994 if (!eight_bit && c & 0x80) eight_bit = endp;
4995 endp--;
4997 /* Do not consider LF as ascii if preceded by CR, since that
4998 confuses eol decoding. */
4999 if (begp < endp && endp < endp_orig
5000 && endp[-1] == '\r' && endp[0] == '\n')
5001 endp++;
5002 if (begp < endp && endp[-1] == ISO_CODE_ESC)
5004 if (endp + 1 < endp_orig && end[0] == '(' && end[1] == 'B')
5005 /* This is an ASCII designation sequence. We can
5006 surely skip the tail. But, if we have
5007 encountered an 8-bit code, skip only the codes
5008 after that. */
5009 endp = eight_bit ? eight_bit : endp + 2;
5010 else
5011 /* Hmmm, we can't skip the tail. */
5012 endp = endp_orig;
5014 else if (eight_bit)
5015 endp = eight_bit;
5018 break;
5020 default:
5021 abort ();
5023 *beg += begp - begp_orig;
5024 *end += endp - endp_orig;
5025 return;
5028 /* Like shrink_decoding_region but for encoding. */
5030 static void
5031 shrink_encoding_region (beg, end, coding, str)
5032 int *beg, *end;
5033 struct coding_system *coding;
5034 unsigned char *str;
5036 unsigned char *begp_orig, *begp, *endp_orig, *endp;
5037 int eol_conversion;
5038 Lisp_Object translation_table;
5040 if (coding->type == coding_type_ccl
5041 || coding->eol_type == CODING_EOL_CRLF
5042 || coding->eol_type == CODING_EOL_CR
5043 || coding->cmp_data && coding->cmp_data->used > 0)
5045 /* We can't skip any data. */
5046 return;
5048 if (coding->type == coding_type_no_conversion
5049 || coding->type == coding_type_raw_text
5050 || coding->type == coding_type_emacs_mule
5051 || coding->type == coding_type_undecided)
5053 /* We need no conversion, but don't have to skip any data here.
5054 Encoding routine handles them effectively anyway. */
5055 return;
5058 translation_table = coding->translation_table_for_encode;
5059 if (NILP (translation_table) && !NILP (Venable_character_translation))
5060 translation_table = Vstandard_translation_table_for_encode;
5061 if (CHAR_TABLE_P (translation_table))
5063 int i;
5064 for (i = 0; i < 128; i++)
5065 if (!NILP (CHAR_TABLE_REF (translation_table, i)))
5066 break;
5067 if (i < 128)
5068 /* Some ASCII character should be tranlsated. We give up
5069 shrinking. */
5070 return;
5073 if (str)
5075 begp_orig = begp = str + *beg;
5076 endp_orig = endp = str + *end;
5078 else
5080 begp_orig = begp = BYTE_POS_ADDR (*beg);
5081 endp_orig = endp = begp + *end - *beg;
5084 eol_conversion = (coding->eol_type == CODING_EOL_CR
5085 || coding->eol_type == CODING_EOL_CRLF);
5087 /* Here, we don't have to check coding->pre_write_conversion because
5088 the caller is expected to have handled it already. */
5089 switch (coding->type)
5091 case coding_type_iso2022:
5092 if (CODING_SPEC_ISO_INITIAL_DESIGNATION (coding, 0) != CHARSET_ASCII)
5093 /* We can't skip any data. */
5094 break;
5095 if (coding->flags & CODING_FLAG_ISO_DESIGNATE_AT_BOL)
5097 unsigned char *bol = begp;
5098 while (begp < endp && *begp < 0x80)
5100 begp++;
5101 if (begp[-1] == '\n')
5102 bol = begp;
5104 begp = bol;
5105 goto label_skip_tail;
5107 /* fall down ... */
5109 case coding_type_sjis:
5110 case coding_type_big5:
5111 /* We can skip all ASCII characters at the head and tail. */
5112 if (eol_conversion)
5113 while (begp < endp && *begp < 0x80 && *begp != '\n') begp++;
5114 else
5115 while (begp < endp && *begp < 0x80) begp++;
5116 label_skip_tail:
5117 if (eol_conversion)
5118 while (begp < endp && endp[-1] < 0x80 && endp[-1] != '\n') endp--;
5119 else
5120 while (begp < endp && *(endp - 1) < 0x80) endp--;
5121 break;
5123 default:
5124 abort ();
5127 *beg += begp - begp_orig;
5128 *end += endp - endp_orig;
5129 return;
5132 /* As shrinking conversion region requires some overhead, we don't try
5133 shrinking if the length of conversion region is less than this
5134 value. */
5135 static int shrink_conversion_region_threshhold = 1024;
5137 #define SHRINK_CONVERSION_REGION(beg, end, coding, str, encodep) \
5138 do { \
5139 if (*(end) - *(beg) > shrink_conversion_region_threshhold) \
5141 if (encodep) shrink_encoding_region (beg, end, coding, str); \
5142 else shrink_decoding_region (beg, end, coding, str); \
5144 } while (0)
5146 static Lisp_Object
5147 code_convert_region_unwind (dummy)
5148 Lisp_Object dummy;
5150 inhibit_pre_post_conversion = 0;
5151 return Qnil;
5154 /* Store information about all compositions in the range FROM and TO
5155 of OBJ in memory blocks pointed by CODING->cmp_data. OBJ is a
5156 buffer or a string, defaults to the current buffer. */
5158 void
5159 coding_save_composition (coding, from, to, obj)
5160 struct coding_system *coding;
5161 int from, to;
5162 Lisp_Object obj;
5164 Lisp_Object prop;
5165 int start, end;
5167 if (coding->composing == COMPOSITION_DISABLED)
5168 return;
5169 if (!coding->cmp_data)
5170 coding_allocate_composition_data (coding, from);
5171 if (!find_composition (from, to, &start, &end, &prop, obj)
5172 || end > to)
5173 return;
5174 if (start < from
5175 && (!find_composition (end, to, &start, &end, &prop, obj)
5176 || end > to))
5177 return;
5178 coding->composing = COMPOSITION_NO;
5181 if (COMPOSITION_VALID_P (start, end, prop))
5183 enum composition_method method = COMPOSITION_METHOD (prop);
5184 if (coding->cmp_data->used + COMPOSITION_DATA_MAX_BUNCH_LENGTH
5185 >= COMPOSITION_DATA_SIZE)
5186 coding_allocate_composition_data (coding, from);
5187 /* For relative composition, we remember start and end
5188 positions, for the other compositions, we also remember
5189 components. */
5190 CODING_ADD_COMPOSITION_START (coding, start - from, method);
5191 if (method != COMPOSITION_RELATIVE)
5193 /* We must store a*/
5194 Lisp_Object val, ch;
5196 val = COMPOSITION_COMPONENTS (prop);
5197 if (CONSP (val))
5198 while (CONSP (val))
5200 ch = XCAR (val), val = XCDR (val);
5201 CODING_ADD_COMPOSITION_COMPONENT (coding, XINT (ch));
5203 else if (VECTORP (val) || STRINGP (val))
5205 int len = (VECTORP (val)
5206 ? XVECTOR (val)->size : XSTRING (val)->size);
5207 int i;
5208 for (i = 0; i < len; i++)
5210 ch = (STRINGP (val)
5211 ? Faref (val, make_number (i))
5212 : XVECTOR (val)->contents[i]);
5213 CODING_ADD_COMPOSITION_COMPONENT (coding, XINT (ch));
5216 else /* INTEGERP (val) */
5217 CODING_ADD_COMPOSITION_COMPONENT (coding, XINT (val));
5219 CODING_ADD_COMPOSITION_END (coding, end - from);
5221 start = end;
5223 while (start < to
5224 && find_composition (start, to, &start, &end, &prop, obj)
5225 && end <= to);
5227 /* Make coding->cmp_data point to the first memory block. */
5228 while (coding->cmp_data->prev)
5229 coding->cmp_data = coding->cmp_data->prev;
5230 coding->cmp_data_start = 0;
5233 /* Reflect the saved information about compositions to OBJ.
5234 CODING->cmp_data points to a memory block for the informaiton. OBJ
5235 is a buffer or a string, defaults to the current buffer. */
5237 void
5238 coding_restore_composition (coding, obj)
5239 struct coding_system *coding;
5240 Lisp_Object obj;
5242 struct composition_data *cmp_data = coding->cmp_data;
5244 if (!cmp_data)
5245 return;
5247 while (cmp_data->prev)
5248 cmp_data = cmp_data->prev;
5250 while (cmp_data)
5252 int i;
5254 for (i = 0; i < cmp_data->used && cmp_data->data[i] > 0;
5255 i += cmp_data->data[i])
5257 int *data = cmp_data->data + i;
5258 enum composition_method method = (enum composition_method) data[3];
5259 Lisp_Object components;
5261 if (method == COMPOSITION_RELATIVE)
5262 components = Qnil;
5263 else
5265 int len = data[0] - 4, j;
5266 Lisp_Object args[MAX_COMPOSITION_COMPONENTS * 2 - 1];
5268 for (j = 0; j < len; j++)
5269 args[j] = make_number (data[4 + j]);
5270 components = (method == COMPOSITION_WITH_ALTCHARS
5271 ? Fstring (len, args) : Fvector (len, args));
5273 compose_text (data[1], data[2], components, Qnil, obj);
5275 cmp_data = cmp_data->next;
5279 /* Decode (if ENCODEP is zero) or encode (if ENCODEP is nonzero) the
5280 text from FROM to TO (byte positions are FROM_BYTE and TO_BYTE) by
5281 coding system CODING, and return the status code of code conversion
5282 (currently, this value has no meaning).
5284 How many characters (and bytes) are converted to how many
5285 characters (and bytes) are recorded in members of the structure
5286 CODING.
5288 If REPLACE is nonzero, we do various things as if the original text
5289 is deleted and a new text is inserted. See the comments in
5290 replace_range (insdel.c) to know what we are doing.
