/* Coding system handler (conversion, detection, etc).
Copyright (C) 2001-2020 Free Software Foundation, Inc.
Copyright (C) 1995, 1996, 1997, 1998, 1999, 2000, 2001, 2002, 2003, 2004,
2005, 2006, 2007, 2008, 2009, 2010, 2011
National Institute of Advanced Industrial Science and Technology (AIST)
Registration Number H14PRO021
Copyright (C) 2003
National Institute of Advanced Industrial Science and Technology (AIST)
Registration Number H13PRO009
This file is part of GNU Emacs.
GNU Emacs is free software: you can redistribute it and/or modify
it under the terms of the GNU General Public License as published by
the Free Software Foundation, either version 3 of the License, or (at
your option) any later version.
GNU Emacs is distributed in the hope that it will be useful,
but WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
GNU General Public License for more details.
You should have received a copy of the GNU General Public License
along with GNU Emacs. If not, see . */
/*** TABLE OF CONTENTS ***
0. General comments
1. Preamble
2. Emacs' internal format (emacs-utf-8) handlers
3. UTF-8 handlers
4. UTF-16 handlers
5. Charset-base coding systems handlers
6. emacs-mule (old Emacs' internal format) handlers
7. ISO2022 handlers
8. Shift-JIS and BIG5 handlers
9. CCL handlers
10. C library functions
11. Emacs Lisp library functions
12. Postamble
*/
/*** 0. General comments ***
CODING SYSTEM
A coding system is an object for an encoding mechanism that contains
information about how to convert byte sequences to character
sequences and vice versa. When we say "decode", it means converting
a byte sequence of a specific coding system into a character
sequence that is represented by Emacs' internal coding system
`emacs-utf-8', and when we say "encode", it means converting a
character sequence of emacs-utf-8 to a byte sequence of a specific
coding system.
In Emacs Lisp, a coding system is represented by a Lisp symbol. On
the C level, a coding system is represented by a vector of attributes
stored in the hash table Vcharset_hash_table. The conversion from
coding system symbol to attributes vector is done by looking up
Vcharset_hash_table by the symbol.
Coding systems are classified into the following types depending on
the encoding mechanism. Here's a brief description of the types.
o UTF-8
o UTF-16
o Charset-base coding system
A coding system defined by one or more (coded) character sets.
Decoding and encoding are done by a code converter defined for each
character set.
o Old Emacs internal format (emacs-mule)
The coding system adopted by old versions of Emacs (20 and 21).
o ISO2022-base coding system
The most famous coding system for multiple character sets. X's
Compound Text, various EUCs (Extended Unix Code), and coding systems
used in the Internet communication such as ISO-2022-JP are all
variants of ISO2022.
o SJIS (or Shift-JIS or MS-Kanji-Code)
A coding system to encode character sets: ASCII, JISX0201, and
JISX0208. Widely used for PC's in Japan. Details are described in
section 8.
o BIG5
A coding system to encode character sets: ASCII and Big5. Widely
used for Chinese (mainly in Taiwan and Hong Kong). Details are
described in section 8. In this file, when we write "big5" (all
lowercase), we mean the coding system, and when we write "Big5"
(capitalized), we mean the character set.
o CCL
If a user wants to decode/encode text encoded in a coding system
not listed above, he can supply a decoder and an encoder for it in
CCL (Code Conversion Language) programs. Emacs executes the CCL
program while decoding/encoding.
o Raw-text
A coding system for text containing raw eight-bit data. Emacs
treats each byte of source text as a character (except for
end-of-line conversion).
o No-conversion
Like raw text, but don't do end-of-line conversion.
END-OF-LINE FORMAT
How text end-of-line is encoded depends on operating system. For
instance, Unix's format is just one byte of LF (line-feed) code,
whereas DOS's format is two-byte sequence of `carriage-return' and
`line-feed' codes. Classic Mac OS's format is usually one byte of
`carriage-return'.
Since text character encoding and end-of-line encoding are
independent, any coding system described above can take any format
of end-of-line (except for no-conversion).
STRUCT CODING_SYSTEM
Before using a coding system for code conversion (i.e. decoding and
encoding), we setup a structure of type `struct coding_system'.
This structure keeps various information about a specific code
conversion (e.g. the location of source and destination data).
*/
/* COMMON MACROS */
/*** GENERAL NOTES on `detect_coding_XXX ()' functions ***
These functions check if a byte sequence specified as a source in
CODING conforms to the format of XXX, and update the members of
DETECT_INFO.
Return true if the byte sequence conforms to XXX.
Below is the template of these functions. */
#if 0
static bool
detect_coding_XXX (struct coding_system *coding,
struct coding_detection_info *detect_info)
{
const unsigned char *src = coding->source;
const unsigned char *src_end = coding->source + coding->src_bytes;
bool multibytep = coding->src_multibyte;
ptrdiff_t consumed_chars = 0;
int found = 0;
...;
while (1)
{
/* Get one byte from the source. If the source is exhausted, jump
to no_more_source:. */
ONE_MORE_BYTE (c);
if (! __C_conforms_to_XXX___ (c))
break;
if (! __C_strongly_suggests_XXX__ (c))
found = CATEGORY_MASK_XXX;
}
/* The byte sequence is invalid for XXX. */
detect_info->rejected |= CATEGORY_MASK_XXX;
return 0;
no_more_source:
/* The source exhausted successfully. */
detect_info->found |= found;
return 1;
}
#endif
/*** GENERAL NOTES on `decode_coding_XXX ()' functions ***
These functions decode a byte sequence specified as a source by
CODING. The resulting multibyte text goes to a place pointed to by
CODING->charbuf, the length of which should not exceed
CODING->charbuf_size;
These functions set the information of original and decoded texts in
CODING->consumed, CODING->consumed_char, and CODING->charbuf_used.
They also set CODING->result to one of CODING_RESULT_XXX indicating
how the decoding is finished.
Below is the template of these functions. */
#if 0
static void
decode_coding_XXXX (struct coding_system *coding)
{
const unsigned char *src = coding->source + coding->consumed;
const unsigned char *src_end = coding->source + coding->src_bytes;
/* SRC_BASE remembers the start position in source in each loop.
The loop will be exited when there's not enough source code, or
when there's no room in CHARBUF for a decoded character. */
const unsigned char *src_base;
/* A buffer to produce decoded characters. */
int *charbuf = coding->charbuf + coding->charbuf_used;
int *charbuf_end = coding->charbuf + coding->charbuf_size;
bool multibytep = coding->src_multibyte;
while (1)
{
src_base = src;
if (charbuf < charbuf_end)
/* No more room to produce a decoded character. */
break;
ONE_MORE_BYTE (c);
/* Decode it. */
}
no_more_source:
if (src_base < src_end
&& coding->mode & CODING_MODE_LAST_BLOCK)
/* If the source ends by partial bytes to construct a character,
treat them as eight-bit raw data. */
while (src_base < src_end && charbuf < charbuf_end)
*charbuf++ = *src_base++;
/* Remember how many bytes and characters we consumed. If the
source is multibyte, the bytes and chars are not identical. */
coding->consumed = coding->consumed_char = src_base - coding->source;
/* Remember how many characters we produced. */
coding->charbuf_used = charbuf - coding->charbuf;
}
#endif
/*** GENERAL NOTES on `encode_coding_XXX ()' functions ***
These functions encode SRC_BYTES length text at SOURCE of Emacs'
internal multibyte format by CODING. The resulting byte sequence
goes to a place pointed to by DESTINATION, the length of which
should not exceed DST_BYTES.
These functions set the information of original and encoded texts in
the members produced, produced_char, consumed, and consumed_char of
the structure *CODING. They also set the member result to one of
CODING_RESULT_XXX indicating how the encoding finished.
DST_BYTES zero means that source area and destination area are
overlapped, which means that we can produce an encoded text until it
reaches at the head of not-yet-encoded source text.
Below is a template of these functions. */
#if 0
static void
encode_coding_XXX (struct coding_system *coding)
{
bool multibytep = coding->dst_multibyte;
int *charbuf = coding->charbuf;
int *charbuf_end = charbuf->charbuf + coding->charbuf_used;
unsigned char *dst = coding->destination + coding->produced;
unsigned char *dst_end = coding->destination + coding->dst_bytes;
unsigned char *adjusted_dst_end = dst_end - _MAX_BYTES_PRODUCED_IN_LOOP_;
ptrdiff_t produced_chars = 0;
for (; charbuf < charbuf_end && dst < adjusted_dst_end; charbuf++)
{
int c = *charbuf;
/* Encode C into DST, and increment DST. */
}
label_no_more_destination:
/* How many chars and bytes we produced. */
coding->produced_char += produced_chars;
coding->produced = dst - coding->destination;
}
#endif
/*** 1. Preamble ***/
#include
#ifdef HAVE_WCHAR_H
#include
#endif /* HAVE_WCHAR_H */
#include "lisp.h"
#include "character.h"
#include "buffer.h"
#include "charset.h"
#include "ccl.h"
#include "composite.h"
#include "coding.h"
#include "termhooks.h"
#include "pdumper.h"
Lisp_Object Vcoding_system_hash_table;
/* Coding-systems are handed between Emacs Lisp programs and C internal
routines by the following three variables. */
/* Coding system to be used to encode text for terminal display when
terminal coding system is nil. */
struct coding_system safe_terminal_coding;
/* Two special coding systems. */
static Lisp_Object Vsjis_coding_system;
static Lisp_Object Vbig5_coding_system;
/* ISO2022 section */
#define CODING_ISO_INITIAL(coding, reg) \
(XFIXNUM (AREF (AREF (CODING_ID_ATTRS ((coding)->id), \
coding_attr_iso_initial), \
reg)))
#define CODING_ISO_REQUEST(coding, charset_id) \
(((charset_id) <= (coding)->max_charset_id \
? ((coding)->safe_charsets[charset_id] != 255 \
? (coding)->safe_charsets[charset_id] \
: -1) \
: -1))
#define CODING_ISO_FLAGS(coding) \
((coding)->spec.iso_2022.flags)
#define CODING_ISO_DESIGNATION(coding, reg) \
((coding)->spec.iso_2022.current_designation[reg])
#define CODING_ISO_INVOCATION(coding, plane) \
((coding)->spec.iso_2022.current_invocation[plane])
#define CODING_ISO_SINGLE_SHIFTING(coding) \
((coding)->spec.iso_2022.single_shifting)
#define CODING_ISO_BOL(coding) \
((coding)->spec.iso_2022.bol)
#define CODING_ISO_INVOKED_CHARSET(coding, plane) \
(CODING_ISO_INVOCATION (coding, plane) < 0 ? -1 \
: CODING_ISO_DESIGNATION (coding, CODING_ISO_INVOCATION (coding, plane)))
#define CODING_ISO_CMP_STATUS(coding) \
(&(coding)->spec.iso_2022.cmp_status)
#define CODING_ISO_EXTSEGMENT_LEN(coding) \
((coding)->spec.iso_2022.ctext_extended_segment_len)
#define CODING_ISO_EMBEDDED_UTF_8(coding) \
((coding)->spec.iso_2022.embedded_utf_8)
/* Control characters of ISO2022. */
/* code */ /* function */
#define ISO_CODE_SO 0x0E /* shift-out */
#define ISO_CODE_SI 0x0F /* shift-in */
#define ISO_CODE_SS2_7 0x19 /* single-shift-2 for 7-bit code */
#define ISO_CODE_ESC 0x1B /* escape */
#define ISO_CODE_SS2 0x8E /* single-shift-2 */
#define ISO_CODE_SS3 0x8F /* single-shift-3 */
#define ISO_CODE_CSI 0x9B /* control-sequence-introducer */
/* All code (1-byte) of ISO2022 is classified into one of the
followings. */
enum iso_code_class_type
{
ISO_control_0, /* Control codes in the range
0x00..0x1F and 0x7F, except for the
following 5 codes. */
ISO_shift_out, /* ISO_CODE_SO (0x0E) */
ISO_shift_in, /* ISO_CODE_SI (0x0F) */
ISO_single_shift_2_7, /* ISO_CODE_SS2_7 (0x19) */
ISO_escape, /* ISO_CODE_ESC (0x1B) */
ISO_control_1, /* Control codes in the range
0x80..0x9F, except for the
following 3 codes. */
ISO_single_shift_2, /* ISO_CODE_SS2 (0x8E) */
ISO_single_shift_3, /* ISO_CODE_SS3 (0x8F) */
ISO_control_sequence_introducer, /* ISO_CODE_CSI (0x9B) */
ISO_0x20_or_0x7F, /* Codes of the values 0x20 or 0x7F. */
ISO_graphic_plane_0, /* Graphic codes in the range 0x21..0x7E. */
ISO_0xA0_or_0xFF, /* Codes of the values 0xA0 or 0xFF. */
ISO_graphic_plane_1 /* Graphic codes in the range 0xA1..0xFE. */
};
/** The macros CODING_ISO_FLAG_XXX defines a flag bit of the
`iso-flags' attribute of an iso2022 coding system. */
/* If set, produce long-form designation sequence (e.g. ESC $ ( A)
instead of the correct short-form sequence (e.g. ESC $ A). */
#define CODING_ISO_FLAG_LONG_FORM 0x0001
/* If set, reset graphic planes and registers at end-of-line to the
initial state. */
#define CODING_ISO_FLAG_RESET_AT_EOL 0x0002
/* If set, reset graphic planes and registers before any control
characters to the initial state. */
#define CODING_ISO_FLAG_RESET_AT_CNTL 0x0004
/* If set, encode by 7-bit environment. */
#define CODING_ISO_FLAG_SEVEN_BITS 0x0008
/* If set, use locking-shift function. */
#define CODING_ISO_FLAG_LOCKING_SHIFT 0x0010
/* If set, use single-shift function. Overwrite
CODING_ISO_FLAG_LOCKING_SHIFT. */
#define CODING_ISO_FLAG_SINGLE_SHIFT 0x0020
/* If set, use designation escape sequence. */
#define CODING_ISO_FLAG_DESIGNATION 0x0040
/* If set, produce revision number sequence. */
#define CODING_ISO_FLAG_REVISION 0x0080
/* If set, produce ISO6429's direction specifying sequence. */
#define CODING_ISO_FLAG_DIRECTION 0x0100
/* If set, assume designation states are reset at beginning of line on
output. */
#define CODING_ISO_FLAG_INIT_AT_BOL 0x0200
/* If set, designation sequence should be placed at beginning of line
on output. */
#define CODING_ISO_FLAG_DESIGNATE_AT_BOL 0x0400
/* If set, do not encode unsafe characters on output. */
#define CODING_ISO_FLAG_SAFE 0x0800
/* If set, extra latin codes (128..159) are accepted as a valid code
on input. */
#define CODING_ISO_FLAG_LATIN_EXTRA 0x1000
#define CODING_ISO_FLAG_COMPOSITION 0x2000
/* #define CODING_ISO_FLAG_EUC_TW_SHIFT 0x4000 */
#define CODING_ISO_FLAG_USE_ROMAN 0x8000
#define CODING_ISO_FLAG_USE_OLDJIS 0x10000
#define CODING_ISO_FLAG_LEVEL_4 0x20000
#define CODING_ISO_FLAG_FULL_SUPPORT 0x100000
/* A character to be produced on output if encoding of the original
character is prohibited by CODING_ISO_FLAG_SAFE. */
#define CODING_INHIBIT_CHARACTER_SUBSTITUTION '?'
/* UTF-8 section */
#define CODING_UTF_8_BOM(coding) \
((coding)->spec.utf_8_bom)
/* UTF-16 section */
#define CODING_UTF_16_BOM(coding) \
((coding)->spec.utf_16.bom)
#define CODING_UTF_16_ENDIAN(coding) \
((coding)->spec.utf_16.endian)
#define CODING_UTF_16_SURROGATE(coding) \
((coding)->spec.utf_16.surrogate)
/* CCL section */
#define CODING_CCL_DECODER(coding) \
AREF (CODING_ID_ATTRS ((coding)->id), coding_attr_ccl_decoder)
#define CODING_CCL_ENCODER(coding) \
AREF (CODING_ID_ATTRS ((coding)->id), coding_attr_ccl_encoder)
#define CODING_CCL_VALIDS(coding) \
(SDATA (AREF (CODING_ID_ATTRS ((coding)->id), coding_attr_ccl_valids)))
/* Index for each coding category in `coding_categories' */
enum coding_category
{
coding_category_iso_7,
coding_category_iso_7_tight,
coding_category_iso_8_1,
coding_category_iso_8_2,
coding_category_iso_7_else,
coding_category_iso_8_else,
coding_category_utf_8_auto,
coding_category_utf_8_nosig,
coding_category_utf_8_sig,
coding_category_utf_16_auto,
coding_category_utf_16_be,
coding_category_utf_16_le,
coding_category_utf_16_be_nosig,
coding_category_utf_16_le_nosig,
coding_category_charset,
coding_category_sjis,
coding_category_big5,
coding_category_ccl,
coding_category_emacs_mule,
/* All above are targets of code detection. */
coding_category_raw_text,
coding_category_undecided,
coding_category_max
};
/* Definitions of flag bits used in detect_coding_XXXX. */
#define CATEGORY_MASK_ISO_7 (1 << coding_category_iso_7)
#define CATEGORY_MASK_ISO_7_TIGHT (1 << coding_category_iso_7_tight)
#define CATEGORY_MASK_ISO_8_1 (1 << coding_category_iso_8_1)
#define CATEGORY_MASK_ISO_8_2 (1 << coding_category_iso_8_2)
#define CATEGORY_MASK_ISO_7_ELSE (1 << coding_category_iso_7_else)
#define CATEGORY_MASK_ISO_8_ELSE (1 << coding_category_iso_8_else)
#define CATEGORY_MASK_UTF_8_AUTO (1 << coding_category_utf_8_auto)
#define CATEGORY_MASK_UTF_8_NOSIG (1 << coding_category_utf_8_nosig)
#define CATEGORY_MASK_UTF_8_SIG (1 << coding_category_utf_8_sig)
#define CATEGORY_MASK_UTF_16_AUTO (1 << coding_category_utf_16_auto)
#define CATEGORY_MASK_UTF_16_BE (1 << coding_category_utf_16_be)
#define CATEGORY_MASK_UTF_16_LE (1 << coding_category_utf_16_le)
#define CATEGORY_MASK_UTF_16_BE_NOSIG (1 << coding_category_utf_16_be_nosig)
#define CATEGORY_MASK_UTF_16_LE_NOSIG (1 << coding_category_utf_16_le_nosig)
#define CATEGORY_MASK_CHARSET (1 << coding_category_charset)
#define CATEGORY_MASK_SJIS (1 << coding_category_sjis)
#define CATEGORY_MASK_BIG5 (1 << coding_category_big5)
#define CATEGORY_MASK_CCL (1 << coding_category_ccl)
#define CATEGORY_MASK_EMACS_MULE (1 << coding_category_emacs_mule)
#define CATEGORY_MASK_RAW_TEXT (1 << coding_category_raw_text)
/* This value is returned if detect_coding_mask () find nothing other
than ASCII characters. */
#define CATEGORY_MASK_ANY \
(CATEGORY_MASK_ISO_7 \
| CATEGORY_MASK_ISO_7_TIGHT \
| CATEGORY_MASK_ISO_8_1 \
| CATEGORY_MASK_ISO_8_2 \
| CATEGORY_MASK_ISO_7_ELSE \
| CATEGORY_MASK_ISO_8_ELSE \
| CATEGORY_MASK_UTF_8_AUTO \
| CATEGORY_MASK_UTF_8_NOSIG \
| CATEGORY_MASK_UTF_8_SIG \
| CATEGORY_MASK_UTF_16_AUTO \
| CATEGORY_MASK_UTF_16_BE \
| CATEGORY_MASK_UTF_16_LE \
| CATEGORY_MASK_UTF_16_BE_NOSIG \
| CATEGORY_MASK_UTF_16_LE_NOSIG \
| CATEGORY_MASK_CHARSET \
| CATEGORY_MASK_SJIS \
| CATEGORY_MASK_BIG5 \
| CATEGORY_MASK_CCL \
| CATEGORY_MASK_EMACS_MULE)
#define CATEGORY_MASK_ISO_7BIT \
(CATEGORY_MASK_ISO_7 | CATEGORY_MASK_ISO_7_TIGHT)
#define CATEGORY_MASK_ISO_8BIT \
(CATEGORY_MASK_ISO_8_1 | CATEGORY_MASK_ISO_8_2)
#define CATEGORY_MASK_ISO_ELSE \
(CATEGORY_MASK_ISO_7_ELSE | CATEGORY_MASK_ISO_8_ELSE)
#define CATEGORY_MASK_ISO_ESCAPE \
(CATEGORY_MASK_ISO_7 \
| CATEGORY_MASK_ISO_7_TIGHT \
| CATEGORY_MASK_ISO_7_ELSE \
| CATEGORY_MASK_ISO_8_ELSE)
#define CATEGORY_MASK_ISO \
( CATEGORY_MASK_ISO_7BIT \
| CATEGORY_MASK_ISO_8BIT \
| CATEGORY_MASK_ISO_ELSE)
#define CATEGORY_MASK_UTF_16 \
(CATEGORY_MASK_UTF_16_AUTO \
| CATEGORY_MASK_UTF_16_BE \
| CATEGORY_MASK_UTF_16_LE \
| CATEGORY_MASK_UTF_16_BE_NOSIG \
| CATEGORY_MASK_UTF_16_LE_NOSIG)
#define CATEGORY_MASK_UTF_8 \
(CATEGORY_MASK_UTF_8_AUTO \
| CATEGORY_MASK_UTF_8_NOSIG \
| CATEGORY_MASK_UTF_8_SIG)
/* Table of coding categories (Lisp symbols). This variable is for
internal use only. */
static Lisp_Object Vcoding_category_table;
/* Table of coding-categories ordered by priority. */
static enum coding_category coding_priorities[coding_category_max];
/* Nth element is a coding context for the coding system bound to the
Nth coding category. */
static struct coding_system coding_categories[coding_category_max];
/* Encode a flag that can be nil, something else, or t as -1, 0, 1. */
static int
encode_inhibit_flag (Lisp_Object flag)
{
return NILP (flag) ? -1 : EQ (flag, Qt);
}
/* True if the value of ENCODED_FLAG says a flag should be treated as set.
1 means yes, -1 means no, 0 means ask the user variable VAR. */
static bool
inhibit_flag (int encoded_flag, bool var)
{
return 0 < encoded_flag + var;
}
#define CODING_GET_INFO(coding, attrs, charset_list) \
do { \
(attrs) = CODING_ID_ATTRS ((coding)->id); \
(charset_list) = CODING_ATTR_CHARSET_LIST (attrs); \
} while (false)
/* True if CODING's destination can be grown. */
static bool
growable_destination (struct coding_system *coding)
{
return STRINGP (coding->dst_object) || BUFFERP (coding->dst_object);
}
/* Safely get one byte from the source text pointed by SRC which ends
at SRC_END, and set C to that byte. If there are not enough bytes
in the source, it jumps to 'no_more_source'. If MULTIBYTEP,
and a multibyte character is found at SRC, set C to the
negative value of the character code. The caller should declare
and set these variables appropriately in advance:
src, src_end, multibytep */
#define ONE_MORE_BYTE(c) \
do { \
if (src == src_end) \
{ \
if (src_base < src) \
record_conversion_result \
(coding, CODING_RESULT_INSUFFICIENT_SRC); \
goto no_more_source; \
} \
c = *src++; \
if (multibytep && (c & 0x80)) \
{ \
if ((c & 0xFE) == 0xC0) \
c = ((c & 1) << 6) | *src++; \
else \
{ \
src--; \
c = - string_char_advance (&src); \
record_conversion_result \
(coding, CODING_RESULT_INVALID_SRC); \
} \
} \
consumed_chars++; \
} while (0)
/* Safely get two bytes from the source text pointed by SRC which ends
at SRC_END, and set C1 and C2 to those bytes while skipping the
heading multibyte characters. If there are not enough bytes in the
source, it jumps to 'no_more_source'. If MULTIBYTEP and
a multibyte character is found for C2, set C2 to the negative value
of the character code. The caller should declare and set these
variables appropriately in advance:
src, src_end, multibytep
It is intended that this macro is used in detect_coding_utf_16. */
#define TWO_MORE_BYTES(c1, c2) \
do { \
do { \
if (src == src_end) \
goto no_more_source; \
c1 = *src++; \
if (multibytep && (c1 & 0x80)) \
{ \
if ((c1 & 0xFE) == 0xC0) \
c1 = ((c1 & 1) << 6) | *src++; \
else \
{ \
src += BYTES_BY_CHAR_HEAD (c1) - 1; \
c1 = -1; \
} \
} \
} while (c1 < 0); \
if (src == src_end) \
goto no_more_source; \
c2 = *src++; \
if (multibytep && (c2 & 0x80)) \
{ \
if ((c2 & 0xFE) == 0xC0) \
c2 = ((c2 & 1) << 6) | *src++; \
else \
c2 = -1; \
} \
} while (0)
/* Store a byte C in the place pointed by DST and increment DST to the
next free point, and increment PRODUCED_CHARS. The caller should
assure that C is 0..127, and declare and set the variable `dst'
appropriately in advance.
*/
#define EMIT_ONE_ASCII_BYTE(c) \
do { \
produced_chars++; \
*dst++ = (c); \
} while (0)
/* Like EMIT_ONE_ASCII_BYTE but store two bytes; C1 and C2. */
#define EMIT_TWO_ASCII_BYTES(c1, c2) \
do { \
produced_chars += 2; \
*dst++ = (c1), *dst++ = (c2); \
} while (0)
/* Store a byte C in the place pointed by DST and increment DST to the
next free point, and increment PRODUCED_CHARS. If MULTIBYTEP,
store in an appropriate multibyte form. The caller should
declare and set the variables `dst' and `multibytep' appropriately
in advance. */
#define EMIT_ONE_BYTE(c) \
do { \
produced_chars++; \
if (multibytep) \
{ \
unsigned ch = (c); \
if (ch >= 0x80) \
ch = BYTE8_TO_CHAR (ch); \
dst += CHAR_STRING (ch, dst); \
} \
else \
*dst++ = (c); \
} while (0)
/* Like EMIT_ONE_BYTE, but emit two bytes; C1 and C2. */
#define EMIT_TWO_BYTES(c1, c2) \
do { \
produced_chars += 2; \
if (multibytep) \
{ \
unsigned ch; \
\
ch = (c1); \
if (ch >= 0x80) \
ch = BYTE8_TO_CHAR (ch); \
dst += CHAR_STRING (ch, dst); \
ch = (c2); \
if (ch >= 0x80) \
ch = BYTE8_TO_CHAR (ch); \
dst += CHAR_STRING (ch, dst); \
} \
else \
{ \
*dst++ = (c1); \
*dst++ = (c2); \
} \
} while (0)
#define EMIT_THREE_BYTES(c1, c2, c3) \
do { \
EMIT_ONE_BYTE (c1); \
EMIT_TWO_BYTES (c2, c3); \
} while (0)
#define EMIT_FOUR_BYTES(c1, c2, c3, c4) \
do { \
EMIT_TWO_BYTES (c1, c2); \
EMIT_TWO_BYTES (c3, c4); \
} while (0)
static void
record_conversion_result (struct coding_system *coding,
enum coding_result_code result)
{
coding->result = result;
switch (result)
{
case CODING_RESULT_INSUFFICIENT_SRC:
Vlast_code_conversion_error = Qinsufficient_source;
break;
case CODING_RESULT_INVALID_SRC:
Vlast_code_conversion_error = Qinvalid_source;
break;
case CODING_RESULT_INTERRUPT:
Vlast_code_conversion_error = Qinterrupted;
break;
case CODING_RESULT_INSUFFICIENT_DST:
/* Don't record this error in Vlast_code_conversion_error
because it happens just temporarily and is resolved when the
whole conversion is finished. */
break;
case CODING_RESULT_SUCCESS:
break;
default:
Vlast_code_conversion_error = intern ("Unknown error");
}
}
/* These wrapper macros are used to preserve validity of pointers into
buffer text across calls to decode_char, encode_char, etc, which
could cause relocation of buffers if it loads a charset map,
because loading a charset map allocates large structures. */
#define CODING_DECODE_CHAR(coding, src, src_base, src_end, charset, code, c) \
do { \
ptrdiff_t offset; \
\
charset_map_loaded = 0; \
c = DECODE_CHAR (charset, code); \
if (charset_map_loaded \
&& (offset = coding_change_source (coding))) \
{ \
src += offset; \
src_base += offset; \
src_end += offset; \
} \
} while (0)
#define CODING_ENCODE_CHAR(coding, dst, dst_end, charset, c, code) \
do { \
ptrdiff_t offset; \
\
charset_map_loaded = 0; \
code = ENCODE_CHAR (charset, c); \
if (charset_map_loaded \
&& (offset = coding_change_destination (coding))) \
{ \
dst += offset; \
dst_end += offset; \
} \
} while (0)
#define CODING_CHAR_CHARSET(coding, dst, dst_end, c, charset_list, code_return, charset) \
do { \
ptrdiff_t offset; \
\
charset_map_loaded = 0; \
charset = char_charset (c, charset_list, code_return); \
if (charset_map_loaded \
&& (offset = coding_change_destination (coding))) \
{ \
dst += offset; \
dst_end += offset; \
} \
} while (0)
#define CODING_CHAR_CHARSET_P(coding, dst, dst_end, c, charset, result) \
do { \
ptrdiff_t offset; \
\
charset_map_loaded = 0; \
result = CHAR_CHARSET_P (c, charset); \
if (charset_map_loaded \
&& (offset = coding_change_destination (coding))) \
{ \
dst += offset; \
dst_end += offset; \
} \
} while (0)
/* If there are at least BYTES length of room at dst, allocate memory
for coding->destination and update dst and dst_end. We don't have
to take care of coding->source which will be relocated. It is
handled by calling coding_set_source in encode_coding. */
#define ASSURE_DESTINATION(bytes) \
do { \
if (dst + (bytes) >= dst_end) \
{ \
ptrdiff_t more_bytes = charbuf_end - charbuf + (bytes); \
\
dst = alloc_destination (coding, more_bytes, dst); \
dst_end = coding->destination + coding->dst_bytes; \
} \
} while (0)
/* Store multibyte form of the character C in P, and advance P to the
end of the multibyte form. This used to be like adding CHAR_STRING
without ever calling MAYBE_UNIFY_CHAR, but nowadays we don't call
MAYBE_UNIFY_CHAR in CHAR_STRING. */
#define CHAR_STRING_ADVANCE_NO_UNIFY(c, p) ((p) += CHAR_STRING (c, p))
/* Return the character code of character whose multibyte form is at
P, and advance P to the end of the multibyte form. This used to be
like string_char_advance without ever calling MAYBE_UNIFY_CHAR, but
nowadays string_char_advance doesn't call MAYBE_UNIFY_CHAR. */
#define STRING_CHAR_ADVANCE_NO_UNIFY(p) string_char_advance (&(p))
/* Set coding->source from coding->src_object. */
static void
coding_set_source (struct coding_system *coding)
{
if (BUFFERP (coding->src_object))
{
struct buffer *buf = XBUFFER (coding->src_object);
if (coding->src_pos < 0)
coding->source = BUF_GAP_END_ADDR (buf) + coding->src_pos_byte;
else
coding->source = BUF_BYTE_ADDRESS (buf, coding->src_pos_byte);
}
else if (STRINGP (coding->src_object))
{
coding->source = SDATA (coding->src_object) + coding->src_pos_byte;
}
else
{
/* Otherwise, the source is C string and is never relocated
automatically. Thus we don't have to update anything. */
}
}
/* Set coding->source from coding->src_object, and return how many
bytes coding->source was changed. */
static ptrdiff_t
coding_change_source (struct coding_system *coding)
{
const unsigned char *orig = coding->source;
coding_set_source (coding);
return coding->source - orig;
}
/* Set coding->destination from coding->dst_object. */
static void
coding_set_destination (struct coding_system *coding)
{
if (BUFFERP (coding->dst_object))
{
if (BUFFERP (coding->src_object) && coding->src_pos < 0)
{
coding->destination = BEG_ADDR + coding->dst_pos_byte - BEG_BYTE;
coding->dst_bytes = (GAP_END_ADDR
- (coding->src_bytes - coding->consumed)
- coding->destination);
}
else
{
/* We are sure that coding->dst_pos_byte is before the gap
of the buffer. */
coding->destination = (BUF_BEG_ADDR (XBUFFER (coding->dst_object))
+ coding->dst_pos_byte - BEG_BYTE);
coding->dst_bytes = (BUF_GAP_END_ADDR (XBUFFER (coding->dst_object))
- coding->destination);
}
}
else
{
/* Otherwise, the destination is C string and is never relocated
automatically. Thus we don't have to update anything. */
}
}
/* Set coding->destination from coding->dst_object, and return how
many bytes coding->destination was changed. */
static ptrdiff_t
coding_change_destination (struct coding_system *coding)
{
const unsigned char *orig = coding->destination;
coding_set_destination (coding);
return coding->destination - orig;
}
static void
coding_alloc_by_realloc (struct coding_system *coding, ptrdiff_t bytes)
{
ptrdiff_t newbytes;
if (INT_ADD_WRAPV (coding->dst_bytes, bytes, &newbytes)
|| SIZE_MAX < newbytes)
string_overflow ();
coding->destination = xrealloc (coding->destination, newbytes);
coding->dst_bytes = newbytes;
}
static void
coding_alloc_by_making_gap (struct coding_system *coding,
ptrdiff_t gap_head_used, ptrdiff_t bytes)
{
if (EQ (coding->src_object, coding->dst_object))
{
/* The gap may contain the produced data at the head and not-yet
consumed data at the tail. To preserve those data, we at
first make the gap size to zero, then increase the gap
size. */
ptrdiff_t add = GAP_SIZE;
GPT += gap_head_used, GPT_BYTE += gap_head_used;
GAP_SIZE = 0; ZV += add; Z += add; ZV_BYTE += add; Z_BYTE += add;
make_gap (bytes);
GAP_SIZE += add; ZV -= add; Z -= add; ZV_BYTE -= add; Z_BYTE -= add;
GPT -= gap_head_used, GPT_BYTE -= gap_head_used;
}
else
make_gap_1 (XBUFFER (coding->dst_object), bytes);
}
static unsigned char *
alloc_destination (struct coding_system *coding, ptrdiff_t nbytes,
unsigned char *dst)
{
ptrdiff_t offset = dst - coding->destination;
if (BUFFERP (coding->dst_object))
{
struct buffer *buf = XBUFFER (coding->dst_object);
coding_alloc_by_making_gap (coding, dst - BUF_GPT_ADDR (buf), nbytes);
}
else
coding_alloc_by_realloc (coding, nbytes);
coding_set_destination (coding);
dst = coding->destination + offset;
return dst;
}
/** Macros for annotations. */
/* An annotation data is stored in the array coding->charbuf in this
format:
[ -LENGTH ANNOTATION_MASK NCHARS ... ]
LENGTH is the number of elements in the annotation.
ANNOTATION_MASK is one of CODING_ANNOTATE_XXX_MASK.
NCHARS is the number of characters in the text annotated.
The format of the following elements depend on ANNOTATION_MASK.