5292 If REPLACE is zero, it is assumed that the source text is unibyte.
5293 Otherwize, it is assumed that the source text is multibyte. */
5296 code_convert_region (from, from_byte, to, to_byte, coding, encodep, replace)
5297 int from, from_byte, to, to_byte, encodep, replace;
5298 struct coding_system *coding;
5300 int len = to - from, len_byte = to_byte - from_byte;
5301 int require, inserted, inserted_byte;
5302 int head_skip, tail_skip, total_skip = 0;
5303 Lisp_Object saved_coding_symbol;
5304 int first = 1;
5305 unsigned char *src, *dst;
5306 Lisp_Object deletion;
5307 int orig_point = PT, orig_len = len;
5308 int prev_Z;
5309 int multibyte_p = !NILP (current_buffer->enable_multibyte_characters);
5311 deletion = Qnil;
5312 saved_coding_symbol = coding->symbol;
5314 if (from < PT && PT < to)
5316 TEMP_SET_PT_BOTH (from, from_byte);
5317 orig_point = from;
5320 if (replace)
5322 int saved_from = from;
5323 int saved_inhibit_modification_hooks;
5325 prepare_to_modify_buffer (from, to, &from);
5326 if (saved_from != from)
5328 to = from + len;
5329 from_byte = CHAR_TO_BYTE (from), to_byte = CHAR_TO_BYTE (to);
5330 len_byte = to_byte - from_byte;
5333 /* The code conversion routine can not preserve text properties
5334 for now. So, we must remove all text properties in the
5335 region. Here, we must suppress all modification hooks. */
5336 saved_inhibit_modification_hooks = inhibit_modification_hooks;
5337 inhibit_modification_hooks = 1;
5338 Fset_text_properties (make_number (from), make_number (to), Qnil, Qnil);
5339 inhibit_modification_hooks = saved_inhibit_modification_hooks;
5342 if (! encodep && CODING_REQUIRE_DETECTION (coding))
5344 /* We must detect encoding of text and eol format. */
5346 if (from < GPT && to > GPT)
5347 move_gap_both (from, from_byte);
5348 if (coding->type == coding_type_undecided)
5350 detect_coding (coding, BYTE_POS_ADDR (from_byte), len_byte);
5351 if (coding->type == coding_type_undecided)
5353 /* It seems that the text contains only ASCII, but we
5354 should not leave it undecided because the deeper
5355 decoding routine (decode_coding) tries to detect the
5356 encodings again in vain. */
5357 coding->type = coding_type_emacs_mule;
5358 coding->category_idx = CODING_CATEGORY_IDX_EMACS_MULE;
5361 if (coding->eol_type == CODING_EOL_UNDECIDED
5362 && coding->type != coding_type_ccl)
5364 detect_eol (coding, BYTE_POS_ADDR (from_byte), len_byte);
5365 if (coding->eol_type == CODING_EOL_UNDECIDED)
5366 coding->eol_type = CODING_EOL_LF;
5367 /* We had better recover the original eol format if we
5368 encounter an inconsitent eol format while decoding. */
5369 coding->mode |= CODING_MODE_INHIBIT_INCONSISTENT_EOL;
5373 /* Now we convert the text. */
5375 /* For encoding, we must process pre-write-conversion in advance. */
5376 if (! inhibit_pre_post_conversion
5377 && encodep
5378 && SYMBOLP (coding->pre_write_conversion)
5379 && ! NILP (Ffboundp (coding->pre_write_conversion)))
5381 /* The function in pre-write-conversion may put a new text in a
5382 new buffer. */
5383 struct buffer *prev = current_buffer;
5384 Lisp_Object new;
5385 int count = specpdl_ptr - specpdl;
5387 record_unwind_protect (code_convert_region_unwind, Qnil);
5388 /* We should not call any more pre-write/post-read-conversion
5389 functions while this pre-write-conversion is running. */
5390 inhibit_pre_post_conversion = 1;
5391 call2 (coding->pre_write_conversion,
5392 make_number (from), make_number (to));
5393 inhibit_pre_post_conversion = 0;
5394 /* Discard the unwind protect. */
5395 specpdl_ptr--;
5397 if (current_buffer != prev)
5399 len = ZV - BEGV;
5400 new = Fcurrent_buffer ();
5401 set_buffer_internal_1 (prev);
5402 del_range_2 (from, from_byte, to, to_byte, 0);
5403 TEMP_SET_PT_BOTH (from, from_byte);
5404 insert_from_buffer (XBUFFER (new), 1, len, 0);
5405 Fkill_buffer (new);
5406 if (orig_point >= to)
5407 orig_point += len - orig_len;
5408 else if (orig_point > from)
5409 orig_point = from;
5410 orig_len = len;
5411 to = from + len;
5412 from_byte = CHAR_TO_BYTE (from);
5413 to_byte = CHAR_TO_BYTE (to);
5414 len_byte = to_byte - from_byte;
5415 TEMP_SET_PT_BOTH (from, from_byte);
5419 if (replace)
5420 deletion = make_buffer_string_both (from, from_byte, to, to_byte, 1);
5422 if (coding->composing != COMPOSITION_DISABLED)
5424 if (encodep)
5425 coding_save_composition (coding, from, to, Fcurrent_buffer ());
5426 else
5427 coding_allocate_composition_data (coding, from);
5430 /* Try to skip the heading and tailing ASCIIs. */
5431 if (coding->type != coding_type_ccl)
5433 int from_byte_orig = from_byte, to_byte_orig = to_byte;
5435 if (from < GPT && GPT < to)
5436 move_gap_both (from, from_byte);
5437 SHRINK_CONVERSION_REGION (&from_byte, &to_byte, coding, NULL, encodep);
5438 if (from_byte == to_byte
5439 && (encodep || NILP (coding->post_read_conversion))
5440 && ! CODING_REQUIRE_FLUSHING (coding))
5442 coding->produced = len_byte;
5443 coding->produced_char = len;
5444 if (!replace)
5445 /* We must record and adjust for this new text now. */
5446 adjust_after_insert (from, from_byte_orig, to, to_byte_orig, len);
5447 return 0;
5450 head_skip = from_byte - from_byte_orig;
5451 tail_skip = to_byte_orig - to_byte;
5452 total_skip = head_skip + tail_skip;
5453 from += head_skip;
5454 to -= tail_skip;
5455 len -= total_skip; len_byte -= total_skip;
5458 /* For converion, we must put the gap before the text in addition to
5459 making the gap larger for efficient decoding. The required gap
5460 size starts from 2000 which is the magic number used in make_gap.
5461 But, after one batch of conversion, it will be incremented if we
5462 find that it is not enough . */
5463 require = 2000;
5465 if (GAP_SIZE < require)
5466 make_gap (require - GAP_SIZE);
5467 move_gap_both (from, from_byte);
5469 inserted = inserted_byte = 0;
5471 GAP_SIZE += len_byte;
5472 ZV -= len;
5473 Z -= len;
5474 ZV_BYTE -= len_byte;
5475 Z_BYTE -= len_byte;
5477 if (GPT - BEG < BEG_UNCHANGED)
5478 BEG_UNCHANGED = GPT - BEG;
5479 if (Z - GPT < END_UNCHANGED)
5480 END_UNCHANGED = Z - GPT;
5482 if (!encodep && coding->src_multibyte)
5484 /* Decoding routines expects that the source text is unibyte.
5485 We must convert 8-bit characters of multibyte form to
5486 unibyte. */
5487 int len_byte_orig = len_byte;
5488 len_byte = str_as_unibyte (GAP_END_ADDR - len_byte, len_byte);
5489 if (len_byte < len_byte_orig)
5490 safe_bcopy (GAP_END_ADDR - len_byte_orig, GAP_END_ADDR - len_byte,
5491 len_byte);
5492 coding->src_multibyte = 0;
5495 for (;;)
5497 int result;
5499 /* The buffer memory is now:
5500 +--------+converted-text+---------+-------original-text-------+---+
5501 |<-from->|<--inserted-->|---------|<--------len_byte--------->|---|
5502 |<---------------------- GAP ----------------------->| */
5503 src = GAP_END_ADDR - len_byte;
5504 dst = GPT_ADDR + inserted_byte;
5506 if (encodep)
5507 result = encode_coding (coding, src, dst, len_byte, 0);
5508 else
5509 result = decode_coding (coding, src, dst, len_byte, 0);
5511 /* The buffer memory is now:
5512 +--------+-------converted-text----+--+------original-text----+---+
5513 |<-from->|<-inserted->|<-produced->|--|<-(len_byte-consumed)->|---|
5514 |<---------------------- GAP ----------------------->| */
5516 inserted += coding->produced_char;
5517 inserted_byte += coding->produced;
5518 len_byte -= coding->consumed;
5520 if (result == CODING_FINISH_INSUFFICIENT_CMP)
5522 coding_allocate_composition_data (coding, from + inserted);
5523 continue;
5526 src += coding->consumed;
5527 dst += coding->produced;
5529 if (result == CODING_FINISH_NORMAL)
5531 src += len_byte;
5532 break;
5534 if (! encodep && result == CODING_FINISH_INCONSISTENT_EOL)
5536 unsigned char *pend = dst, *p = pend - inserted_byte;
5537 Lisp_Object eol_type;
5539 /* Encode LFs back to the original eol format (CR or CRLF). */
5540 if (coding->eol_type == CODING_EOL_CR)
5542 while (p < pend) if (*p++ == '\n') p[-1] = '\r';
5544 else
5546 int count = 0;
5548 while (p < pend) if (*p++ == '\n') count++;
5549 if (src - dst < count)
5551 /* We don't have sufficient room for encoding LFs
5552 back to CRLF. We must record converted and
5553 not-yet-converted text back to the buffer
5554 content, enlarge the gap, then record them out of
5555 the buffer contents again. */
5556 int add = len_byte + inserted_byte;
5558 GAP_SIZE -= add;
5559 ZV += add; Z += add; ZV_BYTE += add; Z_BYTE += add;
5560 GPT += inserted_byte; GPT_BYTE += inserted_byte;
5561 make_gap (count - GAP_SIZE);
5562 GAP_SIZE += add;
5563 ZV -= add; Z -= add; ZV_BYTE -= add; Z_BYTE -= add;
5564 GPT -= inserted_byte; GPT_BYTE -= inserted_byte;
5565 /* Don't forget to update SRC, DST, and PEND. */
5566 src = GAP_END_ADDR - len_byte;
5567 dst = GPT_ADDR + inserted_byte;
5568 pend = dst;
5570 inserted += count;
5571 inserted_byte += count;
5572 coding->produced += count;
5573 p = dst = pend + count;
5574 while (count)
5576 *--p = *--pend;
5577 if (*p == '\n') count--, *--p = '\r';
5581 /* Suppress eol-format conversion in the further conversion. */
5582 coding->eol_type = CODING_EOL_LF;
5584 /* Set the coding system symbol to that for Unix-like EOL. */
5585 eol_type = Fget (saved_coding_symbol, Qeol_type);
5586 if (VECTORP (eol_type)
5587 && XVECTOR (eol_type)->size == 3
5588 && SYMBOLP (XVECTOR (eol_type)->contents[CODING_EOL_LF]))
5589 coding->symbol = XVECTOR (eol_type)->contents[CODING_EOL_LF];
5590 else
5591 coding->symbol = saved_coding_symbol;
5593 continue;
5595 if (len_byte <= 0)
5597 if (coding->type != coding_type_ccl
5598 || coding->mode & CODING_MODE_LAST_BLOCK)
5599 break;
5600 coding->mode |= CODING_MODE_LAST_BLOCK;
5601 continue;
5603 if (result == CODING_FINISH_INSUFFICIENT_SRC)
5605 /* The source text ends in invalid codes. Let's just
5606 make them valid buffer contents, and finish conversion. */
5607 inserted += len_byte;
5608 inserted_byte += len_byte;
5609 while (len_byte--)
5610 *dst++ = *src++;
5611 break;
5613 if (result == CODING_FINISH_INTERRUPT)
5615 /* The conversion procedure was interrupted by a user. */
5616 break;
5618 /* Now RESULT == CODING_FINISH_INSUFFICIENT_DST */
5619 if (coding->consumed < 1)
5621 /* It's quite strange to require more memory without
5622 consuming any bytes. Perhaps CCL program bug. */
5623 break;
5625 if (first)
5627 /* We have just done the first batch of conversion which was
5628 stoped because of insufficient gap. Let's reconsider the
5629 required gap size (i.e. SRT - DST) now.
5631 We have converted ORIG bytes (== coding->consumed) into
5632 NEW bytes (coding->produced). To convert the remaining
5633 LEN bytes, we may need REQUIRE bytes of gap, where:
5634 REQUIRE + LEN_BYTE = LEN_BYTE * (NEW / ORIG)
5635 REQUIRE = LEN_BYTE * (NEW - ORIG) / ORIG
5636 Here, we are sure that NEW >= ORIG. */
5637 float ratio = coding->produced - coding->consumed;
5638 ratio /= coding->consumed;
5639 require = len_byte * ratio;
5640 first = 0;
5642 if ((src - dst) < (require + 2000))
5644 /* See the comment above the previous call of make_gap. */
5645 int add = len_byte + inserted_byte;
5647 GAP_SIZE -= add;
5648 ZV += add; Z += add; ZV_BYTE += add; Z_BYTE += add;
5649 GPT += inserted_byte; GPT_BYTE += inserted_byte;
5650 make_gap (require + 2000);
5651 GAP_SIZE += add;
5652 ZV -= add; Z -= add; ZV_BYTE -= add; Z_BYTE -= add;
5653 GPT -= inserted_byte; GPT_BYTE -= inserted_byte;
5656 if (src - dst > 0) *dst = 0; /* Put an anchor. */
5658 if (encodep && coding->dst_multibyte)
5660 /* The output is unibyte. We must convert 8-bit characters to
5661 multibyte form. */
5662 if (inserted_byte * 2 > GAP_SIZE)
5664 GAP_SIZE -= inserted_byte;
5665 ZV += inserted_byte; Z += inserted_byte;
5666 ZV_BYTE += inserted_byte; Z_BYTE += inserted_byte;
5667 GPT += inserted_byte; GPT_BYTE += inserted_byte;
5668 make_gap (inserted_byte - GAP_SIZE);
5669 GAP_SIZE += inserted_byte;
5670 ZV -= inserted_byte; Z -= inserted_byte;
5671 ZV_BYTE -= inserted_byte; Z_BYTE -= inserted_byte;
5672 GPT -= inserted_byte; GPT_BYTE -= inserted_byte;
5674 inserted_byte = str_to_multibyte (GPT_ADDR, GAP_SIZE, inserted_byte);
5677 /* If we have shrinked the conversion area, adjust it now. */
5678 if (total_skip > 0)
5680 if (tail_skip > 0)
5681 safe_bcopy (GAP_END_ADDR, GPT_ADDR + inserted_byte, tail_skip);
5682 inserted += total_skip; inserted_byte += total_skip;
5683 GAP_SIZE += total_skip;
5684 GPT -= head_skip; GPT_BYTE -= head_skip;
5685 ZV -= total_skip; ZV_BYTE -= total_skip;
5686 Z -= total_skip; Z_BYTE -= total_skip;
5687 from -= head_skip; from_byte -= head_skip;
5688 to += tail_skip; to_byte += tail_skip;
5691 prev_Z = Z;
5692 adjust_after_replace (from, from_byte, deletion, inserted, inserted_byte);
5693 inserted = Z - prev_Z;
5695 if (!encodep && coding->cmp_data && coding->cmp_data->used)
5696 coding_restore_composition (coding, Fcurrent_buffer ());
5697 coding_free_composition_data (coding);
5699 if (! inhibit_pre_post_conversion
5700 && ! encodep && ! NILP (coding->post_read_conversion))
5702 Lisp_Object val;
5703 int count = specpdl_ptr - specpdl;
5705 if (from != PT)
5706 TEMP_SET_PT_BOTH (from, from_byte);
5707 prev_Z = Z;
5708 record_unwind_protect (code_convert_region_unwind, Qnil);
5709 /* We should not call any more pre-write/post-read-conversion
5710 functions while this post-read-conversion is running. */
5711 inhibit_pre_post_conversion = 1;
5712 val = call1 (coding->post_read_conversion, make_number (inserted));
5713 inhibit_pre_post_conversion = 0;
5714 /* Discard the unwind protect. */
5715 specpdl_ptr--;
5716 CHECK_NUMBER (val, 0);
5717 inserted += Z - prev_Z;
5720 if (orig_point >= from)
5722 if (orig_point >= from + orig_len)
5723 orig_point += inserted - orig_len;
5724 else
5725 orig_point = from;
5726 TEMP_SET_PT (orig_point);
5729 if (replace)
5731 signal_after_change (from, to - from, inserted);
5732 update_compositions (from, from + inserted, CHECK_BORDER);
5736 coding->consumed = to_byte - from_byte;
5737 coding->consumed_char = to - from;
5738 coding->produced = inserted_byte;
5739 coding->produced_char = inserted;
5742 return 0;
5745 Lisp_Object
5746 run_pre_post_conversion_on_str (str, coding, encodep)
5747 Lisp_Object str;
5748 struct coding_system *coding;
5749 int encodep;
5751 int count = specpdl_ptr - specpdl;
5752 struct gcpro gcpro1;
5753 int multibyte = STRING_MULTIBYTE (str);
5755 record_unwind_protect (Fset_buffer, Fcurrent_buffer ());
5756 record_unwind_protect (code_convert_region_unwind, Qnil);
5757 GCPRO1 (str);
5758 temp_output_buffer_setup (" *code-converting-work*");
5759 set_buffer_internal (XBUFFER (Vstandard_output));
5760 /* We must insert the contents of STR as is without
5761 unibyte<->multibyte conversion. For that, we adjust the
5762 multibyteness of the working buffer to that of STR. */
5763 Ferase_buffer ();
5764 current_buffer->enable_multibyte_characters = multibyte ? Qt : Qnil;
5765 insert_from_string (str, 0, 0,
5766 XSTRING (str)->size, STRING_BYTES (XSTRING (str)), 0);
5767 UNGCPRO;
5768 inhibit_pre_post_conversion = 1;
5769 if (encodep)
5770 call2 (coding->pre_write_conversion, make_number (BEG), make_number (Z));
5771 else
5773 TEMP_SET_PT_BOTH (BEG, BEG_BYTE);
5774 call1 (coding->post_read_conversion, make_number (Z - BEG));
5776 inhibit_pre_post_conversion = 0;
5777 str = make_buffer_string (BEG, Z, 1);
5778 return unbind_to (count, str);
5781 Lisp_Object
5782 decode_coding_string (str, coding, nocopy)
5783 Lisp_Object str;
5784 struct coding_system *coding;
5785 int nocopy;
5787 int len;
5788 struct conversion_buffer buf;
5789 int from, to_byte;
5790 struct gcpro gcpro1;
5791 Lisp_Object saved_coding_symbol;
5792 int result;
5793 int require_decoding;
5794 int shrinked_bytes = 0;
5795 Lisp_Object newstr;
5796 int consumed, consumed_char, produced, produced_char;
5798 from = 0;
5799 to_byte = STRING_BYTES (XSTRING (str));
5801 saved_coding_symbol = coding->symbol;
5802 coding->src_multibyte = STRING_MULTIBYTE (str);
5803 coding->dst_multibyte = 1;
5804 if (CODING_REQUIRE_DETECTION (coding))
5806 /* See the comments in code_convert_region. */
5807 if (coding->type == coding_type_undecided)
5809 detect_coding (coding, XSTRING (str)->data, to_byte);
5810 if (coding->type == coding_type_undecided)
5811 coding->type = coding_type_emacs_mule;
5813 if (coding->eol_type == CODING_EOL_UNDECIDED
5814 && coding->type != coding_type_ccl)
5816 saved_coding_symbol = coding->symbol;
5817 detect_eol (coding, XSTRING (str)->data, to_byte);
5818 if (coding->eol_type == CODING_EOL_UNDECIDED)
5819 coding->eol_type = CODING_EOL_LF;
5820 /* We had better recover the original eol format if we
5821 encounter an inconsitent eol format while decoding. */
5822 coding->mode |= CODING_MODE_INHIBIT_INCONSISTENT_EOL;
5826 if (coding->type == coding_type_no_conversion
5827 || coding->type == coding_type_raw_text)
5828 coding->dst_multibyte = 0;
5830 require_decoding = CODING_REQUIRE_DECODING (coding);
5832 if (STRING_MULTIBYTE (str))
5834 /* Decoding routines expect the source text to be unibyte. */
5835 str = Fstring_as_unibyte (str);
5836 to_byte = STRING_BYTES (XSTRING (str));
5837 nocopy = 1;
5838 coding->src_multibyte = 0;
5841 /* Try to skip the heading and tailing ASCIIs. */
5842 if (require_decoding && coding->type != coding_type_ccl)
5844 SHRINK_CONVERSION_REGION (&from, &to_byte, coding, XSTRING (str)->data,
5846 if (from == to_byte)
5847 require_decoding = 0;
5848 shrinked_bytes = from + (STRING_BYTES (XSTRING (str)) - to_byte);
5851 if (!require_decoding)
5853 coding->consumed = STRING_BYTES (XSTRING (str));
5854 coding->consumed_char = XSTRING (str)->size;
5855 if (coding->dst_multibyte)
5857 str = Fstring_as_multibyte (str);
5858 nocopy = 1;
5860 coding->produced = STRING_BYTES (XSTRING (str));
5861 coding->produced_char = XSTRING (str)->size;
5862 return (nocopy ? str : Fcopy_sequence (str));
5865 if (coding->composing != COMPOSITION_DISABLED)
5866 coding_allocate_composition_data (coding, from);
5867 len = decoding_buffer_size (coding, to_byte - from);
5868 allocate_conversion_buffer (buf, len);
5870 consumed = consumed_char = produced = produced_char = 0;
5871 while (1)
5873 result = decode_coding (coding, XSTRING (str)->data + from + consumed,
5874 buf.data + produced, to_byte - from - consumed,
5875 buf.size - produced);
5876 consumed += coding->consumed;
5877 consumed_char += coding->consumed_char;
5878 produced += coding->produced;
5879 produced_char += coding->produced_char;
5880 if (result == CODING_FINISH_NORMAL
5881 || (result == CODING_FINISH_INSUFFICIENT_SRC
5882 && coding->consumed == 0))
5883 break;
5884 if (result == CODING_FINISH_INSUFFICIENT_CMP)
5885 coding_allocate_composition_data (coding, from + produced_char);
5886 else if (result == CODING_FINISH_INSUFFICIENT_DST)
5887 extend_conversion_buffer (&buf);
5888 else if (result == CODING_FINISH_INCONSISTENT_EOL)
5890 Lisp_Object eol_type;
5892 /* Recover the original EOL format. */
5893 if (coding->eol_type == CODING_EOL_CR)
5895 unsigned char *p;
5896 for (p = buf.data; p < buf.data + produced; p++)
5897 if (*p == '\n') *p = '\r';
5899 else if (coding->eol_type == CODING_EOL_CRLF)
5901 int num_eol = 0;
5902 unsigned char *p0, *p1;
5903 for (p0 = buf.data, p1 = p0 + produced; p0 < p1; p0++)
5904 if (*p0 == '\n') num_eol++;
5905 if (produced + num_eol >= buf.size)
5906 extend_conversion_buffer (&buf);
5907 for (p0 = buf.data + produced, p1 = p0 + num_eol; p0 > buf.data;)
5909 *--p1 = *--p0;
5910 if (*p0 == '\n') *--p1 = '\r';
5912 produced += num_eol;
5913 produced_char += num_eol;
5915 /* Suppress eol-format conversion in the further conversion. */
5916 coding->eol_type = CODING_EOL_LF;
5918 /* Set the coding system symbol to that for Unix-like EOL. */
5919 eol_type = Fget (saved_coding_symbol, Qeol_type);
5920 if (VECTORP (eol_type)
5921 && XVECTOR (eol_type)->size == 3
5922 && SYMBOLP (XVECTOR (eol_type)->contents[CODING_EOL_LF]))
5923 coding->symbol = XVECTOR (eol_type)->contents[CODING_EOL_LF];
5924 else
5925 coding->symbol = saved_coding_symbol;
5931 coding->consumed = consumed;
5932 coding->consumed_char = consumed_char;
5933 coding->produced = produced;
5934 coding->produced_char = produced_char;
5936 if (coding->dst_multibyte)
5937 newstr = make_uninit_multibyte_string (produced_char + shrinked_bytes,
5938 produced + shrinked_bytes);
5939 else