In the case of CODING_ANNOTATE_COMPOSITION_MASK, these elements
follows:
... NBYTES METHOD [ COMPOSITION-COMPONENTS ... ]
NBYTES is the number of bytes specified in the header part of
old-style emacs-mule encoding, or 0 for the other kind of
composition.
METHOD is one of enum composition_method.
Optional COMPOSITION-COMPONENTS are characters and composition
rules.
In the case of CODING_ANNOTATE_CHARSET_MASK, one element CHARSET-ID
follows.
If ANNOTATION_MASK is 0, this annotation is just a space holder to
recover from an invalid annotation, and should be skipped by
produce_annotation. */
/* Maximum length of the header of annotation data. */
#define MAX_ANNOTATION_LENGTH 5
#define ADD_ANNOTATION_DATA(buf, len, mask, nchars) \
do { \
*(buf)++ = -(len); \
*(buf)++ = (mask); \
*(buf)++ = (nchars); \
coding->annotated = 1; \
} while (0);
#define ADD_COMPOSITION_DATA(buf, nchars, nbytes, method) \
do { \
ADD_ANNOTATION_DATA (buf, 5, CODING_ANNOTATE_COMPOSITION_MASK, nchars); \
*buf++ = nbytes; \
*buf++ = method; \
} while (0)
#define ADD_CHARSET_DATA(buf, nchars, id) \
do { \
ADD_ANNOTATION_DATA (buf, 4, CODING_ANNOTATE_CHARSET_MASK, nchars); \
*buf++ = id; \
} while (0)
/* Bitmasks for coding->eol_seen. */
#define EOL_SEEN_NONE 0
#define EOL_SEEN_LF 1
#define EOL_SEEN_CR 2
#define EOL_SEEN_CRLF 4
/*** 2. Emacs' internal format (emacs-utf-8) ***/
/*** 3. UTF-8 ***/
/* See the above "GENERAL NOTES on `detect_coding_XXX ()' functions".
Return true if a text is encoded in UTF-8. */
#define UTF_8_1_OCTET_P(c) ((c) < 0x80)
#define UTF_8_EXTRA_OCTET_P(c) (((c) & 0xC0) == 0x80)
#define UTF_8_2_OCTET_LEADING_P(c) (((c) & 0xE0) == 0xC0)
#define UTF_8_3_OCTET_LEADING_P(c) (((c) & 0xF0) == 0xE0)
#define UTF_8_4_OCTET_LEADING_P(c) (((c) & 0xF8) == 0xF0)
#define UTF_8_5_OCTET_LEADING_P(c) (((c) & 0xFC) == 0xF8)
#define UTF_8_BOM_1 0xEF
#define UTF_8_BOM_2 0xBB
#define UTF_8_BOM_3 0xBF
/* Unlike the other detect_coding_XXX, this function counts the number
of characters and checks the EOL format. */
static bool
detect_coding_utf_8 (struct coding_system *coding,
struct coding_detection_info *detect_info)
{
const unsigned char *src = coding->source, *src_base;
const unsigned char *src_end = coding->source + coding->src_bytes;
bool multibytep = coding->src_multibyte;
ptrdiff_t consumed_chars = 0;
bool bom_found = 0;
ptrdiff_t nchars = coding->head_ascii;
int eol_seen = coding->eol_seen;
detect_info->checked |= CATEGORY_MASK_UTF_8;
/* A coding system of this category is always ASCII compatible. */
src += nchars;
if (src == coding->source /* BOM should be at the head. */
&& src + 3 < src_end /* BOM is 3-byte long. */
&& src[0] == UTF_8_BOM_1
&& src[1] == UTF_8_BOM_2
&& src[2] == UTF_8_BOM_3)
{
bom_found = 1;
src += 3;
nchars++;
}
while (1)
{
int c, c1, c2, c3, c4;
src_base = src;
ONE_MORE_BYTE (c);
if (c < 0 || UTF_8_1_OCTET_P (c))
{
nchars++;
if (c == '\r')
{
if (src < src_end && *src == '\n')
{
eol_seen |= EOL_SEEN_CRLF;
src++;
nchars++;
}
else
eol_seen |= EOL_SEEN_CR;
}
else if (c == '\n')
eol_seen |= EOL_SEEN_LF;
continue;
}
ONE_MORE_BYTE (c1);
if (c1 < 0 || ! UTF_8_EXTRA_OCTET_P (c1))
break;
if (UTF_8_2_OCTET_LEADING_P (c))
{
nchars++;
continue;
}
ONE_MORE_BYTE (c2);
if (c2 < 0 || ! UTF_8_EXTRA_OCTET_P (c2))
break;
if (UTF_8_3_OCTET_LEADING_P (c))
{
nchars++;
continue;
}
ONE_MORE_BYTE (c3);
if (c3 < 0 || ! UTF_8_EXTRA_OCTET_P (c3))
break;
if (UTF_8_4_OCTET_LEADING_P (c))
{
nchars++;
continue;
}
ONE_MORE_BYTE (c4);
if (c4 < 0 || ! UTF_8_EXTRA_OCTET_P (c4))
break;
if (UTF_8_5_OCTET_LEADING_P (c)
/* If we ever need to increase MAX_CHAR, the below may need
to be reviewed. */
&& c < MAX_MULTIBYTE_LEADING_CODE)
{
nchars++;
continue;
}
break;
}
detect_info->rejected |= CATEGORY_MASK_UTF_8;
return 0;
no_more_source:
if (src_base < src && coding->mode & CODING_MODE_LAST_BLOCK)
{
detect_info->rejected |= CATEGORY_MASK_UTF_8;
return 0;
}
if (bom_found)
{
/* The first character 0xFFFE doesn't necessarily mean a BOM. */
detect_info->found |= CATEGORY_MASK_UTF_8_AUTO | CATEGORY_MASK_UTF_8_SIG | CATEGORY_MASK_UTF_8_NOSIG;
}
else
{
detect_info->rejected |= CATEGORY_MASK_UTF_8_SIG;
if (nchars < src_end - coding->source)
/* The found characters are less than source bytes, which
means that we found a valid non-ASCII characters. */
detect_info->found |= CATEGORY_MASK_UTF_8_AUTO | CATEGORY_MASK_UTF_8_NOSIG;
}
coding->detected_utf8_bytes = src_base - coding->source;
coding->detected_utf8_chars = nchars;
return 1;
}
static void
decode_coding_utf_8 (struct coding_system *coding)
{
const unsigned char *src = coding->source + coding->consumed;
const unsigned char *src_end = coding->source + coding->src_bytes;
const unsigned char *src_base;
int *charbuf = coding->charbuf + coding->charbuf_used;
int *charbuf_end = coding->charbuf + coding->charbuf_size;
ptrdiff_t consumed_chars = 0, consumed_chars_base = 0;
bool multibytep = coding->src_multibyte;
enum utf_bom_type bom = CODING_UTF_8_BOM (coding);
bool eol_dos
= !inhibit_eol_conversion && EQ (CODING_ID_EOL_TYPE (coding->id), Qdos);
int byte_after_cr = -1;
if (bom != utf_without_bom)
{
int c1, c2, c3;
src_base = src;
ONE_MORE_BYTE (c1);
if (! UTF_8_3_OCTET_LEADING_P (c1))
src = src_base;
else
{
ONE_MORE_BYTE (c2);
if (! UTF_8_EXTRA_OCTET_P (c2))
src = src_base;
else
{
ONE_MORE_BYTE (c3);
if (! UTF_8_EXTRA_OCTET_P (c3))
src = src_base;
else
{
if ((c1 != UTF_8_BOM_1)
|| (c2 != UTF_8_BOM_2) || (c3 != UTF_8_BOM_3))
src = src_base;
else
CODING_UTF_8_BOM (coding) = utf_without_bom;
}
}
}
}
CODING_UTF_8_BOM (coding) = utf_without_bom;
while (1)
{
int c, c1, c2, c3, c4, c5;
src_base = src;
consumed_chars_base = consumed_chars;
if (charbuf >= charbuf_end)
{
if (byte_after_cr >= 0)
src_base--;
break;
}
/* In the simple case, rapidly handle ordinary characters */
if (multibytep && ! eol_dos
&& charbuf < charbuf_end - 6 && src < src_end - 6)
{
while (charbuf < charbuf_end - 6 && src < src_end - 6)
{
c1 = *src;
if (c1 & 0x80)
break;
src++;
consumed_chars++;
*charbuf++ = c1;
c1 = *src;
if (c1 & 0x80)
break;
src++;
consumed_chars++;
*charbuf++ = c1;
c1 = *src;
if (c1 & 0x80)
break;
src++;
consumed_chars++;
*charbuf++ = c1;
c1 = *src;
if (c1 & 0x80)
break;
src++;
consumed_chars++;
*charbuf++ = c1;
}
/* If we handled at least one character, restart the main loop. */
if (src != src_base)
continue;
}
if (byte_after_cr >= 0)
c1 = byte_after_cr, byte_after_cr = -1;
else
ONE_MORE_BYTE (c1);
if (c1 < 0)
{
c = - c1;
}
else if (UTF_8_1_OCTET_P (c1))
{
if (eol_dos && c1 == '\r')
ONE_MORE_BYTE (byte_after_cr);
c = c1;
}
else
{
ONE_MORE_BYTE (c2);
if (c2 < 0 || ! UTF_8_EXTRA_OCTET_P (c2))
goto invalid_code;
if (UTF_8_2_OCTET_LEADING_P (c1))
{
c = ((c1 & 0x1F) << 6) | (c2 & 0x3F);
/* Reject overlong sequences here and below. Encoders
producing them are incorrect, they can be misleading,
and they mess up read/write invariance. */
if (c < 128)
goto invalid_code;
}
else
{
ONE_MORE_BYTE (c3);
if (c3 < 0 || ! UTF_8_EXTRA_OCTET_P (c3))
goto invalid_code;
if (UTF_8_3_OCTET_LEADING_P (c1))
{
c = (((c1 & 0xF) << 12)
| ((c2 & 0x3F) << 6) | (c3 & 0x3F));
if (c < 0x800
|| (c >= 0xd800 && c < 0xe000)) /* surrogates (invalid) */
goto invalid_code;
}
else
{
ONE_MORE_BYTE (c4);
if (c4 < 0 || ! UTF_8_EXTRA_OCTET_P (c4))
goto invalid_code;
if (UTF_8_4_OCTET_LEADING_P (c1))
{
c = (((c1 & 0x7) << 18) | ((c2 & 0x3F) << 12)
| ((c3 & 0x3F) << 6) | (c4 & 0x3F));
if (c < 0x10000)
goto invalid_code;
}
else
{
ONE_MORE_BYTE (c5);
if (c5 < 0 || ! UTF_8_EXTRA_OCTET_P (c5))
goto invalid_code;
if (UTF_8_5_OCTET_LEADING_P (c1))
{
c = (((c1 & 0x3) << 24) | ((c2 & 0x3F) << 18)
| ((c3 & 0x3F) << 12) | ((c4 & 0x3F) << 6)
| (c5 & 0x3F));
if ((c > MAX_CHAR) || (c < 0x200000))
goto invalid_code;
}
else
goto invalid_code;
}
}
}
}
*charbuf++ = c;
continue;
invalid_code:
src = src_base;
consumed_chars = consumed_chars_base;
ONE_MORE_BYTE (c);
*charbuf++ = ASCII_CHAR_P (c) ? c : BYTE8_TO_CHAR (c);
}
no_more_source:
coding->consumed_char += consumed_chars_base;
coding->consumed = src_base - coding->source;
coding->charbuf_used = charbuf - coding->charbuf;
}
bool
encode_coding_utf_8 (struct coding_system *coding)
{
bool multibytep = coding->dst_multibyte;
int *charbuf = coding->charbuf;
int *charbuf_end = charbuf + coding->charbuf_used;
unsigned char *dst = coding->destination + coding->produced;
unsigned char *dst_end = coding->destination + coding->dst_bytes;
ptrdiff_t produced_chars = 0;
int c;
if (CODING_UTF_8_BOM (coding) == utf_with_bom)
{
ASSURE_DESTINATION (3);
EMIT_THREE_BYTES (UTF_8_BOM_1, UTF_8_BOM_2, UTF_8_BOM_3);
CODING_UTF_8_BOM (coding) = utf_without_bom;
}
if (multibytep)
{
int safe_room = MAX_MULTIBYTE_LENGTH * 2;
while (charbuf < charbuf_end)
{
unsigned char str[MAX_MULTIBYTE_LENGTH], *p, *pend = str;
ASSURE_DESTINATION (safe_room);
c = *charbuf++;
if (CHAR_BYTE8_P (c))
{
c = CHAR_TO_BYTE8 (c);
EMIT_ONE_BYTE (c);
}
else
{
CHAR_STRING_ADVANCE_NO_UNIFY (c, pend);
for (p = str; p < pend; p++)
EMIT_ONE_BYTE (*p);
}
}
}
else
{
int safe_room = MAX_MULTIBYTE_LENGTH;
while (charbuf < charbuf_end)
{
ASSURE_DESTINATION (safe_room);
c = *charbuf++;
if (CHAR_BYTE8_P (c))
*dst++ = CHAR_TO_BYTE8 (c);
else
CHAR_STRING_ADVANCE_NO_UNIFY (c, dst);
}
produced_chars = dst - (coding->destination + coding->produced);
}
record_conversion_result (coding, CODING_RESULT_SUCCESS);
coding->produced_char += produced_chars;
coding->produced = dst - coding->destination;
return 0;
}
/* See the above "GENERAL NOTES on `detect_coding_XXX ()' functions".
Return true if a text is encoded in one of UTF-16 based coding systems. */
static bool
detect_coding_utf_16 (struct coding_system *coding,
struct coding_detection_info *detect_info)
{
const unsigned char *src = coding->source;
const unsigned char *src_end = coding->source + coding->src_bytes;
bool multibytep = coding->src_multibyte;
int c1, c2;
detect_info->checked |= CATEGORY_MASK_UTF_16;
if (coding->mode & CODING_MODE_LAST_BLOCK
&& (coding->src_chars & 1))
{
detect_info->rejected |= CATEGORY_MASK_UTF_16;
return 0;
}
TWO_MORE_BYTES (c1, c2);
if ((c1 == 0xFF) && (c2 == 0xFE))
{
detect_info->found |= (CATEGORY_MASK_UTF_16_LE
| CATEGORY_MASK_UTF_16_AUTO);
detect_info->rejected |= (CATEGORY_MASK_UTF_16_BE
| CATEGORY_MASK_UTF_16_BE_NOSIG
| CATEGORY_MASK_UTF_16_LE_NOSIG);
}
else if ((c1 == 0xFE) && (c2 == 0xFF))
{
detect_info->found |= (CATEGORY_MASK_UTF_16_BE
| CATEGORY_MASK_UTF_16_AUTO);
detect_info->rejected |= (CATEGORY_MASK_UTF_16_LE
| CATEGORY_MASK_UTF_16_BE_NOSIG
| CATEGORY_MASK_UTF_16_LE_NOSIG);
}
else if (c2 < 0)
{
detect_info->rejected |= CATEGORY_MASK_UTF_16;
return 0;
}
else
{
/* We check the dispersion of Eth and Oth bytes where E is even and
O is odd. If both are high, we assume binary data.*/
unsigned char e[256], o[256];
unsigned e_num = 1, o_num = 1;
memset (e, 0, 256);
memset (o, 0, 256);
e[c1] = 1;
o[c2] = 1;
detect_info->rejected |= (CATEGORY_MASK_UTF_16_AUTO
|CATEGORY_MASK_UTF_16_BE
| CATEGORY_MASK_UTF_16_LE);
while ((detect_info->rejected & CATEGORY_MASK_UTF_16)
!= CATEGORY_MASK_UTF_16)
{
TWO_MORE_BYTES (c1, c2);
if (c2 < 0)
break;
if (! e[c1])
{
e[c1] = 1;
e_num++;
if (e_num >= 128)
detect_info->rejected |= CATEGORY_MASK_UTF_16_BE_NOSIG;
}
if (! o[c2])
{
o[c2] = 1;
o_num++;
if (o_num >= 128)
detect_info->rejected |= CATEGORY_MASK_UTF_16_LE_NOSIG;
}
}
return 0;
}
no_more_source:
return 1;
}
static void
decode_coding_utf_16 (struct coding_system *coding)
{
const unsigned char *src = coding->source + coding->consumed;
const unsigned char *src_end = coding->source + coding->src_bytes;
const unsigned char *src_base;
int *charbuf = coding->charbuf + coding->charbuf_used;
/* We may produces at most 3 chars in one loop. */
int *charbuf_end = coding->charbuf + coding->charbuf_size - 2;
ptrdiff_t consumed_chars = 0, consumed_chars_base = 0;
bool multibytep = coding->src_multibyte;
enum utf_bom_type bom = CODING_UTF_16_BOM (coding);
enum utf_16_endian_type endian = CODING_UTF_16_ENDIAN (coding);
int surrogate = CODING_UTF_16_SURROGATE (coding);
bool eol_dos
= !inhibit_eol_conversion && EQ (CODING_ID_EOL_TYPE (coding->id), Qdos);
int byte_after_cr1 = -1, byte_after_cr2 = -1;
if (bom == utf_with_bom)
{
int c, c1, c2;
src_base = src;
ONE_MORE_BYTE (c1);
ONE_MORE_BYTE (c2);
c = (c1 << 8) | c2;
if (endian == utf_16_big_endian
? c != 0xFEFF : c != 0xFFFE)
{
/* The first two bytes are not BOM. Treat them as bytes
for a normal character. */
src = src_base;
}
CODING_UTF_16_BOM (coding) = utf_without_bom;
}
else if (bom == utf_detect_bom)
{
/* We have already tried to detect BOM and failed in
detect_coding. */
CODING_UTF_16_BOM (coding) = utf_without_bom;
}
while (1)
{
int c, c1, c2;
src_base = src;
consumed_chars_base = consumed_chars;
if (charbuf >= charbuf_end)
{
if (byte_after_cr1 >= 0)
src_base -= 2;
break;
}
if (byte_after_cr1 >= 0)
c1 = byte_after_cr1, byte_after_cr1 = -1;
else
ONE_MORE_BYTE (c1);
if (c1 < 0)
{
*charbuf++ = -c1;
continue;
}
if (byte_after_cr2 >= 0)
c2 = byte_after_cr2, byte_after_cr2 = -1;
else
ONE_MORE_BYTE (c2);
if (c2 < 0)
{
*charbuf++ = ASCII_CHAR_P (c1) ? c1 : BYTE8_TO_CHAR (c1);
*charbuf++ = -c2;
continue;
}
c = (endian == utf_16_big_endian
? ((c1 << 8) | c2) : ((c2 << 8) | c1));
if (surrogate)
{
if (! UTF_16_LOW_SURROGATE_P (c))
{
if (endian == utf_16_big_endian)
c1 = surrogate >> 8, c2 = surrogate & 0xFF;
else
c1 = surrogate & 0xFF, c2 = surrogate >> 8;
*charbuf++ = c1;
*charbuf++ = c2;
if (UTF_16_HIGH_SURROGATE_P (c))
CODING_UTF_16_SURROGATE (coding) = surrogate = c;
else
*charbuf++ = c;
}
else
{
c = ((surrogate - 0xD800) << 10) | (c - 0xDC00);
CODING_UTF_16_SURROGATE (coding) = surrogate = 0;
*charbuf++ = 0x10000 + c;
}
}
else
{
if (UTF_16_HIGH_SURROGATE_P (c))
CODING_UTF_16_SURROGATE (coding) = surrogate = c;
else
{
if (eol_dos && c == '\r')
{
ONE_MORE_BYTE (byte_after_cr1);
ONE_MORE_BYTE (byte_after_cr2);
}
*charbuf++ = c;
}
}
}
no_more_source:
coding->consumed_char += consumed_chars_base;
coding->consumed = src_base - coding->source;
coding->charbuf_used = charbuf - coding->charbuf;
}
static bool
encode_coding_utf_16 (struct coding_system *coding)
{
bool multibytep = coding->dst_multibyte;
int *charbuf = coding->charbuf;
int *charbuf_end = charbuf + coding->charbuf_used;
unsigned char *dst = coding->destination + coding->produced;
unsigned char *dst_end = coding->destination + coding->dst_bytes;
int safe_room = 8;
enum utf_bom_type bom = CODING_UTF_16_BOM (coding);
bool big_endian = CODING_UTF_16_ENDIAN (coding) == utf_16_big_endian;
ptrdiff_t produced_chars = 0;
int c;
if (bom != utf_without_bom)
{
ASSURE_DESTINATION (safe_room);
if (big_endian)
EMIT_TWO_BYTES (0xFE, 0xFF);
else
EMIT_TWO_BYTES (0xFF, 0xFE);
CODING_UTF_16_BOM (coding) = utf_without_bom;
}
while (charbuf < charbuf_end)
{
ASSURE_DESTINATION (safe_room);
c = *charbuf++;
if (c > MAX_UNICODE_CHAR)
c = coding->default_char;
if (c < 0x10000)
{
if (big_endian)
EMIT_TWO_BYTES (c >> 8, c & 0xFF);
else
EMIT_TWO_BYTES (c & 0xFF, c >> 8);
}
else
{
int c1, c2;
c -= 0x10000;
c1 = (c >> 10) + 0xD800;
c2 = (c & 0x3FF) + 0xDC00;
if (big_endian)
EMIT_FOUR_BYTES (c1 >> 8, c1 & 0xFF, c2 >> 8, c2 & 0xFF);
else
EMIT_FOUR_BYTES (c1 & 0xFF, c1 >> 8, c2 & 0xFF, c2 >> 8);
}
}
record_conversion_result (coding, CODING_RESULT_SUCCESS);
coding->produced = dst - coding->destination;
coding->produced_char += produced_chars;
return 0;
}
/*** 6. Old Emacs' internal format (emacs-mule) ***/
/* Emacs' internal format for representation of multiple character
sets is a kind of multi-byte encoding, i.e. characters are
represented by variable-length sequences of one-byte codes.
ASCII characters and control characters (e.g. `tab', `newline') are
represented by one-byte sequences which are their ASCII codes, in
the range 0x00 through 0x7F.
8-bit characters of the range 0x80..0x9F are represented by
two-byte sequences of LEADING_CODE_8_BIT_CONTROL and (their 8-bit
code + 0x20).
8-bit characters of the range 0xA0..0xFF are represented by
one-byte sequences which are their 8-bit code.
The other characters are represented by a sequence of `base
leading-code', optional `extended leading-code', and one or two
`position-code's. The length of the sequence is determined by the
base leading-code. Leading-code takes the range 0x81 through 0x9D,
whereas extended leading-code and position-code take the range 0xA0
through 0xFF. See `charset.h' for more details about leading-code
and position-code.
--- CODE RANGE of Emacs' internal format ---
character set range
------------- -----
ascii 0x00..0x7F
eight-bit-control LEADING_CODE_8_BIT_CONTROL + 0xA0..0xBF
eight-bit-graphic 0xA0..0xBF
ELSE 0x81..0x9D + [0xA0..0xFF]+
---------------------------------------------
As this is the internal character representation, the format is
usually not used externally (i.e. in a file or in a data sent to a
process). But, it is possible to have a text externally in this
format (i.e. by encoding by the coding system `emacs-mule').
In that case, a sequence of one-byte codes has a slightly different
form.
At first, all characters in eight-bit-control are represented by
one-byte sequences which are their 8-bit code.
Next, character composition data are represented by the byte
sequence of the form: 0x80 METHOD BYTES CHARS COMPONENT ...,
where,
METHOD is 0xF2 plus one of composition method (enum
composition_method),
BYTES is 0xA0 plus a byte length of this composition data,
CHARS is 0xA0 plus a number of characters composed by this
data,
COMPONENTs are characters of multibyte form or composition
rules encoded by two-byte of ASCII codes.
In addition, for backward compatibility, the following formats are
also recognized as composition data on decoding.
0x80 MSEQ ...
0x80 0xFF MSEQ RULE MSEQ RULE ... MSEQ
Here,
MSEQ is a multibyte form but in these special format:
ASCII: 0xA0 ASCII_CODE+0x80,
other: LEADING_CODE+0x20 FOLLOWING-BYTE ...,
RULE is a one byte code of the range 0xA0..0xF0 that
represents a composition rule.
*/
char emacs_mule_bytes[256];
/* See the above "GENERAL NOTES on `detect_coding_XXX ()' functions".
Return true if a text is encoded in 'emacs-mule'. */
static bool
detect_coding_emacs_mule (struct coding_system *coding,
struct coding_detection_info *detect_info)
{
const unsigned char *src = coding->source, *src_base;
const unsigned char *src_end = coding->source + coding->src_bytes;
bool multibytep = coding->src_multibyte;
ptrdiff_t consumed_chars = 0;
int c;
int found = 0;
detect_info->checked |= CATEGORY_MASK_EMACS_MULE;
/* A coding system of this category is always ASCII compatible. */
src += coding->head_ascii;
while (1)
{
src_base = src;
ONE_MORE_BYTE (c);
if (c < 0)
continue;
if (c == 0x80)
{
/* Perhaps the start of composite character. We simply skip
it because analyzing it is too heavy for detecting. But,
at least, we check that the composite character
constitutes of more than 4 bytes. */
const unsigned char *src_start;
repeat:
src_start = src;
do
{
ONE_MORE_BYTE (c);
}
while (c >= 0xA0);
if (src - src_start <= 4)
break;
found = CATEGORY_MASK_EMACS_MULE;
if (c == 0x80)
goto repeat;
}
if (c < 0x80)
{
if (c < 0x20
&& (c == ISO_CODE_ESC || c == ISO_CODE_SI || c == ISO_CODE_SO))
break;
}
else
{
int more_bytes = emacs_mule_bytes[c] - 1;
while (more_bytes > 0)
{
ONE_MORE_BYTE (c);
if (c < 0xA0)
{
src--; /* Unread the last byte. */
break;
}
more_bytes--;
}
if (more_bytes != 0)
break;
found = CATEGORY_MASK_EMACS_MULE;
}
}
detect_info->rejected |= CATEGORY_MASK_EMACS_MULE;
return 0;
no_more_source:
if (src_base < src && coding->mode & CODING_MODE_LAST_BLOCK)
{
detect_info->rejected |= CATEGORY_MASK_EMACS_MULE;
return 0;
}
detect_info->found |= found;
return 1;
}
/* Parse emacs-mule multibyte sequence at SRC and return the decoded
character. If CMP_STATUS indicates that we must expect MSEQ or
RULE described above, decode it and return the negative value of
the decoded character or rule. If an invalid byte is found, return
-1. If SRC is too short, return -2. */
static int
emacs_mule_char (struct coding_system *coding, const unsigned char *src,
int *nbytes, int *nchars, int *id,
struct composition_status *cmp_status)
{
const unsigned char *src_end = coding->source + coding->src_bytes;
const unsigned char *src_base = src;
bool multibytep = coding->src_multibyte;
int charset_ID;
unsigned code;
int c;
ptrdiff_t consumed_chars = 0;
bool mseq_found = 0;
ONE_MORE_BYTE (c);
if (c < 0)
{
c = -c;
charset_ID = emacs_mule_charset[0];
}
else
{
if (c >= 0xA0)
{
if (cmp_status->state != COMPOSING_NO
&& cmp_status->old_form)
{
if (cmp_status->state == COMPOSING_CHAR)
{
if (c == 0xA0)
{
ONE_MORE_BYTE (c);
c -= 0x80;
if (c < 0)
goto invalid_code;
}
else
c -= 0x20;
mseq_found = 1;
}
else
{
*nbytes = src - src_base;
*nchars = consumed_chars;
return -c;
}
}
else
goto invalid_code;
}
switch (emacs_mule_bytes[c])
{
case 2:
if ((charset_ID = emacs_mule_charset[c]) < 0)
goto invalid_code;
ONE_MORE_BYTE (c);
if (c < 0xA0)
goto invalid_code;
code = c & 0x7F;
break;
case 3:
if (c == EMACS_MULE_LEADING_CODE_PRIVATE_11
|| c == EMACS_MULE_LEADING_CODE_PRIVATE_12)
{
ONE_MORE_BYTE (c);
if (c < 0xA0 || (charset_ID = emacs_mule_charset[c]) < 0)
goto invalid_code;
ONE_MORE_BYTE (c);
if (c < 0xA0)
goto invalid_code;
code = c & 0x7F;
}
else
{
if ((charset_ID = emacs_mule_charset[c]) < 0)
goto invalid_code;
ONE_MORE_BYTE (c);
if (c < 0xA0)
goto invalid_code;
code = (c & 0x7F) << 8;
ONE_MORE_BYTE (c);
if (c < 0xA0)
goto invalid_code;
code |= c & 0x7F;
}
break;
case 4:
ONE_MORE_BYTE (c);
if (c < 0 || (charset_ID = emacs_mule_charset[c]) < 0)
goto invalid_code;
ONE_MORE_BYTE (c);
if (c < 0xA0)
goto invalid_code;
code = (c & 0x7F) << 8;
ONE_MORE_BYTE (c);
if (c < 0xA0)
goto invalid_code;
code |= c & 0x7F;
break;
case 1:
code = c;
charset_ID = ASCII_CHAR_P (code) ? charset_ascii : charset_eight_bit;
break;
default:
emacs_abort ();
}
CODING_DECODE_CHAR (coding, src, src_base, src_end,
CHARSET_FROM_ID (charset_ID), code, c);
if (c < 0)
goto invalid_code;
}
*nbytes = src - src_base;
*nchars = consumed_chars;
if (id)
*id = charset_ID;
return (mseq_found ? -c : c);
no_more_source:
return -2;
invalid_code:
return -1;
}
/* See the above "GENERAL NOTES on `decode_coding_XXX ()' functions". */
/* Handle these composition sequence ('|': the end of header elements,
BYTES and CHARS >= 0xA0):
(1) relative composition: 0x80 0xF2 BYTES CHARS | CHAR ...
(2) altchar composition: 0x80 0xF4 BYTES CHARS | ALT ... ALT CHAR ...
(3) alt&rule composition: 0x80 0xF5 BYTES CHARS | ALT RULE ... ALT CHAR ...
and these old form:
(4) relative composition: 0x80 | MSEQ ... MSEQ
(5) rulebase composition: 0x80 0xFF | MSEQ MRULE ... MSEQ
When the starter 0x80 and the following header elements are found,
this annotation header is produced.
[ -LENGTH(==-5) CODING_ANNOTATE_COMPOSITION_MASK NCHARS NBYTES METHOD ]
NCHARS is CHARS - 0xA0 for (1), (2), (3), and 0 for (4), (5).
NBYTES is BYTES - 0xA0 for (1), (2), (3), and 0 for (4), (5).
Then, upon reading the following elements, these codes are produced
until the composition end is found:
(1) CHAR ... CHAR
(2) ALT ... ALT CHAR ... CHAR
(3) ALT -2 DECODED-RULE ALT -2 DECODED-RULE ... ALT CHAR ... CHAR
(4) CHAR ... CHAR
(5) CHAR -2 DECODED-RULE CHAR -2 DECODED-RULE ... CHAR
When the composition end is found, LENGTH and NCHARS in the
annotation header is updated as below:
(1) LENGTH: unchanged, NCHARS: unchanged
(2) LENGTH: length of the whole sequence minus NCHARS, NCHARS: unchanged
(3) LENGTH: length of the whole sequence minus NCHARS, NCHARS: unchanged
(4) LENGTH: unchanged, NCHARS: number of CHARs
(5) LENGTH: unchanged, NCHARS: number of CHARs
If an error is found while composing, the annotation header is
changed to the original composition header (plus filler -1s) as
below:
(1),(2),(3) [ 0x80 0xF2+METHOD BYTES CHARS -1 ]
(5) [ 0x80 0xFF -1 -1- -1 ]
and the sequence [ -2 DECODED-RULE ] is changed to the original
byte sequence as below:
o the original byte sequence is B: [ B -1 ]
o the original byte sequence is B1 B2: [ B1 B2 ]
Most of the routines are implemented by macros because many
variables and labels in the caller decode_coding_emacs_mule must be
accessible, and they are usually called just once (thus doesn't
increase the size of compiled object). */
/* Decode a composition rule represented by C as a component of
composition sequence of Emacs 20 style. Set RULE to the decoded
rule. */
#define DECODE_EMACS_MULE_COMPOSITION_RULE_20(c, rule) \
do { \
int gref, nref; \
\
c -= 0xA0; \
if (c < 0 || c >= 81) \
goto invalid_code; \
gref = c / 9, nref = c % 9; \
if (gref == 4) gref = 10; \
if (nref == 4) nref = 10; \
rule = COMPOSITION_ENCODE_RULE (gref, nref); \
} while (0)
/* Decode a composition rule represented by C and the following byte
at SRC as a component of composition sequence of Emacs 21 style.
Set RULE to the decoded rule. */
#define DECODE_EMACS_MULE_COMPOSITION_RULE_21(c, rule) \
do { \
int gref, nref; \
\
gref = c - 0x20; \
if (gref < 0 || gref >= 81) \
goto invalid_code; \
ONE_MORE_BYTE (c); \
nref = c - 0x20; \
if (nref < 0 || nref >= 81) \
goto invalid_code; \
rule = COMPOSITION_ENCODE_RULE (gref, nref); \
} while (0)
/* Start of Emacs 21 style format. The first three bytes at SRC are
(METHOD - 0xF2), (BYTES - 0xA0), (CHARS - 0xA0), where BYTES is the
byte length of this composition information, CHARS is the number of
characters composed by this composition. */
#define DECODE_EMACS_MULE_21_COMPOSITION() \
do { \
enum composition_method method = c - 0xF2; \
int nbytes, nchars; \
\
ONE_MORE_BYTE (c); \
if (c < 0) \
goto invalid_code; \
nbytes = c - 0xA0; \
if (nbytes < 3 || (method == COMPOSITION_RELATIVE && nbytes != 4)) \
goto invalid_code; \
ONE_MORE_BYTE (c); \
nchars = c - 0xA0; \
if (nchars <= 0 || nchars >= MAX_COMPOSITION_COMPONENTS) \
goto invalid_code; \
cmp_status->old_form = 0; \
cmp_status->method = method; \
if (method == COMPOSITION_RELATIVE) \
cmp_status->state = COMPOSING_CHAR; \
else \
cmp_status->state = COMPOSING_COMPONENT_CHAR; \
cmp_status->length = MAX_ANNOTATION_LENGTH; \
cmp_status->nchars = nchars; \
cmp_status->ncomps = nbytes - 4; \
ADD_COMPOSITION_DATA (charbuf, nchars, nbytes, method); \
} while (0)
/* Start of Emacs 20 style format for relative composition. */
#define DECODE_EMACS_MULE_20_RELATIVE_COMPOSITION() \
do { \
cmp_status->old_form = 1; \
cmp_status->method = COMPOSITION_RELATIVE; \
cmp_status->state = COMPOSING_CHAR; \
cmp_status->length = MAX_ANNOTATION_LENGTH; \
cmp_status->nchars = cmp_status->ncomps = 0; \
ADD_COMPOSITION_DATA (charbuf, 0, 0, cmp_status->method); \
} while (0)
/* Start of Emacs 20 style format for rule-base composition. */
#define DECODE_EMACS_MULE_20_RULEBASE_COMPOSITION() \
do { \
cmp_status->old_form = 1; \
cmp_status->method = COMPOSITION_WITH_RULE; \
cmp_status->state = COMPOSING_CHAR; \
cmp_status->length = MAX_ANNOTATION_LENGTH; \
cmp_status->nchars = cmp_status->ncomps = 0; \
ADD_COMPOSITION_DATA (charbuf, 0, 0, cmp_status->method); \
} while (0)
#define DECODE_EMACS_MULE_COMPOSITION_START() \
do { \
const unsigned char *current_src = src; \
\
ONE_MORE_BYTE (c); \
if (c < 0) \
goto invalid_code; \
if (c - 0xF2 >= COMPOSITION_RELATIVE \
&& c - 0xF2 <= COMPOSITION_WITH_RULE_ALTCHARS) \
DECODE_EMACS_MULE_21_COMPOSITION (); \
else if (c < 0xA0) \
goto invalid_code; \
else if (c < 0xC0) \
{ \
DECODE_EMACS_MULE_20_RELATIVE_COMPOSITION (); \
/* Re-read C as a composition component. */ \
src = current_src; \
} \
else if (c == 0xFF) \
DECODE_EMACS_MULE_20_RULEBASE_COMPOSITION (); \
else \
goto invalid_code; \
} while (0)
#define EMACS_MULE_COMPOSITION_END() \
do { \
int idx = - cmp_status->length; \
\
if (cmp_status->old_form) \
charbuf[idx + 2] = cmp_status->nchars; \
else if (cmp_status->method > COMPOSITION_RELATIVE) \
charbuf[idx] = charbuf[idx + 2] - cmp_status->length; \
cmp_status->state = COMPOSING_NO; \
} while (0)
static int
emacs_mule_finish_composition (int *charbuf,
struct composition_status *cmp_status)
{
int idx = - cmp_status->length;
int new_chars;
if (cmp_status->old_form && cmp_status->nchars > 0)
{
charbuf[idx + 2] = cmp_status->nchars;
new_chars = 0;
if (cmp_status->method == COMPOSITION_WITH_RULE
&& cmp_status->state == COMPOSING_CHAR)
{
/* The last rule was invalid. */
int rule = charbuf[-1] + 0xA0;
charbuf[-2] = BYTE8_TO_CHAR (rule);
charbuf[-1] = -1;
new_chars = 1;
}
}
else
{
charbuf[idx++] = BYTE8_TO_CHAR (0x80);
if (cmp_status->method == COMPOSITION_WITH_RULE)
{
charbuf[idx++] = BYTE8_TO_CHAR (0xFF);
charbuf[idx++] = -3;
charbuf[idx++] = 0;
new_chars = 1;
}
else
{
int nchars = charbuf[idx + 1] + 0xA0;
int nbytes = charbuf[idx + 2] + 0xA0;
charbuf[idx++] = BYTE8_TO_CHAR (0xF2 + cmp_status->method);
charbuf[idx++] = BYTE8_TO_CHAR (nbytes);
charbuf[idx++] = BYTE8_TO_CHAR (nchars);
charbuf[idx++] = -1;
new_chars = 4;
}
}
cmp_status->state = COMPOSING_NO;
return new_chars;
}
#define EMACS_MULE_MAYBE_FINISH_COMPOSITION() \
do { \
if (cmp_status->state != COMPOSING_NO) \
char_offset += emacs_mule_finish_composition (charbuf, cmp_status); \
} while (0)
static void
decode_coding_emacs_mule (struct coding_system *coding)
{
const unsigned char *src = coding->source + coding->consumed;
const unsigned char *src_end = coding->source + coding->src_bytes;
const unsigned char *src_base;
int *charbuf = coding->charbuf + coding->charbuf_used;
/* We may produce two annotations (charset and composition) in one
loop and one more charset annotation at the end. */
int *charbuf_end
= coding->charbuf + coding->charbuf_size - (MAX_ANNOTATION_LENGTH * 3)
/* We can produce up to 2 characters in a loop. */
- 1;
ptrdiff_t consumed_chars = 0, consumed_chars_base;
bool multibytep = coding->src_multibyte;
ptrdiff_t char_offset = coding->produced_char;
ptrdiff_t last_offset = char_offset;
int last_id = charset_ascii;
bool eol_dos
= !inhibit_eol_conversion && EQ (CODING_ID_EOL_TYPE (coding->id), Qdos);
int byte_after_cr = -1;
struct composition_status *cmp_status = &coding->spec.emacs_mule.cmp_status;
if (cmp_status->state != COMPOSING_NO)
{
int i;
if (charbuf_end - charbuf < cmp_status->length)
emacs_abort ();
for (i = 0; i < cmp_status->length; i++)
*charbuf++ = cmp_status->carryover[i];
coding->annotated = 1;
}
while (1)
{
int c;
int id UNINIT;
src_base = src;
consumed_chars_base = consumed_chars;
if (charbuf >= charbuf_end)
{
if (byte_after_cr >= 0)
src_base--;
break;
}
if (byte_after_cr >= 0)
c = byte_after_cr, byte_after_cr = -1;
else
ONE_MORE_BYTE (c);
if (c < 0 || c == 0x80)
{
EMACS_MULE_MAYBE_FINISH_COMPOSITION ();
if (c < 0)
{
*charbuf++ = -c;
char_offset++;
}
else
DECODE_EMACS_MULE_COMPOSITION_START ();
continue;
}
if (c < 0x80)
{
if (eol_dos && c == '\r')
ONE_MORE_BYTE (byte_after_cr);
id = charset_ascii;
if (cmp_status->state != COMPOSING_NO)
{
if (cmp_status->old_form)
EMACS_MULE_MAYBE_FINISH_COMPOSITION ();
else if (cmp_status->state >= COMPOSING_COMPONENT_CHAR)
cmp_status->ncomps--;
}
}
else
{
int nchars UNINIT, nbytes UNINIT;
/* emacs_mule_char can load a charset map from a file, which
allocates a large structure and might cause buffer text
to be relocated as result. Thus, we need to remember the
original pointer to buffer text, and fix up all related
pointers after the call. */
const unsigned char *orig = coding->source;
ptrdiff_t offset;
c = emacs_mule_char (coding, src_base, &nbytes, &nchars, &id,
cmp_status);
offset = coding->source - orig;
if (offset)
{
src += offset;
src_base += offset;
src_end += offset;
}
if (c < 0)
{
if (c == -1)
goto invalid_code;
if (c == -2)
break;
}
src = src_base + nbytes;
consumed_chars = consumed_chars_base + nchars;
if (cmp_status->state >= COMPOSING_COMPONENT_CHAR)
cmp_status->ncomps -= nchars;
}
/* Now if C >= 0, we found a normally encoded character, if C <
0, we found an old-style composition component character or
rule. */
if (cmp_status->state == COMPOSING_NO)
{
if (last_id != id)
{
if (last_id != charset_ascii)
ADD_CHARSET_DATA (charbuf, char_offset - last_offset,
last_id);
last_id = id;
last_offset = char_offset;
}
*charbuf++ = c;
char_offset++;
}
else if (cmp_status->state == COMPOSING_CHAR)
{
if (cmp_status->old_form)
{
if (c >= 0)
{
EMACS_MULE_MAYBE_FINISH_COMPOSITION ();
*charbuf++ = c;
char_offset++;
}
else
{
*charbuf++ = -c;
cmp_status->nchars++;
cmp_status->length++;
if (cmp_status->nchars == MAX_COMPOSITION_COMPONENTS)
EMACS_MULE_COMPOSITION_END ();
else if (cmp_status->method == COMPOSITION_WITH_RULE)
cmp_status->state = COMPOSING_RULE;
}
}
else
{
*charbuf++ = c;
cmp_status->length++;
cmp_status->nchars--;
if (cmp_status->nchars == 0)
EMACS_MULE_COMPOSITION_END ();
}
}
else if (cmp_status->state == COMPOSING_RULE)
{
int rule;
if (c >= 0)
{
EMACS_MULE_COMPOSITION_END ();
*charbuf++ = c;
char_offset++;
}
else
{
c = -c;
DECODE_EMACS_MULE_COMPOSITION_RULE_20 (c, rule);
if (rule < 0)
goto invalid_code;
*charbuf++ = -2;
*charbuf++ = rule;
cmp_status->length += 2;
cmp_status->state = COMPOSING_CHAR;
}
}
else if (cmp_status->state == COMPOSING_COMPONENT_CHAR)
{
*charbuf++ = c;
cmp_status->length++;
if (cmp_status->ncomps == 0)
cmp_status->state = COMPOSING_CHAR;
else if (cmp_status->ncomps > 0)
{
if (cmp_status->method == COMPOSITION_WITH_RULE_ALTCHARS)
cmp_status->state = COMPOSING_COMPONENT_RULE;
}
else
EMACS_MULE_MAYBE_FINISH_COMPOSITION ();
}
else /* COMPOSING_COMPONENT_RULE */
{
int rule;
DECODE_EMACS_MULE_COMPOSITION_RULE_21 (c, rule);
if (rule < 0)
goto invalid_code;
*charbuf++ = -2;
*charbuf++ = rule;
cmp_status->length += 2;
cmp_status->ncomps--;
if (cmp_status->ncomps > 0)
cmp_status->state = COMPOSING_COMPONENT_CHAR;
else
EMACS_MULE_MAYBE_FINISH_COMPOSITION ();
}
continue;
invalid_code:
EMACS_MULE_MAYBE_FINISH_COMPOSITION ();
src = src_base;
consumed_chars = consumed_chars_base;
ONE_MORE_BYTE (c);
*charbuf++ = ASCII_CHAR_P (c) ? c : BYTE8_TO_CHAR (c);
char_offset++;
}
no_more_source:
if (cmp_status->state != COMPOSING_NO)
{
if (coding->mode & CODING_MODE_LAST_BLOCK)
EMACS_MULE_MAYBE_FINISH_COMPOSITION ();
else
{
int i;
charbuf -= cmp_status->length;
for (i = 0; i < cmp_status->length; i++)
cmp_status->carryover[i] = charbuf[i];
}
}
if (last_id != charset_ascii)
ADD_CHARSET_DATA (charbuf, char_offset - last_offset, last_id);
coding->consumed_char += consumed_chars_base;
coding->consumed = src_base - coding->source;
coding->charbuf_used = charbuf - coding->charbuf;
}
#define EMACS_MULE_LEADING_CODES(id, codes) \
do { \
if (id < 0xA0) \
codes[0] = id, codes[1] = 0; \
else if (id < 0xE0) \
codes[0] = 0x9A, codes[1] = id; \
else if (id < 0xF0) \
codes[0] = 0x9B, codes[1] = id; \
else if (id < 0xF5) \
codes[0] = 0x9C, codes[1] = id; \
else \
codes[0] = 0x9D, codes[1] = id; \
} while (0);
static bool
encode_coding_emacs_mule (struct coding_system *coding)
{
bool multibytep = coding->dst_multibyte;
int *charbuf = coding->charbuf;
int *charbuf_end = charbuf + coding->charbuf_used;
unsigned char *dst = coding->destination + coding->produced;
unsigned char *dst_end = coding->destination + coding->dst_bytes;
int safe_room = 8;
ptrdiff_t produced_chars = 0;
Lisp_Object attrs, charset_list;
int c;
int preferred_charset_id = -1;
CODING_GET_INFO (coding, attrs, charset_list);
if (! EQ (charset_list, Vemacs_mule_charset_list))
{
charset_list = Vemacs_mule_charset_list;
ASET (attrs, coding_attr_charset_list, charset_list);
}
while (charbuf < charbuf_end)
{
ASSURE_DESTINATION (safe_room);
c = *charbuf++;
if (c < 0)
{
/* Handle an annotation. */
switch (*charbuf)
{
case CODING_ANNOTATE_COMPOSITION_MASK:
/* Not yet implemented. */
break;
case CODING_ANNOTATE_CHARSET_MASK:
preferred_charset_id = charbuf[3];
if (preferred_charset_id >= 0
&& NILP (Fmemq (make_fixnum (preferred_charset_id),
charset_list)))
preferred_charset_id = -1;
break;
default:
emacs_abort ();
}
charbuf += -c - 1;
continue;
}
if (ASCII_CHAR_P (c))
EMIT_ONE_ASCII_BYTE (c);
else if (CHAR_BYTE8_P (c))
{
c = CHAR_TO_BYTE8 (c);
EMIT_ONE_BYTE (c);
}
else
{
struct charset *charset;
unsigned code;
int dimension;
int emacs_mule_id;
unsigned char leading_codes[2];
if (preferred_charset_id >= 0)
{
bool result;
charset = CHARSET_FROM_ID (preferred_charset_id);
CODING_CHAR_CHARSET_P (coding, dst, dst_end, c, charset, result);
if (result)
code = ENCODE_CHAR (charset, c);
else
CODING_CHAR_CHARSET (coding, dst, dst_end, c, charset_list,
&code, charset);
}
else
CODING_CHAR_CHARSET (coding, dst, dst_end, c, charset_list,
&code, charset);
if (! charset)
{
c = coding->default_char;
if (ASCII_CHAR_P (c))
{
EMIT_ONE_ASCII_BYTE (c);
continue;
}
CODING_CHAR_CHARSET (coding, dst, dst_end, c, charset_list,
&code, charset);
}
dimension = CHARSET_DIMENSION (charset);
emacs_mule_id = CHARSET_EMACS_MULE_ID (charset);
EMACS_MULE_LEADING_CODES (emacs_mule_id, leading_codes);
EMIT_ONE_BYTE (leading_codes[0]);
if (leading_codes[1])
EMIT_ONE_BYTE (leading_codes[1]);
if (dimension == 1)
EMIT_ONE_BYTE (code | 0x80);
else
{
code |= 0x8080;
EMIT_ONE_BYTE (code >> 8);
EMIT_ONE_BYTE (code & 0xFF);
}
}
}
record_conversion_result (coding, CODING_RESULT_SUCCESS);
coding->produced_char += produced_chars;
coding->produced = dst - coding->destination;
return 0;
}
/*** 7. ISO2022 handlers ***/
/* The following note describes the coding system ISO2022 briefly.
Since the intention of this note is to help understand the
functions in this file, some parts are NOT ACCURATE or are OVERLY
SIMPLIFIED. For thorough understanding, please refer to the
original document of ISO2022. This is equivalent to the standard
ECMA-35, obtainable from (*).
ISO2022 provides many mechanisms to encode several character sets
in 7-bit and 8-bit environments. For 7-bit environments, all text
is encoded using bytes less than 128. This may make the encoded
text a little bit longer, but the text passes more easily through
several types of gateway, some of which strip off the MSB (Most
Significant Bit).
There are two kinds of character sets: control character sets and
graphic character sets. The former contain control characters such
as `newline' and `escape' to provide control functions (control
functions are also provided by escape sequences). The latter
contain graphic characters such as 'A' and '-'. Emacs recognizes
two control character sets and many graphic character sets.
Graphic character sets are classified into one of the following
four classes, according to the number of bytes (DIMENSION) and
number of characters in one dimension (CHARS) of the set:
- DIMENSION1_CHARS94
- DIMENSION1_CHARS96
- DIMENSION2_CHARS94
- DIMENSION2_CHARS96
In addition, each character set is assigned an identification tag,
unique for each set, called the "final character" (denoted as
hereafter). The of each character set is decided by ECMA(*)
when it is registered in ISO. The code range of is 0x30..0x7F
(0x30..0x3F are for private use only).
Note (*): ECMA = European Computer Manufacturers Association
Here are examples of graphic character sets [NAME()]:
o DIMENSION1_CHARS94 -- ASCII('B'), right-half-of-JISX0201('I'), ...
o DIMENSION1_CHARS96 -- right-half-of-ISO8859-1('A'), ...
o DIMENSION2_CHARS94 -- GB2312('A'), JISX0208('B'), ...
o DIMENSION2_CHARS96 -- none for the moment
A code area (1 byte=8 bits) is divided into 4 areas, C0, GL, C1, and GR.
C0 [0x00..0x1F] -- control character plane 0
GL [0x20..0x7F] -- graphic character plane 0
C1 [0x80..0x9F] -- control character plane 1
GR [0xA0..0xFF] -- graphic character plane 1
A control character set is directly designated and invoked to C0 or
C1 by an escape sequence. The most common case is that:
- ISO646's control character set is designated/invoked to C0, and
- ISO6429's control character set is designated/invoked to C1,
and usually these designations/invocations are omitted in encoded
text. In a 7-bit environment, only C0 can be used, and a control
character for C1 is encoded by an appropriate escape sequence to
fit into the environment. All control characters for C1 are
defined to have corresponding escape sequences.
A graphic character set is at first designated to one of four
graphic registers (G0 through G3), then these graphic registers are
invoked to GL or GR. These designations and invocations can be
done independently. The most common case is that G0 is invoked to
GL, G1 is invoked to GR, and ASCII is designated to G0. Usually
these invocations and designations are omitted in encoded text.
In a 7-bit environment, only GL can be used.
When a graphic character set of CHARS94 is invoked to GL, codes
0x20 and 0x7F of the GL area work as control characters SPACE and
DEL respectively, and codes 0xA0 and 0xFF of the GR area should not
be used.
There are two ways of invocation: locking-shift and single-shift.
With locking-shift, the invocation lasts until the next different
invocation, whereas with single-shift, the invocation affects the
following character only and doesn't affect the locking-shift
state. Invocations are done by the following control characters or
escape sequences:
----------------------------------------------------------------------
abbrev function cntrl escape seq description
----------------------------------------------------------------------
SI/LS0 (shift-in) 0x0F none invoke G0 into GL
SO/LS1 (shift-out) 0x0E none invoke G1 into GL
LS2 (locking-shift-2) none ESC 'n' invoke G2 into GL
LS3 (locking-shift-3) none ESC 'o' invoke G3 into GL
LS1R (locking-shift-1 right) none ESC '~' invoke G1 into GR (*)
LS2R (locking-shift-2 right) none ESC '}' invoke G2 into GR (*)
LS3R (locking-shift 3 right) none ESC '|' invoke G3 into GR (*)
SS2 (single-shift-2) 0x8E ESC 'N' invoke G2 for one char
SS3 (single-shift-3) 0x8F ESC 'O' invoke G3 for one char
----------------------------------------------------------------------
(*) These are not used by any known coding system.
Control characters for these functions are defined by macros
ISO_CODE_XXX in `coding.h'.
Designations are done by the following escape sequences:
----------------------------------------------------------------------
escape sequence description
----------------------------------------------------------------------
ESC '(' designate DIMENSION1_CHARS94 to G0
ESC ')' designate DIMENSION1_CHARS94 to G1
ESC '*' designate DIMENSION1_CHARS94 to G2
ESC '+' designate DIMENSION1_CHARS94 to G3
ESC ',' designate DIMENSION1_CHARS96 to G0 (*)
ESC '-' designate DIMENSION1_CHARS96 to G1
ESC '.' designate DIMENSION1_CHARS96 to G2
ESC '/' designate DIMENSION1_CHARS96 to G3
ESC '$' '(' designate DIMENSION2_CHARS94 to G0 (**)
ESC '$' ')' designate DIMENSION2_CHARS94 to G1
ESC '$' '*' designate DIMENSION2_CHARS94 to G2
ESC '$' '+' designate DIMENSION2_CHARS94 to G3
ESC '$' ',' designate DIMENSION2_CHARS96 to G0 (*)
ESC '$' '-' designate DIMENSION2_CHARS96 to G1
ESC '$' '.' designate DIMENSION2_CHARS96 to G2
ESC '$' '/' designate DIMENSION2_CHARS96 to G3
----------------------------------------------------------------------
In this list, "DIMENSION1_CHARS94" means a graphic character set
of dimension 1, chars 94, and final character , etc...
Note (*): Although these designations are not allowed in ISO2022,
Emacs accepts them on decoding, and produces them on encoding
CHARS96 character sets in a coding system which is characterized as
7-bit environment, non-locking-shift, and non-single-shift.
Note (**): If is '@', 'A', or 'B', the intermediate character
'(' must be omitted. We refer to this as "short-form" hereafter.
Now you may notice that there are a lot of ways of encoding the
same multilingual text in ISO2022. Actually, there exist many
coding systems such as Compound Text (used in X11's inter client
communication, ISO-2022-JP (used in Japanese Internet), ISO-2022-KR
(used in Korean Internet), EUC (Extended UNIX Code, used in Asian
localized platforms), and all of these are variants of ISO2022.
In addition to the above, Emacs handles two more kinds of escape
sequences: ISO6429's direction specification and Emacs' private
sequence for specifying character composition.
ISO6429's direction specification takes the following form:
o CSI ']' -- end of the current direction
o CSI '0' ']' -- end of the current direction
o CSI '1' ']' -- start of left-to-right text
o CSI '2' ']' -- start of right-to-left text
The control character CSI (0x9B: control sequence introducer) is
abbreviated to the escape sequence ESC '[' in a 7-bit environment.
Character composition specification takes the following form:
o ESC '0' -- start relative composition
o ESC '1' -- end composition
o ESC '2' -- start rule-base composition (*)
o ESC '3' -- start relative composition with alternate chars (**)
o ESC '4' -- start rule-base composition with alternate chars (**)
Since these are not standard escape sequences of any ISO standard,
the use of them with these meanings is restricted to Emacs only.
(*) This form is used only in Emacs 20.7 and older versions,
but newer versions can safely decode it.
(**) This form is used only in Emacs 21.1 and newer versions,
and older versions can't decode it.
Here's a list of example usages of these composition escape
sequences (categorized by `enum composition_method').
COMPOSITION_RELATIVE:
ESC 0 CHAR [ CHAR ] ESC 1
COMPOSITION_WITH_RULE:
ESC 2 CHAR [ RULE CHAR ] ESC 1
COMPOSITION_WITH_ALTCHARS:
ESC 3 ALTCHAR [ ALTCHAR ] ESC 0 CHAR [ CHAR ] ESC 1
COMPOSITION_WITH_RULE_ALTCHARS:
ESC 4 ALTCHAR [ RULE ALTCHAR ] ESC 0 CHAR [ CHAR ] ESC 1 */
static enum iso_code_class_type iso_code_class[256];
#define SAFE_CHARSET_P(coding, id) \
((id) <= (coding)->max_charset_id \
&& (coding)->safe_charsets[id] != 255)
static void
setup_iso_safe_charsets (Lisp_Object attrs)
{
Lisp_Object charset_list, safe_charsets;
Lisp_Object request;
Lisp_Object reg_usage;
Lisp_Object tail;
EMACS_INT reg94, reg96;
int flags = XFIXNUM (AREF (attrs, coding_attr_iso_flags));
int max_charset_id;
charset_list = CODING_ATTR_CHARSET_LIST (attrs);
if ((flags & CODING_ISO_FLAG_FULL_SUPPORT)
&& ! EQ (charset_list, Viso_2022_charset_list))
{
charset_list = Viso_2022_charset_list;
ASET (attrs, coding_attr_charset_list, charset_list);
ASET (attrs, coding_attr_safe_charsets, Qnil);
}
if (STRINGP (AREF (attrs, coding_attr_safe_charsets)))
return;
max_charset_id = 0;
for (tail = charset_list; CONSP (tail); tail = XCDR (tail))
{
int id = XFIXNUM (XCAR (tail));
if (max_charset_id < id)
max_charset_id = id;
}
safe_charsets = make_uninit_string (max_charset_id + 1);
memset (SDATA (safe_charsets), 255, max_charset_id + 1);
request = AREF (attrs, coding_attr_iso_request);
reg_usage = AREF (attrs, coding_attr_iso_usage);
reg94 = XFIXNUM (XCAR (reg_usage));
reg96 = XFIXNUM (XCDR (reg_usage));
for (tail = charset_list; CONSP (tail); tail = XCDR (tail))
{
Lisp_Object id;
Lisp_Object reg;
struct charset *charset;
id = XCAR (tail);
charset = CHARSET_FROM_ID (XFIXNUM (id));
reg = Fcdr (Fassq (id, request));
if (! NILP (reg))
SSET (safe_charsets, XFIXNUM (id), XFIXNUM (reg));
else if (charset->iso_chars_96)
{
if (reg96 < 4)
SSET (safe_charsets, XFIXNUM (id), reg96);
}
else
{
if (reg94 < 4)
SSET (safe_charsets, XFIXNUM (id), reg94);
}
}
ASET (attrs, coding_attr_safe_charsets, safe_charsets);
}
/* See the above "GENERAL NOTES on `detect_coding_XXX ()' functions".
Return true if a text is encoded in one of ISO-2022 based coding
systems. */
static bool
detect_coding_iso_2022 (struct coding_system *coding,
struct coding_detection_info *detect_info)
{
const unsigned char *src = coding->source, *src_base = src;
const unsigned char *src_end = coding->source + coding->src_bytes;
bool multibytep = coding->src_multibyte;
bool single_shifting = 0;
int id;
int c, c1;
ptrdiff_t consumed_chars = 0;
int i;
int rejected = 0;
int found = 0;
int composition_count = -1;
detect_info->checked |= CATEGORY_MASK_ISO;
for (i = coding_category_iso_7; i <= coding_category_iso_8_else; i++)
{
struct coding_system *this = &(coding_categories[i]);
Lisp_Object attrs, val;
if (this->id < 0)
continue;
attrs = CODING_ID_ATTRS (this->id);
if (CODING_ISO_FLAGS (this) & CODING_ISO_FLAG_FULL_SUPPORT
&& ! EQ (CODING_ATTR_CHARSET_LIST (attrs), Viso_2022_charset_list))
setup_iso_safe_charsets (attrs);
val = CODING_ATTR_SAFE_CHARSETS (attrs);
this->max_charset_id = SCHARS (val) - 1;
this->safe_charsets = SDATA (val);
}
/* A coding system of this category is always ASCII compatible. */
src += coding->head_ascii;
while (rejected != CATEGORY_MASK_ISO)
{
src_base = src;
ONE_MORE_BYTE (c);
switch (c)
{
case ISO_CODE_ESC:
if (inhibit_iso_escape_detection)
break;
single_shifting = 0;
ONE_MORE_BYTE (c);
if (c == 'N' || c == 'O')
{
/* ESC for SS2 or SS3. */
single_shifting = 1;
rejected |= CATEGORY_MASK_ISO_7BIT | CATEGORY_MASK_ISO_8BIT;
}
else if (c == '1')
{
/* End of composition. */
if (composition_count < 0
|| composition_count > MAX_COMPOSITION_COMPONENTS)
/* Invalid */
break;
composition_count = -1;
found |= CATEGORY_MASK_ISO;
}
else if (c >= '0' && c <= '4')
{
/* ESC for start/end composition. */
composition_count = 0;
}
else
{
if (c >= '(' && c <= '/')
{
/* Designation sequence for a charset of dimension 1. */
ONE_MORE_BYTE (c1);
if (c1 < ' ' || c1 >= 0x80
|| (id = iso_charset_table[0][c >= ','][c1]) < 0)
{
/* Invalid designation sequence. Just ignore. */
if (c1 >= 0x80)
rejected |= (CATEGORY_MASK_ISO_7BIT
| CATEGORY_MASK_ISO_7_ELSE);
break;
}
}
else if (c == '$')
{
/* Designation sequence for a charset of dimension 2. */
ONE_MORE_BYTE (c);
if (c >= '@' && c <= 'B')
/* Designation for JISX0208.1978, GB2312, or JISX0208. */
id = iso_charset_table[1][0][c];
else if (c >= '(' && c <= '/')
{
ONE_MORE_BYTE (c1);
if (c1 < ' ' || c1 >= 0x80
|| (id = iso_charset_table[1][c >= ','][c1]) < 0)
{
/* Invalid designation sequence. Just ignore. */
if (c1 >= 0x80)
rejected |= (CATEGORY_MASK_ISO_7BIT
| CATEGORY_MASK_ISO_7_ELSE);
break;
}
}
else
{
/* Invalid designation sequence. Just ignore it. */
if (c >= 0x80)
rejected |= (CATEGORY_MASK_ISO_7BIT
| CATEGORY_MASK_ISO_7_ELSE);
break;
}
}
else
{
/* Invalid escape sequence. Just ignore it. */
if (c >= 0x80)
rejected |= (CATEGORY_MASK_ISO_7BIT
| CATEGORY_MASK_ISO_7_ELSE);
break;
}
/* We found a valid designation sequence for CHARSET. */
rejected |= CATEGORY_MASK_ISO_8BIT;
if (SAFE_CHARSET_P (&coding_categories[coding_category_iso_7],
id))
found |= CATEGORY_MASK_ISO_7;
else
rejected |= CATEGORY_MASK_ISO_7;
if (SAFE_CHARSET_P (&coding_categories[coding_category_iso_7_tight],
id))
found |= CATEGORY_MASK_ISO_7_TIGHT;
else
rejected |= CATEGORY_MASK_ISO_7_TIGHT;
if (SAFE_CHARSET_P (&coding_categories[coding_category_iso_7_else],
id))
found |= CATEGORY_MASK_ISO_7_ELSE;
else
rejected |= CATEGORY_MASK_ISO_7_ELSE;
if (SAFE_CHARSET_P (&coding_categories[coding_category_iso_8_else],
id))
found |= CATEGORY_MASK_ISO_8_ELSE;
else
rejected |= CATEGORY_MASK_ISO_8_ELSE;
}
break;
case ISO_CODE_SO:
case ISO_CODE_SI:
/* Locking shift out/in. */
if (inhibit_iso_escape_detection)
break;
single_shifting = 0;
rejected |= CATEGORY_MASK_ISO_7BIT | CATEGORY_MASK_ISO_8BIT;
break;
case ISO_CODE_CSI:
/* Control sequence introducer. */
single_shifting = 0;
rejected |= CATEGORY_MASK_ISO_7BIT | CATEGORY_MASK_ISO_7_ELSE;
found |= CATEGORY_MASK_ISO_8_ELSE;
goto check_extra_latin;
case ISO_CODE_SS2:
case ISO_CODE_SS3:
/* Single shift. */
if (inhibit_iso_escape_detection)
break;
single_shifting = 0;
rejected |= CATEGORY_MASK_ISO_7BIT | CATEGORY_MASK_ISO_7_ELSE;
if (CODING_ISO_FLAGS (&coding_categories[coding_category_iso_8_1])
& CODING_ISO_FLAG_SINGLE_SHIFT)
{
found |= CATEGORY_MASK_ISO_8_1;
single_shifting = 1;
}
if (CODING_ISO_FLAGS (&coding_categories[coding_category_iso_8_2])
& CODING_ISO_FLAG_SINGLE_SHIFT)
{
found |= CATEGORY_MASK_ISO_8_2;
single_shifting = 1;
}
if (single_shifting)
break;
goto check_extra_latin;
default:
if (c < 0)
continue;
if (c < 0x80)
{
if (composition_count >= 0)
composition_count++;
single_shifting = 0;
break;
}
rejected |= CATEGORY_MASK_ISO_7BIT | CATEGORY_MASK_ISO_7_ELSE;
if (c >= 0xA0)
{
found |= CATEGORY_MASK_ISO_8_1;
/* Check the length of succeeding codes of the range
0xA0..0FF. If the byte length is even, we include
CATEGORY_MASK_ISO_8_2 in `found'. We can check this
only when we are not single shifting. */
if (! single_shifting
&& ! (rejected & CATEGORY_MASK_ISO_8_2))
{
ptrdiff_t len = 1;
while (src < src_end)
{
src_base = src;
ONE_MORE_BYTE (c);
if (c < 0xA0)
{
src = src_base;
break;
}
len++;
}
if (len & 1 && src < src_end)
{
rejected |= CATEGORY_MASK_ISO_8_2;
if (composition_count >= 0)
composition_count += len;
}
else
{
found |= CATEGORY_MASK_ISO_8_2;
if (composition_count >= 0)
composition_count += len / 2;
}
}
break;
}
check_extra_latin:
if (! VECTORP (Vlatin_extra_code_table)
|| NILP (AREF (Vlatin_extra_code_table, c)))
{
rejected = CATEGORY_MASK_ISO;
break;
}
if (CODING_ISO_FLAGS (&coding_categories[coding_category_iso_8_1])
& CODING_ISO_FLAG_LATIN_EXTRA)
found |= CATEGORY_MASK_ISO_8_1;
else
rejected |= CATEGORY_MASK_ISO_8_1;
rejected |= CATEGORY_MASK_ISO_8_2;
break;
}
}
detect_info->rejected |= CATEGORY_MASK_ISO;
return 0;
no_more_source:
detect_info->rejected |= rejected;
detect_info->found |= (found & ~rejected);
return 1;
}
/* Set designation state into CODING. Set CHARS_96 to -1 if the
escape sequence should be kept. */
#define DECODE_DESIGNATION(reg, dim, chars_96, final) \
do { \
int id, prev; \
\
if (final < '0' || final >= 128 \
|| ((id = ISO_CHARSET_TABLE (dim, chars_96, final)) < 0) \
|| !SAFE_CHARSET_P (coding, id)) \
{ \
CODING_ISO_DESIGNATION (coding, reg) = -2; \
chars_96 = -1; \
break; \
} \
prev = CODING_ISO_DESIGNATION (coding, reg); \
if (id == charset_jisx0201_roman) \
{ \
if (CODING_ISO_FLAGS (coding) & CODING_ISO_FLAG_USE_ROMAN) \
id = charset_ascii; \
} \
else if (id == charset_jisx0208_1978) \
{ \
if (CODING_ISO_FLAGS (coding) & CODING_ISO_FLAG_USE_OLDJIS) \
id = charset_jisx0208; \
} \
CODING_ISO_DESIGNATION (coding, reg) = id; \
/* If there was an invalid designation to REG previously, and this \
designation is ASCII to REG, we should keep this designation \
sequence. */ \
if (prev == -2 && id == charset_ascii) \
chars_96 = -1; \
} while (0)
/* Handle these composition sequence (ALT: alternate char):
(1) relative composition: ESC 0 CHAR ... ESC 1
(2) rulebase composition: ESC 2 CHAR RULE CHAR RULE ... CHAR ESC 1
(3) altchar composition: ESC 3 ALT ... ALT ESC 0 CHAR ... ESC 1
(4) alt&rule composition: ESC 4 ALT RULE ... ALT ESC 0 CHAR ... ESC 1
When the start sequence (ESC 0/2/3/4) is found, this annotation
header is produced.