5940 newstr = make_uninit_string (produced + shrinked_bytes);
5941 if (from > 0)
5942 bcopy (XSTRING (str)->data, XSTRING (newstr)->data, from);
5943 bcopy (buf.data, XSTRING (newstr)->data + from, produced);
5944 if (shrinked_bytes > from)
5945 bcopy (XSTRING (str)->data + to_byte,
5946 XSTRING (newstr)->data + from + produced,
5947 shrinked_bytes - from);
5948 free_conversion_buffer (&buf);
5950 if (coding->cmp_data && coding->cmp_data->used)
5951 coding_restore_composition (coding, newstr);
5952 coding_free_composition_data (coding);
5954 if (SYMBOLP (coding->post_read_conversion)
5955 && !NILP (Ffboundp (coding->post_read_conversion)))
5956 newstr = run_pre_post_conversion_on_str (newstr, coding, 0);
5958 return newstr;
5961 Lisp_Object
5962 encode_coding_string (str, coding, nocopy)
5963 Lisp_Object str;
5964 struct coding_system *coding;
5965 int nocopy;
5967 int len;
5968 struct conversion_buffer buf;
5969 int from, to, to_byte;
5970 int result;
5971 int shrinked_bytes = 0;
5972 Lisp_Object newstr;
5973 int consumed, consumed_char, produced, produced_char;
5975 if (SYMBOLP (coding->pre_write_conversion)
5976 && !NILP (Ffboundp (coding->pre_write_conversion)))
5977 str = run_pre_post_conversion_on_str (str, coding, 1);
5979 from = 0;
5980 to = XSTRING (str)->size;
5981 to_byte = STRING_BYTES (XSTRING (str));
5983 /* Encoding routines determine the multibyteness of the source text
5984 by coding->src_multibyte. */
5985 coding->src_multibyte = STRING_MULTIBYTE (str);
5986 coding->dst_multibyte = 0;
5987 if (! CODING_REQUIRE_ENCODING (coding))
5989 coding->consumed = STRING_BYTES (XSTRING (str));
5990 coding->consumed_char = XSTRING (str)->size;
5991 if (STRING_MULTIBYTE (str))
5993 str = Fstring_as_unibyte (str);
5994 nocopy = 1;
5996 coding->produced = STRING_BYTES (XSTRING (str));
5997 coding->produced_char = XSTRING (str)->size;
5998 return (nocopy ? str : Fcopy_sequence (str));
6001 if (coding->composing != COMPOSITION_DISABLED)
6002 coding_save_composition (coding, from, to, str);
6004 /* Try to skip the heading and tailing ASCIIs. */
6005 if (coding->type != coding_type_ccl)
6007 SHRINK_CONVERSION_REGION (&from, &to_byte, coding, XSTRING (str)->data,
6009 if (from == to_byte)
6010 return (nocopy ? str : Fcopy_sequence (str));
6011 shrinked_bytes = from + (STRING_BYTES (XSTRING (str)) - to_byte);
6014 len = encoding_buffer_size (coding, to_byte - from);
6015 allocate_conversion_buffer (buf, len);
6017 consumed = consumed_char = produced = produced_char = 0;
6018 while (1)
6020 result = encode_coding (coding, XSTRING (str)->data + from + consumed,
6021 buf.data + produced, to_byte - from - consumed,
6022 buf.size - produced);
6023 consumed += coding->consumed;
6024 consumed_char += coding->consumed_char;
6025 produced += coding->produced;
6026 produced_char += coding->produced_char;
6027 if (result == CODING_FINISH_NORMAL
6028 || (result == CODING_FINISH_INSUFFICIENT_SRC
6029 && coding->consumed == 0))
6030 break;
6031 /* Now result should be CODING_FINISH_INSUFFICIENT_DST. */
6032 extend_conversion_buffer (&buf);
6035 coding->consumed = consumed;
6036 coding->consumed_char = consumed_char;
6037 coding->produced = produced;
6038 coding->produced_char = produced_char;
6040 newstr = make_uninit_string (produced + shrinked_bytes);
6041 if (from > 0)
6042 bcopy (XSTRING (str)->data, XSTRING (newstr)->data, from);
6043 bcopy (buf.data, XSTRING (newstr)->data + from, produced);
6044 if (shrinked_bytes > from)
6045 bcopy (XSTRING (str)->data + to_byte,
6046 XSTRING (newstr)->data + from + produced,
6047 shrinked_bytes - from);
6049 free_conversion_buffer (&buf);
6050 coding_free_composition_data (coding);
6052 return newstr;
6056 #ifdef emacs
6057 /*** 8. Emacs Lisp library functions ***/
6059 DEFUN ("coding-system-p", Fcoding_system_p, Scoding_system_p, 1, 1, 0,
6060 "Return t if OBJECT is nil or a coding-system.\n\
6061 See the documentation of `make-coding-system' for information\n\
6062 about coding-system objects.")
6063 (obj)
6064 Lisp_Object obj;
6066 if (NILP (obj))
6067 return Qt;
6068 if (!SYMBOLP (obj))
6069 return Qnil;
6070 /* Get coding-spec vector for OBJ. */
6071 obj = Fget (obj, Qcoding_system);
6072 return ((VECTORP (obj) && XVECTOR (obj)->size == 5)
6073 ? Qt : Qnil);
6076 DEFUN ("read-non-nil-coding-system", Fread_non_nil_coding_system,
6077 Sread_non_nil_coding_system, 1, 1, 0,
6078 "Read a coding system from the minibuffer, prompting with string PROMPT.")
6079 (prompt)
6080 Lisp_Object prompt;
6082 Lisp_Object val;
6085 val = Fcompleting_read (prompt, Vcoding_system_alist, Qnil,
6086 Qt, Qnil, Qcoding_system_history, Qnil, Qnil);
6088 while (XSTRING (val)->size == 0);
6089 return (Fintern (val, Qnil));
6092 DEFUN ("read-coding-system", Fread_coding_system, Sread_coding_system, 1, 2, 0,
6093 "Read a coding system from the minibuffer, prompting with string PROMPT.\n\
6094 If the user enters null input, return second argument DEFAULT-CODING-SYSTEM.")
6095 (prompt, default_coding_system)
6096 Lisp_Object prompt, default_coding_system;
6098 Lisp_Object val;
6099 if (SYMBOLP (default_coding_system))
6100 XSETSTRING (default_coding_system, XSYMBOL (default_coding_system)->name);
6101 val = Fcompleting_read (prompt, Vcoding_system_alist, Qnil,
6102 Qt, Qnil, Qcoding_system_history,
6103 default_coding_system, Qnil);
6104 return (XSTRING (val)->size == 0 ? Qnil : Fintern (val, Qnil));
6107 DEFUN ("check-coding-system", Fcheck_coding_system, Scheck_coding_system,
6108 1, 1, 0,
6109 "Check validity of CODING-SYSTEM.\n\
6110 If valid, return CODING-SYSTEM, else signal a `coding-system-error' error.\n\
6111 It is valid if it is a symbol with a non-nil `coding-system' property.\n\
6112 The value of property should be a vector of length 5.")
6113 (coding_system)
6114 Lisp_Object coding_system;
6116 CHECK_SYMBOL (coding_system, 0);
6117 if (!NILP (Fcoding_system_p (coding_system)))
6118 return coding_system;
6119 while (1)
6120 Fsignal (Qcoding_system_error, Fcons (coding_system, Qnil));
6123 Lisp_Object
6124 detect_coding_system (src, src_bytes, highest, multibytep)
6125 unsigned char *src;
6126 int src_bytes, highest;
6127 int multibytep;
6129 int coding_mask, eol_type;
6130 Lisp_Object val, tmp;
6131 int dummy;
6133 coding_mask = detect_coding_mask (src, src_bytes, NULL, &dummy, multibytep);
6134 eol_type = detect_eol_type (src, src_bytes, &dummy);
6135 if (eol_type == CODING_EOL_INCONSISTENT)
6136 eol_type = CODING_EOL_UNDECIDED;
6138 if (!coding_mask)
6140 val = Qundecided;
6141 if (eol_type != CODING_EOL_UNDECIDED)
6143 Lisp_Object val2;
6144 val2 = Fget (Qundecided, Qeol_type);
6145 if (VECTORP (val2))
6146 val = XVECTOR (val2)->contents[eol_type];
6148 return (highest ? val : Fcons (val, Qnil));
6151 /* At first, gather possible coding systems in VAL. */
6152 val = Qnil;
6153 for (tmp = Vcoding_category_list; CONSP (tmp); tmp = XCDR (tmp))
6155 Lisp_Object category_val, category_index;
6157 category_index = Fget (XCAR (tmp), Qcoding_category_index);
6158 category_val = Fsymbol_value (XCAR (tmp));
6159 if (!NILP (category_val)
6160 && NATNUMP (category_index)
6161 && (coding_mask & (1 << XFASTINT (category_index))))
6163 val = Fcons (category_val, val);
6164 if (highest)
6165 break;
6168 if (!highest)
6169 val = Fnreverse (val);
6171 /* Then, replace the elements with subsidiary coding systems. */
6172 for (tmp = val; CONSP (tmp); tmp = XCDR (tmp))
6174 if (eol_type != CODING_EOL_UNDECIDED
6175 && eol_type != CODING_EOL_INCONSISTENT)
6177 Lisp_Object eol;
6178 eol = Fget (XCAR (tmp), Qeol_type);
6179 if (VECTORP (eol))
6180 XCAR (tmp) = XVECTOR (eol)->contents[eol_type];
6183 return (highest ? XCAR (val) : val);
6186 DEFUN ("detect-coding-region", Fdetect_coding_region, Sdetect_coding_region,
6187 2, 3, 0,
6188 "Detect coding system of the text in the region between START and END.\n\
6189 Return a list of possible coding systems ordered by priority.\n\
6191 If only ASCII characters are found, it returns a list of single element\n\
6192 `undecided' or its subsidiary coding system according to a detected\n\
6193 end-of-line format.\n\
6195 If optional argument HIGHEST is non-nil, return the coding system of\n\
6196 highest priority.")
6197 (start, end, highest)
6198 Lisp_Object start, end, highest;
6200 int from, to;
6201 int from_byte, to_byte;
6203 CHECK_NUMBER_COERCE_MARKER (start, 0);
6204 CHECK_NUMBER_COERCE_MARKER (end, 1);
6206 validate_region (&start, &end);
6207 from = XINT (start), to = XINT (end);
6208 from_byte = CHAR_TO_BYTE (from);
6209 to_byte = CHAR_TO_BYTE (to);
6211 if (from < GPT && to >= GPT)
6212 move_gap_both (to, to_byte);
6214 return detect_coding_system (BYTE_POS_ADDR (from_byte),
6215 to_byte - from_byte,
6216 !NILP (highest),
6217 !NILP (current_buffer
6218 ->enable_multibyte_characters));
6221 DEFUN ("detect-coding-string", Fdetect_coding_string, Sdetect_coding_string,
6222 1, 2, 0,
6223 "Detect coding system of the text in STRING.\n\
6224 Return a list of possible coding systems ordered by priority.\n\
6226 If only ASCII characters are found, it returns a list of single element\n\
6227 `undecided' or its subsidiary coding system according to a detected\n\
6228 end-of-line format.\n\
6230 If optional argument HIGHEST is non-nil, return the coding system of\n\
6231 highest priority.")
6232 (string, highest)
6233 Lisp_Object string, highest;
6235 CHECK_STRING (string, 0);
6237 return detect_coding_system (XSTRING (string)->data,
6238 STRING_BYTES (XSTRING (string)),
6239 !NILP (highest),
6240 STRING_MULTIBYTE (string));
6243 /* Return an intersection of lists L1 and L2. */
6245 static Lisp_Object
6246 intersection (l1, l2)
6247 Lisp_Object l1, l2;
6249 Lisp_Object val;
6251 for (val = Qnil; CONSP (l1); l1 = XCDR (l1))
6253 if (!NILP (Fmemq (XCAR (l1), l2)))
6254 val = Fcons (XCAR (l1), val);
6256 return val;
6260 /* Subroutine for Fsafe_coding_systems_region_internal.
6262 Return a list of coding systems that safely encode the multibyte
6263 text between P and PEND. SAFE_CODINGS, if non-nil, is a list of
6264 possible coding systems. If it is nil, it means that we have not
6265 yet found any coding systems.
6267 WORK_TABLE is a copy of the char-table Vchar_coding_system_table. An
6268 element of WORK_TABLE is set to t once the element is looked up.
6270 If a non-ASCII single byte char is found, set
6271 *single_byte_char_found to 1. */
6273 static Lisp_Object
6274 find_safe_codings (p, pend, safe_codings, work_table, single_byte_char_found)
6275 unsigned char *p, *pend;
6276 Lisp_Object safe_codings, work_table;
6277 int *single_byte_char_found;
6279 int c, len, idx;
6280 Lisp_Object val;
6282 while (p < pend)
6284 c = STRING_CHAR_AND_LENGTH (p, pend - p, len);
6285 p += len;
6286 if (ASCII_BYTE_P (c))
6287 /* We can ignore ASCII characters here. */
6288 continue;
6289 if (SINGLE_BYTE_CHAR_P (c))
6290 *single_byte_char_found = 1;
6291 if (NILP (safe_codings))
6292 continue;
6293 /* Check the safe coding systems for C. */
6294 val = char_table_ref_and_index (work_table, c, &idx);
6295 if (EQ (val, Qt))
6296 /* This element was already checked. Ignore it. */
6297 continue;
6298 /* Remember that we checked this element. */
6299 CHAR_TABLE_SET (work_table, make_number (idx), Qt);
6301 /* If there are some safe coding systems for C and we have
6302 already found the other set of coding systems for the
6303 different characters, get the intersection of them. */
6304 if (!EQ (safe_codings, Qt) && !NILP (val))
6305 val = intersection (safe_codings, val);
6306 safe_codings = val;
6308 return safe_codings;
6312 /* Return a list of coding systems that safely encode the text between
6313 START and END. If the text contains only ASCII or is unibyte,
6314 return t. */
6316 DEFUN ("find-coding-systems-region-internal",
6317 Ffind_coding_systems_region_internal,
6318 Sfind_coding_systems_region_internal, 2, 2, 0,
6319 "Internal use only.")
6320 (start, end)
6321 Lisp_Object start, end;
6323 Lisp_Object work_table, safe_codings;
6324 int non_ascii_p = 0;
6325 int single_byte_char_found = 0;
6326 unsigned char *p1, *p1end, *p2, *p2end, *p;
6328 if (STRINGP (start))
6330 if (!STRING_MULTIBYTE (start))
6331 return Qt;
6332 p1 = XSTRING (start)->data, p1end = p1 + STRING_BYTES (XSTRING (start));
6333 p2 = p2end = p1end;
6334 if (XSTRING (start)->size != STRING_BYTES (XSTRING (start)))
6335 non_ascii_p = 1;
6337 else
6339 int from, to, stop;
6341 CHECK_NUMBER_COERCE_MARKER (start, 0);
6342 CHECK_NUMBER_COERCE_MARKER (end, 1);
6343 if (XINT (start) < BEG || XINT (end) > Z || XINT (start) > XINT (end))
6344 args_out_of_range (start, end);
6345 if (NILP (current_buffer->enable_multibyte_characters))
6346 return Qt;
6347 from = CHAR_TO_BYTE (XINT (start));
6348 to = CHAR_TO_BYTE (XINT (end));
6349 stop = from < GPT_BYTE && GPT_BYTE < to ? GPT_BYTE : to;
6350 p1 = BYTE_POS_ADDR (from), p1end = p1 + (stop - from);
6351 if (stop == to)
6352 p2 = p2end = p1end;
6353 else
6354 p2 = BYTE_POS_ADDR (stop), p2end = p2 + (to - stop);
6355 if (XINT (end) - XINT (start) != to - from)
6356 non_ascii_p = 1;
6359 if (!non_ascii_p)
6361 /* We are sure that the text contains no multibyte character.
6362 Check if it contains eight-bit-graphic. */
6363 p = p1;
6364 for (p = p1; p < p1end && ASCII_BYTE_P (*p); p++);
6365 if (p == p1end)
6367 for (p = p2; p < p2end && ASCII_BYTE_P (*p); p++);
6368 if (p == p2end)
6369 return Qt;
6373 /* The text contains non-ASCII characters. */
6374 work_table = Fcopy_sequence (Vchar_coding_system_table);
6375 safe_codings = find_safe_codings (p1, p1end, Qt, work_table,
6376 &single_byte_char_found);
6377 if (p2 < p2end)
6378 safe_codings = find_safe_codings (p2, p2end, safe_codings, work_table,
6379 &single_byte_char_found);
6381 if (!single_byte_char_found)
6383 /* Append generic coding systems. */
6384 Lisp_Object args[2];
6385 args[0] = safe_codings;
6386 args[1] = Fchar_table_extra_slot (Vchar_coding_system_table,
6387 make_number (0));
6388 safe_codings = Fappend (2, args);
6390 else
6391 safe_codings = Fcons (Qraw_text,
6392 Fcons (Qemacs_mule,
6393 Fcons (Qno_conversion, safe_codings)));
6394 return safe_codings;
6398 Lisp_Object
6399 code_convert_region1 (start, end, coding_system, encodep)
6400 Lisp_Object start, end, coding_system;
6401 int encodep;
6403 struct coding_system coding;
6404 int from, to;
6406 CHECK_NUMBER_COERCE_MARKER (start, 0);
6407 CHECK_NUMBER_COERCE_MARKER (end, 1);
6408 CHECK_SYMBOL (coding_system, 2);
6410 validate_region (&start, &end);
6411 from = XFASTINT (start);
6412 to = XFASTINT (end);
6414 if (NILP (coding_system))
6415 return make_number (to - from);
6417 if (setup_coding_system (Fcheck_coding_system (coding_system), &coding) < 0)
6418 error ("Invalid coding system: %s", XSYMBOL (coding_system)->name->data);
6420 coding.mode |= CODING_MODE_LAST_BLOCK;
6421 coding.src_multibyte = coding.dst_multibyte
6422 = !NILP (current_buffer->enable_multibyte_characters);
6423 code_convert_region (from, CHAR_TO_BYTE (from), to, CHAR_TO_BYTE (to),
6424 &coding, encodep, 1);
6425 Vlast_coding_system_used = coding.symbol;
6426 return make_number (coding.produced_char);
6429 DEFUN ("decode-coding-region", Fdecode_coding_region, Sdecode_coding_region,
6430 3, 3, "r\nzCoding system: ",
6431 "Decode the current region from the specified coding system.\n\
6432 When called from a program, takes three arguments:\n\
6433 START, END, and CODING-SYSTEM. START and END are buffer positions.\n\
6434 This function sets `last-coding-system-used' to the precise coding system\n\
6435 used (which may be different from CODING-SYSTEM if CODING-SYSTEM is\n\
6436 not fully specified.)\n\
6437 It returns the length of the decoded text.")
6438 (start, end, coding_system)
6439 Lisp_Object start, end, coding_system;
6441 return code_convert_region1 (start, end, coding_system, 0);
6444 DEFUN ("encode-coding-region", Fencode_coding_region, Sencode_coding_region,
6445 3, 3, "r\nzCoding system: ",
6446 "Encode the current region into the specified coding system.\n\
6447 When called from a program, takes three arguments:\n\
6448 START, END, and CODING-SYSTEM. START and END are buffer positions.\n\
6449 This function sets `last-coding-system-used' to the precise coding system\n\
6450 used (which may be different from CODING-SYSTEM if CODING-SYSTEM is\n\
6451 not fully specified.)\n\
6452 It returns the length of the encoded text.")
6453 (start, end, coding_system)
6454 Lisp_Object start, end, coding_system;
6456 return code_convert_region1 (start, end, coding_system, 1);
6459 Lisp_Object
6460 code_convert_string1 (string, coding_system, nocopy, encodep)
6461 Lisp_Object string, coding_system, nocopy;
6462 int encodep;
6464 struct coding_system coding;
6466 CHECK_STRING (string, 0);
6467 CHECK_SYMBOL (coding_system, 1);
6469 if (NILP (coding_system))
6470 return (NILP (nocopy) ? Fcopy_sequence (string) : string);
6472 if (setup_coding_system (Fcheck_coding_system (coding_system), &coding) < 0)
6473 error ("Invalid coding system: %s", XSYMBOL (coding_system)->name->data);
6475 coding.mode |= CODING_MODE_LAST_BLOCK;
6476 string = (encodep
6477 ? encode_coding_string (string, &coding, !NILP (nocopy))
6478 : decode_coding_string (string, &coding, !NILP (nocopy)));
6479 Vlast_coding_system_used = coding.symbol;
6481 return string;
6484 DEFUN ("decode-coding-string", Fdecode_coding_string, Sdecode_coding_string,
6485 2, 3, 0,
6486 "Decode STRING which is encoded in CODING-SYSTEM, and return the result.\n\
6487 Optional arg NOCOPY non-nil means it is ok to return STRING itself\n\
6488 if the decoding operation is trivial.\n\
6489 This function sets `last-coding-system-used' to the precise coding system\n\
6490 used (which may be different from CODING-SYSTEM if CODING-SYSTEM is\n\
6491 not fully specified.)")
6492 (string, coding_system, nocopy)
6493 Lisp_Object string, coding_system, nocopy;
6495 return code_convert_string1 (string, coding_system, nocopy, 0);
6498 DEFUN ("encode-coding-string", Fencode_coding_string, Sencode_coding_string,
6499 2, 3, 0,
6500 "Encode STRING to CODING-SYSTEM, and return the result.\n\
6501 Optional arg NOCOPY non-nil means it is ok to return STRING itself\n\
6502 if the encoding operation is trivial.\n\
6503 This function sets `last-coding-system-used' to the precise coding system\n\
6504 used (which may be different from CODING-SYSTEM if CODING-SYSTEM is\n\
6505 not fully specified.)")
6506 (string, coding_system, nocopy)
6507 Lisp_Object string, coding_system, nocopy;
6509 return code_convert_string1 (string, coding_system, nocopy, 1);
6512 /* Encode or decode STRING according to CODING_SYSTEM.