[ -LENGTH(==-5) CODING_ANNOTATE_COMPOSITION_MASK NCHARS(==0) 0 METHOD ]
Then, upon reading CHAR or RULE (one or two bytes), these codes are
produced until the end sequence (ESC 1) is found:
(1) CHAR ... CHAR
(2) CHAR -2 DECODED-RULE CHAR -2 DECODED-RULE ... CHAR
(3) ALT ... ALT -1 -1 CHAR ... CHAR
(4) ALT -2 DECODED-RULE ALT -2 DECODED-RULE ... ALT -1 -1 CHAR ... CHAR
When the end sequence (ESC 1) is found, LENGTH and NCHARS in the
annotation header is updated as below:
(1) LENGTH: unchanged, NCHARS: number of CHARs
(2) LENGTH: unchanged, NCHARS: number of CHARs
(3) LENGTH: += number of ALTs + 2, NCHARS: number of CHARs
(4) LENGTH: += number of ALTs * 3, NCHARS: number of CHARs
If an error is found while composing, the annotation header is
changed to:
[ ESC '0'/'2'/'3'/'4' -2 0 ]
and the sequence [ -2 DECODED-RULE ] is changed to the original
byte sequence as below:
o the original byte sequence is B: [ B -1 ]
o the original byte sequence is B1 B2: [ B1 B2 ]
and the sequence [ -1 -1 ] is changed to the original byte
sequence:
[ ESC '0' ]
*/
/* Decode a composition rule C1 and maybe one more byte from the
source, and set RULE to the encoded composition rule. If the rule
is invalid, goto invalid_code. */
#define DECODE_COMPOSITION_RULE(rule) \
do { \
rule = c1 - 32; \
if (rule < 0) \
goto invalid_code; \
if (rule < 81) /* old format (before ver.21) */ \
{ \
int gref = (rule) / 9; \
int nref = (rule) % 9; \
if (gref == 4) gref = 10; \
if (nref == 4) nref = 10; \
rule = COMPOSITION_ENCODE_RULE (gref, nref); \
} \
else /* new format (after ver.21) */ \
{ \
int b; \
\
ONE_MORE_BYTE (b); \
if (! COMPOSITION_ENCODE_RULE_VALID (rule - 81, b - 32)) \
goto invalid_code; \
rule = COMPOSITION_ENCODE_RULE (rule - 81, b - 32); \
rule += 0x100; /* Distinguish it from the old format. */ \
} \
} while (0)
#define ENCODE_COMPOSITION_RULE(rule) \
do { \
int gref = (rule % 0x100) / 12, nref = (rule % 0x100) % 12; \
\
if (rule < 0x100) /* old format */ \
{ \
if (gref == 10) gref = 4; \
if (nref == 10) nref = 4; \
charbuf[idx] = 32 + gref * 9 + nref; \
charbuf[idx + 1] = -1; \
new_chars++; \
} \
else /* new format */ \
{ \
charbuf[idx] = 32 + 81 + gref; \
charbuf[idx + 1] = 32 + nref; \
new_chars += 2; \
} \
} while (0)
/* Finish the current composition as invalid. */
static int
finish_composition (int *charbuf, struct composition_status *cmp_status)
{
int idx = - cmp_status->length;
int new_chars;
/* Recover the original ESC sequence */
charbuf[idx++] = ISO_CODE_ESC;
charbuf[idx++] = (cmp_status->method == COMPOSITION_RELATIVE ? '0'
: cmp_status->method == COMPOSITION_WITH_RULE ? '2'
: cmp_status->method == COMPOSITION_WITH_ALTCHARS ? '3'
/* cmp_status->method == COMPOSITION_WITH_RULE_ALTCHARS */
: '4');
charbuf[idx++] = -2;
charbuf[idx++] = 0;
charbuf[idx++] = -1;
new_chars = cmp_status->nchars;
if (cmp_status->method >= COMPOSITION_WITH_RULE)
for (; idx < 0; idx++)
{
int elt = charbuf[idx];
if (elt == -2)
{
ENCODE_COMPOSITION_RULE (charbuf[idx + 1]);
idx++;
}
else if (elt == -1)
{
charbuf[idx++] = ISO_CODE_ESC;
charbuf[idx] = '0';
new_chars += 2;
}
}
cmp_status->state = COMPOSING_NO;
return new_chars;
}
/* If characters are under composition, finish the composition. */
#define MAYBE_FINISH_COMPOSITION() \
do { \
if (cmp_status->state != COMPOSING_NO) \
char_offset += finish_composition (charbuf, cmp_status); \
} while (0)
/* Handle composition start sequence ESC 0, ESC 2, ESC 3, or ESC 4.
ESC 0 : relative composition : ESC 0 CHAR ... ESC 1
ESC 2 : rulebase composition : ESC 2 CHAR RULE CHAR RULE ... CHAR ESC 1
ESC 3 : altchar composition : ESC 3 CHAR ... ESC 0 CHAR ... ESC 1
ESC 4 : alt&rule composition : ESC 4 CHAR RULE ... CHAR ESC 0 CHAR ... ESC 1
Produce this annotation sequence now:
[ -LENGTH(==-4) CODING_ANNOTATE_COMPOSITION_MASK NCHARS(==0) METHOD ]
*/
#define DECODE_COMPOSITION_START(c1) \
do { \
if (c1 == '0' \
&& ((cmp_status->state == COMPOSING_COMPONENT_CHAR \
&& cmp_status->method == COMPOSITION_WITH_ALTCHARS) \
|| (cmp_status->state == COMPOSING_COMPONENT_RULE \
&& cmp_status->method == COMPOSITION_WITH_RULE_ALTCHARS))) \
{ \
*charbuf++ = -1; \
*charbuf++= -1; \
cmp_status->state = COMPOSING_CHAR; \
cmp_status->length += 2; \
} \
else \
{ \
MAYBE_FINISH_COMPOSITION (); \
cmp_status->method = (c1 == '0' ? COMPOSITION_RELATIVE \
: c1 == '2' ? COMPOSITION_WITH_RULE \
: c1 == '3' ? COMPOSITION_WITH_ALTCHARS \
: COMPOSITION_WITH_RULE_ALTCHARS); \
cmp_status->state \
= (c1 <= '2' ? COMPOSING_CHAR : COMPOSING_COMPONENT_CHAR); \
ADD_COMPOSITION_DATA (charbuf, 0, 0, cmp_status->method); \
cmp_status->length = MAX_ANNOTATION_LENGTH; \
cmp_status->nchars = cmp_status->ncomps = 0; \
coding->annotated = 1; \
} \
} while (0)
/* Handle composition end sequence ESC 1. */
#define DECODE_COMPOSITION_END() \
do { \
if (cmp_status->nchars == 0 \
|| ((cmp_status->state == COMPOSING_CHAR) \
== (cmp_status->method == COMPOSITION_WITH_RULE))) \
{ \
MAYBE_FINISH_COMPOSITION (); \
goto invalid_code; \
} \
if (cmp_status->method == COMPOSITION_WITH_ALTCHARS) \
charbuf[- cmp_status->length] -= cmp_status->ncomps + 2; \
else if (cmp_status->method == COMPOSITION_WITH_RULE_ALTCHARS) \
charbuf[- cmp_status->length] -= cmp_status->ncomps * 3; \
charbuf[- cmp_status->length + 2] = cmp_status->nchars; \
char_offset += cmp_status->nchars; \
cmp_status->state = COMPOSING_NO; \
} while (0)
/* Store a composition rule RULE in charbuf, and update cmp_status. */
#define STORE_COMPOSITION_RULE(rule) \
do { \
*charbuf++ = -2; \
*charbuf++ = rule; \
cmp_status->length += 2; \
cmp_status->state--; \
} while (0)
/* Store a composed char or a component char C in charbuf, and update
cmp_status. */
#define STORE_COMPOSITION_CHAR(c) \
do { \
*charbuf++ = (c); \
cmp_status->length++; \
if (cmp_status->state == COMPOSING_CHAR) \
cmp_status->nchars++; \
else \
cmp_status->ncomps++; \
if (cmp_status->method == COMPOSITION_WITH_RULE \
|| (cmp_status->method == COMPOSITION_WITH_RULE_ALTCHARS \
&& cmp_status->state == COMPOSING_COMPONENT_CHAR)) \
cmp_status->state++; \
} while (0)
/* See the above "GENERAL NOTES on `decode_coding_XXX ()' functions". */
static void
decode_coding_iso_2022 (struct coding_system *coding)
{
const unsigned char *src = coding->source + coding->consumed;
const unsigned char *src_end = coding->source + coding->src_bytes;
const unsigned char *src_base;
int *charbuf = coding->charbuf + coding->charbuf_used;
/* We may produce two annotations (charset and composition) in one
loop and one more charset annotation at the end. */
int *charbuf_end
= coding->charbuf + coding->charbuf_size - (MAX_ANNOTATION_LENGTH * 3);
ptrdiff_t consumed_chars = 0, consumed_chars_base;
bool multibytep = coding->src_multibyte;
/* Charsets invoked to graphic plane 0 and 1 respectively. */
int charset_id_0 = CODING_ISO_INVOKED_CHARSET (coding, 0);
int charset_id_1 = CODING_ISO_INVOKED_CHARSET (coding, 1);
int charset_id_2, charset_id_3;
struct charset *charset;
int c;
struct composition_status *cmp_status = CODING_ISO_CMP_STATUS (coding);
Lisp_Object attrs = CODING_ID_ATTRS (coding->id);
ptrdiff_t char_offset = coding->produced_char;
ptrdiff_t last_offset = char_offset;
int last_id = charset_ascii;
bool eol_dos
= !inhibit_eol_conversion && EQ (CODING_ID_EOL_TYPE (coding->id), Qdos);
int byte_after_cr = -1;
int i;
setup_iso_safe_charsets (attrs);
coding->safe_charsets = SDATA (CODING_ATTR_SAFE_CHARSETS (attrs));
if (cmp_status->state != COMPOSING_NO)
{
if (charbuf_end - charbuf < cmp_status->length)
emacs_abort ();
for (i = 0; i < cmp_status->length; i++)
*charbuf++ = cmp_status->carryover[i];
coding->annotated = 1;
}
while (1)
{
int c1, c2, c3;
src_base = src;
consumed_chars_base = consumed_chars;
if (charbuf >= charbuf_end)
{
if (byte_after_cr >= 0)
src_base--;
break;
}
if (byte_after_cr >= 0)
c1 = byte_after_cr, byte_after_cr = -1;
else
ONE_MORE_BYTE (c1);
if (c1 < 0)
goto invalid_code;
if (CODING_ISO_EXTSEGMENT_LEN (coding) > 0)
{
*charbuf++ = ASCII_CHAR_P (c1) ? c1 : BYTE8_TO_CHAR (c1);
char_offset++;
CODING_ISO_EXTSEGMENT_LEN (coding)--;
continue;
}
if (CODING_ISO_EMBEDDED_UTF_8 (coding))
{
if (c1 == ISO_CODE_ESC)
{
if (src + 1 >= src_end)
goto no_more_source;
*charbuf++ = ISO_CODE_ESC;
char_offset++;
if (src[0] == '%' && src[1] == '@')
{
src += 2;
consumed_chars += 2;
char_offset += 2;
/* We are sure charbuf can contain two more chars. */
*charbuf++ = '%';
*charbuf++ = '@';
CODING_ISO_EMBEDDED_UTF_8 (coding) = 0;
}
}
else
{
*charbuf++ = ASCII_CHAR_P (c1) ? c1 : BYTE8_TO_CHAR (c1);
char_offset++;
}
continue;
}
if ((cmp_status->state == COMPOSING_RULE
|| cmp_status->state == COMPOSING_COMPONENT_RULE)
&& c1 != ISO_CODE_ESC)
{
int rule;
DECODE_COMPOSITION_RULE (rule);
STORE_COMPOSITION_RULE (rule);
continue;
}
/* We produce at most one character. */
switch (iso_code_class [c1])
{
case ISO_0x20_or_0x7F:
if (charset_id_0 < 0
|| ! CHARSET_ISO_CHARS_96 (CHARSET_FROM_ID (charset_id_0)))
/* This is SPACE or DEL. */
charset = CHARSET_FROM_ID (charset_ascii);
else
charset = CHARSET_FROM_ID (charset_id_0);
break;
case ISO_graphic_plane_0:
if (charset_id_0 < 0)
charset = CHARSET_FROM_ID (charset_ascii);
else
charset = CHARSET_FROM_ID (charset_id_0);
break;
case ISO_0xA0_or_0xFF:
if (charset_id_1 < 0
|| ! CHARSET_ISO_CHARS_96 (CHARSET_FROM_ID (charset_id_1))
|| CODING_ISO_FLAGS (coding) & CODING_ISO_FLAG_SEVEN_BITS)
goto invalid_code;
/* This is a graphic character, we fall down ... */
FALLTHROUGH;
case ISO_graphic_plane_1:
if (charset_id_1 < 0)
goto invalid_code;
charset = CHARSET_FROM_ID (charset_id_1);
break;
case ISO_control_0:
if (eol_dos && c1 == '\r')
ONE_MORE_BYTE (byte_after_cr);
MAYBE_FINISH_COMPOSITION ();
charset = CHARSET_FROM_ID (charset_ascii);
break;
case ISO_control_1:
goto invalid_code;
case ISO_shift_out:
if (! (CODING_ISO_FLAGS (coding) & CODING_ISO_FLAG_LOCKING_SHIFT)
|| CODING_ISO_DESIGNATION (coding, 1) < 0)
goto invalid_code;
CODING_ISO_INVOCATION (coding, 0) = 1;
charset_id_0 = CODING_ISO_INVOKED_CHARSET (coding, 0);
continue;
case ISO_shift_in:
if (! (CODING_ISO_FLAGS (coding) & CODING_ISO_FLAG_LOCKING_SHIFT))
goto invalid_code;
CODING_ISO_INVOCATION (coding, 0) = 0;
charset_id_0 = CODING_ISO_INVOKED_CHARSET (coding, 0);
continue;
case ISO_single_shift_2_7:
if (! (CODING_ISO_FLAGS (coding) & CODING_ISO_FLAG_SEVEN_BITS))
goto invalid_code;
FALLTHROUGH;
case ISO_single_shift_2:
if (! (CODING_ISO_FLAGS (coding) & CODING_ISO_FLAG_SINGLE_SHIFT))
goto invalid_code;
/* SS2 is handled as an escape sequence of ESC 'N' */
c1 = 'N';
goto label_escape_sequence;
case ISO_single_shift_3:
if (! (CODING_ISO_FLAGS (coding) & CODING_ISO_FLAG_SINGLE_SHIFT))
goto invalid_code;
/* SS2 is handled as an escape sequence of ESC 'O' */
c1 = 'O';
goto label_escape_sequence;
case ISO_control_sequence_introducer:
/* CSI is handled as an escape sequence of ESC '[' ... */
c1 = '[';
goto label_escape_sequence;
case ISO_escape:
ONE_MORE_BYTE (c1);
label_escape_sequence:
/* Escape sequences handled here are invocation,
designation, direction specification, and character
composition specification. */
switch (c1)
{
case '&': /* revision of following character set */
ONE_MORE_BYTE (c1);
if (!(c1 >= '@' && c1 <= '~'))
goto invalid_code;
ONE_MORE_BYTE (c1);
if (c1 != ISO_CODE_ESC)
goto invalid_code;
ONE_MORE_BYTE (c1);
goto label_escape_sequence;
case '$': /* designation of 2-byte character set */
if (! (CODING_ISO_FLAGS (coding) & CODING_ISO_FLAG_DESIGNATION))
goto invalid_code;
{
int reg, chars96;
ONE_MORE_BYTE (c1);
if (c1 >= '@' && c1 <= 'B')
{ /* designation of JISX0208.1978, GB2312.1980,
or JISX0208.1980 */
reg = 0, chars96 = 0;
}
else if (c1 >= 0x28 && c1 <= 0x2B)
{ /* designation of DIMENSION2_CHARS94 character set */
reg = c1 - 0x28, chars96 = 0;
ONE_MORE_BYTE (c1);
}
else if (c1 >= 0x2C && c1 <= 0x2F)
{ /* designation of DIMENSION2_CHARS96 character set */
reg = c1 - 0x2C, chars96 = 1;
ONE_MORE_BYTE (c1);
}
else
goto invalid_code;
DECODE_DESIGNATION (reg, 2, chars96, c1);
/* We must update these variables now. */
if (reg == 0)
charset_id_0 = CODING_ISO_INVOKED_CHARSET (coding, 0);
else if (reg == 1)
charset_id_1 = CODING_ISO_INVOKED_CHARSET (coding, 1);
if (chars96 < 0)
goto invalid_code;
}
continue;
case 'n': /* invocation of locking-shift-2 */
if (! (CODING_ISO_FLAGS (coding) & CODING_ISO_FLAG_LOCKING_SHIFT)
|| CODING_ISO_DESIGNATION (coding, 2) < 0)
goto invalid_code;
CODING_ISO_INVOCATION (coding, 0) = 2;
charset_id_0 = CODING_ISO_INVOKED_CHARSET (coding, 0);
continue;
case 'o': /* invocation of locking-shift-3 */
if (! (CODING_ISO_FLAGS (coding) & CODING_ISO_FLAG_LOCKING_SHIFT)
|| CODING_ISO_DESIGNATION (coding, 3) < 0)
goto invalid_code;
CODING_ISO_INVOCATION (coding, 0) = 3;
charset_id_0 = CODING_ISO_INVOKED_CHARSET (coding, 0);
continue;
case 'N': /* invocation of single-shift-2 */
if (! (CODING_ISO_FLAGS (coding) & CODING_ISO_FLAG_SINGLE_SHIFT)
|| CODING_ISO_DESIGNATION (coding, 2) < 0)
goto invalid_code;
charset_id_2 = CODING_ISO_DESIGNATION (coding, 2);
if (charset_id_2 < 0)
charset = CHARSET_FROM_ID (charset_ascii);
else
charset = CHARSET_FROM_ID (charset_id_2);
ONE_MORE_BYTE (c1);
if (c1 < 0x20 || (c1 >= 0x80 && c1 < 0xA0)
|| (! (CODING_ISO_FLAGS (coding) & CODING_ISO_FLAG_SEVEN_BITS)
&& ((CODING_ISO_FLAGS (coding) & CODING_ISO_FLAG_LEVEL_4)
? c1 >= 0x80 : c1 < 0x80)))
goto invalid_code;
break;
case 'O': /* invocation of single-shift-3 */
if (! (CODING_ISO_FLAGS (coding) & CODING_ISO_FLAG_SINGLE_SHIFT)
|| CODING_ISO_DESIGNATION (coding, 3) < 0)
goto invalid_code;
charset_id_3 = CODING_ISO_DESIGNATION (coding, 3);
if (charset_id_3 < 0)
charset = CHARSET_FROM_ID (charset_ascii);
else
charset = CHARSET_FROM_ID (charset_id_3);
ONE_MORE_BYTE (c1);
if (c1 < 0x20 || (c1 >= 0x80 && c1 < 0xA0)
|| (! (CODING_ISO_FLAGS (coding) & CODING_ISO_FLAG_SEVEN_BITS)
&& ((CODING_ISO_FLAGS (coding) & CODING_ISO_FLAG_LEVEL_4)
? c1 >= 0x80 : c1 < 0x80)))
goto invalid_code;
break;
case '0': case '2': case '3': case '4': /* start composition */
if (! (coding->common_flags & CODING_ANNOTATE_COMPOSITION_MASK))
goto invalid_code;
if (last_id != charset_ascii)
{
ADD_CHARSET_DATA (charbuf, char_offset- last_offset, last_id);
last_id = charset_ascii;
last_offset = char_offset;
}
DECODE_COMPOSITION_START (c1);
continue;
case '1': /* end composition */
if (cmp_status->state == COMPOSING_NO)
goto invalid_code;
DECODE_COMPOSITION_END ();
continue;
case '[': /* specification of direction */
if (! (CODING_ISO_FLAGS (coding) & CODING_ISO_FLAG_DIRECTION))
goto invalid_code;
/* For the moment, nested direction is not supported.
So, `coding->mode & CODING_MODE_DIRECTION' zero means
left-to-right, and nonzero means right-to-left. */
ONE_MORE_BYTE (c1);
switch (c1)
{
case ']': /* end of the current direction */
coding->mode &= ~CODING_MODE_DIRECTION;
break;
case '0': /* end of the current direction */
case '1': /* start of left-to-right direction */
ONE_MORE_BYTE (c1);
if (c1 == ']')
coding->mode &= ~CODING_MODE_DIRECTION;
else
goto invalid_code;
break;
case '2': /* start of right-to-left direction */
ONE_MORE_BYTE (c1);
if (c1 == ']')
coding->mode |= CODING_MODE_DIRECTION;
else
goto invalid_code;
break;
default:
goto invalid_code;
}
continue;
case '%':
ONE_MORE_BYTE (c1);
if (c1 == '/')
{
/* CTEXT extended segment:
ESC % / [0-4] M L --ENCODING-NAME-- \002 --BYTES--
We keep these bytes as is for the moment.
They may be decoded by post-read-conversion. */
int dim, M, L;
int size;
ONE_MORE_BYTE (dim);
if (dim < '0' || dim > '4')
goto invalid_code;
ONE_MORE_BYTE (M);
if (M < 128)
goto invalid_code;
ONE_MORE_BYTE (L);
if (L < 128)
goto invalid_code;
size = ((M - 128) * 128) + (L - 128);
if (charbuf + 6 > charbuf_end)
goto break_loop;
*charbuf++ = ISO_CODE_ESC;
*charbuf++ = '%';
*charbuf++ = '/';
*charbuf++ = dim;
*charbuf++ = BYTE8_TO_CHAR (M);
*charbuf++ = BYTE8_TO_CHAR (L);
CODING_ISO_EXTSEGMENT_LEN (coding) = size;
}
else if (c1 == 'G')
{
/* XFree86 extension for embedding UTF-8 in CTEXT:
ESC % G --UTF-8-BYTES-- ESC % @
We keep these bytes as is for the moment.
They may be decoded by post-read-conversion. */
if (charbuf + 3 > charbuf_end)
goto break_loop;
*charbuf++ = ISO_CODE_ESC;
*charbuf++ = '%';
*charbuf++ = 'G';
CODING_ISO_EMBEDDED_UTF_8 (coding) = 1;
}
else
goto invalid_code;
continue;
break;
default:
if (! (CODING_ISO_FLAGS (coding) & CODING_ISO_FLAG_DESIGNATION))
goto invalid_code;
{
int reg, chars96;
if (c1 >= 0x28 && c1 <= 0x2B)
{ /* designation of DIMENSION1_CHARS94 character set */
reg = c1 - 0x28, chars96 = 0;
ONE_MORE_BYTE (c1);
}
else if (c1 >= 0x2C && c1 <= 0x2F)
{ /* designation of DIMENSION1_CHARS96 character set */
reg = c1 - 0x2C, chars96 = 1;
ONE_MORE_BYTE (c1);
}
else
goto invalid_code;
DECODE_DESIGNATION (reg, 1, chars96, c1);
/* We must update these variables now. */
if (reg == 0)
charset_id_0 = CODING_ISO_INVOKED_CHARSET (coding, 0);
else if (reg == 1)
charset_id_1 = CODING_ISO_INVOKED_CHARSET (coding, 1);
if (chars96 < 0)
goto invalid_code;
}
continue;
}
break;
default:
emacs_abort ();
}
if (cmp_status->state == COMPOSING_NO
&& charset->id != charset_ascii
&& last_id != charset->id)
{
if (last_id != charset_ascii)
ADD_CHARSET_DATA (charbuf, char_offset - last_offset, last_id);
last_id = charset->id;
last_offset = char_offset;
}
/* Now we know CHARSET and 1st position code C1 of a character.
Produce a decoded character while getting 2nd and 3rd
position codes C2, C3 if necessary. */
if (CHARSET_DIMENSION (charset) > 1)
{
ONE_MORE_BYTE (c2);
if (c2 < 0x20 || (c2 >= 0x80 && c2 < 0xA0)
|| ((c1 & 0x80) != (c2 & 0x80)))
/* C2 is not in a valid range. */
goto invalid_code;
if (CHARSET_DIMENSION (charset) == 2)
c1 = (c1 << 8) | c2;
else
{
ONE_MORE_BYTE (c3);
if (c3 < 0x20 || (c3 >= 0x80 && c3 < 0xA0)
|| ((c1 & 0x80) != (c3 & 0x80)))
/* C3 is not in a valid range. */
goto invalid_code;
c1 = (c1 << 16) | (c2 << 8) | c2;
}
}
c1 &= 0x7F7F7F;
CODING_DECODE_CHAR (coding, src, src_base, src_end, charset, c1, c);
if (c < 0)
{
MAYBE_FINISH_COMPOSITION ();
for (; src_base < src; src_base++, char_offset++)
{
if (ASCII_CHAR_P (*src_base))
*charbuf++ = *src_base;
else
*charbuf++ = BYTE8_TO_CHAR (*src_base);
}
}
else if (cmp_status->state == COMPOSING_NO)
{
*charbuf++ = c;
char_offset++;
}
else if ((cmp_status->state == COMPOSING_CHAR
? cmp_status->nchars
: cmp_status->ncomps)
>= MAX_COMPOSITION_COMPONENTS)
{
/* Too long composition. */
MAYBE_FINISH_COMPOSITION ();
*charbuf++ = c;
char_offset++;
}
else
STORE_COMPOSITION_CHAR (c);
continue;
invalid_code:
MAYBE_FINISH_COMPOSITION ();
src = src_base;
consumed_chars = consumed_chars_base;
ONE_MORE_BYTE (c);
*charbuf++ = c < 0 ? -c : ASCII_CHAR_P (c) ? c : BYTE8_TO_CHAR (c);
char_offset++;
/* Reset the invocation and designation status to the safest
one; i.e. designate ASCII to the graphic register 0, and
invoke that register to the graphic plane 0. This typically
helps the case that a designation sequence for ASCII "ESC (
B" is somehow broken (e.g. broken by a newline). */
CODING_ISO_INVOCATION (coding, 0) = 0;
CODING_ISO_DESIGNATION (coding, 0) = charset_ascii;
charset_id_0 = charset_ascii;
continue;
break_loop:
break;
}
no_more_source:
if (cmp_status->state != COMPOSING_NO)
{
if (coding->mode & CODING_MODE_LAST_BLOCK)
MAYBE_FINISH_COMPOSITION ();
else
{
charbuf -= cmp_status->length;
for (i = 0; i < cmp_status->length; i++)
cmp_status->carryover[i] = charbuf[i];
}
}
else if (last_id != charset_ascii)
ADD_CHARSET_DATA (charbuf, char_offset - last_offset, last_id);
coding->consumed_char += consumed_chars_base;
coding->consumed = src_base - coding->source;
coding->charbuf_used = charbuf - coding->charbuf;
}
/* ISO2022 encoding stuff. */
/*
It is not enough to say just "ISO2022" on encoding, we have to
specify more details. In Emacs, each coding system of ISO2022
variant has the following specifications:
1. Initial designation to G0 thru G3.
2. Allows short-form designation?
3. ASCII should be designated to G0 before control characters?
4. ASCII should be designated to G0 at end of line?
5. 7-bit environment or 8-bit environment?
6. Use locking-shift?
7. Use Single-shift?
And the following two are only for Japanese:
8. Use ASCII in place of JIS0201-1976-Roman?
9. Use JISX0208-1983 in place of JISX0208-1978?
These specifications are encoded in CODING_ISO_FLAGS (coding) as flag bits
defined by macros CODING_ISO_FLAG_XXX. See `coding.h' for more
details.
*/
/* Produce codes (escape sequence) for designating CHARSET to graphic
register REG at DST, and increment DST. If of CHARSET is
'@', 'A', or 'B' and the coding system CODING allows, produce
designation sequence of short-form. */
#define ENCODE_DESIGNATION(charset, reg, coding) \
do { \
unsigned char final_char = CHARSET_ISO_FINAL (charset); \
const char *intermediate_char_94 = "()*+"; \
const char *intermediate_char_96 = ",-./"; \
int revision = -1; \
\
if (CODING_ISO_FLAGS (coding) & CODING_ISO_FLAG_REVISION) \
revision = CHARSET_ISO_REVISION (charset); \
\
if (revision >= 0) \
{ \
EMIT_TWO_ASCII_BYTES (ISO_CODE_ESC, '&'); \
EMIT_ONE_BYTE ('@' + revision); \
} \
EMIT_ONE_ASCII_BYTE (ISO_CODE_ESC); \
if (CHARSET_DIMENSION (charset) == 1) \
{ \
int b; \
if (! CHARSET_ISO_CHARS_96 (charset)) \
b = intermediate_char_94[reg]; \
else \
b = intermediate_char_96[reg]; \
EMIT_ONE_ASCII_BYTE (b); \
} \
else \
{ \
EMIT_ONE_ASCII_BYTE ('$'); \
if (! CHARSET_ISO_CHARS_96 (charset)) \
{ \
if (CODING_ISO_FLAGS (coding) & CODING_ISO_FLAG_LONG_FORM \
|| reg != 0 \
|| final_char < '@' || final_char > 'B') \
EMIT_ONE_ASCII_BYTE (intermediate_char_94[reg]); \
} \
else \
EMIT_ONE_ASCII_BYTE (intermediate_char_96[reg]); \
} \
EMIT_ONE_ASCII_BYTE (final_char); \
\
CODING_ISO_DESIGNATION (coding, reg) = CHARSET_ID (charset); \
} while (0)
/* The following two macros produce codes (control character or escape
sequence) for ISO2022 single-shift functions (single-shift-2 and
single-shift-3). */
#define ENCODE_SINGLE_SHIFT_2 \
do { \
if (CODING_ISO_FLAGS (coding) & CODING_ISO_FLAG_SEVEN_BITS) \
EMIT_TWO_ASCII_BYTES (ISO_CODE_ESC, 'N'); \
else \
EMIT_ONE_BYTE (ISO_CODE_SS2); \
CODING_ISO_SINGLE_SHIFTING (coding) = 1; \
} while (0)
#define ENCODE_SINGLE_SHIFT_3 \
do { \
if (CODING_ISO_FLAGS (coding) & CODING_ISO_FLAG_SEVEN_BITS) \
EMIT_TWO_ASCII_BYTES (ISO_CODE_ESC, 'O'); \
else \
EMIT_ONE_BYTE (ISO_CODE_SS3); \
CODING_ISO_SINGLE_SHIFTING (coding) = 1; \
} while (0)
/* The following four macros produce codes (control character or
escape sequence) for ISO2022 locking-shift functions (shift-in,
shift-out, locking-shift-2, and locking-shift-3). */
#define ENCODE_SHIFT_IN \
do { \
EMIT_ONE_ASCII_BYTE (ISO_CODE_SI); \
CODING_ISO_INVOCATION (coding, 0) = 0; \
} while (0)
#define ENCODE_SHIFT_OUT \
do { \
EMIT_ONE_ASCII_BYTE (ISO_CODE_SO); \
CODING_ISO_INVOCATION (coding, 0) = 1; \
} while (0)
#define ENCODE_LOCKING_SHIFT_2 \
do { \
EMIT_TWO_ASCII_BYTES (ISO_CODE_ESC, 'n'); \
CODING_ISO_INVOCATION (coding, 0) = 2; \
} while (0)
#define ENCODE_LOCKING_SHIFT_3 \
do { \
EMIT_TWO_ASCII_BYTES (ISO_CODE_ESC, 'n'); \
CODING_ISO_INVOCATION (coding, 0) = 3; \
} while (0)
/* Produce codes for a DIMENSION1 character whose character set is
CHARSET and whose position-code is C1. Designation and invocation
sequences are also produced in advance if necessary. */
#define ENCODE_ISO_CHARACTER_DIMENSION1(charset, c1) \
do { \
int id = CHARSET_ID (charset); \
\
if ((CODING_ISO_FLAGS (coding) & CODING_ISO_FLAG_USE_ROMAN) \
&& id == charset_ascii) \
{ \
id = charset_jisx0201_roman; \
charset = CHARSET_FROM_ID (id); \
} \
\
if (CODING_ISO_SINGLE_SHIFTING (coding)) \
{ \
if (CODING_ISO_FLAGS (coding) & CODING_ISO_FLAG_SEVEN_BITS) \
EMIT_ONE_ASCII_BYTE (c1 & 0x7F); \
else \
EMIT_ONE_BYTE (c1 | 0x80); \
CODING_ISO_SINGLE_SHIFTING (coding) = 0; \
break; \
} \
else if (id == CODING_ISO_INVOKED_CHARSET (coding, 0)) \
{ \
EMIT_ONE_ASCII_BYTE (c1 & 0x7F); \
break; \
} \
else if (id == CODING_ISO_INVOKED_CHARSET (coding, 1)) \
{ \
EMIT_ONE_BYTE (c1 | 0x80); \
break; \
} \
else \
/* Since CHARSET is not yet invoked to any graphic planes, we \
must invoke it, or, at first, designate it to some graphic \
register. Then repeat the loop to actually produce the \
character. */ \
dst = encode_invocation_designation (charset, coding, dst, \
&produced_chars); \
} while (1)
/* Produce codes for a DIMENSION2 character whose character set is
CHARSET and whose position-codes are C1 and C2. Designation and
invocation codes are also produced in advance if necessary. */
#define ENCODE_ISO_CHARACTER_DIMENSION2(charset, c1, c2) \
do { \
int id = CHARSET_ID (charset); \
\
if ((CODING_ISO_FLAGS (coding) & CODING_ISO_FLAG_USE_OLDJIS) \
&& id == charset_jisx0208) \
{ \
id = charset_jisx0208_1978; \
charset = CHARSET_FROM_ID (id); \
} \
\
if (CODING_ISO_SINGLE_SHIFTING (coding)) \
{ \
if (CODING_ISO_FLAGS (coding) & CODING_ISO_FLAG_SEVEN_BITS) \
EMIT_TWO_ASCII_BYTES ((c1) & 0x7F, (c2) & 0x7F); \
else \
EMIT_TWO_BYTES ((c1) | 0x80, (c2) | 0x80); \
CODING_ISO_SINGLE_SHIFTING (coding) = 0; \
break; \
} \
else if (id == CODING_ISO_INVOKED_CHARSET (coding, 0)) \
{ \
EMIT_TWO_ASCII_BYTES ((c1) & 0x7F, (c2) & 0x7F); \
break; \
} \
else if (id == CODING_ISO_INVOKED_CHARSET (coding, 1)) \
{ \
EMIT_TWO_BYTES ((c1) | 0x80, (c2) | 0x80); \
break; \
} \
else \
/* Since CHARSET is not yet invoked to any graphic planes, we \
must invoke it, or, at first, designate it to some graphic \
register. Then repeat the loop to actually produce the \
character. */ \
dst = encode_invocation_designation (charset, coding, dst, \
&produced_chars); \
} while (1)
#define ENCODE_ISO_CHARACTER(charset, c) \
do { \
unsigned code; \
CODING_ENCODE_CHAR (coding, dst, dst_end, (charset), (c), code); \
\
if (CHARSET_DIMENSION (charset) == 1) \
ENCODE_ISO_CHARACTER_DIMENSION1 ((charset), code); \
else \
ENCODE_ISO_CHARACTER_DIMENSION2 ((charset), code >> 8, code & 0xFF); \
} while (0)
/* Produce designation and invocation codes at a place pointed by DST
to use CHARSET. The element `spec.iso_2022' of *CODING is updated.