6513 Do not set Vlast_coding_system_used.
6515 This function is called only from macros DECODE_FILE and
6516 ENCODE_FILE, thus we ignore character composition. */
6518 Lisp_Object
6519 code_convert_string_norecord (string, coding_system, encodep)
6520 Lisp_Object string, coding_system;
6521 int encodep;
6523 struct coding_system coding;
6525 CHECK_STRING (string, 0);
6526 CHECK_SYMBOL (coding_system, 1);
6528 if (NILP (coding_system))
6529 return string;
6531 if (setup_coding_system (Fcheck_coding_system (coding_system), &coding) < 0)
6532 error ("Invalid coding system: %s", XSYMBOL (coding_system)->name->data);
6534 coding.composing = COMPOSITION_DISABLED;
6535 coding.mode |= CODING_MODE_LAST_BLOCK;
6536 return (encodep
6537 ? encode_coding_string (string, &coding, 1)
6538 : decode_coding_string (string, &coding, 1));
6541 DEFUN ("decode-sjis-char", Fdecode_sjis_char, Sdecode_sjis_char, 1, 1, 0,
6542 "Decode a Japanese character which has CODE in shift_jis encoding.\n\
6543 Return the corresponding character.")
6544 (code)
6545 Lisp_Object code;
6547 unsigned char c1, c2, s1, s2;
6548 Lisp_Object val;
6550 CHECK_NUMBER (code, 0);
6551 s1 = (XFASTINT (code)) >> 8, s2 = (XFASTINT (code)) & 0xFF;
6552 if (s1 == 0)
6554 if (s2 < 0x80)
6555 XSETFASTINT (val, s2);
6556 else if (s2 >= 0xA0 || s2 <= 0xDF)
6557 XSETFASTINT (val, MAKE_CHAR (charset_katakana_jisx0201, s2, 0));
6558 else
6559 error ("Invalid Shift JIS code: %x", XFASTINT (code));
6561 else
6563 if ((s1 < 0x80 || s1 > 0x9F && s1 < 0xE0 || s1 > 0xEF)
6564 || (s2 < 0x40 || s2 == 0x7F || s2 > 0xFC))
6565 error ("Invalid Shift JIS code: %x", XFASTINT (code));
6566 DECODE_SJIS (s1, s2, c1, c2);
6567 XSETFASTINT (val, MAKE_CHAR (charset_jisx0208, c1, c2));
6569 return val;
6572 DEFUN ("encode-sjis-char", Fencode_sjis_char, Sencode_sjis_char, 1, 1, 0,
6573 "Encode a Japanese character CHAR to shift_jis encoding.\n\
6574 Return the corresponding code in SJIS.")
6575 (ch)
6576 Lisp_Object ch;
6578 int charset, c1, c2, s1, s2;
6579 Lisp_Object val;
6581 CHECK_NUMBER (ch, 0);
6582 SPLIT_CHAR (XFASTINT (ch), charset, c1, c2);
6583 if (charset == CHARSET_ASCII)
6585 val = ch;
6587 else if (charset == charset_jisx0208
6588 && c1 > 0x20 && c1 < 0x7F && c2 > 0x20 && c2 < 0x7F)
6590 ENCODE_SJIS (c1, c2, s1, s2);
6591 XSETFASTINT (val, (s1 << 8) | s2);
6593 else if (charset == charset_katakana_jisx0201
6594 && c1 > 0x20 && c2 < 0xE0)
6596 XSETFASTINT (val, c1 | 0x80);
6598 else
6599 error ("Can't encode to shift_jis: %d", XFASTINT (ch));
6600 return val;
6603 DEFUN ("decode-big5-char", Fdecode_big5_char, Sdecode_big5_char, 1, 1, 0,
6604 "Decode a Big5 character which has CODE in BIG5 coding system.\n\
6605 Return the corresponding character.")
6606 (code)
6607 Lisp_Object code;
6609 int charset;
6610 unsigned char b1, b2, c1, c2;
6611 Lisp_Object val;
6613 CHECK_NUMBER (code, 0);
6614 b1 = (XFASTINT (code)) >> 8, b2 = (XFASTINT (code)) & 0xFF;
6615 if (b1 == 0)
6617 if (b2 >= 0x80)
6618 error ("Invalid BIG5 code: %x", XFASTINT (code));
6619 val = code;
6621 else
6623 if ((b1 < 0xA1 || b1 > 0xFE)
6624 || (b2 < 0x40 || (b2 > 0x7E && b2 < 0xA1) || b2 > 0xFE))
6625 error ("Invalid BIG5 code: %x", XFASTINT (code));
6626 DECODE_BIG5 (b1, b2, charset, c1, c2);
6627 XSETFASTINT (val, MAKE_CHAR (charset, c1, c2));
6629 return val;
6632 DEFUN ("encode-big5-char", Fencode_big5_char, Sencode_big5_char, 1, 1, 0,
6633 "Encode the Big5 character CHAR to BIG5 coding system.\n\
6634 Return the corresponding character code in Big5.")
6635 (ch)
6636 Lisp_Object ch;
6638 int charset, c1, c2, b1, b2;
6639 Lisp_Object val;
6641 CHECK_NUMBER (ch, 0);
6642 SPLIT_CHAR (XFASTINT (ch), charset, c1, c2);
6643 if (charset == CHARSET_ASCII)
6645 val = ch;
6647 else if ((charset == charset_big5_1
6648 && (XFASTINT (ch) >= 0x250a1 && XFASTINT (ch) <= 0x271ec))
6649 || (charset == charset_big5_2
6650 && XFASTINT (ch) >= 0x290a1 && XFASTINT (ch) <= 0x2bdb2))
6652 ENCODE_BIG5 (charset, c1, c2, b1, b2);
6653 XSETFASTINT (val, (b1 << 8) | b2);
6655 else
6656 error ("Can't encode to Big5: %d", XFASTINT (ch));
6657 return val;
6660 DEFUN ("set-terminal-coding-system-internal",
6661 Fset_terminal_coding_system_internal,
6662 Sset_terminal_coding_system_internal, 1, 1, 0, "")
6663 (coding_system)
6664 Lisp_Object coding_system;
6666 CHECK_SYMBOL (coding_system, 0);
6667 setup_coding_system (Fcheck_coding_system (coding_system), &terminal_coding);
6668 /* We had better not send unsafe characters to terminal. */
6669 terminal_coding.flags |= CODING_FLAG_ISO_SAFE;
6670 /* Characer composition should be disabled. */
6671 terminal_coding.composing = COMPOSITION_DISABLED;
6672 /* Error notification should be suppressed. */
6673 terminal_coding.suppress_error = 1;
6674 terminal_coding.src_multibyte = 1;
6675 terminal_coding.dst_multibyte = 0;
6676 return Qnil;
6679 DEFUN ("set-safe-terminal-coding-system-internal",
6680 Fset_safe_terminal_coding_system_internal,
6681 Sset_safe_terminal_coding_system_internal, 1, 1, 0, "")
6682 (coding_system)
6683 Lisp_Object coding_system;
6685 CHECK_SYMBOL (coding_system, 0);
6686 setup_coding_system (Fcheck_coding_system (coding_system),
6687 &safe_terminal_coding);
6688 /* Characer composition should be disabled. */
6689 safe_terminal_coding.composing = COMPOSITION_DISABLED;
6690 /* Error notification should be suppressed. */
6691 terminal_coding.suppress_error = 1;
6692 safe_terminal_coding.src_multibyte = 1;
6693 safe_terminal_coding.dst_multibyte = 0;
6694 return Qnil;
6697 DEFUN ("terminal-coding-system",
6698 Fterminal_coding_system, Sterminal_coding_system, 0, 0, 0,
6699 "Return coding system specified for terminal output.")
6702 return terminal_coding.symbol;
6705 DEFUN ("set-keyboard-coding-system-internal",
6706 Fset_keyboard_coding_system_internal,
6707 Sset_keyboard_coding_system_internal, 1, 1, 0, "")
6708 (coding_system)
6709 Lisp_Object coding_system;
6711 CHECK_SYMBOL (coding_system, 0);
6712 setup_coding_system (Fcheck_coding_system (coding_system), &keyboard_coding);
6713 /* Characer composition should be disabled. */
6714 keyboard_coding.composing = COMPOSITION_DISABLED;
6715 return Qnil;
6718 DEFUN ("keyboard-coding-system",
6719 Fkeyboard_coding_system, Skeyboard_coding_system, 0, 0, 0,
6720 "Return coding system specified for decoding keyboard input.")
6723 return keyboard_coding.symbol;
6727 DEFUN ("find-operation-coding-system", Ffind_operation_coding_system,
6728 Sfind_operation_coding_system, 1, MANY, 0,
6729 "Choose a coding system for an operation based on the target name.\n\
6730 The value names a pair of coding systems: (DECODING-SYSTEM . ENCODING-SYSTEM).\n\
6731 DECODING-SYSTEM is the coding system to use for decoding\n\
6732 \(in case OPERATION does decoding), and ENCODING-SYSTEM is the coding system\n\
6733 for encoding (in case OPERATION does encoding).\n\
6735 The first argument OPERATION specifies an I/O primitive:\n\
6736 For file I/O, `insert-file-contents' or `write-region'.\n\
6737 For process I/O, `call-process', `call-process-region', or `start-process'.\n\
6738 For network I/O, `open-network-stream'.\n\
6740 The remaining arguments should be the same arguments that were passed\n\
6741 to the primitive. Depending on which primitive, one of those arguments\n\
6742 is selected as the TARGET. For example, if OPERATION does file I/O,\n\
6743 whichever argument specifies the file name is TARGET.\n\
6745 TARGET has a meaning which depends on OPERATION:\n\
6746 For file I/O, TARGET is a file name.\n\
6747 For process I/O, TARGET is a process name.\n\
6748 For network I/O, TARGET is a service name or a port number\n\
6750 This function looks up what specified for TARGET in,\n\
6751 `file-coding-system-alist', `process-coding-system-alist',\n\
6752 or `network-coding-system-alist' depending on OPERATION.\n\
6753 They may specify a coding system, a cons of coding systems,\n\
6754 or a function symbol to call.\n\
6755 In the last case, we call the function with one argument,\n\
6756 which is a list of all the arguments given to this function.")
6757 (nargs, args)
6758 int nargs;
6759 Lisp_Object *args;
6761 Lisp_Object operation, target_idx, target, val;
6762 register Lisp_Object chain;
6764 if (nargs < 2)
6765 error ("Too few arguments");
6766 operation = args[0];
6767 if (!SYMBOLP (operation)
6768 || !INTEGERP (target_idx = Fget (operation, Qtarget_idx)))
6769 error ("Invalid first arguement");
6770 if (nargs < 1 + XINT (target_idx))
6771 error ("Too few arguments for operation: %s",
6772 XSYMBOL (operation)->name->data);
6773 target = args[XINT (target_idx) + 1];
6774 if (!(STRINGP (target)
6775 || (EQ (operation, Qopen_network_stream) && INTEGERP (target))))
6776 error ("Invalid %dth argument", XINT (target_idx) + 1);
6778 chain = ((EQ (operation, Qinsert_file_contents)
6779 || EQ (operation, Qwrite_region))
6780 ? Vfile_coding_system_alist
6781 : (EQ (operation, Qopen_network_stream)
6782 ? Vnetwork_coding_system_alist
6783 : Vprocess_coding_system_alist));
6784 if (NILP (chain))
6785 return Qnil;
6787 for (; CONSP (chain); chain = XCDR (chain))
6789 Lisp_Object elt;
6790 elt = XCAR (chain);
6792 if (CONSP (elt)
6793 && ((STRINGP (target)
6794 && STRINGP (XCAR (elt))
6795 && fast_string_match (XCAR (elt), target) >= 0)
6796 || (INTEGERP (target) && EQ (target, XCAR (elt)))))
6798 val = XCDR (elt);
6799 /* Here, if VAL is both a valid coding system and a valid
6800 function symbol, we return VAL as a coding system. */
6801 if (CONSP (val))
6802 return val;
6803 if (! SYMBOLP (val))
6804 return Qnil;
6805 if (! NILP (Fcoding_system_p (val)))
6806 return Fcons (val, val);
6807 if (! NILP (Ffboundp (val)))
6809 val = call1 (val, Flist (nargs, args));
6810 if (CONSP (val))
6811 return val;
6812 if (SYMBOLP (val) && ! NILP (Fcoding_system_p (val)))
6813 return Fcons (val, val);
6815 return Qnil;
6818 return Qnil;
6821 DEFUN ("update-coding-systems-internal", Fupdate_coding_systems_internal,
6822 Supdate_coding_systems_internal, 0, 0, 0,
6823 "Update internal database for ISO2022 and CCL based coding systems.\n\
6824 When values of any coding categories are changed, you must\n\
6825 call this function")
6828 int i;
6830 for (i = CODING_CATEGORY_IDX_EMACS_MULE; i < CODING_CATEGORY_IDX_MAX; i++)
6832 Lisp_Object val;
6834 val = XSYMBOL (XVECTOR (Vcoding_category_table)->contents[i])->value;
6835 if (!NILP (val))
6837 if (! coding_system_table[i])
6838 coding_system_table[i] = ((struct coding_system *)
6839 xmalloc (sizeof (struct coding_system)));
6840 setup_coding_system (val, coding_system_table[i]);
6842 else if (coding_system_table[i])
6844 xfree (coding_system_table[i]);
6845 coding_system_table[i] = NULL;
6849 return Qnil;
6852 DEFUN ("set-coding-priority-internal", Fset_coding_priority_internal,
6853 Sset_coding_priority_internal, 0, 0, 0,
6854 "Update internal database for the current value of `coding-category-list'.\n\