Return new DST. */
static unsigned char *
encode_invocation_designation (struct charset *charset,
struct coding_system *coding,
unsigned char *dst, ptrdiff_t *p_nchars)
{
bool multibytep = coding->dst_multibyte;
ptrdiff_t produced_chars = *p_nchars;
int reg; /* graphic register number */
int id = CHARSET_ID (charset);
/* At first, check designations. */
for (reg = 0; reg < 4; reg++)
if (id == CODING_ISO_DESIGNATION (coding, reg))
break;
if (reg >= 4)
{
/* CHARSET is not yet designated to any graphic registers. */
/* At first check the requested designation. */
reg = CODING_ISO_REQUEST (coding, id);
if (reg < 0)
/* Since CHARSET requests no special designation, designate it
to graphic register 0. */
reg = 0;
ENCODE_DESIGNATION (charset, reg, coding);
}
if (CODING_ISO_INVOCATION (coding, 0) != reg
&& CODING_ISO_INVOCATION (coding, 1) != reg)
{
/* Since the graphic register REG is not invoked to any graphic
planes, invoke it to graphic plane 0. */
switch (reg)
{
case 0: /* graphic register 0 */
ENCODE_SHIFT_IN;
break;
case 1: /* graphic register 1 */
ENCODE_SHIFT_OUT;
break;
case 2: /* graphic register 2 */
if (CODING_ISO_FLAGS (coding) & CODING_ISO_FLAG_SINGLE_SHIFT)
ENCODE_SINGLE_SHIFT_2;
else
ENCODE_LOCKING_SHIFT_2;
break;
case 3: /* graphic register 3 */
if (CODING_ISO_FLAGS (coding) & CODING_ISO_FLAG_SINGLE_SHIFT)
ENCODE_SINGLE_SHIFT_3;
else
ENCODE_LOCKING_SHIFT_3;
break;
default:
break;
}
}
*p_nchars = produced_chars;
return dst;
}
/* Produce codes for designation and invocation to reset the graphic
planes and registers to initial state. */
#define ENCODE_RESET_PLANE_AND_REGISTER() \
do { \
int reg; \
struct charset *charset; \
\
if (CODING_ISO_INVOCATION (coding, 0) != 0) \
ENCODE_SHIFT_IN; \
for (reg = 0; reg < 4; reg++) \
if (CODING_ISO_INITIAL (coding, reg) >= 0 \
&& (CODING_ISO_DESIGNATION (coding, reg) \
!= CODING_ISO_INITIAL (coding, reg))) \
{ \
charset = CHARSET_FROM_ID (CODING_ISO_INITIAL (coding, reg)); \
ENCODE_DESIGNATION (charset, reg, coding); \
} \
} while (0)
/* Produce designation sequences of charsets in the line started from
CHARBUF to a place pointed by DST, and return the number of
produced bytes. DST should not directly point a buffer text area
which may be relocated by char_charset call.
If the current block ends before any end-of-line, we may fail to
find all the necessary designations. */
static ptrdiff_t
encode_designation_at_bol (struct coding_system *coding,
int *charbuf, int *charbuf_end,
unsigned char *dst)
{
unsigned char *orig = dst;
struct charset *charset;
/* Table of charsets to be designated to each graphic register. */
int r[4];
int c, found = 0, reg;
ptrdiff_t produced_chars = 0;
bool multibytep = coding->dst_multibyte;
Lisp_Object attrs;
Lisp_Object charset_list;
attrs = CODING_ID_ATTRS (coding->id);
charset_list = CODING_ATTR_CHARSET_LIST (attrs);
if (EQ (charset_list, Qiso_2022))
charset_list = Viso_2022_charset_list;
for (reg = 0; reg < 4; reg++)
r[reg] = -1;
while (charbuf < charbuf_end && found < 4)
{
int id;
c = *charbuf++;
if (c == '\n')
break;
charset = char_charset (c, charset_list, NULL);
id = CHARSET_ID (charset);
reg = CODING_ISO_REQUEST (coding, id);
if (reg >= 0 && r[reg] < 0)
{
found++;
r[reg] = id;
}
}
if (found)
{
for (reg = 0; reg < 4; reg++)
if (r[reg] >= 0
&& CODING_ISO_DESIGNATION (coding, reg) != r[reg])
ENCODE_DESIGNATION (CHARSET_FROM_ID (r[reg]), reg, coding);
}
return dst - orig;
}
/* See the above "GENERAL NOTES on `encode_coding_XXX ()' functions". */
static bool
encode_coding_iso_2022 (struct coding_system *coding)
{
bool multibytep = coding->dst_multibyte;
int *charbuf = coding->charbuf;
int *charbuf_end = charbuf + coding->charbuf_used;
unsigned char *dst = coding->destination + coding->produced;
unsigned char *dst_end = coding->destination + coding->dst_bytes;
int safe_room = 16;
bool bol_designation
= (CODING_ISO_FLAGS (coding) & CODING_ISO_FLAG_DESIGNATE_AT_BOL
&& CODING_ISO_BOL (coding));
ptrdiff_t produced_chars = 0;
Lisp_Object attrs, eol_type, charset_list;
bool ascii_compatible;
int c;
int preferred_charset_id = -1;
CODING_GET_INFO (coding, attrs, charset_list);
eol_type = inhibit_eol_conversion ? Qunix : CODING_ID_EOL_TYPE (coding->id);
if (VECTORP (eol_type))
eol_type = Qunix;
setup_iso_safe_charsets (attrs);
/* Charset list may have been changed. */
charset_list = CODING_ATTR_CHARSET_LIST (attrs);
coding->safe_charsets = SDATA (CODING_ATTR_SAFE_CHARSETS (attrs));
ascii_compatible
= (! NILP (CODING_ATTR_ASCII_COMPAT (attrs))
&& ! (CODING_ISO_FLAGS (coding) & (CODING_ISO_FLAG_DESIGNATION
| CODING_ISO_FLAG_LOCKING_SHIFT)));
while (charbuf < charbuf_end)
{
ASSURE_DESTINATION (safe_room);
if (bol_designation)
{
/* We have to produce designation sequences if any now. */
unsigned char desig_buf[16];
ptrdiff_t nbytes;
ptrdiff_t offset;
charset_map_loaded = 0;
nbytes = encode_designation_at_bol (coding, charbuf, charbuf_end,
desig_buf);
if (charset_map_loaded
&& (offset = coding_change_destination (coding)))
{
dst += offset;
dst_end += offset;
}
memcpy (dst, desig_buf, nbytes);
dst += nbytes;
/* We are sure that designation sequences are all ASCII bytes. */
produced_chars += nbytes;
bol_designation = 0;
ASSURE_DESTINATION (safe_room);
}
c = *charbuf++;
if (c < 0)
{
/* Handle an annotation. */
switch (*charbuf)
{
case CODING_ANNOTATE_COMPOSITION_MASK:
/* Not yet implemented. */
break;
case CODING_ANNOTATE_CHARSET_MASK:
preferred_charset_id = charbuf[2];
if (preferred_charset_id >= 0
&& NILP (Fmemq (make_fixnum (preferred_charset_id),
charset_list)))
preferred_charset_id = -1;
break;
default:
emacs_abort ();
}
charbuf += -c - 1;
continue;
}
/* Now encode the character C. */
if (c < 0x20 || c == 0x7F)
{
if (c == '\n'
|| (c == '\r' && EQ (eol_type, Qmac)))
{
if (CODING_ISO_FLAGS (coding) & CODING_ISO_FLAG_RESET_AT_EOL)
ENCODE_RESET_PLANE_AND_REGISTER ();
if (CODING_ISO_FLAGS (coding) & CODING_ISO_FLAG_INIT_AT_BOL)
{
int i;
for (i = 0; i < 4; i++)
CODING_ISO_DESIGNATION (coding, i)
= CODING_ISO_INITIAL (coding, i);
}
bol_designation = ((CODING_ISO_FLAGS (coding)
& CODING_ISO_FLAG_DESIGNATE_AT_BOL)
!= 0);
}
else if (CODING_ISO_FLAGS (coding) & CODING_ISO_FLAG_RESET_AT_CNTL)
ENCODE_RESET_PLANE_AND_REGISTER ();
EMIT_ONE_ASCII_BYTE (c);
}
else if (ASCII_CHAR_P (c))
{
if (ascii_compatible)
EMIT_ONE_ASCII_BYTE (c);
else
{
struct charset *charset = CHARSET_FROM_ID (charset_ascii);
ENCODE_ISO_CHARACTER (charset, c);
}
}
else if (CHAR_BYTE8_P (c))
{
c = CHAR_TO_BYTE8 (c);
EMIT_ONE_BYTE (c);
}
else
{
struct charset *charset;
if (preferred_charset_id >= 0)
{
bool result;
charset = CHARSET_FROM_ID (preferred_charset_id);
CODING_CHAR_CHARSET_P (coding, dst, dst_end, c, charset, result);
if (! result)
CODING_CHAR_CHARSET (coding, dst, dst_end, c, charset_list,
NULL, charset);
}
else
CODING_CHAR_CHARSET (coding, dst, dst_end, c, charset_list,
NULL, charset);
if (!charset)
{
if (coding->mode & CODING_MODE_SAFE_ENCODING)
{
c = CODING_INHIBIT_CHARACTER_SUBSTITUTION;
charset = CHARSET_FROM_ID (charset_ascii);
}
else
{
c = coding->default_char;
CODING_CHAR_CHARSET (coding, dst, dst_end, c,
charset_list, NULL, charset);
}
}
ENCODE_ISO_CHARACTER (charset, c);
}
}
if (coding->mode & CODING_MODE_LAST_BLOCK
&& CODING_ISO_FLAGS (coding) & CODING_ISO_FLAG_RESET_AT_EOL)
{
ASSURE_DESTINATION (safe_room);
ENCODE_RESET_PLANE_AND_REGISTER ();
}
record_conversion_result (coding, CODING_RESULT_SUCCESS);
CODING_ISO_BOL (coding) = bol_designation;
coding->produced_char += produced_chars;
coding->produced = dst - coding->destination;
return 0;
}
/*** 8,9. SJIS and BIG5 handlers ***/
/* Although SJIS and BIG5 are not ISO's coding system, they are used
quite widely. So, for the moment, Emacs supports them in the bare
C code. But, in the future, they may be supported only by CCL. */
/* SJIS is a coding system encoding three character sets: ASCII, right
half of JISX0201-Kana, and JISX0208. An ASCII character is encoded
as is. A character of charset katakana-jisx0201 is encoded by
"position-code + 0x80". A character of charset japanese-jisx0208
is encoded in 2-byte but two position-codes are divided and shifted
so that it fit in the range below.
--- CODE RANGE of SJIS ---
(character set) (range)
ASCII 0x00 .. 0x7F
KATAKANA-JISX0201 0xA0 .. 0xDF
JISX0208 (1st byte) 0x81 .. 0x9F and 0xE0 .. 0xEF
(2nd byte) 0x40 .. 0x7E and 0x80 .. 0xFC
-------------------------------
*/
/* BIG5 is a coding system encoding two character sets: ASCII and
Big5. An ASCII character is encoded as is. Big5 is a two-byte
character set and is encoded in two-byte.
--- CODE RANGE of BIG5 ---
(character set) (range)
ASCII 0x00 .. 0x7F
Big5 (1st byte) 0xA1 .. 0xFE
(2nd byte) 0x40 .. 0x7E and 0xA1 .. 0xFE
--------------------------
*/
/* See the above "GENERAL NOTES on `detect_coding_XXX ()' functions".
Return true if a text is encoded in SJIS. */
static bool
detect_coding_sjis (struct coding_system *coding,
struct coding_detection_info *detect_info)
{
const unsigned char *src = coding->source, *src_base;
const unsigned char *src_end = coding->source + coding->src_bytes;
bool multibytep = coding->src_multibyte;
ptrdiff_t consumed_chars = 0;
int found = 0;
int c;
Lisp_Object attrs, charset_list;
int max_first_byte_of_2_byte_code;
CODING_GET_INFO (coding, attrs, charset_list);
max_first_byte_of_2_byte_code = list_length (charset_list) <= 3 ? 0xEF : 0xFC;
detect_info->checked |= CATEGORY_MASK_SJIS;
/* A coding system of this category is always ASCII compatible. */
src += coding->head_ascii;
while (1)
{
src_base = src;
ONE_MORE_BYTE (c);
if (c < 0x80)
continue;
if ((c >= 0x81 && c <= 0x9F)
|| (c >= 0xE0 && c <= max_first_byte_of_2_byte_code))
{
ONE_MORE_BYTE (c);
if (c < 0x40 || c == 0x7F || c > 0xFC)
break;
found = CATEGORY_MASK_SJIS;
}
else if (c >= 0xA0 && c < 0xE0)
found = CATEGORY_MASK_SJIS;
else
break;
}
detect_info->rejected |= CATEGORY_MASK_SJIS;
return 0;
no_more_source:
if (src_base < src && coding->mode & CODING_MODE_LAST_BLOCK)
{
detect_info->rejected |= CATEGORY_MASK_SJIS;
return 0;
}
detect_info->found |= found;
return 1;
}
/* See the above "GENERAL NOTES on `detect_coding_XXX ()' functions".
Return true if a text is encoded in BIG5. */
static bool
detect_coding_big5 (struct coding_system *coding,
struct coding_detection_info *detect_info)
{
const unsigned char *src = coding->source, *src_base;
const unsigned char *src_end = coding->source + coding->src_bytes;
bool multibytep = coding->src_multibyte;
ptrdiff_t consumed_chars = 0;
int found = 0;
int c;
detect_info->checked |= CATEGORY_MASK_BIG5;
/* A coding system of this category is always ASCII compatible. */
src += coding->head_ascii;
while (1)
{
src_base = src;
ONE_MORE_BYTE (c);
if (c < 0x80)
continue;
if (c >= 0xA1)
{
ONE_MORE_BYTE (c);
if (c < 0x40 || (c >= 0x7F && c <= 0xA0))
return 0;
found = CATEGORY_MASK_BIG5;
}
else
break;
}
detect_info->rejected |= CATEGORY_MASK_BIG5;
return 0;
no_more_source:
if (src_base < src && coding->mode & CODING_MODE_LAST_BLOCK)
{
detect_info->rejected |= CATEGORY_MASK_BIG5;
return 0;
}
detect_info->found |= found;
return 1;
}
/* See the above "GENERAL NOTES on `decode_coding_XXX ()' functions". */
static void
decode_coding_sjis (struct coding_system *coding)
{
const unsigned char *src = coding->source + coding->consumed;
const unsigned char *src_end = coding->source + coding->src_bytes;
const unsigned char *src_base;
int *charbuf = coding->charbuf + coding->charbuf_used;
/* We may produce one charset annotation in one loop and one more at
the end. */
int *charbuf_end
= coding->charbuf + coding->charbuf_size - (MAX_ANNOTATION_LENGTH * 2);
ptrdiff_t consumed_chars = 0, consumed_chars_base;
bool multibytep = coding->src_multibyte;
struct charset *charset_roman, *charset_kanji, *charset_kana;
struct charset *charset_kanji2;
Lisp_Object attrs, charset_list, val;
ptrdiff_t char_offset = coding->produced_char;
ptrdiff_t last_offset = char_offset;
int last_id = charset_ascii;
bool eol_dos
= !inhibit_eol_conversion && EQ (CODING_ID_EOL_TYPE (coding->id), Qdos);
int byte_after_cr = -1;
CODING_GET_INFO (coding, attrs, charset_list);
val = charset_list;
charset_roman = CHARSET_FROM_ID (XFIXNUM (XCAR (val))), val = XCDR (val);
charset_kana = CHARSET_FROM_ID (XFIXNUM (XCAR (val))), val = XCDR (val);
charset_kanji = CHARSET_FROM_ID (XFIXNUM (XCAR (val))), val = XCDR (val);
charset_kanji2 = NILP (val) ? NULL : CHARSET_FROM_ID (XFIXNUM (XCAR (val)));
while (1)
{
int c, c1;
struct charset *charset;
src_base = src;
consumed_chars_base = consumed_chars;
if (charbuf >= charbuf_end)
{
if (byte_after_cr >= 0)
src_base--;
break;
}
if (byte_after_cr >= 0)
c = byte_after_cr, byte_after_cr = -1;
else
ONE_MORE_BYTE (c);
if (c < 0)
goto invalid_code;
if (c < 0x80)
{
if (eol_dos && c == '\r')
ONE_MORE_BYTE (byte_after_cr);
charset = charset_roman;
}
else if (c == 0x80 || c == 0xA0)
goto invalid_code;
else if (c >= 0xA1 && c <= 0xDF)
{
/* SJIS -> JISX0201-Kana */
c &= 0x7F;
charset = charset_kana;
}
else if (c <= 0xEF)
{
/* SJIS -> JISX0208 */
ONE_MORE_BYTE (c1);
if (c1 < 0x40 || c1 == 0x7F || c1 > 0xFC)
goto invalid_code;
c = (c << 8) | c1;
SJIS_TO_JIS (c);
charset = charset_kanji;
}
else if (c <= 0xFC && charset_kanji2)
{
/* SJIS -> JISX0213-2 */
ONE_MORE_BYTE (c1);
if (c1 < 0x40 || c1 == 0x7F || c1 > 0xFC)
goto invalid_code;
c = (c << 8) | c1;
SJIS_TO_JIS2 (c);
charset = charset_kanji2;
}
else
goto invalid_code;
if (charset->id != charset_ascii
&& last_id != charset->id)
{
if (last_id != charset_ascii)
ADD_CHARSET_DATA (charbuf, char_offset - last_offset, last_id);
last_id = charset->id;
last_offset = char_offset;
}
CODING_DECODE_CHAR (coding, src, src_base, src_end, charset, c, c);
*charbuf++ = c;
char_offset++;
continue;
invalid_code:
src = src_base;
consumed_chars = consumed_chars_base;
ONE_MORE_BYTE (c);
*charbuf++ = c < 0 ? -c : BYTE8_TO_CHAR (c);
char_offset++;
}
no_more_source:
if (last_id != charset_ascii)
ADD_CHARSET_DATA (charbuf, char_offset - last_offset, last_id);
coding->consumed_char += consumed_chars_base;
coding->consumed = src_base - coding->source;
coding->charbuf_used = charbuf - coding->charbuf;
}
static void
decode_coding_big5 (struct coding_system *coding)
{
const unsigned char *src = coding->source + coding->consumed;
const unsigned char *src_end = coding->source + coding->src_bytes;
const unsigned char *src_base;
int *charbuf = coding->charbuf + coding->charbuf_used;
/* We may produce one charset annotation in one loop and one more at
the end. */
int *charbuf_end
= coding->charbuf + coding->charbuf_size - (MAX_ANNOTATION_LENGTH * 2);
ptrdiff_t consumed_chars = 0, consumed_chars_base;
bool multibytep = coding->src_multibyte;
struct charset *charset_roman, *charset_big5;
Lisp_Object attrs, charset_list, val;
ptrdiff_t char_offset = coding->produced_char;
ptrdiff_t last_offset = char_offset;
int last_id = charset_ascii;
bool eol_dos
= !inhibit_eol_conversion && EQ (CODING_ID_EOL_TYPE (coding->id), Qdos);
int byte_after_cr = -1;
CODING_GET_INFO (coding, attrs, charset_list);
val = charset_list;
charset_roman = CHARSET_FROM_ID (XFIXNUM (XCAR (val))), val = XCDR (val);
charset_big5 = CHARSET_FROM_ID (XFIXNUM (XCAR (val)));
while (1)
{
int c, c1;
struct charset *charset;
src_base = src;
consumed_chars_base = consumed_chars;
if (charbuf >= charbuf_end)
{
if (byte_after_cr >= 0)
src_base--;
break;
}
if (byte_after_cr >= 0)
c = byte_after_cr, byte_after_cr = -1;
else
ONE_MORE_BYTE (c);
if (c < 0)
goto invalid_code;
if (c < 0x80)
{
if (eol_dos && c == '\r')
ONE_MORE_BYTE (byte_after_cr);
charset = charset_roman;
}
else
{
/* BIG5 -> Big5 */
if (c < 0xA1 || c > 0xFE)
goto invalid_code;
ONE_MORE_BYTE (c1);
if (c1 < 0x40 || (c1 > 0x7E && c1 < 0xA1) || c1 > 0xFE)
goto invalid_code;
c = c << 8 | c1;
charset = charset_big5;
}
if (charset->id != charset_ascii
&& last_id != charset->id)
{
if (last_id != charset_ascii)
ADD_CHARSET_DATA (charbuf, char_offset - last_offset, last_id);
last_id = charset->id;
last_offset = char_offset;
}
CODING_DECODE_CHAR (coding, src, src_base, src_end, charset, c, c);
*charbuf++ = c;
char_offset++;
continue;
invalid_code:
src = src_base;
consumed_chars = consumed_chars_base;
ONE_MORE_BYTE (c);
*charbuf++ = c < 0 ? -c : BYTE8_TO_CHAR (c);
char_offset++;
}
no_more_source:
if (last_id != charset_ascii)
ADD_CHARSET_DATA (charbuf, char_offset - last_offset, last_id);
coding->consumed_char += consumed_chars_base;
coding->consumed = src_base - coding->source;
coding->charbuf_used = charbuf - coding->charbuf;
}
/* See the above "GENERAL NOTES on `encode_coding_XXX ()' functions".
This function can encode charsets `ascii', `katakana-jisx0201',
`japanese-jisx0208', `chinese-big5-1', and `chinese-big5-2'. We
are sure that all these charsets are registered as official charset
(i.e. do not have extended leading-codes). Characters of other
charsets are produced without any encoding. */
static bool
encode_coding_sjis (struct coding_system *coding)
{
bool multibytep = coding->dst_multibyte;
int *charbuf = coding->charbuf;
int *charbuf_end = charbuf + coding->charbuf_used;
unsigned char *dst = coding->destination + coding->produced;
unsigned char *dst_end = coding->destination + coding->dst_bytes;
int safe_room = 4;
ptrdiff_t produced_chars = 0;
Lisp_Object attrs, charset_list, val;
bool ascii_compatible;
struct charset *charset_kanji, *charset_kana;
struct charset *charset_kanji2;
int c;
CODING_GET_INFO (coding, attrs, charset_list);
val = XCDR (charset_list);
charset_kana = CHARSET_FROM_ID (XFIXNUM (XCAR (val))), val = XCDR (val);
charset_kanji = CHARSET_FROM_ID (XFIXNUM (XCAR (val))), val = XCDR (val);
charset_kanji2 = NILP (val) ? NULL : CHARSET_FROM_ID (XFIXNUM (XCAR (val)));
ascii_compatible = ! NILP (CODING_ATTR_ASCII_COMPAT (attrs));
while (charbuf < charbuf_end)
{
ASSURE_DESTINATION (safe_room);
c = *charbuf++;
/* Now encode the character C. */
if (ASCII_CHAR_P (c) && ascii_compatible)
EMIT_ONE_ASCII_BYTE (c);
else if (CHAR_BYTE8_P (c))
{
c = CHAR_TO_BYTE8 (c);
EMIT_ONE_BYTE (c);
}
else
{
unsigned code;
struct charset *charset;
CODING_CHAR_CHARSET (coding, dst, dst_end, c, charset_list,
&code, charset);
if (!charset)
{
if (coding->mode & CODING_MODE_SAFE_ENCODING)
{
code = CODING_INHIBIT_CHARACTER_SUBSTITUTION;
charset = CHARSET_FROM_ID (charset_ascii);
}
else
{
c = coding->default_char;
CODING_CHAR_CHARSET (coding, dst, dst_end, c,
charset_list, &code, charset);
}
}
if (code == CHARSET_INVALID_CODE (charset))
emacs_abort ();
if (charset == charset_kanji)
{
int c1, c2;
JIS_TO_SJIS (code);
c1 = code >> 8, c2 = code & 0xFF;
EMIT_TWO_BYTES (c1, c2);
}
else if (charset == charset_kana)
EMIT_ONE_BYTE (code | 0x80);
else if (charset_kanji2 && charset == charset_kanji2)
{
int c1, c2;
c1 = code >> 8;
if (c1 == 0x21 || (c1 >= 0x23 && c1 <= 0x25)
|| c1 == 0x28
|| (c1 >= 0x2C && c1 <= 0x2F) || c1 >= 0x6E)
{
JIS_TO_SJIS2 (code);
c1 = code >> 8, c2 = code & 0xFF;
EMIT_TWO_BYTES (c1, c2);
}
else
EMIT_ONE_ASCII_BYTE (code & 0x7F);
}
else
EMIT_ONE_ASCII_BYTE (code & 0x7F);
}
}
record_conversion_result (coding, CODING_RESULT_SUCCESS);
coding->produced_char += produced_chars;
coding->produced = dst - coding->destination;
return 0;
}
static bool
encode_coding_big5 (struct coding_system *coding)
{
bool multibytep = coding->dst_multibyte;
int *charbuf = coding->charbuf;
int *charbuf_end = charbuf + coding->charbuf_used;
unsigned char *dst = coding->destination + coding->produced;
unsigned char *dst_end = coding->destination + coding->dst_bytes;
int safe_room = 4;
ptrdiff_t produced_chars = 0;
Lisp_Object attrs, charset_list, val;
bool ascii_compatible;
struct charset *charset_big5;
int c;
CODING_GET_INFO (coding, attrs, charset_list);
val = XCDR (charset_list);
charset_big5 = CHARSET_FROM_ID (XFIXNUM (XCAR (val)));
ascii_compatible = ! NILP (CODING_ATTR_ASCII_COMPAT (attrs));
while (charbuf < charbuf_end)
{
ASSURE_DESTINATION (safe_room);
c = *charbuf++;
/* Now encode the character C. */
if (ASCII_CHAR_P (c) && ascii_compatible)
EMIT_ONE_ASCII_BYTE (c);
else if (CHAR_BYTE8_P (c))
{
c = CHAR_TO_BYTE8 (c);
EMIT_ONE_BYTE (c);
}
else
{
unsigned code;
struct charset *charset;
CODING_CHAR_CHARSET (coding, dst, dst_end, c, charset_list,
&code, charset);
if (! charset)
{
if (coding->mode & CODING_MODE_SAFE_ENCODING)
{
code = CODING_INHIBIT_CHARACTER_SUBSTITUTION;
charset = CHARSET_FROM_ID (charset_ascii);
}
else
{
c = coding->default_char;
CODING_CHAR_CHARSET (coding, dst, dst_end, c,
charset_list, &code, charset);
}
}
if (code == CHARSET_INVALID_CODE (charset))
emacs_abort ();
if (charset == charset_big5)
{
int c1, c2;
c1 = code >> 8, c2 = code & 0xFF;
EMIT_TWO_BYTES (c1, c2);
}
else
EMIT_ONE_ASCII_BYTE (code & 0x7F);
}
}
record_conversion_result (coding, CODING_RESULT_SUCCESS);
coding->produced_char += produced_chars;
coding->produced = dst - coding->destination;
return 0;
}
/*** 10. CCL handlers ***/
/* See the above "GENERAL NOTES on `detect_coding_XXX ()' functions".
Return true if a text is encoded in a coding system of which
encoder/decoder are written in CCL program. */
static bool
detect_coding_ccl (struct coding_system *coding,
struct coding_detection_info *detect_info)
{
const unsigned char *src = coding->source, *src_base;
const unsigned char *src_end = coding->source + coding->src_bytes;
bool multibytep = coding->src_multibyte;
ptrdiff_t consumed_chars = 0;
int found = 0;
unsigned char *valids;
ptrdiff_t head_ascii = coding->head_ascii;
Lisp_Object attrs;
detect_info->checked |= CATEGORY_MASK_CCL;
coding = &coding_categories[coding_category_ccl];
valids = CODING_CCL_VALIDS (coding);
attrs = CODING_ID_ATTRS (coding->id);
if (! NILP (CODING_ATTR_ASCII_COMPAT (attrs)))
src += head_ascii;
while (1)
{
int c;
src_base = src;
ONE_MORE_BYTE (c);
if (c < 0 || ! valids[c])
break;
if ((valids[c] > 1))
found = CATEGORY_MASK_CCL;
}
detect_info->rejected |= CATEGORY_MASK_CCL;
return 0;
no_more_source:
detect_info->found |= found;
return 1;
}
static void
decode_coding_ccl (struct coding_system *coding)
{
const unsigned char *src = coding->source + coding->consumed;
const unsigned char *src_end = coding->source + coding->src_bytes;
int *charbuf = coding->charbuf + coding->charbuf_used;
int *charbuf_end = coding->charbuf + coding->charbuf_size;
ptrdiff_t consumed_chars = 0;
bool multibytep = coding->src_multibyte;
struct ccl_program *ccl = &coding->spec.ccl->ccl;
int source_charbuf[1024];
int source_byteidx[1025];
Lisp_Object attrs, charset_list;
CODING_GET_INFO (coding, attrs, charset_list);
while (1)
{
const unsigned char *p = src;
ptrdiff_t offset;
int i = 0;
if (multibytep)
{
while (i < 1024 && p < src_end)
{
source_byteidx[i] = p - src;
source_charbuf[i++] = string_char_advance (&p);
}
source_byteidx[i] = p - src;
}
else
while (i < 1024 && p < src_end)
source_charbuf[i++] = *p++;
if (p == src_end && coding->mode & CODING_MODE_LAST_BLOCK)
ccl->last_block = true;
/* As ccl_driver calls DECODE_CHAR, buffer may be relocated. */
charset_map_loaded = 0;
ccl_driver (ccl, source_charbuf, charbuf, i, charbuf_end - charbuf,
charset_list);
if (charset_map_loaded
&& (offset = coding_change_source (coding)))
{
p += offset;
src += offset;
src_end += offset;
}
charbuf += ccl->produced;
if (multibytep)
src += source_byteidx[ccl->consumed];
else
src += ccl->consumed;
consumed_chars += ccl->consumed;
if (p == src_end || ccl->status != CCL_STAT_SUSPEND_BY_SRC)
break;
}
switch (ccl->status)
{
case CCL_STAT_SUSPEND_BY_SRC:
record_conversion_result (coding, CODING_RESULT_INSUFFICIENT_SRC);
break;
case CCL_STAT_SUSPEND_BY_DST:
record_conversion_result (coding, CODING_RESULT_INSUFFICIENT_DST);
break;
case CCL_STAT_QUIT:
case CCL_STAT_INVALID_CMD:
record_conversion_result (coding, CODING_RESULT_INTERRUPT);
break;
default:
record_conversion_result (coding, CODING_RESULT_SUCCESS);
break;
}
coding->consumed_char += consumed_chars;
coding->consumed = src - coding->source;
coding->charbuf_used = charbuf - coding->charbuf;
}
static bool
encode_coding_ccl (struct coding_system *coding)
{
struct ccl_program *ccl = &coding->spec.ccl->ccl;
bool multibytep = coding->dst_multibyte;
int *charbuf = coding->charbuf;
int *charbuf_end = charbuf + coding->charbuf_used;
unsigned char *dst = coding->destination + coding->produced;
unsigned char *dst_end = coding->destination + coding->dst_bytes;
int destination_charbuf[1024];
ptrdiff_t produced_chars = 0;
int i;
Lisp_Object attrs, charset_list;
CODING_GET_INFO (coding, attrs, charset_list);
if (coding->consumed_char == coding->src_chars
&& coding->mode & CODING_MODE_LAST_BLOCK)
ccl->last_block = true;
do
{
ptrdiff_t offset;
/* As ccl_driver calls DECODE_CHAR, buffer may be relocated. */
charset_map_loaded = 0;
ccl_driver (ccl, charbuf, destination_charbuf,
charbuf_end - charbuf, 1024, charset_list);
if (charset_map_loaded
&& (offset = coding_change_destination (coding)))
dst += offset;
if (multibytep)
{
ASSURE_DESTINATION (ccl->produced * 2);
for (i = 0; i < ccl->produced; i++)
EMIT_ONE_BYTE (destination_charbuf[i] & 0xFF);
}
else
{
ASSURE_DESTINATION (ccl->produced);
for (i = 0; i < ccl->produced; i++)
*dst++ = destination_charbuf[i] & 0xFF;
produced_chars += ccl->produced;
}
charbuf += ccl->consumed;
if (ccl->status == CCL_STAT_QUIT
|| ccl->status == CCL_STAT_INVALID_CMD)
break;
}
while (charbuf < charbuf_end);
switch (ccl->status)
{
case CCL_STAT_SUSPEND_BY_SRC:
record_conversion_result (coding, CODING_RESULT_INSUFFICIENT_SRC);
break;
case CCL_STAT_SUSPEND_BY_DST:
record_conversion_result (coding, CODING_RESULT_INSUFFICIENT_DST);
break;
case CCL_STAT_QUIT:
case CCL_STAT_INVALID_CMD:
record_conversion_result (coding, CODING_RESULT_INTERRUPT);
break;
default:
record_conversion_result (coding, CODING_RESULT_SUCCESS);
break;
}
coding->produced_char += produced_chars;
coding->produced = dst - coding->destination;
return 0;
}
/*** 10, 11. no-conversion handlers ***/
/* See the above "GENERAL NOTES on `decode_coding_XXX ()' functions". */
static void
decode_coding_raw_text (struct coding_system *coding)
{
bool eol_dos
= !inhibit_eol_conversion && EQ (CODING_ID_EOL_TYPE (coding->id), Qdos);
coding->chars_at_source = 1;
coding->consumed_char = coding->src_chars;
coding->consumed = coding->src_bytes;
if (eol_dos && coding->source[coding->src_bytes - 1] == '\r')
{
coding->consumed_char--;
coding->consumed--;
record_conversion_result (coding, CODING_RESULT_INSUFFICIENT_SRC);
}
else
record_conversion_result (coding, CODING_RESULT_SUCCESS);
}
static bool
encode_coding_raw_text (struct coding_system *coding)
{
bool multibytep = coding->dst_multibyte;
int *charbuf = coding->charbuf;
int *charbuf_end = coding->charbuf + coding->charbuf_used;
unsigned char *dst = coding->destination + coding->produced;
unsigned char *dst_end = coding->destination + coding->dst_bytes;
ptrdiff_t produced_chars = 0;
int c;
if (multibytep)
{
int safe_room = MAX_MULTIBYTE_LENGTH * 2;
if (coding->src_multibyte)
while (charbuf < charbuf_end)
{
ASSURE_DESTINATION (safe_room);
c = *charbuf++;
if (ASCII_CHAR_P (c))
EMIT_ONE_ASCII_BYTE (c);
else if (CHAR_BYTE8_P (c))
{
c = CHAR_TO_BYTE8 (c);
EMIT_ONE_BYTE (c);
}
else
{
unsigned char str[MAX_MULTIBYTE_LENGTH];
int len = CHAR_STRING (c, str);
for (int i = 0; i < len; i++)
EMIT_ONE_BYTE (str[i]);
}
}
else
while (charbuf < charbuf_end)
{
ASSURE_DESTINATION (safe_room);
c = *charbuf++;
EMIT_ONE_BYTE (c);
}
}
else
{
if (coding->src_multibyte)
{
int safe_room = MAX_MULTIBYTE_LENGTH;
while (charbuf < charbuf_end)
{
ASSURE_DESTINATION (safe_room);
c = *charbuf++;
if (ASCII_CHAR_P (c))
*dst++ = c;
else if (CHAR_BYTE8_P (c))
*dst++ = CHAR_TO_BYTE8 (c);
else
dst += CHAR_STRING (c, dst);
}
}
else
{
ASSURE_DESTINATION (charbuf_end - charbuf);
while (charbuf < charbuf_end && dst < dst_end)
*dst++ = *charbuf++;
}
produced_chars = dst - (coding->destination + coding->produced);
}
record_conversion_result (coding, CODING_RESULT_SUCCESS);
coding->produced_char += produced_chars;
coding->produced = dst - coding->destination;
return 0;
}
/* See the above "GENERAL NOTES on `detect_coding_XXX ()' functions".
Return true if a text is encoded in a charset-based coding system. */
static bool
detect_coding_charset (struct coding_system *coding,
struct coding_detection_info *detect_info)
{
const unsigned char *src = coding->source, *src_base;
const unsigned char *src_end = coding->source + coding->src_bytes;
bool multibytep = coding->src_multibyte;
ptrdiff_t consumed_chars = 0;
Lisp_Object attrs, valids, name;
int found = 0;
ptrdiff_t head_ascii = coding->head_ascii;
bool check_latin_extra = 0;
detect_info->checked |= CATEGORY_MASK_CHARSET;
coding = &coding_categories[coding_category_charset];
attrs = CODING_ID_ATTRS (coding->id);
valids = AREF (attrs, coding_attr_charset_valids);
name = CODING_ID_NAME (coding->id);
if (strncmp (SSDATA (SYMBOL_NAME (name)),
"iso-8859-", sizeof ("iso-8859-") - 1) == 0
|| strncmp (SSDATA (SYMBOL_NAME (name)),
"iso-latin-", sizeof ("iso-latin-") - 1) == 0)
check_latin_extra = 1;
if (! NILP (CODING_ATTR_ASCII_COMPAT (attrs)))
src += head_ascii;
while (1)
{
int c;
Lisp_Object val;
struct charset *charset;
int dim, idx;
src_base = src;
ONE_MORE_BYTE (c);
if (c < 0)
continue;
val = AREF (valids, c);
if (NILP (val))
break;
if (c >= 0x80)
{
if (c < 0xA0
&& check_latin_extra
&& (!VECTORP (Vlatin_extra_code_table)
|| NILP (AREF (Vlatin_extra_code_table, c))))
break;
found = CATEGORY_MASK_CHARSET;
}
if (FIXNUMP (val))
{
charset = CHARSET_FROM_ID (XFIXNAT (val));
dim = CHARSET_DIMENSION (charset);
for (idx = 1; idx < dim; idx++)
{
if (src == src_end)
goto too_short;
ONE_MORE_BYTE (c);
if (c < charset->code_space[(dim - 1 - idx) * 4]
|| c > charset->code_space[(dim - 1 - idx) * 4 + 1])
break;
}
if (idx < dim)
break;
}
else
{
idx = 1;
for (; CONSP (val); val = XCDR (val))
{
charset = CHARSET_FROM_ID (XFIXNAT (XCAR (val)));
dim = CHARSET_DIMENSION (charset);
while (idx < dim)
{
if (src == src_end)
goto too_short;
ONE_MORE_BYTE (c);
if (c < charset->code_space[(dim - 1 - idx) * 4]
|| c > charset->code_space[(dim - 1 - idx) * 4 + 1])
break;
idx++;
}
if (idx == dim)
{
val = Qnil;
break;
}
}
if (CONSP (val))
break;
}
}
too_short:
detect_info->rejected |= CATEGORY_MASK_CHARSET;
return 0;
no_more_source:
detect_info->found |= found;
return 1;
}
static void
decode_coding_charset (struct coding_system *coding)
{
const unsigned char *src = coding->source + coding->consumed;
const unsigned char *src_end = coding->source + coding->src_bytes;
const unsigned char *src_base;
int *charbuf = coding->charbuf + coding->charbuf_used;
/* We may produce one charset annotation in one loop and one more at
the end. */
int *charbuf_end
= coding->charbuf + coding->charbuf_size - (MAX_ANNOTATION_LENGTH * 2);
ptrdiff_t consumed_chars = 0, consumed_chars_base;
bool multibytep = coding->src_multibyte;
Lisp_Object attrs = CODING_ID_ATTRS (coding->id);
Lisp_Object valids;
ptrdiff_t char_offset = coding->produced_char;
ptrdiff_t last_offset = char_offset;
int last_id = charset_ascii;
bool eol_dos
= !inhibit_eol_conversion && EQ (CODING_ID_EOL_TYPE (coding->id), Qdos);
int byte_after_cr = -1;
valids = AREF (attrs, coding_attr_charset_valids);
while (1)
{
int c;
Lisp_Object val;
struct charset *charset;
int dim;
int len = 1;
unsigned code;
src_base = src;
consumed_chars_base = consumed_chars;
if (charbuf >= charbuf_end)
{
if (byte_after_cr >= 0)
src_base--;
break;
}
if (byte_after_cr >= 0)
{
c = byte_after_cr;
byte_after_cr = -1;
}
else
{
ONE_MORE_BYTE (c);
if (eol_dos && c == '\r')
ONE_MORE_BYTE (byte_after_cr);
}
if (c < 0)
goto invalid_code;
code = c;
val = AREF (valids, c);
if (! FIXNUMP (val) && ! CONSP (val))
goto invalid_code;
if (FIXNUMP (val))
{
charset = CHARSET_FROM_ID (XFIXNAT (val));
dim = CHARSET_DIMENSION (charset);
while (len < dim)
{
ONE_MORE_BYTE (c);
code = (code << 8) | c;
len++;
}
CODING_DECODE_CHAR (coding, src, src_base, src_end,
charset, code, c);
}
else
{
/* VAL is a list of charset IDs. It is assured that the
list is sorted by charset dimensions (smaller one
comes first). */
while (CONSP (val))
{
charset = CHARSET_FROM_ID (XFIXNAT (XCAR (val)));
dim = CHARSET_DIMENSION (charset);
while (len < dim)
{
ONE_MORE_BYTE (c);
code = (code << 8) | c;
len++;
}
CODING_DECODE_CHAR (coding, src, src_base,
src_end, charset, code, c);
if (c >= 0)
break;
val = XCDR (val);
}
}
if (c < 0)
goto invalid_code;
if (charset->id != charset_ascii
&& last_id != charset->id)
{
if (last_id != charset_ascii)
ADD_CHARSET_DATA (charbuf, char_offset - last_offset, last_id);
last_id = charset->id;
last_offset = char_offset;
}
*charbuf++ = c;
char_offset++;
continue;
invalid_code:
src = src_base;
consumed_chars = consumed_chars_base;
ONE_MORE_BYTE (c);
*charbuf++ = c < 0 ? -c : ASCII_CHAR_P (c) ? c : BYTE8_TO_CHAR (c);
char_offset++;
}
no_more_source:
if (last_id != charset_ascii)
ADD_CHARSET_DATA (charbuf, char_offset - last_offset, last_id);
coding->consumed_char += consumed_chars_base;
coding->consumed = src_base - coding->source;
coding->charbuf_used = charbuf - coding->charbuf;
}
static bool
encode_coding_charset (struct coding_system *coding)
{
bool multibytep = coding->dst_multibyte;
int *charbuf = coding->charbuf;
int *charbuf_end = charbuf + coding->charbuf_used;
unsigned char *dst = coding->destination + coding->produced;
unsigned char *dst_end = coding->destination + coding->dst_bytes;
int safe_room = MAX_MULTIBYTE_LENGTH;
ptrdiff_t produced_chars = 0;
Lisp_Object attrs, charset_list;
bool ascii_compatible;
int c;
CODING_GET_INFO (coding, attrs, charset_list);
ascii_compatible = ! NILP (CODING_ATTR_ASCII_COMPAT (attrs));
while (charbuf < charbuf_end)
{
struct charset *charset;
unsigned code;
ASSURE_DESTINATION (safe_room);
c = *charbuf++;
if (ascii_compatible && ASCII_CHAR_P (c))
EMIT_ONE_ASCII_BYTE (c);
else if (CHAR_BYTE8_P (c))
{
c = CHAR_TO_BYTE8 (c);
EMIT_ONE_BYTE (c);
}
else
{
CODING_CHAR_CHARSET (coding, dst, dst_end, c, charset_list,
&code, charset);
if (charset)
{
if (CHARSET_DIMENSION (charset) == 1)
EMIT_ONE_BYTE (code);
else if (CHARSET_DIMENSION (charset) == 2)
EMIT_TWO_BYTES (code >> 8, code & 0xFF);
else if (CHARSET_DIMENSION (charset) == 3)
EMIT_THREE_BYTES (code >> 16, (code >> 8) & 0xFF, code & 0xFF);
else
EMIT_FOUR_BYTES (code >> 24, (code >> 16) & 0xFF,
(code >> 8) & 0xFF, code & 0xFF);
}
else
{
if (coding->mode & CODING_MODE_SAFE_ENCODING)
c = CODING_INHIBIT_CHARACTER_SUBSTITUTION;
else
c = coding->default_char;
EMIT_ONE_BYTE (c);
}
}
}
record_conversion_result (coding, CODING_RESULT_SUCCESS);
coding->produced_char += produced_chars;
coding->produced = dst - coding->destination;
return 0;
}
/*** 7. C library functions ***/
/* Setup coding context CODING from information about CODING_SYSTEM.
If CODING_SYSTEM is nil, `no-conversion' is assumed. If
CODING_SYSTEM is invalid, signal an error. */
void
setup_coding_system (Lisp_Object coding_system, struct coding_system *coding)
{
Lisp_Object attrs;
Lisp_Object eol_type;
Lisp_Object coding_type;
Lisp_Object val;
if (NILP (coding_system))
coding_system = Qundecided;
CHECK_CODING_SYSTEM_GET_ID (coding_system, coding->id);
attrs = CODING_ID_ATTRS (coding->id);
eol_type = inhibit_eol_conversion ? Qunix : CODING_ID_EOL_TYPE (coding->id);
coding->mode = 0;
if (VECTORP (eol_type))
coding->common_flags = (CODING_REQUIRE_DECODING_MASK
| CODING_REQUIRE_DETECTION_MASK);
else if (! EQ (eol_type, Qunix))
coding->common_flags = (CODING_REQUIRE_DECODING_MASK
| CODING_REQUIRE_ENCODING_MASK);
else
coding->common_flags = 0;
if (! NILP (CODING_ATTR_POST_READ (attrs)))
coding->common_flags |= CODING_REQUIRE_DECODING_MASK;
if (! NILP (CODING_ATTR_PRE_WRITE (attrs)))
coding->common_flags |= CODING_REQUIRE_ENCODING_MASK;
if (! NILP (CODING_ATTR_FOR_UNIBYTE (attrs)))
coding->common_flags |= CODING_FOR_UNIBYTE_MASK;
val = CODING_ATTR_SAFE_CHARSETS (attrs);
coding->max_charset_id = SCHARS (val) - 1;
coding->safe_charsets = SDATA (val);
coding->default_char = XFIXNUM (CODING_ATTR_DEFAULT_CHAR (attrs));
coding->carryover_bytes = 0;
coding->raw_destination = 0;
coding_type = CODING_ATTR_TYPE (attrs);
if (EQ (coding_type, Qundecided))
{
coding->detector = NULL;
coding->decoder = decode_coding_raw_text;
coding->encoder = encode_coding_raw_text;
coding->common_flags |= CODING_REQUIRE_DETECTION_MASK;
coding->spec.undecided.inhibit_nbd
= (encode_inhibit_flag
(AREF (attrs, coding_attr_undecided_inhibit_nul_byte_detection)));
coding->spec.undecided.inhibit_ied
= (encode_inhibit_flag
(AREF (attrs, coding_attr_undecided_inhibit_iso_escape_detection)));
coding->spec.undecided.prefer_utf_8
= ! NILP (AREF (attrs, coding_attr_undecided_prefer_utf_8));
}
else if (EQ (coding_type, Qiso_2022))
{
int i;
int flags = XFIXNUM (AREF (attrs, coding_attr_iso_flags));
/* Invoke graphic register 0 to plane 0. */
CODING_ISO_INVOCATION (coding, 0) = 0;
/* Invoke graphic register 1 to plane 1 if we can use 8-bit. */
CODING_ISO_INVOCATION (coding, 1)
= (flags & CODING_ISO_FLAG_SEVEN_BITS ? -1 : 1);
/* Setup the initial status of designation. */
for (i = 0; i < 4; i++)
CODING_ISO_DESIGNATION (coding, i) = CODING_ISO_INITIAL (coding, i);
/* Not single shifting initially. */
CODING_ISO_SINGLE_SHIFTING (coding) = 0;
/* Beginning of buffer should also be regarded as bol. */
CODING_ISO_BOL (coding) = 1;
coding->detector = detect_coding_iso_2022;
coding->decoder = decode_coding_iso_2022;
coding->encoder = encode_coding_iso_2022;
if (flags & CODING_ISO_FLAG_SAFE)
coding->mode |= CODING_MODE_SAFE_ENCODING;
coding->common_flags
|= (CODING_REQUIRE_DECODING_MASK | CODING_REQUIRE_ENCODING_MASK
| CODING_REQUIRE_FLUSHING_MASK);
if (flags & CODING_ISO_FLAG_COMPOSITION)
coding->common_flags |= CODING_ANNOTATE_COMPOSITION_MASK;
if (flags & CODING_ISO_FLAG_DESIGNATION)
coding->common_flags |= CODING_ANNOTATE_CHARSET_MASK;
if (flags & CODING_ISO_FLAG_FULL_SUPPORT)
{
setup_iso_safe_charsets (attrs);
val = CODING_ATTR_SAFE_CHARSETS (attrs);
coding->max_charset_id = SCHARS (val) - 1;
coding->safe_charsets = SDATA (val);
}
CODING_ISO_FLAGS (coding) = flags;
CODING_ISO_CMP_STATUS (coding)->state = COMPOSING_NO;
CODING_ISO_CMP_STATUS (coding)->method = COMPOSITION_NO;
CODING_ISO_EXTSEGMENT_LEN (coding) = 0;
CODING_ISO_EMBEDDED_UTF_8 (coding) = 0;
}
else if (EQ (coding_type, Qcharset))
{
coding->detector = detect_coding_charset;
coding->decoder = decode_coding_charset;
coding->encoder = encode_coding_charset;
coding->common_flags
|= (CODING_REQUIRE_DECODING_MASK | CODING_REQUIRE_ENCODING_MASK);
}
else if (EQ (coding_type, Qutf_8))
{
val = AREF (attrs, coding_attr_utf_bom);
CODING_UTF_8_BOM (coding) = (CONSP (val) ? utf_detect_bom
: EQ (val, Qt) ? utf_with_bom
: utf_without_bom);
coding->detector = detect_coding_utf_8;
coding->decoder = decode_coding_utf_8;
coding->encoder = encode_coding_utf_8;
coding->common_flags
|= (CODING_REQUIRE_DECODING_MASK | CODING_REQUIRE_ENCODING_MASK);
if (CODING_UTF_8_BOM (coding) == utf_detect_bom)
coding->common_flags |= CODING_REQUIRE_DETECTION_MASK;
}
else if (EQ (coding_type, Qutf_16))
{
val = AREF (attrs, coding_attr_utf_bom);
CODING_UTF_16_BOM (coding) = (CONSP (val) ? utf_detect_bom
: EQ (val, Qt) ? utf_with_bom
: utf_without_bom);
val = AREF (attrs, coding_attr_utf_16_endian);
CODING_UTF_16_ENDIAN (coding) = (EQ (val, Qbig) ? utf_16_big_endian
: utf_16_little_endian);
CODING_UTF_16_SURROGATE (coding) = 0;
coding->detector = detect_coding_utf_16;
coding->decoder = decode_coding_utf_16;
coding->encoder = encode_coding_utf_16;
coding->common_flags
|= (CODING_REQUIRE_DECODING_MASK | CODING_REQUIRE_ENCODING_MASK);
if (CODING_UTF_16_BOM (coding) == utf_detect_bom)
coding->common_flags |= CODING_REQUIRE_DETECTION_MASK;
}
else if (EQ (coding_type, Qccl))
{
coding->detector = detect_coding_ccl;
coding->decoder = decode_coding_ccl;
coding->encoder = encode_coding_ccl;
coding->common_flags
|= (CODING_REQUIRE_DECODING_MASK | CODING_REQUIRE_ENCODING_MASK
| CODING_REQUIRE_FLUSHING_MASK);
}
else if (EQ (coding_type, Qemacs_mule))
{
coding->detector = detect_coding_emacs_mule;
coding->decoder = decode_coding_emacs_mule;
coding->encoder = encode_coding_emacs_mule;
coding->common_flags
|= (CODING_REQUIRE_DECODING_MASK | CODING_REQUIRE_ENCODING_MASK);
if (! NILP (AREF (attrs, coding_attr_emacs_mule_full))
&& ! EQ (CODING_ATTR_CHARSET_LIST (attrs), Vemacs_mule_charset_list))
{
Lisp_Object tail, safe_charsets;
int max_charset_id = 0;
for (tail = Vemacs_mule_charset_list; CONSP (tail);
tail = XCDR (tail))
if (max_charset_id < XFIXNAT (XCAR (tail)))
max_charset_id = XFIXNAT (XCAR (tail));
safe_charsets = make_uninit_string (max_charset_id + 1);
memset (SDATA (safe_charsets), 255, max_charset_id + 1);
for (tail = Vemacs_mule_charset_list; CONSP (tail);
tail = XCDR (tail))
SSET (safe_charsets, XFIXNAT (XCAR (tail)), 0);
coding->max_charset_id = max_charset_id;
coding->safe_charsets = SDATA (safe_charsets);
}
coding->spec.emacs_mule.cmp_status.state = COMPOSING_NO;
coding->spec.emacs_mule.cmp_status.method = COMPOSITION_NO;
}
else if (EQ (coding_type, Qshift_jis))
{
coding->detector = detect_coding_sjis;
coding->decoder = decode_coding_sjis;
coding->encoder = encode_coding_sjis;
coding->common_flags
|= (CODING_REQUIRE_DECODING_MASK | CODING_REQUIRE_ENCODING_MASK);
}
else if (EQ (coding_type, Qbig5))
{
coding->detector = detect_coding_big5;
coding->decoder = decode_coding_big5;
coding->encoder = encode_coding_big5;
coding->common_flags
|= (CODING_REQUIRE_DECODING_MASK | CODING_REQUIRE_ENCODING_MASK);
}
else /* EQ (coding_type, Qraw_text) */
{
coding->detector = NULL;
coding->decoder = decode_coding_raw_text;
coding->encoder = encode_coding_raw_text;
if (! EQ (eol_type, Qunix))
{
coding->common_flags |= CODING_REQUIRE_DECODING_MASK;
if (! VECTORP (eol_type))
coding->common_flags |= CODING_REQUIRE_ENCODING_MASK;
}
}
return;
}
/* Return a list of charsets supported by CODING. */
Lisp_Object
coding_charset_list (struct coding_system *coding)
{
Lisp_Object attrs, charset_list;
CODING_GET_INFO (coding, attrs, charset_list);
if (EQ (CODING_ATTR_TYPE (attrs), Qiso_2022))
{
int flags = XFIXNUM (AREF (attrs, coding_attr_iso_flags));
if (flags & CODING_ISO_FLAG_FULL_SUPPORT)
charset_list = Viso_2022_charset_list;
}
else if (EQ (CODING_ATTR_TYPE (attrs), Qemacs_mule))
{
charset_list = Vemacs_mule_charset_list;
}
return charset_list;
}
/* Return a list of charsets supported by CODING-SYSTEM. */
Lisp_Object
coding_system_charset_list (Lisp_Object coding_system)
{
ptrdiff_t id;
Lisp_Object attrs, charset_list;
CHECK_CODING_SYSTEM_GET_ID (coding_system, id);
attrs = CODING_ID_ATTRS (id);
if (EQ (CODING_ATTR_TYPE (attrs), Qiso_2022))
{
int flags = XFIXNUM (AREF (attrs, coding_attr_iso_flags));
if (flags & CODING_ISO_FLAG_FULL_SUPPORT)
charset_list = Viso_2022_charset_list;
else
charset_list = CODING_ATTR_CHARSET_LIST (attrs);
}
else if (EQ (CODING_ATTR_TYPE (attrs), Qemacs_mule))
{
charset_list = Vemacs_mule_charset_list;
}
else
{
charset_list = CODING_ATTR_CHARSET_LIST (attrs);
}
return charset_list;
}
/* Return raw-text or one of its subsidiaries that has the same
eol_type as CODING-SYSTEM. */
Lisp_Object
raw_text_coding_system (Lisp_Object coding_system)
{
Lisp_Object spec, attrs;
Lisp_Object eol_type, raw_text_eol_type;
if (NILP (coding_system))
return Qraw_text;
spec = CODING_SYSTEM_SPEC (coding_system);
attrs = AREF (spec, 0);
if (EQ (CODING_ATTR_TYPE (attrs), Qraw_text))
return coding_system;
eol_type = AREF (spec, 2);
if (VECTORP (eol_type))
return Qraw_text;
spec = CODING_SYSTEM_SPEC (Qraw_text);
raw_text_eol_type = AREF (spec, 2);
return (EQ (eol_type, Qunix) ? AREF (raw_text_eol_type, 0)
: EQ (eol_type, Qdos) ? AREF (raw_text_eol_type, 1)
: AREF (raw_text_eol_type, 2));
}
/* Return true if CODING corresponds to raw-text coding-system. */
bool
raw_text_coding_system_p (struct coding_system *coding)
{
return (coding->decoder == decode_coding_raw_text
&& coding->encoder == encode_coding_raw_text) ? true : false;
}
/* If CODING_SYSTEM doesn't specify end-of-line format, return one of
the subsidiary that has the same eol-spec as PARENT (if it is not
nil and specifies end-of-line format) or the system's setting. */
Lisp_Object
coding_inherit_eol_type (Lisp_Object coding_system, Lisp_Object parent)
{
Lisp_Object spec, eol_type;
if (NILP (coding_system))
coding_system = Qraw_text;
else
CHECK_CODING_SYSTEM (coding_system);
spec = CODING_SYSTEM_SPEC (coding_system);
eol_type = AREF (spec, 2);
if (VECTORP (eol_type))
{
/* Format of end-of-line decided by system.
This is Qunix on Unix and Mac, Qdos on DOS/Windows.
This has an effect only for external encoding (i.e., for output to
file and process), not for in-buffer or Lisp string encoding. */
Lisp_Object system_eol_type = Qunix;
#ifdef DOS_NT
system_eol_type = Qdos;
#endif
Lisp_Object parent_eol_type = system_eol_type;
if (! NILP (parent))
{
CHECK_CODING_SYSTEM (parent);
Lisp_Object parent_spec = CODING_SYSTEM_SPEC (parent);
Lisp_Object pspec_type = AREF (parent_spec, 2);
if (!VECTORP (pspec_type))
parent_eol_type = pspec_type;
}
if (EQ (parent_eol_type, Qunix))
coding_system = AREF (eol_type, 0);
else if (EQ (parent_eol_type, Qdos))
coding_system = AREF (eol_type, 1);
else if (EQ (parent_eol_type, Qmac))
coding_system = AREF (eol_type, 2);
}
return coding_system;
}
/* Check if text-conversion and eol-conversion of CODING_SYSTEM are
decided for writing to a process. If not, complement them, and
return a new coding system. */
Lisp_Object
complement_process_encoding_system (Lisp_Object coding_system)
{
Lisp_Object coding_base = Qnil, eol_base = Qnil;
Lisp_Object spec, attrs;
int i;
for (i = 0; i < 3; i++)
{
if (i == 1)
coding_system = CDR_SAFE (Vdefault_process_coding_system);
else if (i == 2)
coding_system = preferred_coding_system ();
spec = CODING_SYSTEM_SPEC (coding_system);
if (NILP (spec))
continue;
attrs = AREF (spec, 0);
if (NILP (coding_base) && ! EQ (CODING_ATTR_TYPE (attrs), Qundecided))
coding_base = CODING_ATTR_BASE_NAME (attrs);
if (NILP (eol_base) && ! VECTORP (AREF (spec, 2)))
eol_base = coding_system;
if (! NILP (coding_base) && ! NILP (eol_base))
break;
}
if (i > 0)
/* The original CODING_SYSTEM didn't specify text-conversion or
eol-conversion. Be sure that we return a fully complemented
coding system. */
coding_system = coding_inherit_eol_type (coding_base, eol_base);
return coding_system;
}
/* Emacs has a mechanism to automatically detect a coding system if it
is one of Emacs' internal format, ISO2022, SJIS, and BIG5. But,
it's impossible to distinguish some coding systems accurately
because they use the same range of codes. So, at first, coding
systems are categorized into 7, those are:
o coding-category-emacs-mule
The category for a coding system which has the same code range
as Emacs' internal format. Assigned the coding-system (Lisp
symbol) `emacs-mule' by default.
o coding-category-sjis
The category for a coding system which has the same code range
as SJIS. Assigned the coding-system (Lisp
symbol) `japanese-shift-jis' by default.
o coding-category-iso-7
The category for a coding system which has the same code range
as ISO2022 of 7-bit environment. This doesn't use any locking
shift and single shift functions. This can encode/decode all
charsets. Assigned the coding-system (Lisp symbol)
`iso-2022-7bit' by default.
o coding-category-iso-7-tight
Same as coding-category-iso-7 except that this can
encode/decode only the specified charsets.
o coding-category-iso-8-1
The category for a coding system which has the same code range
as ISO2022 of 8-bit environment and graphic plane 1 used only
for DIMENSION1 charset. This doesn't use any locking shift
and single shift functions. Assigned the coding-system (Lisp
symbol) `iso-latin-1' by default.
o coding-category-iso-8-2
The category for a coding system which has the same code range
as ISO2022 of 8-bit environment and graphic plane 1 used only
for DIMENSION2 charset. This doesn't use any locking shift
and single shift functions. Assigned the coding-system (Lisp
symbol) `japanese-iso-8bit' by default.
o coding-category-iso-7-else
The category for a coding system which has the same code range
as ISO2022 of 7-bit environment but uses locking shift or
single shift functions. Assigned the coding-system (Lisp
symbol) `iso-2022-7bit-lock' by default.
o coding-category-iso-8-else
The category for a coding system which has the same code range
as ISO2022 of 8-bit environment but uses locking shift or
single shift functions. Assigned the coding-system (Lisp
symbol) `iso-2022-8bit-ss2' by default.
o coding-category-big5
The category for a coding system which has the same code range
as BIG5. Assigned the coding-system (Lisp symbol)
`cn-big5' by default.
o coding-category-utf-8
The category for a coding system which has the same code range
as UTF-8 (cf. RFC3629). Assigned the coding-system (Lisp
symbol) `utf-8' by default.
o coding-category-utf-16-be
The category for a coding system in which a text has an
Unicode signature (cf. Unicode Standard) in the order of BIG
endian at the head. Assigned the coding-system (Lisp symbol)
`utf-16-be' by default.
o coding-category-utf-16-le
The category for a coding system in which a text has an
Unicode signature (cf. Unicode Standard) in the order of
LITTLE endian at the head. Assigned the coding-system (Lisp
symbol) `utf-16-le' by default.
o coding-category-ccl
The category for a coding system of which encoder/decoder is
written in CCL programs. The default value is nil, i.e., no
coding system is assigned.
o coding-category-binary
The category for a coding system not categorized in any of the
above. Assigned the coding-system (Lisp symbol)
`no-conversion' by default.
Each of them is a Lisp symbol and the value is an actual
`coding-system's (this is also a Lisp symbol) assigned by a user.
What Emacs does actually is to detect a category of coding system.
Then, it uses a `coding-system' assigned to it. If Emacs can't
decide only one possible category, it selects a category of the
highest priority. Priorities of categories are also specified by a
user in a Lisp variable `coding-category-list'.
*/
static Lisp_Object adjust_coding_eol_type (struct coding_system *coding,
int eol_seen);
/* Return the number of ASCII characters at the head of the source.
By side effects, set coding->head_ascii and update
coding->eol_seen. The value of coding->eol_seen is "logical or" of
EOL_SEEN_LF, EOL_SEEN_CR, and EOL_SEEN_CRLF, but the value is
reliable only when all the source bytes are ASCII. */
static ptrdiff_t
check_ascii (struct coding_system *coding)
{
const unsigned char *src, *end;
Lisp_Object eol_type = CODING_ID_EOL_TYPE (coding->id);
int eol_seen = coding->eol_seen;
coding_set_source (coding);
src = coding->source;
end = src + coding->src_bytes;
if (inhibit_eol_conversion
|| SYMBOLP (eol_type))
{
/* We don't have to check EOL format. */
while (src < end && !( *src & 0x80))
{
if (*src++ == '\n')
eol_seen |= EOL_SEEN_LF;
}
}
else
{
end--; /* We look ahead one byte for "CR LF". */
while (src < end)
{
int c = *src;
if (c & 0x80)
break;
src++;
if (c == '\r')
{
if (*src == '\n')
{
eol_seen |= EOL_SEEN_CRLF;
src++;
}
else
eol_seen |= EOL_SEEN_CR;
}
else if (c == '\n')
eol_seen |= EOL_SEEN_LF;
}
if (src == end)
{
int c = *src;
/* All bytes but the last one C are ASCII. */
if (! (c & 0x80))
{
if (c == '\r')
eol_seen |= EOL_SEEN_CR;
else if (c == '\n')
eol_seen |= EOL_SEEN_LF;
src++;
}
}
}
coding->head_ascii = src - coding->source;
coding->eol_seen = eol_seen;
return (coding->head_ascii);
}
/* Return the number of characters at the source if all the bytes are
valid UTF-8 (of Unicode range). Otherwise, return -1. By side
effects, update coding->eol_seen. The value of coding->eol_seen is
"logical or" of EOL_SEEN_LF, EOL_SEEN_CR, and EOL_SEEN_CRLF, but
the value is reliable only when all the source bytes are valid
UTF-8. */
static ptrdiff_t
check_utf_8 (struct coding_system *coding)
{
const unsigned char *src, *end;
int eol_seen;
ptrdiff_t nchars = coding->head_ascii;
if (coding->head_ascii < 0)
check_ascii (coding);
else
coding_set_source (coding);
src = coding->source + coding->head_ascii;
/* We look ahead one byte for CR LF. */
end = coding->source + coding->src_bytes - 1;
eol_seen = coding->eol_seen;
while (src < end)
{
int c = *src;
if (UTF_8_1_OCTET_P (*src))
{
src++;
if (c < 0x20)
{
if (c == '\r')
{
if (*src == '\n')
{
eol_seen |= EOL_SEEN_CRLF;
src++;
nchars++;
}
else
eol_seen |= EOL_SEEN_CR;
}
else if (c == '\n')
eol_seen |= EOL_SEEN_LF;
}
}
else if (UTF_8_2_OCTET_LEADING_P (c))
{
if (c < 0xC2 /* overlong sequence */
|| src + 1 >= end
|| ! UTF_8_EXTRA_OCTET_P (src[1]))
return -1;
src += 2;
}
else if (UTF_8_3_OCTET_LEADING_P (c))
{
if (src + 2 >= end
|| ! (UTF_8_EXTRA_OCTET_P (src[1])
&& UTF_8_EXTRA_OCTET_P (src[2])))
return -1;
c = (((c & 0xF) << 12)
| ((src[1] & 0x3F) << 6) | (src[2] & 0x3F));
if (c < 0x800 /* overlong sequence */
|| (c >= 0xd800 && c < 0xe000)) /* surrogates (invalid) */
return -1;
src += 3;
}
else if (UTF_8_4_OCTET_LEADING_P (c))
{
if (src + 3 >= end
|| ! (UTF_8_EXTRA_OCTET_P (src[1])
&& UTF_8_EXTRA_OCTET_P (src[2])
&& UTF_8_EXTRA_OCTET_P (src[3])))
return -1;
c = (((c & 0x7) << 18) | ((src[1] & 0x3F) << 12)
| ((src[2] & 0x3F) << 6) | (src[3] & 0x3F));
if (c < 0x10000 /* overlong sequence */
|| c >= 0x110000) /* non-Unicode character */
return -1;
src += 4;
}
else
return -1;
nchars++;
}
if (src == end)
{
if (! UTF_8_1_OCTET_P (*src))
return -1;
nchars++;
if (*src == '\r')
eol_seen |= EOL_SEEN_CR;
else if (*src == '\n')
eol_seen |= EOL_SEEN_LF;
}
coding->eol_seen = eol_seen;
return nchars;
}
/* Return whether STRING is a valid UTF-8 string. STRING must be a
unibyte string. */
bool
utf8_string_p (Lisp_Object string)
{
eassert (!STRING_MULTIBYTE (string));
struct coding_system coding;
setup_coding_system (Qutf_8_unix, &coding);
/* We initialize only the fields that check_utf_8 accesses. */
coding.head_ascii = -1;
coding.src_pos = 0;
coding.src_pos_byte = 0;
coding.src_chars = SCHARS (string);
coding.src_bytes = SBYTES (string);
coding.src_object = string;
coding.eol_seen = EOL_SEEN_NONE;
return check_utf_8 (&coding) != -1;
}
/* Like make_string, but always returns a multibyte Lisp string, and
avoids decoding if TEXT is encoded in UTF-8. */
Lisp_Object
make_string_from_utf8 (const char *text, ptrdiff_t nbytes)
{
#if 0
/* This method is on average 2 times slower than if we use
decode_string_utf_8. However, please leave the slower
implementation in the code for now, in case it needs to be reused
in some situations. */
ptrdiff_t chars, bytes;
parse_str_as_multibyte ((const unsigned char *) text, nbytes,
&chars, &bytes);
/* If TEXT is a valid UTF-8 string, we can convert it to a Lisp
string directly. Otherwise, we need to decode it. */
if (chars == nbytes || bytes == nbytes)
return make_specified_string (text, chars, nbytes, true);
else
{
struct coding_system coding;
setup_coding_system (Qutf_8_unix, &coding);
coding.mode |= CODING_MODE_LAST_BLOCK;
coding.source = (const unsigned char *) text;
decode_coding_object (&coding, Qnil, 0, 0, nbytes, nbytes, Qt);
return coding.dst_object;
}
#else
return decode_string_utf_8 (Qnil, text, nbytes, Qnil, false, Qt, Qt);
#endif
}
/* Detect how end-of-line of a text of length SRC_BYTES pointed by
SOURCE is encoded. If CATEGORY is one of
coding_category_utf_16_XXXX, assume that CR and LF are encoded by
two-byte, else they are encoded by one-byte.
Return one of EOL_SEEN_XXX. */
#define MAX_EOL_CHECK_COUNT 3
static int
detect_eol (const unsigned char *source, ptrdiff_t src_bytes,
enum coding_category category)
{
const unsigned char *src = source, *src_end = src + src_bytes;
unsigned char c;
int total = 0;
int eol_seen = EOL_SEEN_NONE;
if ((1 << category) & CATEGORY_MASK_UTF_16)
{
bool msb = category == (coding_category_utf_16_le
| coding_category_utf_16_le_nosig);
bool lsb = !msb;
while (src + 1 < src_end)
{
c = src[lsb];
if (src[msb] == 0 && (c == '\n' || c == '\r'))
{
int this_eol;
if (c == '\n')
this_eol = EOL_SEEN_LF;
else if (src + 3 >= src_end
|| src[msb + 2] != 0
|| src[lsb + 2] != '\n')
this_eol = EOL_SEEN_CR;
else
{
this_eol = EOL_SEEN_CRLF;
src += 2;
}
if (eol_seen == EOL_SEEN_NONE)
/* This is the first end-of-line. */
eol_seen = this_eol;
else if (eol_seen != this_eol)
{
/* The found type is different from what found before.