6855 This function is internal use only.")
6858 int i = 0, idx;
6859 Lisp_Object val;
6861 val = Vcoding_category_list;
6863 while (CONSP (val) && i < CODING_CATEGORY_IDX_MAX)
6865 if (! SYMBOLP (XCAR (val)))
6866 break;
6867 idx = XFASTINT (Fget (XCAR (val), Qcoding_category_index));
6868 if (idx >= CODING_CATEGORY_IDX_MAX)
6869 break;
6870 coding_priorities[i++] = (1 << idx);
6871 val = XCDR (val);
6873 /* If coding-category-list is valid and contains all coding
6874 categories, `i' should be CODING_CATEGORY_IDX_MAX now. If not,
6875 the following code saves Emacs from crashing. */
6876 while (i < CODING_CATEGORY_IDX_MAX)
6877 coding_priorities[i++] = CODING_CATEGORY_MASK_RAW_TEXT;
6879 return Qnil;
6882 #endif /* emacs */
6885 /*** 9. Post-amble ***/
6887 void
6888 init_coding_once ()
6890 int i;
6892 /* Emacs' internal format specific initialize routine. */
6893 for (i = 0; i <= 0x20; i++)
6894 emacs_code_class[i] = EMACS_control_code;
6895 emacs_code_class[0x0A] = EMACS_linefeed_code;
6896 emacs_code_class[0x0D] = EMACS_carriage_return_code;
6897 for (i = 0x21 ; i < 0x7F; i++)
6898 emacs_code_class[i] = EMACS_ascii_code;
6899 emacs_code_class[0x7F] = EMACS_control_code;
6900 for (i = 0x80; i < 0xFF; i++)
6901 emacs_code_class[i] = EMACS_invalid_code;
6902 emacs_code_class[LEADING_CODE_PRIVATE_11] = EMACS_leading_code_3;
6903 emacs_code_class[LEADING_CODE_PRIVATE_12] = EMACS_leading_code_3;
6904 emacs_code_class[LEADING_CODE_PRIVATE_21] = EMACS_leading_code_4;
6905 emacs_code_class[LEADING_CODE_PRIVATE_22] = EMACS_leading_code_4;
6907 /* ISO2022 specific initialize routine. */
6908 for (i = 0; i < 0x20; i++)
6909 iso_code_class[i] = ISO_control_0;
6910 for (i = 0x21; i < 0x7F; i++)
6911 iso_code_class[i] = ISO_graphic_plane_0;
6912 for (i = 0x80; i < 0xA0; i++)
6913 iso_code_class[i] = ISO_control_1;
6914 for (i = 0xA1; i < 0xFF; i++)
6915 iso_code_class[i] = ISO_graphic_plane_1;
6916 iso_code_class[0x20] = iso_code_class[0x7F] = ISO_0x20_or_0x7F;
6917 iso_code_class[0xA0] = iso_code_class[0xFF] = ISO_0xA0_or_0xFF;
6918 iso_code_class[ISO_CODE_CR] = ISO_carriage_return;
6919 iso_code_class[ISO_CODE_SO] = ISO_shift_out;
6920 iso_code_class[ISO_CODE_SI] = ISO_shift_in;
6921 iso_code_class[ISO_CODE_SS2_7] = ISO_single_shift_2_7;
6922 iso_code_class[ISO_CODE_ESC] = ISO_escape;
6923 iso_code_class[ISO_CODE_SS2] = ISO_single_shift_2;
6924 iso_code_class[ISO_CODE_SS3] = ISO_single_shift_3;
6925 iso_code_class[ISO_CODE_CSI] = ISO_control_sequence_introducer;
6927 setup_coding_system (Qnil, &keyboard_coding);
6928 setup_coding_system (Qnil, &terminal_coding);
6929 setup_coding_system (Qnil, &safe_terminal_coding);
6930 setup_coding_system (Qnil, &default_buffer_file_coding);
6932 bzero (coding_system_table, sizeof coding_system_table);
6934 bzero (ascii_skip_code, sizeof ascii_skip_code);
6935 for (i = 0; i < 128; i++)
6936 ascii_skip_code[i] = 1;
6938 #if defined (MSDOS) || defined (WINDOWSNT)
6939 system_eol_type = CODING_EOL_CRLF;
6940 #else
6941 system_eol_type = CODING_EOL_LF;
6942 #endif
6944 inhibit_pre_post_conversion = 0;
6947 #ifdef emacs
6949 void
6950 syms_of_coding ()
6952 Qtarget_idx = intern ("target-idx");
6953 staticpro (&Qtarget_idx);
6955 Qcoding_system_history = intern ("coding-system-history");
6956 staticpro (&Qcoding_system_history);
6957 Fset (Qcoding_system_history, Qnil);
6959 /* Target FILENAME is the first argument. */
6960 Fput (Qinsert_file_contents, Qtarget_idx, make_number (0));
6961 /* Target FILENAME is the third argument. */
6962 Fput (Qwrite_region, Qtarget_idx, make_number (2));
6964 Qcall_process = intern ("call-process");
6965 staticpro (&Qcall_process);
6966 /* Target PROGRAM is the first argument. */
6967 Fput (Qcall_process, Qtarget_idx, make_number (0));
6969 Qcall_process_region = intern ("call-process-region");
6970 staticpro (&Qcall_process_region);
6971 /* Target PROGRAM is the third argument. */
6972 Fput (Qcall_process_region, Qtarget_idx, make_number (2));
6974 Qstart_process = intern ("start-process");
6975 staticpro (&Qstart_process);
6976 /* Target PROGRAM is the third argument. */
6977 Fput (Qstart_process, Qtarget_idx, make_number (2));
6979 Qopen_network_stream = intern ("open-network-stream");
6980 staticpro (&Qopen_network_stream);
6981 /* Target SERVICE is the fourth argument. */
6982 Fput (Qopen_network_stream, Qtarget_idx, make_number (3));
6984 Qcoding_system = intern ("coding-system");
6985 staticpro (&Qcoding_system);
6987 Qeol_type = intern ("eol-type");
6988 staticpro (&Qeol_type);
6990 Qbuffer_file_coding_system = intern ("buffer-file-coding-system");
6991 staticpro (&Qbuffer_file_coding_system);
6993 Qpost_read_conversion = intern ("post-read-conversion");
6994 staticpro (&Qpost_read_conversion);
6996 Qpre_write_conversion = intern ("pre-write-conversion");
6997 staticpro (&Qpre_write_conversion);
6999 Qno_conversion = intern ("no-conversion");
7000 staticpro (&Qno_conversion);
7002 Qundecided = intern ("undecided");
7003 staticpro (&Qundecided);
7005 Qcoding_system_p = intern ("coding-system-p");
7006 staticpro (&Qcoding_system_p);
7008 Qcoding_system_error = intern ("coding-system-error");
7009 staticpro (&Qcoding_system_error);
7011 Fput (Qcoding_system_error, Qerror_conditions,
7012 Fcons (Qcoding_system_error, Fcons (Qerror, Qnil)));
7013 Fput (Qcoding_system_error, Qerror_message,
7014 build_string ("Invalid coding system"));
7016 Qcoding_category = intern ("coding-category");
7017 staticpro (&Qcoding_category);
7018 Qcoding_category_index = intern ("coding-category-index");
7019 staticpro (&Qcoding_category_index);
7021 Vcoding_category_table
7022 = Fmake_vector (make_number (CODING_CATEGORY_IDX_MAX), Qnil);
7023 staticpro (&Vcoding_category_table);
7025 int i;
7026 for (i = 0; i < CODING_CATEGORY_IDX_MAX; i++)
7028 XVECTOR (Vcoding_category_table)->contents[i]
7029 = intern (coding_category_name[i]);
7030 Fput (XVECTOR (Vcoding_category_table)->contents[i],
7031 Qcoding_category_index, make_number (i));
7035 Qtranslation_table = intern ("translation-table");
7036 staticpro (&Qtranslation_table);
7037 Fput (Qtranslation_table, Qchar_table_extra_slots, make_number (1));
7039 Qtranslation_table_id = intern ("translation-table-id");
7040 staticpro (&Qtranslation_table_id);
7042 Qtranslation_table_for_decode = intern ("translation-table-for-decode");
7043 staticpro (&Qtranslation_table_for_decode);
7045 Qtranslation_table_for_encode = intern ("translation-table-for-encode");
7046 staticpro (&Qtranslation_table_for_encode);
7048 Qsafe_chars = intern ("safe-chars");
7049 staticpro (&Qsafe_chars);
7051 Qchar_coding_system = intern ("char-coding-system");
7052 staticpro (&Qchar_coding_system);
7054 /* Intern this now in case it isn't already done.
7055 Setting this variable twice is harmless.
7056 But don't staticpro it here--that is done in alloc.c. */
7057 Qchar_table_extra_slots = intern ("char-table-extra-slots");
7058 Fput (Qsafe_chars, Qchar_table_extra_slots, make_number (0));
7059 Fput (Qchar_coding_system, Qchar_table_extra_slots, make_number (1));
7061 Qvalid_codes = intern ("valid-codes");
7062 staticpro (&Qvalid_codes);
7064 Qemacs_mule = intern ("emacs-mule");
7065 staticpro (&Qemacs_mule);
7067 Qraw_text = intern ("raw-text");
7068 staticpro (&Qraw_text);
7070 defsubr (&Scoding_system_p);
7071 defsubr (&Sread_coding_system);
7072 defsubr (&Sread_non_nil_coding_system);
7073 defsubr (&Scheck_coding_system);
7074 defsubr (&Sdetect_coding_region);
7075 defsubr (&Sdetect_coding_string);
7076 defsubr (&Sfind_coding_systems_region_internal);
7077 defsubr (&Sdecode_coding_region);
7078 defsubr (&Sencode_coding_region);
7079 defsubr (&Sdecode_coding_string);
7080 defsubr (&Sencode_coding_string);
7081 defsubr (&Sdecode_sjis_char);
7082 defsubr (&Sencode_sjis_char);
7083 defsubr (&Sdecode_big5_char);
7084 defsubr (&Sencode_big5_char);
7085 defsubr (&Sset_terminal_coding_system_internal);
7086 defsubr (&Sset_safe_terminal_coding_system_internal);
7087 defsubr (&Sterminal_coding_system);
7088 defsubr (&Sset_keyboard_coding_system_internal);
7089 defsubr (&Skeyboard_coding_system);
7090 defsubr (&Sfind_operation_coding_system);
7091 defsubr (&Supdate_coding_systems_internal);
7092 defsubr (&Sset_coding_priority_internal);
7094 DEFVAR_LISP ("coding-system-list", &Vcoding_system_list,
7095 "List of coding systems.\n\
7097 Do not alter the value of this variable manually. This variable should be\n\
7098 updated by the functions `make-coding-system' and\n\
7099 `define-coding-system-alias'.");
7100 Vcoding_system_list = Qnil;
7102 DEFVAR_LISP ("coding-system-alist", &Vcoding_system_alist,
7103 "Alist of coding system names.\n\
7104 Each element is one element list of coding system name.\n\
7105 This variable is given to `completing-read' as TABLE argument.\n\
7107 Do not alter the value of this variable manually. This variable should be\n\
7108 updated by the functions `make-coding-system' and\n\
7109 `define-coding-system-alias'.");
7110 Vcoding_system_alist = Qnil;
7112 DEFVAR_LISP ("coding-category-list", &Vcoding_category_list,
7113 "List of coding-categories (symbols) ordered by priority.");
7115 int i;
7117 Vcoding_category_list = Qnil;
7118 for (i = CODING_CATEGORY_IDX_MAX - 1; i >= 0; i--)
7119 Vcoding_category_list
7120 = Fcons (XVECTOR (Vcoding_category_table)->contents[i],
7121 Vcoding_category_list);
7124 DEFVAR_LISP ("coding-system-for-read", &Vcoding_system_for_read,
7125 "Specify the coding system for read operations.\n\
7126 It is useful to bind this variable with `let', but do not set it globally.\n\
7127 If the value is a coding system, it is used for decoding on read operation.\n\
7128 If not, an appropriate element is used from one of the coding system alists:\n\
7129 There are three such tables, `file-coding-system-alist',\n\
7130 `process-coding-system-alist', and `network-coding-system-alist'.");
7131 Vcoding_system_for_read = Qnil;
7133 DEFVAR_LISP ("coding-system-for-write", &Vcoding_system_for_write,
7134 "Specify the coding system for write operations.\n\
7135 Programs bind this variable with `let', but you should not set it globally.\n\
7136 If the value is a coding system, it is used for encoding of output,\n\
7137 when writing it to a file and when sending it to a file or subprocess.\n\
7139 If this does not specify a coding system, an appropriate element\n\
7140 is used from one of the coding system alists:\n\
7141 There are three such tables, `file-coding-system-alist',\n\
7142 `process-coding-system-alist', and `network-coding-system-alist'.\n\
7143 For output to files, if the above procedure does not specify a coding system,\n\
7144 the value of `buffer-file-coding-system' is used.");
7145 Vcoding_system_for_write = Qnil;
7147 DEFVAR_LISP ("last-coding-system-used", &Vlast_coding_system_used,
7148 "Coding system used in the latest file or process I/O.");
7149 Vlast_coding_system_used = Qnil;
7151 DEFVAR_BOOL ("inhibit-eol-conversion", &inhibit_eol_conversion,
7152 "*Non-nil means always inhibit code conversion of end-of-line format.\n\
7153 See info node `Coding Systems' and info node `Text and Binary' concerning\n\
7154 such conversion.");
7155 inhibit_eol_conversion = 0;
7157 DEFVAR_BOOL ("inherit-process-coding-system", &inherit_process_coding_system,
7158 "Non-nil means process buffer inherits coding system of process output.\n\
7159 Bind it to t if the process output is to be treated as if it were a file\n\
7160 read from some filesystem.");
7161 inherit_process_coding_system = 0;
7163 DEFVAR_LISP ("file-coding-system-alist", &Vfile_coding_system_alist,
7164 "Alist to decide a coding system to use for a file I/O operation.\n\
7165 The format is ((PATTERN . VAL) ...),\n\
7166 where PATTERN is a regular expression matching a file name,\n\
7167 VAL is a coding system, a cons of coding systems, or a function symbol.\n\
7168 If VAL is a coding system, it is used for both decoding and encoding\n\
7169 the file contents.\n\
7170 If VAL is a cons of coding systems, the car part is used for decoding,\n\
7171 and the cdr part is used for encoding.\n\
7172 If VAL is a function symbol, the function must return a coding system\n\
7173 or a cons of coding systems which are used as above.\n\
7175 See also the function `find-operation-coding-system'\n\
7176 and the variable `auto-coding-alist'.");
7177 Vfile_coding_system_alist = Qnil;
7179 DEFVAR_LISP ("process-coding-system-alist", &Vprocess_coding_system_alist,
7180 "Alist to decide a coding system to use for a process I/O operation.\n\
7181 The format is ((PATTERN . VAL) ...),\n\
7182 where PATTERN is a regular expression matching a program name,\n\
7183 VAL is a coding system, a cons of coding systems, or a function symbol.\n\
7184 If VAL is a coding system, it is used for both decoding what received\n\
7185 from the program and encoding what sent to the program.\n\
7186 If VAL is a cons of coding systems, the car part is used for decoding,\n\
7187 and the cdr part is used for encoding.\n\
7188 If VAL is a function symbol, the function must return a coding system\n\
7189 or a cons of coding systems which are used as above.\n\
7191 See also the function `find-operation-coding-system'.");
7192 Vprocess_coding_system_alist = Qnil;
7194 DEFVAR_LISP ("network-coding-system-alist", &Vnetwork_coding_system_alist,
7195 "Alist to decide a coding system to use for a network I/O operation.\n\
7196 The format is ((PATTERN . VAL) ...),\n\
7197 where PATTERN is a regular expression matching a network service name\n\
7198 or is a port number to connect to,\n\
7199 VAL is a coding system, a cons of coding systems, or a function symbol.\n\
7200 If VAL is a coding system, it is used for both decoding what received\n\
7201 from the network stream and encoding what sent to the network stream.\n\
7202 If VAL is a cons of coding systems, the car part is used for decoding,\n\
7203 and the cdr part is used for encoding.\n\
7204 If VAL is a function symbol, the function must return a coding system\n\
7205 or a cons of coding systems which are used as above.\n\
7207 See also the function `find-operation-coding-system'.");
7208 Vnetwork_coding_system_alist = Qnil;
7210 DEFVAR_LISP ("locale-coding-system", &Vlocale_coding_system,
7211 "Coding system to use with system messages.");
7212 Vlocale_coding_system = Qnil;
7214 /* The eol mnemonics are reset in startup.el system-dependently. */
7215 DEFVAR_LISP ("eol-mnemonic-unix", &eol_mnemonic_unix,
7216 "*String displayed in mode line for UNIX-like (LF) end-of-line format.");
7217 eol_mnemonic_unix = build_string (":");
7219 DEFVAR_LISP ("eol-mnemonic-dos", &eol_mnemonic_dos,
7220 "*String displayed in mode line for DOS-like (CRLF) end-of-line format.");
7221 eol_mnemonic_dos = build_string ("\\");
7223 DEFVAR_LISP ("eol-mnemonic-mac", &eol_mnemonic_mac,
7224 "*String displayed in mode line for MAC-like (CR) end-of-line format.");
7225 eol_mnemonic_mac = build_string ("/");
7227 DEFVAR_LISP ("eol-mnemonic-undecided", &eol_mnemonic_undecided,
7228 "*String displayed in mode line when end-of-line format is not yet determined.");
7229 eol_mnemonic_undecided = build_string (":");
7231 DEFVAR_LISP ("enable-character-translation", &Venable_character_translation,
7232 "*Non-nil enables character translation while encoding and decoding.");
7233 Venable_character_translation = Qt;
7235 DEFVAR_LISP ("standard-translation-table-for-decode",
7236 &Vstandard_translation_table_for_decode,
7237 "Table for translating characters while decoding.");
7238 Vstandard_translation_table_for_decode = Qnil;
7240 DEFVAR_LISP ("standard-translation-table-for-encode",
7241 &Vstandard_translation_table_for_encode,
7242 "Table for translationg characters while encoding.");
7243 Vstandard_translation_table_for_encode = Qnil;
7245 DEFVAR_LISP ("charset-revision-table", &Vcharset_revision_alist,
7246 "Alist of charsets vs revision numbers.\n\
7247 While encoding, if a charset (car part of an element) is found,\n\
7248 designate it with the escape sequence identifing revision (cdr part of the element).");
7249 Vcharset_revision_alist = Qnil;
7251 DEFVAR_LISP ("default-process-coding-system",
7252 &Vdefault_process_coding_system,
7253 "Cons of coding systems used for process I/O by default.\n\
7254 The car part is used for decoding a process output,\n\
7255 the cdr part is used for encoding a text to be sent to a process.");
7256 Vdefault_process_coding_system = Qnil;
7258 DEFVAR_LISP ("latin-extra-code-table", &Vlatin_extra_code_table,
7259 "Table of extra Latin codes in the range 128..159 (inclusive).\n\
7260 This is a vector of length 256.\n\
7261 If Nth element is non-nil, the existence of code N in a file\n\
7262 \(or output of subprocess) doesn't prevent it to be detected as\n\
7263 a coding system of ISO 2022 variant which has a flag\n\
7264 `accept-latin-extra-code' t (e.g. iso-latin-1) on reading a file\n\
7265 or reading output of a subprocess.\n\
7266 Only 128th through 159th elements has a meaning.");
7267 Vlatin_extra_code_table = Fmake_vector (make_number (256), Qnil);
7269 DEFVAR_LISP ("select-safe-coding-system-function",
7270 &Vselect_safe_coding_system_function,
7271 "Function to call to select safe coding system for encoding a text.\n\
7273 If set, this function is called to force a user to select a proper\n\
7274 coding system which can encode the text in the case that a default\n\
7275 coding system used in each operation can't encode the text.\n\
7277 The default value is `select-safe-coding-system' (which see).");
7278 Vselect_safe_coding_system_function = Qnil;
7280 DEFVAR_LISP ("char-coding-system-table", &Vchar_coding_system_table,
7281 "Char-table containing safe coding systems of each characters.\n\
7282 Each element doesn't include such generic coding systems that can\n\
7283 encode any characters. They are in the first extra slot.");
7284 Vchar_coding_system_table = Fmake_char_table (Qchar_coding_system, Qnil);
7286 DEFVAR_BOOL ("inhibit-iso-escape-detection",
7287 &inhibit_iso_escape_detection,
7288 "If non-nil, Emacs ignores ISO2022's escape sequence on code detection.\n\
7290 By default, on reading a file, Emacs tries to detect how the text is\n\
7291 encoded. This code detection is sensitive to escape sequences. If\n\
7292 the sequence is valid as ISO2022, the code is determined as one of\n\
7293 the ISO2022 encodings, and the file is decoded by the corresponding\n\
7294 coding system (e.g. `iso-2022-7bit').\n\
7296 However, there may be a case that you want to read escape sequences in\n\
7297 a file as is. In such a case, you can set this variable to non-nil.\n\
7298 Then, as the code detection ignores any escape sequences, no file is\n\
7299 detected as encoded in some ISO2022 encoding. The result is that all\n\
7300 escape sequences become visible in a buffer.\n\
7302 The default value is nil, and it is strongly recommended not to change\n\
7303 it. That is because many Emacs Lisp source files that contain\n\
7304 non-ASCII characters are encoded by the coding system `iso-2022-7bit'\n\
7305 in Emacs's distribution, and they won't be decoded correctly on\n\
7306 reading if you suppress escape sequence detection.\n\
7308 The other way to read escape sequences in a file without decoding is\n\
7309 to explicitly specify some coding system that doesn't use ISO2022's\n\
7310 escape sequence (e.g `latin-1') on reading by \\[universal-coding-system-argument].");
7311 inhibit_iso_escape_detection = 0;
7314 char *
7315 emacs_strerror (error_number)
7316 int error_number;
7318 char *str;
7320 synchronize_system_messages_locale ();
7321 str = strerror (error_number);
7323 if (! NILP (Vlocale_coding_system))
7325 Lisp_Object dec = code_convert_string_norecord (build_string (str),
7326 Vlocale_coding_system,
7328 str = (char *) XSTRING (dec)->data;
7331 return str;
7334 #endif /* emacs */