Allow for stray ^M characters in DOS EOL files. */
if ((eol_seen == EOL_SEEN_CR && this_eol == EOL_SEEN_CRLF)
|| (eol_seen == EOL_SEEN_CRLF
&& this_eol == EOL_SEEN_CR))
eol_seen = EOL_SEEN_CRLF;
else
{
eol_seen = EOL_SEEN_LF;
break;
}
}
if (++total == MAX_EOL_CHECK_COUNT)
break;
}
src += 2;
}
}
else
while (src < src_end)
{
c = *src++;
if (c == '\n' || c == '\r')
{
int this_eol;
if (c == '\n')
this_eol = EOL_SEEN_LF;
else if (src >= src_end || *src != '\n')
this_eol = EOL_SEEN_CR;
else
this_eol = EOL_SEEN_CRLF, src++;
if (eol_seen == EOL_SEEN_NONE)
/* This is the first end-of-line. */
eol_seen = this_eol;
else if (eol_seen != this_eol)
{
/* The found type is different from what found before.
Allow for stray ^M characters in DOS EOL files. */
if ((eol_seen == EOL_SEEN_CR && this_eol == EOL_SEEN_CRLF)
|| (eol_seen == EOL_SEEN_CRLF && this_eol == EOL_SEEN_CR))
eol_seen = EOL_SEEN_CRLF;
else
{
eol_seen = EOL_SEEN_LF;
break;
}
}
if (++total == MAX_EOL_CHECK_COUNT)
break;
}
}
return eol_seen;
}
static Lisp_Object
adjust_coding_eol_type (struct coding_system *coding, int eol_seen)
{
Lisp_Object eol_type;
eol_type = CODING_ID_EOL_TYPE (coding->id);
if (! VECTORP (eol_type))
/* Already adjusted. */
return eol_type;
if (eol_seen & EOL_SEEN_LF)
{
coding->id = CODING_SYSTEM_ID (AREF (eol_type, 0));
eol_type = Qunix;
}
else if (eol_seen & EOL_SEEN_CRLF)
{
coding->id = CODING_SYSTEM_ID (AREF (eol_type, 1));
eol_type = Qdos;
}
else if (eol_seen & EOL_SEEN_CR)
{
coding->id = CODING_SYSTEM_ID (AREF (eol_type, 2));
eol_type = Qmac;
}
return eol_type;
}
/* Detect how a text specified in CODING is encoded. If a coding
system is detected, update fields of CODING by the detected coding
system. */
static void
detect_coding (struct coding_system *coding)
{
const unsigned char *src, *src_end;
unsigned int saved_mode = coding->mode;
Lisp_Object found = Qnil;
Lisp_Object eol_type = CODING_ID_EOL_TYPE (coding->id);
coding->consumed = coding->consumed_char = 0;
coding->produced = coding->produced_char = 0;
coding_set_source (coding);
src_end = coding->source + coding->src_bytes;
coding->eol_seen = EOL_SEEN_NONE;
/* If we have not yet decided the text encoding type, detect it
now. */
if (EQ (CODING_ATTR_TYPE (CODING_ID_ATTRS (coding->id)), Qundecided))
{
int c, i;
struct coding_detection_info detect_info;
bool nul_byte_found = 0, eight_bit_found = 0;
bool inhibit_nbd = inhibit_flag (coding->spec.undecided.inhibit_nbd,
inhibit_nul_byte_detection);
bool inhibit_ied = inhibit_flag (coding->spec.undecided.inhibit_ied,
inhibit_iso_escape_detection);
bool prefer_utf_8 = coding->spec.undecided.prefer_utf_8;
coding->head_ascii = 0;
detect_info.checked = detect_info.found = detect_info.rejected = 0;
for (src = coding->source; src < src_end; src++)
{
c = *src;
if (c & 0x80)
{
eight_bit_found = 1;
if (nul_byte_found)
break;
}
else if (c < 0x20)
{
if ((c == ISO_CODE_ESC || c == ISO_CODE_SI || c == ISO_CODE_SO)
&& ! inhibit_ied
&& ! detect_info.checked)
{
if (detect_coding_iso_2022 (coding, &detect_info))
{
/* We have scanned the whole data. */
if (! (detect_info.rejected & CATEGORY_MASK_ISO_7_ELSE))
{
/* We didn't find an 8-bit code. We may
have found a NUL-byte, but it's very
rare that a binary file conforms to
ISO-2022. */
src = src_end;
coding->head_ascii = src - coding->source;
}
detect_info.rejected |= ~CATEGORY_MASK_ISO_ESCAPE;
break;
}
}
else if (! c && !inhibit_nbd)
{
nul_byte_found = 1;
if (eight_bit_found)
break;
}
else if (! disable_ascii_optimization
&& ! inhibit_eol_conversion)
{
if (c == '\r')
{
if (src < src_end && src[1] == '\n')
{
coding->eol_seen |= EOL_SEEN_CRLF;
src++;
if (! eight_bit_found)
coding->head_ascii++;
}
else
coding->eol_seen |= EOL_SEEN_CR;
}
else if (c == '\n')
{
coding->eol_seen |= EOL_SEEN_LF;
}
}
if (! eight_bit_found)
coding->head_ascii++;
}
else if (! eight_bit_found)
coding->head_ascii++;
}
if (nul_byte_found || eight_bit_found
|| coding->head_ascii < coding->src_bytes
|| detect_info.found)
{
enum coding_category category;
struct coding_system *this;
if (coding->head_ascii == coding->src_bytes)
/* As all bytes are 7-bit, we can ignore non-ISO-2022 codings. */
for (i = 0; i < coding_category_raw_text; i++)
{
category = coding_priorities[i];
this = coding_categories + category;
if (detect_info.found & (1 << category))
break;
}
else
{
if (nul_byte_found)
{
detect_info.checked |= ~CATEGORY_MASK_UTF_16;
detect_info.rejected |= ~CATEGORY_MASK_UTF_16;
}
else if (prefer_utf_8
&& detect_coding_utf_8 (coding, &detect_info))
{
detect_info.checked |= ~CATEGORY_MASK_UTF_8;
detect_info.rejected |= ~CATEGORY_MASK_UTF_8;
}
for (i = 0; i < coding_category_raw_text; i++)
{
category = coding_priorities[i];
this = coding_categories + category;
/* Some of this->detector (e.g. detect_coding_sjis)
require this information. */
coding->id = this->id;
if (this->id < 0)
{
/* No coding system of this category is defined. */
detect_info.rejected |= (1 << category);
}
else if (category >= coding_category_raw_text)
continue;
else if (detect_info.checked & (1 << category))
{
if (detect_info.found & (1 << category))
break;
}
else if ((*(this->detector)) (coding, &detect_info)
&& detect_info.found & (1 << category))
break;
}
}
if (i < coding_category_raw_text)
{
if (category == coding_category_utf_8_auto)
{
Lisp_Object coding_systems;
coding_systems = AREF (CODING_ID_ATTRS (this->id),
coding_attr_utf_bom);
if (CONSP (coding_systems))
{
if (detect_info.found & CATEGORY_MASK_UTF_8_SIG)
found = XCAR (coding_systems);
else
found = XCDR (coding_systems);
}
else
found = CODING_ID_NAME (this->id);
}
else if (category == coding_category_utf_16_auto)
{
Lisp_Object coding_systems;
coding_systems = AREF (CODING_ID_ATTRS (this->id),
coding_attr_utf_bom);
if (CONSP (coding_systems))
{
if (detect_info.found & CATEGORY_MASK_UTF_16_LE)
found = XCAR (coding_systems);
else if (detect_info.found & CATEGORY_MASK_UTF_16_BE)
found = XCDR (coding_systems);
}
else
found = CODING_ID_NAME (this->id);
}
else
found = CODING_ID_NAME (this->id);
}
else if (nul_byte_found)
found = Qno_conversion;
else if ((detect_info.rejected & CATEGORY_MASK_ANY)
== CATEGORY_MASK_ANY)
found = Qraw_text;
else if (detect_info.rejected)
for (i = 0; i < coding_category_raw_text; i++)
if (! (detect_info.rejected & (1 << coding_priorities[i])))
{
this = coding_categories + coding_priorities[i];
found = CODING_ID_NAME (this->id);
break;
}
}
}
else if (XFIXNUM (CODING_ATTR_CATEGORY (CODING_ID_ATTRS (coding->id)))
== coding_category_utf_8_auto)
{
Lisp_Object coding_systems;
struct coding_detection_info detect_info;
coding_systems
= AREF (CODING_ID_ATTRS (coding->id), coding_attr_utf_bom);
detect_info.found = detect_info.rejected = 0;
if (check_ascii (coding) == coding->src_bytes)
{
if (CONSP (coding_systems))
found = XCDR (coding_systems);
}
else
{
if (CONSP (coding_systems)
&& detect_coding_utf_8 (coding, &detect_info))
{
if (detect_info.found & CATEGORY_MASK_UTF_8_SIG)
found = XCAR (coding_systems);
else
found = XCDR (coding_systems);
}
}
}
else if (XFIXNUM (CODING_ATTR_CATEGORY (CODING_ID_ATTRS (coding->id)))
== coding_category_utf_16_auto)
{
Lisp_Object coding_systems;
struct coding_detection_info detect_info;
coding_systems
= AREF (CODING_ID_ATTRS (coding->id), coding_attr_utf_bom);
detect_info.found = detect_info.rejected = 0;
coding->head_ascii = 0;
if (CONSP (coding_systems)
&& detect_coding_utf_16 (coding, &detect_info))
{
if (detect_info.found & CATEGORY_MASK_UTF_16_LE)
found = XCAR (coding_systems);
else if (detect_info.found & CATEGORY_MASK_UTF_16_BE)
found = XCDR (coding_systems);
}
}
if (! NILP (found))
{
int specified_eol = (VECTORP (eol_type) ? EOL_SEEN_NONE
: EQ (eol_type, Qdos) ? EOL_SEEN_CRLF
: EQ (eol_type, Qmac) ? EOL_SEEN_CR
: EOL_SEEN_LF);
setup_coding_system (found, coding);
if (specified_eol != EOL_SEEN_NONE)
adjust_coding_eol_type (coding, specified_eol);
}
coding->mode = saved_mode;
}
static void
decode_eol (struct coding_system *coding)
{
Lisp_Object eol_type;
unsigned char *p, *pbeg, *pend;
eol_type = CODING_ID_EOL_TYPE (coding->id);
if (EQ (eol_type, Qunix) || inhibit_eol_conversion)
return;
if (NILP (coding->dst_object))
pbeg = coding->destination;
else
pbeg = BYTE_POS_ADDR (coding->dst_pos_byte);
pend = pbeg + coding->produced;
if (VECTORP (eol_type))
{
int eol_seen = EOL_SEEN_NONE;
for (p = pbeg; p < pend; p++)
{
if (*p == '\n')
eol_seen |= EOL_SEEN_LF;
else if (*p == '\r')
{
if (p + 1 < pend && *(p + 1) == '\n')
{
eol_seen |= EOL_SEEN_CRLF;
p++;
}
else
eol_seen |= EOL_SEEN_CR;
}
}
/* Handle DOS-style EOLs in a file with stray ^M characters. */
if ((eol_seen & EOL_SEEN_CRLF) != 0
&& (eol_seen & EOL_SEEN_CR) != 0
&& (eol_seen & EOL_SEEN_LF) == 0)
eol_seen = EOL_SEEN_CRLF;
else if (eol_seen != EOL_SEEN_NONE
&& eol_seen != EOL_SEEN_LF
&& eol_seen != EOL_SEEN_CRLF
&& eol_seen != EOL_SEEN_CR)
eol_seen = EOL_SEEN_LF;
if (eol_seen != EOL_SEEN_NONE)
eol_type = adjust_coding_eol_type (coding, eol_seen);
}
if (EQ (eol_type, Qmac))
{
for (p = pbeg; p < pend; p++)
if (*p == '\r')
*p = '\n';
}
else if (EQ (eol_type, Qdos))
{
ptrdiff_t n = 0;
ptrdiff_t pos = coding->dst_pos;
ptrdiff_t pos_byte = coding->dst_pos_byte;
ptrdiff_t pos_end = pos_byte + coding->produced - 1;
/* This assertion is here instead of code, now deleted, that
handled the NILP case, which no longer happens with the
current codebase. */
eassert (!NILP (coding->dst_object));
while (pos_byte < pos_end)
{
int incr;
p = BYTE_POS_ADDR (pos_byte);
if (coding->dst_multibyte)
incr = BYTES_BY_CHAR_HEAD (*p);
else
incr = 1;
if (*p == '\r' && p[1] == '\n')
{
del_range_2 (pos, pos_byte, pos + 1, pos_byte + 1, 0);
n++;
pos_end--;
}
pos++;
pos_byte += incr;
}
coding->produced -= n;
coding->produced_char -= n;
}
}
/* MAX_LOOKUP's maximum value. MAX_LOOKUP is an int and so cannot
exceed INT_MAX. Also, MAX_LOOKUP is multiplied by sizeof (int) for
alloca, so it cannot exceed MAX_ALLOCA / sizeof (int). */
enum { MAX_LOOKUP_MAX = min (INT_MAX, MAX_ALLOCA / sizeof (int)) };
/* Return a translation table (or list of them) from coding system
attribute vector ATTRS for encoding (if ENCODEP) or decoding (if
not ENCODEP). */
static Lisp_Object
get_translation_table (Lisp_Object attrs, bool encodep, int *max_lookup)
{
Lisp_Object standard, translation_table;
Lisp_Object val;
if (NILP (Venable_character_translation))
{
if (max_lookup)
*max_lookup = 0;
return Qnil;
}
if (encodep)
translation_table = CODING_ATTR_ENCODE_TBL (attrs),
standard = Vstandard_translation_table_for_encode;
else
translation_table = CODING_ATTR_DECODE_TBL (attrs),
standard = Vstandard_translation_table_for_decode;
if (NILP (translation_table))
translation_table = standard;
else
{
if (SYMBOLP (translation_table))
translation_table = Fget (translation_table, Qtranslation_table);
else if (CONSP (translation_table))
{
translation_table = Fcopy_sequence (translation_table);
for (val = translation_table; CONSP (val); val = XCDR (val))
if (SYMBOLP (XCAR (val)))
XSETCAR (val, Fget (XCAR (val), Qtranslation_table));
}
if (CHAR_TABLE_P (standard))
{
if (CONSP (translation_table))
translation_table = nconc2 (translation_table, list1 (standard));
else
translation_table = list2 (translation_table, standard);
}
}
if (max_lookup)
{
*max_lookup = 1;
if (CHAR_TABLE_P (translation_table)
&& CHAR_TABLE_EXTRA_SLOTS (XCHAR_TABLE (translation_table)) > 1)
{
val = XCHAR_TABLE (translation_table)->extras[1];
if (FIXNATP (val) && *max_lookup < XFIXNAT (val))
*max_lookup = min (XFIXNAT (val), MAX_LOOKUP_MAX);
}
else if (CONSP (translation_table))
{
Lisp_Object tail;
for (tail = translation_table; CONSP (tail); tail = XCDR (tail))
if (CHAR_TABLE_P (XCAR (tail))
&& CHAR_TABLE_EXTRA_SLOTS (XCHAR_TABLE (XCAR (tail))) > 1)
{
Lisp_Object tailval = XCHAR_TABLE (XCAR (tail))->extras[1];
if (FIXNATP (tailval) && *max_lookup < XFIXNAT (tailval))
*max_lookup = min (XFIXNAT (tailval), MAX_LOOKUP_MAX);
}
}
}
return translation_table;
}
#define LOOKUP_TRANSLATION_TABLE(table, c, trans) \
do { \
trans = Qnil; \
if (CHAR_TABLE_P (table)) \
{ \
trans = CHAR_TABLE_REF (table, c); \
if (CHARACTERP (trans)) \
c = XFIXNAT (trans), trans = Qnil; \
} \
else if (CONSP (table)) \
{ \
Lisp_Object tail; \
\
for (tail = table; CONSP (tail); tail = XCDR (tail)) \
if (CHAR_TABLE_P (XCAR (tail))) \
{ \
trans = CHAR_TABLE_REF (XCAR (tail), c); \
if (CHARACTERP (trans)) \
c = XFIXNAT (trans), trans = Qnil; \
else if (! NILP (trans)) \
break; \
} \
} \
} while (0)
/* Return a translation of character(s) at BUF according to TRANS.
TRANS is TO-CHAR, [TO-CHAR ...], or ((FROM . TO) ...) where FROM =
[FROM-CHAR ...], TO is TO-CHAR or [TO-CHAR ...]. The return value
is TO-CHAR or [TO-CHAR ...] if a translation is found, Qnil if not
found, or Qt if BUF is too short to lookup characters in FROM. As
a side effect, if a translation is found, *NCHARS is set to the
number of characters being translated. */
static Lisp_Object
get_translation (Lisp_Object trans, int *buf, int *buf_end, ptrdiff_t *nchars)
{
if (FIXNUMP (trans) || VECTORP (trans))
{
*nchars = 1;
return trans;
}
for (; CONSP (trans); trans = XCDR (trans))
{
Lisp_Object val = XCAR (trans);
Lisp_Object from = XCAR (val);
ptrdiff_t len = ASIZE (from);
ptrdiff_t i;
for (i = 0; i < len; i++)
{
if (buf + i == buf_end)
return Qt;
if (XFIXNUM (AREF (from, i)) != buf[i])
break;
}
if (i == len)
{
*nchars = len;
return XCDR (val);
}
}
return Qnil;
}
static int
produce_chars (struct coding_system *coding, Lisp_Object translation_table,
bool last_block)
{
unsigned char *dst = coding->destination + coding->produced;
unsigned char *dst_end = coding->destination + coding->dst_bytes;
ptrdiff_t produced;
ptrdiff_t produced_chars = 0;
int carryover = 0;
if (! coding->chars_at_source)
{
/* Source characters are in coding->charbuf. */
int *buf = coding->charbuf;
int *buf_end = buf + coding->charbuf_used;
if (EQ (coding->src_object, coding->dst_object)
&& ! NILP (coding->dst_object))
{
eassert (growable_destination (coding));
coding_set_source (coding);
dst_end = ((unsigned char *) coding->source) + coding->consumed;
}
while (buf < buf_end)
{
int c = *buf;
ptrdiff_t i;
if (c >= 0)
{
ptrdiff_t from_nchars = 1, to_nchars = 1;
Lisp_Object trans = Qnil;
LOOKUP_TRANSLATION_TABLE (translation_table, c, trans);
if (! NILP (trans))
{
trans = get_translation (trans, buf, buf_end, &from_nchars);
if (FIXNUMP (trans))
c = XFIXNUM (trans);
else if (VECTORP (trans))
{
to_nchars = ASIZE (trans);
c = XFIXNUM (AREF (trans, 0));
}
else if (EQ (trans, Qt) && ! last_block)
break;
}
if ((dst_end - dst) / MAX_MULTIBYTE_LENGTH < to_nchars)
{
eassert (growable_destination (coding));
ptrdiff_t dst_size;
if (INT_MULTIPLY_WRAPV (to_nchars, MAX_MULTIBYTE_LENGTH,
&dst_size)
|| INT_ADD_WRAPV (buf_end - buf, dst_size, &dst_size))
memory_full (SIZE_MAX);
dst = alloc_destination (coding, dst_size, dst);
if (EQ (coding->src_object, coding->dst_object))
{
coding_set_source (coding);
dst_end = (((unsigned char *) coding->source)
+ coding->consumed);
}
else
dst_end = coding->destination + coding->dst_bytes;
}
for (i = 0; i < to_nchars; i++)
{
if (i > 0)
c = XFIXNUM (AREF (trans, i));
if (coding->dst_multibyte
|| ! CHAR_BYTE8_P (c))
CHAR_STRING_ADVANCE_NO_UNIFY (c, dst);
else
*dst++ = CHAR_TO_BYTE8 (c);
}
produced_chars += to_nchars;
buf += from_nchars;
}
else
/* This is an annotation datum. (-C) is the length. */
buf += -c;
}
carryover = buf_end - buf;
}
else
{
/* Source characters are at coding->source. */
const unsigned char *src = coding->source;
const unsigned char *src_end = src + coding->consumed;
if (EQ (coding->dst_object, coding->src_object))
{
eassert (growable_destination (coding));
dst_end = (unsigned char *) src;
}
if (coding->src_multibyte != coding->dst_multibyte)
{
if (coding->src_multibyte)
{
bool multibytep = 1;
ptrdiff_t consumed_chars = 0;
while (1)
{
const unsigned char *src_base = src;
int c;
ONE_MORE_BYTE (c);
if (dst == dst_end)
{
eassert (growable_destination (coding));
if (EQ (coding->src_object, coding->dst_object))
dst_end = (unsigned char *) src;
if (dst == dst_end)
{
ptrdiff_t offset = src - coding->source;
dst = alloc_destination (coding, src_end - src + 1,
dst);
dst_end = coding->destination + coding->dst_bytes;
coding_set_source (coding);
src = coding->source + offset;
src_end = coding->source + coding->consumed;
if (EQ (coding->src_object, coding->dst_object))
dst_end = (unsigned char *) src;
}
}
*dst++ = c;
produced_chars++;
}
no_more_source:
;
}
else
while (src < src_end)
{
bool multibytep = 1;
int c = *src++;
if (dst >= dst_end - 1)
{
eassert (growable_destination (coding));
if (EQ (coding->src_object, coding->dst_object))
dst_end = (unsigned char *) src;
if (dst >= dst_end - 1)
{
ptrdiff_t offset = src - coding->source;
ptrdiff_t more_bytes;
if (EQ (coding->src_object, coding->dst_object))
more_bytes = ((src_end - src) / 2) + 2;
else
more_bytes = src_end - src + 2;
dst = alloc_destination (coding, more_bytes, dst);
dst_end = coding->destination + coding->dst_bytes;
coding_set_source (coding);
src = coding->source + offset;
src_end = coding->source + coding->consumed;
if (EQ (coding->src_object, coding->dst_object))
dst_end = (unsigned char *) src;
}
}
EMIT_ONE_BYTE (c);
}
}
else
{
if (!EQ (coding->src_object, coding->dst_object))
{
ptrdiff_t require = coding->src_bytes - coding->dst_bytes;
if (require > 0)
{
ptrdiff_t offset = src - coding->source;
dst = alloc_destination (coding, require, dst);
coding_set_source (coding);
src = coding->source + offset;
src_end = coding->source + coding->consumed;
}
}
produced_chars = coding->consumed_char;
while (src < src_end)
*dst++ = *src++;
}
}
produced = dst - (coding->destination + coding->produced);
if (BUFFERP (coding->dst_object) && produced_chars > 0)
insert_from_gap (produced_chars, produced, 0);
coding->produced += produced;
coding->produced_char += produced_chars;
return carryover;
}
/* Compose text in CODING->object according to the annotation data at
CHARBUF. CHARBUF is an array:
[ -LENGTH ANNOTATION_MASK NCHARS NBYTES METHOD [ COMPONENTS... ] ]
*/
static void
produce_composition (struct coding_system *coding, int *charbuf, ptrdiff_t pos)
{
int len;
ptrdiff_t to;
enum composition_method method;
Lisp_Object components;
len = -charbuf[0] - MAX_ANNOTATION_LENGTH;
to = pos + charbuf[2];
method = (enum composition_method) (charbuf[4]);
if (method == COMPOSITION_RELATIVE)
components = Qnil;
else
{
Lisp_Object args[MAX_COMPOSITION_COMPONENTS * 2 - 1];
int i, j;
if (method == COMPOSITION_WITH_RULE)
len = charbuf[2] * 3 - 2;
charbuf += MAX_ANNOTATION_LENGTH;
/* charbuf = [ CHRA ... CHAR] or [ CHAR -2 RULE ... CHAR ] */
for (i = j = 0; i < len && charbuf[i] != -1; i++, j++)
{
if (charbuf[i] >= 0)
args[j] = make_fixnum (charbuf[i]);
else
{
i++;
args[j] = make_fixnum (charbuf[i] % 0x100);
}
}
components = (i == j ? Fstring (j, args) : Fvector (j, args));
}
compose_text (pos, to, components, Qnil, coding->dst_object);
}
/* Put `charset' property on text in CODING->object according to
the annotation data at CHARBUF. CHARBUF is an array:
[ -LENGTH ANNOTATION_MASK NCHARS CHARSET-ID ]
*/
static void
produce_charset (struct coding_system *coding, int *charbuf, ptrdiff_t pos)
{
ptrdiff_t from = pos - charbuf[2];
struct charset *charset = CHARSET_FROM_ID (charbuf[3]);
Fput_text_property (make_fixnum (from), make_fixnum (pos),
Qcharset, CHARSET_NAME (charset),
coding->dst_object);
}
#define MAX_CHARBUF_SIZE 0x4000
/* How many units decoding functions expect in coding->charbuf at
most. Currently, decode_coding_emacs_mule expects the following
size, and that is the largest value. */
#define MAX_CHARBUF_EXTRA_SIZE ((MAX_ANNOTATION_LENGTH * 3) + 1)
#define ALLOC_CONVERSION_WORK_AREA(coding, size) \
do { \
ptrdiff_t units = min ((size) + MAX_CHARBUF_EXTRA_SIZE, \
MAX_CHARBUF_SIZE); \
coding->charbuf = SAFE_ALLOCA (units * sizeof (int)); \
coding->charbuf_size = units; \
} while (0)
static void
produce_annotation (struct coding_system *coding, ptrdiff_t pos)
{
int *charbuf = coding->charbuf;
int *charbuf_end = charbuf + coding->charbuf_used;
if (NILP (coding->dst_object))
return;
while (charbuf < charbuf_end)
{
if (*charbuf >= 0)
pos++, charbuf++;
else
{
int len = -*charbuf;
if (len > 2)
switch (charbuf[1])
{
case CODING_ANNOTATE_COMPOSITION_MASK:
produce_composition (coding, charbuf, pos);
break;
case CODING_ANNOTATE_CHARSET_MASK:
produce_charset (coding, charbuf, pos);
break;
default:
break;
}
charbuf += len;
}
}
}
/* Decode the data at CODING->src_object into CODING->dst_object.
CODING->src_object is a buffer, a string, or nil.
CODING->dst_object is a buffer.
If CODING->src_object is a buffer, it must be the current buffer.
In this case, if CODING->src_pos is positive, it is a position of
the source text in the buffer, otherwise, the source text is in the
gap area of the buffer, and CODING->src_pos specifies the offset of
the text from the end of the gap (and GPT must be equal to PT).
When the text is taken from the gap, it can't be at the beginning
of the gap because the new decoded text is progressively accumulated
at the beginning of the gap before it gets inserted at PT (this way,
as the output grows, the input shrinks, so we only need to allocate
enough space for `max(IN, OUT)` instead of `IN + OUT`).
If CODING->src_object is a string, CODING->src_pos is an index to
that string.
If CODING->src_object is nil, CODING->source must already point to
the non-relocatable memory area. In this case, CODING->src_pos is
an offset from CODING->source.
The decoded data is inserted at the current point of the buffer
CODING->dst_object.
*/
static void
decode_coding (struct coding_system *coding)
{
Lisp_Object attrs;
Lisp_Object undo_list;
Lisp_Object translation_table;
struct ccl_spec cclspec;
int carryover;
int i;
USE_SAFE_ALLOCA;
if (BUFFERP (coding->src_object)
&& coding->src_pos > 0
&& coding->src_pos < GPT
&& coding->src_pos + coding->src_chars > GPT)
move_gap_both (coding->src_pos, coding->src_pos_byte);
undo_list = Qt;
if (BUFFERP (coding->dst_object))
{
set_buffer_internal (XBUFFER (coding->dst_object));
if (GPT != PT)
move_gap_both (PT, PT_BYTE);
/* We must disable undo_list in order to record the whole insert
transaction via record_insert at the end. But doing so also
disables the recording of the first change to the undo_list.
Therefore we check for first change here and record it via
record_first_change if needed. */
if (MODIFF <= SAVE_MODIFF)
record_first_change ();
undo_list = BVAR (current_buffer, undo_list);
bset_undo_list (current_buffer, Qt);
}
coding->consumed = coding->consumed_char = 0;
coding->produced = coding->produced_char = 0;
coding->chars_at_source = 0;
record_conversion_result (coding, CODING_RESULT_SUCCESS);
ALLOC_CONVERSION_WORK_AREA (coding, coding->src_bytes);
attrs = CODING_ID_ATTRS (coding->id);
translation_table = get_translation_table (attrs, 0, NULL);
carryover = 0;
if (coding->decoder == decode_coding_ccl)
{
coding->spec.ccl = &cclspec;
setup_ccl_program (&cclspec.ccl, CODING_CCL_DECODER (coding));
}
do
{
ptrdiff_t pos = coding->dst_pos + coding->produced_char;
coding_set_source (coding);
coding->annotated = 0;
coding->charbuf_used = carryover;
(*(coding->decoder)) (coding);
coding_set_destination (coding);
carryover = produce_chars (coding, translation_table, 0);
if (coding->annotated)
produce_annotation (coding, pos);
for (i = 0; i < carryover; i++)
coding->charbuf[i]
= coding->charbuf[coding->charbuf_used - carryover + i];
}
while (coding->result == CODING_RESULT_INSUFFICIENT_DST
|| (coding->consumed < coding->src_bytes
&& (coding->result == CODING_RESULT_SUCCESS
|| coding->result == CODING_RESULT_INVALID_SRC)));
if (carryover > 0)
{
coding_set_destination (coding);
coding->charbuf_used = carryover;
produce_chars (coding, translation_table, 1);
}
coding->carryover_bytes = 0;
if (coding->consumed < coding->src_bytes)
{
ptrdiff_t nbytes = coding->src_bytes - coding->consumed;
const unsigned char *src;
coding_set_source (coding);
coding_set_destination (coding);
src = coding->source + coding->consumed;
if (coding->mode & CODING_MODE_LAST_BLOCK)
{
/* Flush out unprocessed data as binary chars. We are sure
that the number of data is less than the size of
coding->charbuf. */
coding->charbuf_used = 0;
coding->chars_at_source = 0;
while (nbytes-- > 0)
{
int c;
/* Copy raw bytes in their 2-byte forms from multibyte
text as single characters. */
if (coding->src_multibyte
&& CHAR_BYTE8_HEAD_P (*src) && nbytes > 0)
{
c = string_char_advance (&src);
nbytes--;
}
else
{
c = *src++;
if (c & 0x80)
c = BYTE8_TO_CHAR (c);
}
coding->charbuf[coding->charbuf_used++] = c;
}
produce_chars (coding, Qnil, 1);
}
else
{
/* Record unprocessed bytes in coding->carryover. We are
sure that the number of data is less than the size of
coding->carryover. */
unsigned char *p = coding->carryover;
if (nbytes > sizeof coding->carryover)
nbytes = sizeof coding->carryover;
coding->carryover_bytes = nbytes;
while (nbytes-- > 0)
*p++ = *src++;
}
coding->consumed = coding->src_bytes;
}
if (! EQ (CODING_ID_EOL_TYPE (coding->id), Qunix)
&& !inhibit_eol_conversion)
decode_eol (coding);
if (BUFFERP (coding->dst_object))
{
bset_undo_list (current_buffer, undo_list);
record_insert (coding->dst_pos, coding->produced_char);
}
SAFE_FREE ();
}
/* Extract an annotation datum from a composition starting at POS and
ending before LIMIT of CODING->src_object (buffer or string), store
the data in BUF, set *STOP to a starting position of the next
composition (if any) or to LIMIT, and return the address of the
next element of BUF.
If such an annotation is not found, set *STOP to a starting
position of a composition after POS (if any) or to LIMIT, and
return BUF. */
static int *
handle_composition_annotation (ptrdiff_t pos, ptrdiff_t limit,
struct coding_system *coding, int *buf,
ptrdiff_t *stop)
{
ptrdiff_t start, end;
Lisp_Object prop;
if (! find_composition (pos, limit, &start, &end, &prop, coding->src_object)
|| end > limit)
*stop = limit;
else if (start > pos)
*stop = start;
else
{
if (start == pos)
{
/* We found a composition. Store the corresponding
annotation data in BUF. */
int *head = buf;
enum composition_method method = composition_method (prop);
int nchars = COMPOSITION_LENGTH (prop);
ADD_COMPOSITION_DATA (buf, nchars, 0, method);
if (method != COMPOSITION_RELATIVE)
{
Lisp_Object components;
ptrdiff_t i, len, i_byte;
components = COMPOSITION_COMPONENTS (prop);
if (VECTORP (components))
{
len = ASIZE (components);
for (i = 0; i < len; i++)
*buf++ = XFIXNUM (AREF (components, i));
}
else if (STRINGP (components))
{
len = SCHARS (components);
i = i_byte = 0;
while (i < len)
*buf++ = fetch_string_char_advance (components,
&i, &i_byte);
}
else if (FIXNUMP (components))
{
len = 1;
*buf++ = XFIXNUM (components);
}
else if (CONSP (components))
{
for (len = 0; CONSP (components);
len++, components = XCDR (components))
*buf++ = XFIXNUM (XCAR (components));
}
else
emacs_abort ();
*head -= len;
}
}
if (find_composition (end, limit, &start, &end, &prop,
coding->src_object)
&& end <= limit)
*stop = start;
else
*stop = limit;
}
return buf;
}
/* Extract an annotation datum from a text property `charset' at POS of
CODING->src_object (buffer of string), store the data in BUF, set
*STOP to the position where the value of `charset' property changes
(limiting by LIMIT), and return the address of the next element of
BUF.
If the property value is nil, set *STOP to the position where the
property value is non-nil (limiting by LIMIT), and return BUF. */
static int *
handle_charset_annotation (ptrdiff_t pos, ptrdiff_t limit,
struct coding_system *coding, int *buf,
ptrdiff_t *stop)
{
Lisp_Object val, next;
int id;
val = Fget_text_property (make_fixnum (pos), Qcharset, coding->src_object);
if (! NILP (val) && CHARSETP (val))
id = XFIXNUM (CHARSET_SYMBOL_ID (val));
else
id = -1;
ADD_CHARSET_DATA (buf, 0, id);
next = Fnext_single_property_change (make_fixnum (pos), Qcharset,
coding->src_object,
make_fixnum (limit));
*stop = XFIXNUM (next);
return buf;
}
static void
consume_chars (struct coding_system *coding, Lisp_Object translation_table,
int max_lookup)
{
int *buf = coding->charbuf;
int *buf_end = coding->charbuf + coding->charbuf_size;
const unsigned char *src = coding->source + coding->consumed;
const unsigned char *src_end = coding->source + coding->src_bytes;
ptrdiff_t pos = coding->src_pos + coding->consumed_char;
ptrdiff_t end_pos = coding->src_pos + coding->src_chars;
bool multibytep = coding->src_multibyte;
Lisp_Object eol_type;
int c;
ptrdiff_t stop, stop_composition, stop_charset;
int *lookup_buf = NULL;
if (! NILP (translation_table))
lookup_buf = alloca (sizeof (int) * max_lookup);
eol_type = inhibit_eol_conversion ? Qunix : CODING_ID_EOL_TYPE (coding->id);
if (VECTORP (eol_type))
eol_type = Qunix;
/* Note: composition handling is not yet implemented. */
coding->common_flags &= ~CODING_ANNOTATE_COMPOSITION_MASK;
if (NILP (coding->src_object))
stop = stop_composition = stop_charset = end_pos;
else
{
if (coding->common_flags & CODING_ANNOTATE_COMPOSITION_MASK)
stop = stop_composition = pos;
else
stop = stop_composition = end_pos;
if (coding->common_flags & CODING_ANNOTATE_CHARSET_MASK)
stop = stop_charset = pos;
else
stop_charset = end_pos;
}
/* Compensate for CRLF and conversion. */
buf_end -= 1 + MAX_ANNOTATION_LENGTH;
while (buf < buf_end)
{
Lisp_Object trans;
if (pos == stop)
{
if (pos == end_pos)
break;
if (pos == stop_composition)
buf = handle_composition_annotation (pos, end_pos, coding,
buf, &stop_composition);
if (pos == stop_charset)
buf = handle_charset_annotation (pos, end_pos, coding,
buf, &stop_charset);
stop = (stop_composition < stop_charset
? stop_composition : stop_charset);
}
if (! multibytep)
{
if (coding->encoder == encode_coding_raw_text
|| coding->encoder == encode_coding_ccl)
c = *src++, pos++;
else
{
int bytes = multibyte_length (src, src_end, true, true);
if (0 < bytes)
c = STRING_CHAR_ADVANCE_NO_UNIFY (src), pos += bytes;
else
c = BYTE8_TO_CHAR (*src), src++, pos++;
}
}
else
c = STRING_CHAR_ADVANCE_NO_UNIFY (src), pos++;
if ((c == '\r') && (coding->mode & CODING_MODE_SELECTIVE_DISPLAY))
c = '\n';
if (! EQ (eol_type, Qunix))
{
if (c == '\n')
{
if (EQ (eol_type, Qdos))
*buf++ = '\r';
else
c = '\r';
}
}
trans = Qnil;
LOOKUP_TRANSLATION_TABLE (translation_table, c, trans);
if (NILP (trans))
*buf++ = c;
else
{
ptrdiff_t from_nchars = 1, to_nchars = 1;
int *lookup_buf_end;
const unsigned char *p = src;
int i;
lookup_buf[0] = c;
for (i = 1; i < max_lookup && p < src_end; i++)
lookup_buf[i] = string_char_advance (&p);
lookup_buf_end = lookup_buf + i;
trans = get_translation (trans, lookup_buf, lookup_buf_end,
&from_nchars);
if (FIXNUMP (trans))
c = XFIXNUM (trans);
else if (VECTORP (trans))
{
to_nchars = ASIZE (trans);
if (buf_end - buf < to_nchars)
break;
c = XFIXNUM (AREF (trans, 0));
}
else
break;
*buf++ = c;
for (i = 1; i < to_nchars; i++)
*buf++ = XFIXNUM (AREF (trans, i));
for (i = 1; i < from_nchars; i++, pos++)
src += multibyte_length (src, NULL, false, true);
}
}
coding->consumed = src - coding->source;
coding->consumed_char = pos - coding->src_pos;
coding->charbuf_used = buf - coding->charbuf;
coding->chars_at_source = 0;
}
/* Encode the text at CODING->src_object into CODING->dst_object.
CODING->src_object is a buffer or a string.
CODING->dst_object is a buffer or nil.
If CODING->src_object is a buffer, it must be the current buffer.
In this case, if CODING->src_pos is positive, it is a position of
the source text in the buffer, otherwise. the source text is in the
gap area of the buffer, and coding->src_pos specifies the offset of
the text from GPT (which must be the same as PT). If this is the
same buffer as CODING->dst_object, CODING->src_pos must be
negative and CODING should not have `pre-write-conversion'.
If CODING->src_object is a string, CODING should not have
`pre-write-conversion'.
If CODING->dst_object is a buffer, the encoded data is inserted at
the current point of that buffer.
If CODING->dst_object is nil, the encoded data is placed at the
memory area specified by CODING->destination. */
static void
encode_coding (struct coding_system *coding)
{
Lisp_Object attrs;
Lisp_Object translation_table;
int max_lookup;
struct ccl_spec cclspec;
USE_SAFE_ALLOCA;
attrs = CODING_ID_ATTRS (coding->id);
if (coding->encoder == encode_coding_raw_text)
translation_table = Qnil, max_lookup = 0;
else
translation_table = get_translation_table (attrs, 1, &max_lookup);
if (BUFFERP (coding->dst_object))
{
set_buffer_internal (XBUFFER (coding->dst_object));
coding->dst_multibyte
= ! NILP (BVAR (current_buffer, enable_multibyte_characters));
}
coding->consumed = coding->consumed_char = 0;
coding->produced = coding->produced_char = 0;
record_conversion_result (coding, CODING_RESULT_SUCCESS);
ALLOC_CONVERSION_WORK_AREA (coding, coding->src_chars);
if (coding->encoder == encode_coding_ccl)
{
coding->spec.ccl = &cclspec;
setup_ccl_program (&cclspec.ccl, CODING_CCL_ENCODER (coding));
}
do {
coding_set_source (coding);
consume_chars (coding, translation_table, max_lookup);
coding_set_destination (coding);
(*(coding->encoder)) (coding);
} while (coding->consumed_char < coding->src_chars);
if (BUFFERP (coding->dst_object) && coding->produced_char > 0)
insert_from_gap (coding->produced_char, coding->produced, 0);
SAFE_FREE ();
}
/* Code-conversion operations use internal buffers. There's a single
reusable buffer, which is created the first time it is needed, and
then never killed. When this reusable buffer is being used, the
reused_workbuf_in_use flag is set. If we need another conversion
buffer while the reusable one is in use (e.g., if code-conversion
is reentered when another code-conversion is in progress), we
create temporary buffers using the name of the reusable buffer as
the base name, see code_conversion_save below. These temporary
buffers are killed when the code-conversion operations that use
them return, see code_conversion_restore below. */
/* A string that serves as name of the reusable work buffer, and as base
name of temporary work buffers used for code-conversion operations. */
Lisp_Object Vcode_conversion_workbuf_name;
/* The reusable working buffer, created once and never killed. */
static Lisp_Object Vcode_conversion_reused_workbuf;
/* True iff Vcode_conversion_reused_workbuf is already in use. */
static bool reused_workbuf_in_use;
static void
code_conversion_restore (Lisp_Object arg)
{
Lisp_Object current, workbuf;
current = XCAR (arg);
workbuf = XCDR (arg);
if (! NILP (workbuf))
{
if (EQ (workbuf, Vcode_conversion_reused_workbuf))
reused_workbuf_in_use = 0;
else
Fkill_buffer (workbuf);
}
set_buffer_internal (XBUFFER (current));
}
Lisp_Object
code_conversion_save (bool with_work_buf, bool multibyte)
{
Lisp_Object workbuf = Qnil;
if (with_work_buf)
{
if (reused_workbuf_in_use)
{
Lisp_Object name
= Fgenerate_new_buffer_name (Vcode_conversion_workbuf_name, Qnil);
workbuf = Fget_buffer_create (name);
}
else
{
if (NILP (Fbuffer_live_p (Vcode_conversion_reused_workbuf)))
Vcode_conversion_reused_workbuf
= Fget_buffer_create (Vcode_conversion_workbuf_name);
workbuf = Vcode_conversion_reused_workbuf;
}
}
record_unwind_protect (code_conversion_restore,
Fcons (Fcurrent_buffer (), workbuf));
if (!NILP (workbuf))
{
struct buffer *current = current_buffer;
set_buffer_internal (XBUFFER (workbuf));
/* We can't allow modification hooks to run in the work buffer. For
instance, directory_files_internal assumes that file decoding
doesn't compile new regexps. */
Fset (Fmake_local_variable (Qinhibit_modification_hooks), Qt);
Ferase_buffer ();
bset_undo_list (current_buffer, Qt);
bset_enable_multibyte_characters (current_buffer, multibyte ? Qt : Qnil);
if (EQ (workbuf, Vcode_conversion_reused_workbuf))
reused_workbuf_in_use = 1;
set_buffer_internal (current);
}
return workbuf;
}
static void
coding_restore_undo_list (Lisp_Object arg)
{
Lisp_Object undo_list = XCAR (arg);
struct buffer *buf = XBUFFER (XCDR (arg));
bset_undo_list (buf, undo_list);
}
/* Decode the *last* BYTES of the gap and insert them at point. */
void
decode_coding_gap (struct coding_system *coding, ptrdiff_t bytes)
{
ptrdiff_t count = SPECPDL_INDEX ();
Lisp_Object attrs;
eassert (GPT_BYTE == PT_BYTE);
coding->src_object = Fcurrent_buffer ();
coding->src_chars = bytes;
coding->src_bytes = bytes;
coding->src_pos = -bytes;
coding->src_pos_byte = -bytes;
coding->src_multibyte = false;
coding->dst_object = coding->src_object;
coding->dst_pos = PT;
coding->dst_pos_byte = PT_BYTE;
eassert (coding->dst_multibyte
== !NILP (BVAR (current_buffer, enable_multibyte_characters)));
coding->head_ascii = -1;
coding->detected_utf8_bytes = coding->detected_utf8_chars = -1;
coding->eol_seen = EOL_SEEN_NONE;
if (CODING_REQUIRE_DETECTION (coding))
detect_coding (coding);
attrs = CODING_ID_ATTRS (coding->id);
if (! disable_ascii_optimization
&& ! coding->src_multibyte
&& ! NILP (CODING_ATTR_ASCII_COMPAT (attrs))
&& NILP (CODING_ATTR_POST_READ (attrs))
&& NILP (get_translation_table (attrs, 0, NULL)))
{
ptrdiff_t chars = coding->head_ascii;
if (chars < 0)
chars = check_ascii (coding);
if (chars != bytes)
{
/* There exists a non-ASCII byte. */
if (EQ (CODING_ATTR_TYPE (attrs), Qutf_8)
&& coding->detected_utf8_bytes == coding->src_bytes)
{
if (coding->detected_utf8_chars >= 0)
chars = coding->detected_utf8_chars;
else
chars = check_utf_8 (coding);
if (CODING_UTF_8_BOM (coding) != utf_without_bom
&& coding->head_ascii == 0
&& coding->source[0] == UTF_8_BOM_1
&& coding->source[1] == UTF_8_BOM_2
&& coding->source[2] == UTF_8_BOM_3)
{
chars--;
bytes -= 3;
coding->src_bytes -= 3;
}
}
else
chars = -1;
}
if (chars >= 0)
{
Lisp_Object eol_type;
eol_type = CODING_ID_EOL_TYPE (coding->id);
if (VECTORP (eol_type))
{
if (coding->eol_seen != EOL_SEEN_NONE)
eol_type = adjust_coding_eol_type (coding, coding->eol_seen);
}
if (EQ (eol_type, Qmac))
{
unsigned char *src_end = GAP_END_ADDR;
unsigned char *src = src_end - coding->src_bytes;
while (src < src_end)
{
if (*src++ == '\r')
src[-1] = '\n';
}
}
else if (EQ (eol_type, Qdos))
{
unsigned char *src = GAP_END_ADDR;
unsigned char *src_beg = src - coding->src_bytes;
unsigned char *dst = src;
ptrdiff_t diff;
while (src_beg < src)
{
*--dst = *--src;
if (*src == '\n' && src > src_beg && src[-1] == '\r')
src--;
}
diff = dst - src;
bytes -= diff;
chars -= diff;
}
coding->produced = bytes;
coding->produced_char = chars;
insert_from_gap (chars, bytes, 1);
return;
}
}
code_conversion_save (0, 0);
coding->mode |= CODING_MODE_LAST_BLOCK;
current_buffer->text->inhibit_shrinking = 1;
decode_coding (coding);
current_buffer->text->inhibit_shrinking = 0;
if (! NILP (CODING_ATTR_POST_READ (attrs)))
{
ptrdiff_t prev_Z = Z, prev_Z_BYTE = Z_BYTE;
Lisp_Object val;
Lisp_Object undo_list = BVAR (current_buffer, undo_list);
record_unwind_protect (coding_restore_undo_list,
Fcons (undo_list, Fcurrent_buffer ()));
bset_undo_list (current_buffer, Qt);
TEMP_SET_PT_BOTH (coding->dst_pos, coding->dst_pos_byte);
val = call1 (CODING_ATTR_POST_READ (attrs),
make_fixnum (coding->produced_char));
CHECK_FIXNAT (val);
coding->produced_char += Z - prev_Z;
coding->produced += Z_BYTE - prev_Z_BYTE;
}
unbind_to (count, Qnil);
}
/* Decode the text in the range FROM/FROM_BYTE and TO/TO_BYTE in
SRC_OBJECT into DST_OBJECT by coding context CODING.
SRC_OBJECT is a buffer, a string, or Qnil.
If it is a buffer, the text is at point of the buffer. FROM and TO
are positions in the buffer.
If it is a string, the text is at the beginning of the string.
FROM and TO are indices to the string.
If it is nil, the text is at coding->source. FROM and TO are
indices to coding->source.
DST_OBJECT is a buffer, Qt, or Qnil.
If it is a buffer, the decoded text is inserted at point of the
buffer. If the buffer is the same as SRC_OBJECT, the source text
is deleted.
If it is Qt, a string is made from the decoded text, and
set in CODING->dst_object.
If it is Qnil, the decoded text is stored at CODING->destination.
The caller must allocate CODING->dst_bytes bytes at
CODING->destination by xmalloc. If the decoded text is longer than
CODING->dst_bytes, CODING->destination is relocated by xrealloc.
*/
void
decode_coding_object (struct coding_system *coding,
Lisp_Object src_object,
ptrdiff_t from, ptrdiff_t from_byte,
ptrdiff_t to, ptrdiff_t to_byte,
Lisp_Object dst_object)
{
ptrdiff_t count = SPECPDL_INDEX ();
unsigned char *destination UNINIT;
ptrdiff_t dst_bytes UNINIT;
ptrdiff_t chars = to - from;
ptrdiff_t bytes = to_byte - from_byte;
Lisp_Object attrs;
ptrdiff_t saved_pt = -1, saved_pt_byte UNINIT;
bool need_marker_adjustment = 0;
Lisp_Object old_deactivate_mark;
old_deactivate_mark = Vdeactivate_mark;
if (NILP (dst_object))
{
destination = coding->destination;
dst_bytes = coding->dst_bytes;
}
coding->src_object = src_object;
coding->src_chars = chars;
coding->src_bytes = bytes;
coding->src_multibyte = chars < bytes;
if (STRINGP (src_object))
{
coding->src_pos = from;
coding->src_pos_byte = from_byte;
}
else if (BUFFERP (src_object))
{
set_buffer_internal (XBUFFER (src_object));
if (from != GPT)
move_gap_both (from, from_byte);
if (EQ (src_object, dst_object))
{
struct Lisp_Marker *tail;
for (tail = BUF_MARKERS (current_buffer); tail; tail = tail->next)
{
tail->need_adjustment
= tail->charpos == (tail->insertion_type ? from : to);
need_marker_adjustment |= tail->need_adjustment;
}
saved_pt = PT, saved_pt_byte = PT_BYTE;
TEMP_SET_PT_BOTH (from, from_byte);
current_buffer->text->inhibit_shrinking = 1;
del_range_both (from, from_byte, to, to_byte, 1);
coding->src_pos = -chars;
coding->src_pos_byte = -bytes;
}
else
{
coding->src_pos = from;
coding->src_pos_byte = from_byte;
}
}
if (CODING_REQUIRE_DETECTION (coding))
detect_coding (coding);
attrs = CODING_ID_ATTRS (coding->id);
if (EQ (dst_object, Qt)
|| (! NILP (CODING_ATTR_POST_READ (attrs))
&& NILP (dst_object)))
{
coding->dst_multibyte = !CODING_FOR_UNIBYTE (coding);
coding->dst_object = code_conversion_save (1, coding->dst_multibyte);
coding->dst_pos = BEG;
coding->dst_pos_byte = BEG_BYTE;
}
else if (BUFFERP (dst_object))
{
code_conversion_save (0, 0);
coding->dst_object = dst_object;
coding->dst_pos = BUF_PT (XBUFFER (dst_object));
coding->dst_pos_byte = BUF_PT_BYTE (XBUFFER (dst_object));
coding->dst_multibyte
= ! NILP (BVAR (XBUFFER (dst_object), enable_multibyte_characters));
}
else
{
code_conversion_save (0, 0);
coding->dst_object = Qnil;
/* Most callers presume this will return a multibyte result, and they
won't use `binary' or `raw-text' anyway, so let's not worry about
CODING_FOR_UNIBYTE. */
coding->dst_multibyte = 1;
}
decode_coding (coding);
if (BUFFERP (coding->dst_object))
set_buffer_internal (XBUFFER (coding->dst_object));
if (! NILP (CODING_ATTR_POST_READ (attrs)))
{
ptrdiff_t prev_Z = Z, prev_Z_BYTE = Z_BYTE;
Lisp_Object val;
Lisp_Object undo_list = BVAR (current_buffer, undo_list);
ptrdiff_t count1 = SPECPDL_INDEX ();
record_unwind_protect (coding_restore_undo_list,
Fcons (undo_list, Fcurrent_buffer ()));
bset_undo_list (current_buffer, Qt);
TEMP_SET_PT_BOTH (coding->dst_pos, coding->dst_pos_byte);
val = safe_call1 (CODING_ATTR_POST_READ (attrs),
make_fixnum (coding->produced_char));
CHECK_FIXNAT (val);
coding->produced_char += Z - prev_Z;
coding->produced += Z_BYTE - prev_Z_BYTE;
unbind_to (count1, Qnil);
}
if (EQ (dst_object, Qt))
{
coding->dst_object = Fbuffer_string ();
}
else if (NILP (dst_object) && BUFFERP (coding->dst_object))
{
set_buffer_internal (XBUFFER (coding->dst_object));
if (dst_bytes < coding->produced)
{
eassert (coding->produced > 0);
destination = xrealloc (destination, coding->produced);
if (BEGV < GPT && GPT < BEGV + coding->produced_char)
move_gap_both (BEGV, BEGV_BYTE);
memcpy (destination, BEGV_ADDR, coding->produced);
coding->destination = destination;
}
}
if (saved_pt >= 0)
{
/* This is the case of:
(BUFFERP (src_object) && EQ (src_object, dst_object))
As we have moved PT while replacing the original buffer
contents, we must recover it now. */
set_buffer_internal (XBUFFER (src_object));
current_buffer->text->inhibit_shrinking = 0;
if (saved_pt < from)
TEMP_SET_PT_BOTH (saved_pt, saved_pt_byte);
else if (saved_pt < from + chars)
TEMP_SET_PT_BOTH (from, from_byte);
else if (! NILP (BVAR (current_buffer, enable_multibyte_characters)))
TEMP_SET_PT_BOTH (saved_pt + (coding->produced_char - chars),
saved_pt_byte + (coding->produced - bytes));
else
TEMP_SET_PT_BOTH (saved_pt + (coding->produced - bytes),
saved_pt_byte + (coding->produced - bytes));
if (need_marker_adjustment)
{
struct Lisp_Marker *tail;
for (tail = BUF_MARKERS (current_buffer); tail; tail = tail->next)
if (tail->need_adjustment)
{
tail->need_adjustment = 0;
if (tail->insertion_type)
{
tail->bytepos = from_byte;
tail->charpos = from;
}
else
{
tail->bytepos = from_byte + coding->produced;
tail->charpos
= (NILP (BVAR (current_buffer, enable_multibyte_characters))
? tail->bytepos : from + coding->produced_char);
}
}
}
}
Vdeactivate_mark = old_deactivate_mark;
unbind_to (count, coding->dst_object);
}
void
encode_coding_object (struct coding_system *coding,
Lisp_Object src_object,
ptrdiff_t from, ptrdiff_t from_byte,
ptrdiff_t to, ptrdiff_t to_byte,
Lisp_Object dst_object)
{
ptrdiff_t count = SPECPDL_INDEX ();
ptrdiff_t chars = to - from;
ptrdiff_t bytes = to_byte - from_byte;
Lisp_Object attrs;
ptrdiff_t saved_pt = -1, saved_pt_byte;
bool need_marker_adjustment = 0;
bool kill_src_buffer = 0;
Lisp_Object old_deactivate_mark;
old_deactivate_mark = Vdeactivate_mark;
coding->src_object = src_object;
coding->src_chars = chars;
coding->src_bytes = bytes;
coding->src_multibyte = chars < bytes;
attrs = CODING_ID_ATTRS (coding->id);
if (EQ (src_object, dst_object))
{
struct Lisp_Marker *tail;
for (tail = BUF_MARKERS (current_buffer); tail; tail = tail->next)
{
tail->need_adjustment
= tail->charpos == (tail->insertion_type ? from : to);
need_marker_adjustment |= tail->need_adjustment;
}
}
if (! NILP (CODING_ATTR_PRE_WRITE (attrs)))
{
coding->src_object = code_conversion_save (1, coding->src_multibyte);
set_buffer_internal (XBUFFER (coding->src_object));
if (STRINGP (src_object))
insert_from_string (src_object, from, from_byte, chars, bytes, 0);
else if (BUFFERP (src_object))
insert_from_buffer (XBUFFER (src_object), from, chars, 0);
else
insert_1_both ((char *) coding->source + from, chars, bytes, 0, 0, 0);
if (EQ (src_object, dst_object))
{
set_buffer_internal (XBUFFER (src_object));
saved_pt = PT, saved_pt_byte = PT_BYTE;
del_range_both (from, from_byte, to, to_byte, 1);
set_buffer_internal (XBUFFER (coding->src_object));
}
safe_call2 (CODING_ATTR_PRE_WRITE (attrs),
make_fixnum (BEG), make_fixnum (Z));
if (XBUFFER (coding->src_object) != current_buffer)
kill_src_buffer = 1;
coding->src_object = Fcurrent_buffer ();
if (BEG != GPT)
move_gap_both (BEG, BEG_BYTE);
coding->src_chars = Z - BEG;
coding->src_bytes = Z_BYTE - BEG_BYTE;
coding->src_pos = BEG;
coding->src_pos_byte = BEG_BYTE;
coding->src_multibyte = Z < Z_BYTE;
}
else if (STRINGP (src_object))
{
code_conversion_save (0, 0);
coding->src_pos = from;
coding->src_pos_byte = from_byte;
}
else if (BUFFERP (src_object))
{
code_conversion_save (0, 0);
set_buffer_internal (XBUFFER (src_object));
if (EQ (src_object, dst_object))
{
saved_pt = PT, saved_pt_byte = PT_BYTE;
coding->src_object = del_range_1 (from, to, 1, 1);
coding->src_pos = 0;
coding->src_pos_byte = 0;
}
else
{
if (from < GPT && to >= GPT)
move_gap_both (from, from_byte);
coding->src_pos = from;
coding->src_pos_byte = from_byte;
}
}
else
{
code_conversion_save (0, 0);
coding->src_pos = from;
coding->src_pos_byte = from_byte;
}
if (BUFFERP (dst_object))
{
coding->dst_object = dst_object;
if (EQ (src_object, dst_object))
{
coding->dst_pos = from;
coding->dst_pos_byte = from_byte;
}
else
{
struct buffer *current = current_buffer;
set_buffer_temp (XBUFFER (dst_object));
coding->dst_pos = PT;
coding->dst_pos_byte = PT_BYTE;
move_gap_both (coding->dst_pos, coding->dst_pos_byte);
set_buffer_temp (current);
}
coding->dst_multibyte
= ! NILP (BVAR (XBUFFER (dst_object), enable_multibyte_characters));
}
else if (EQ (dst_object, Qt))
{
ptrdiff_t dst_bytes = max (1, coding->src_chars);
coding->dst_object = Qnil;
coding->destination = xmalloc (dst_bytes);
coding->dst_bytes = dst_bytes;
coding->dst_multibyte = 0;
}
else
{
coding->dst_object = Qnil;
coding->dst_multibyte = 0;
}
encode_coding (coding);
if (EQ (dst_object, Qt))
{
if (BUFFERP (coding->dst_object))
coding->dst_object = Fbuffer_string ();
else if (coding->raw_destination)
/* This is used to avoid creating huge Lisp string.
NOTE: caller who sets `raw_destination' is also
responsible for freeing `destination' buffer. */
coding->dst_object = Qnil;
else
{
coding->dst_object
= make_unibyte_string ((char *) coding->destination,
coding->produced);
xfree (coding->destination);
}
}
if (saved_pt >= 0)
{
/* This is the case of:
(BUFFERP (src_object) && EQ (src_object, dst_object))
As we have moved PT while replacing the original buffer
contents, we must recover it now. */
set_buffer_internal (XBUFFER (src_object));
if (saved_pt < from)
TEMP_SET_PT_BOTH (saved_pt, saved_pt_byte);
else if (saved_pt < from + chars)
TEMP_SET_PT_BOTH (from, from_byte);
else if (! NILP (BVAR (current_buffer, enable_multibyte_characters)))
TEMP_SET_PT_BOTH (saved_pt + (coding->produced_char - chars),
saved_pt_byte + (coding->produced - bytes));
else
TEMP_SET_PT_BOTH (saved_pt + (coding->produced - bytes),
saved_pt_byte + (coding->produced - bytes));
if (need_marker_adjustment)
{
struct Lisp_Marker *tail;
for (tail = BUF_MARKERS (current_buffer); tail; tail = tail->next)
if (tail->need_adjustment)
{
tail->need_adjustment = 0;
if (tail->insertion_type)
{
tail->bytepos = from_byte;
tail->charpos = from;
}
else
{
tail->bytepos = from_byte + coding->produced;
tail->charpos
= (NILP (BVAR (current_buffer, enable_multibyte_characters))
? tail->bytepos : from + coding->produced_char);
}
}
}
}
if (kill_src_buffer)
Fkill_buffer (coding->src_object);
Vdeactivate_mark = old_deactivate_mark;
unbind_to (count, Qnil);
}
Lisp_Object
preferred_coding_system (void)
{
int id = coding_categories[coding_priorities[0]].id;
return CODING_ID_NAME (id);
}
#if defined (WINDOWSNT) || defined (CYGWIN)
Lisp_Object
from_unicode (Lisp_Object str)
{
CHECK_STRING (str);
if (!STRING_MULTIBYTE (str) &&
SBYTES (str) & 1)
{
str = Fsubstring (str, make_fixnum (0), make_fixnum (-1));
}
return code_convert_string_norecord (str, Qutf_16le, 0);
}
Lisp_Object
from_unicode_buffer (const wchar_t *wstr)
{
/* We get one of the two final NUL bytes for free. */
ptrdiff_t len = 1 + sizeof (wchar_t) * wcslen (wstr);
AUTO_STRING_WITH_LEN (str, (char *) wstr, len);
return from_unicode (str);
}
wchar_t *
to_unicode (Lisp_Object str, Lisp_Object *buf)
{
*buf = code_convert_string_norecord (str, Qutf_16le, 1);
/* We need to make another copy (in addition to the one made by
code_convert_string_norecord) to ensure that the final string is
_doubly_ zero terminated --- that is, that the string is
terminated by two zero bytes and one utf-16le NUL character.
Because strings are already terminated with a single zero byte,
we just add one additional zero. */
str = make_uninit_string (SBYTES (*buf) + 1);
memcpy (SDATA (str), SDATA (*buf), SBYTES (*buf));
SDATA (str) [SBYTES (*buf)] = '\0';
*buf = str;
return WCSDATA (*buf);
}
#endif /* WINDOWSNT || CYGWIN */
/*** 8. Emacs Lisp library functions ***/
DEFUN ("coding-system-p", Fcoding_system_p, Scoding_system_p, 1, 1, 0,
doc: /* Return t if OBJECT is nil or a coding-system.
See the documentation of `define-coding-system' for information
about coding-system objects. */)
(Lisp_Object object)
{
if (NILP (object)
|| CODING_SYSTEM_ID (object) >= 0)
return Qt;
if (! SYMBOLP (object)
|| NILP (Fget (object, Qcoding_system_define_form)))
return Qnil;
return Qt;
}
DEFUN ("read-non-nil-coding-system", Fread_non_nil_coding_system,
Sread_non_nil_coding_system, 1, 1, 0,
doc: /* Read a coding system from the minibuffer, prompting with string PROMPT. */)
(Lisp_Object prompt)
{
Lisp_Object val;
do
{
val = Fcompleting_read (prompt, Vcoding_system_alist, Qnil,
Qt, Qnil, Qcoding_system_history, Qnil, Qnil);
}
while (SCHARS (val) == 0);
return (Fintern (val, Qnil));
}
DEFUN ("read-coding-system", Fread_coding_system, Sread_coding_system, 1, 2, 0,
doc: /* Read a coding system from the minibuffer, prompting with string PROMPT.
If the user enters null input, return second argument DEFAULT-CODING-SYSTEM.
Ignores case when completing coding systems (all Emacs coding systems
are lower-case). */)
(Lisp_Object prompt, Lisp_Object default_coding_system)
{
Lisp_Object val;
ptrdiff_t count = SPECPDL_INDEX ();
if (SYMBOLP (default_coding_system))
default_coding_system = SYMBOL_NAME (default_coding_system);
specbind (Qcompletion_ignore_case, Qt);
val = Fcompleting_read (prompt, Vcoding_system_alist, Qnil,
Qt, Qnil, Qcoding_system_history,
default_coding_system, Qnil);
val = unbind_to (count, val);
return (SCHARS (val) == 0 ? Qnil : Fintern (val, Qnil));
}
DEFUN ("check-coding-system", Fcheck_coding_system, Scheck_coding_system,
1, 1, 0,
doc: /* Check validity of CODING-SYSTEM.
If valid, return CODING-SYSTEM, else signal a `coding-system-error' error.
It is valid if it is nil or a symbol defined as a coding system by the
function `define-coding-system'. */)
(Lisp_Object coding_system)
{
Lisp_Object define_form;
define_form = Fget (coding_system, Qcoding_system_define_form);
if (! NILP (define_form))
{
Fput (coding_system, Qcoding_system_define_form, Qnil);
safe_eval (define_form);
}
if (!NILP (Fcoding_system_p (coding_system)))
return coding_system;
xsignal1 (Qcoding_system_error, coding_system);
}
/* Detect how the bytes at SRC of length SRC_BYTES are encoded. If
HIGHEST, return the coding system of the highest
priority among the detected coding systems. Otherwise return a
list of detected coding systems sorted by their priorities. If
MULTIBYTEP, it is assumed that the bytes are in correct
multibyte form but contains only ASCII and eight-bit chars.
Otherwise, the bytes are raw bytes.
CODING-SYSTEM controls the detection as below:
If it is nil, detect both text-format and eol-format. If the
text-format part of CODING-SYSTEM is already specified
(e.g. `iso-latin-1'), detect only eol-format. If the eol-format
part of CODING-SYSTEM is already specified (e.g. `undecided-unix'),
detect only text-format. */
Lisp_Object
detect_coding_system (const unsigned char *src,
ptrdiff_t src_chars, ptrdiff_t src_bytes,
bool highest, bool multibytep,
Lisp_Object coding_system)
{
const unsigned char *src_end = src + src_bytes;
Lisp_Object attrs, eol_type;
Lisp_Object val = Qnil;
struct coding_system coding;
ptrdiff_t id;
struct coding_detection_info detect_info;
enum coding_category base_category;
bool nul_byte_found = 0, eight_bit_found = 0;
if (NILP (coding_system))
coding_system = Qundecided;
setup_coding_system (coding_system, &coding);
attrs = CODING_ID_ATTRS (coding.id);
eol_type = CODING_ID_EOL_TYPE (coding.id);
coding_system = CODING_ATTR_BASE_NAME (attrs);
coding.source = src;
coding.src_chars = src_chars;
coding.src_bytes = src_bytes;
coding.src_multibyte = multibytep;
coding.consumed = 0;
coding.mode |= CODING_MODE_LAST_BLOCK;
coding.head_ascii = 0;
detect_info.checked = detect_info.found = detect_info.rejected = 0;
/* At first, detect text-format if necessary. */
base_category = XFIXNUM (CODING_ATTR_CATEGORY (attrs));
if (base_category == coding_category_undecided)
{
enum coding_category category UNINIT;
struct coding_system *this UNINIT;
int c, i;
bool inhibit_nbd = inhibit_flag (coding.spec.undecided.inhibit_nbd,
inhibit_nul_byte_detection);
bool inhibit_ied = inhibit_flag (coding.spec.undecided.inhibit_ied,
inhibit_iso_escape_detection);
bool prefer_utf_8 = coding.spec.undecided.prefer_utf_8;
/* Skip all ASCII bytes except for a few ISO2022 controls. */
for (; src < src_end; src++)
{
c = *src;
if (c & 0x80)
{
eight_bit_found = 1;
if (nul_byte_found)
break;
}
else if (c < 0x20)
{
if ((c == ISO_CODE_ESC || c == ISO_CODE_SI || c == ISO_CODE_SO)
&& ! inhibit_ied
&& ! detect_info.checked)
{
if (detect_coding_iso_2022 (&coding, &detect_info))
{
/* We have scanned the whole data. */
if (! (detect_info.rejected & CATEGORY_MASK_ISO_7_ELSE))
{
/* We didn't find an 8-bit code. We may
have found a NUL-byte, but it's very
rare that a binary file confirm to
ISO-2022. */
src = src_end;
coding.head_ascii = src - coding.source;
}
detect_info.rejected |= ~CATEGORY_MASK_ISO_ESCAPE;
break;
}
}
else if (! c && !inhibit_nbd)
{
nul_byte_found = 1;
if (eight_bit_found)
break;
}
if (! eight_bit_found)
coding.head_ascii++;
}
else if (! eight_bit_found)
coding.head_ascii++;
}
if (nul_byte_found || eight_bit_found
|| coding.head_ascii < coding.src_bytes
|| detect_info.found)
{
if (coding.head_ascii == coding.src_bytes)
/* As all bytes are 7-bit, we can ignore non-ISO-2022 codings. */
for (i = 0; i < coding_category_raw_text; i++)
{
category = coding_priorities[i];
this = coding_categories + category;
if (detect_info.found & (1 << category))
break;
}
else
{
if (nul_byte_found)
{
detect_info.checked |= ~CATEGORY_MASK_UTF_16;
detect_info.rejected |= ~CATEGORY_MASK_UTF_16;
}
else if (prefer_utf_8
&& detect_coding_utf_8 (&coding, &detect_info))
{
detect_info.checked |= ~CATEGORY_MASK_UTF_8;
detect_info.rejected |= ~CATEGORY_MASK_UTF_8;
}
for (i = 0; i < coding_category_raw_text; i++)
{
category = coding_priorities[i];
this = coding_categories + category;
if (this->id < 0)
{
/* No coding system of this category is defined. */
detect_info.rejected |= (1 << category);
}
else if (category >= coding_category_raw_text)
continue;
else if (detect_info.checked & (1 << category))
{
if (highest
&& (detect_info.found & (1 << category)))
break;
}
else if ((*(this->detector)) (&coding, &detect_info)
&& highest
&& (detect_info.found & (1 << category)))
{
if (category == coding_category_utf_16_auto)
{
if (detect_info.found & CATEGORY_MASK_UTF_16_LE)
category = coding_category_utf_16_le;
else
category = coding_category_utf_16_be;
}
break;
}
}
}
}
if ((detect_info.rejected & CATEGORY_MASK_ANY) == CATEGORY_MASK_ANY
|| nul_byte_found)
{
detect_info.found = CATEGORY_MASK_RAW_TEXT;
id = CODING_SYSTEM_ID (Qno_conversion);
val = list1i (id);
}
else if (! detect_info.rejected && ! detect_info.found)
{
detect_info.found = CATEGORY_MASK_ANY;
id = coding_categories[coding_category_undecided].id;
val = list1i (id);
}
else if (highest)
{
if (detect_info.found)
{
detect_info.found = 1 << category;
val = list1i (this->id);
}
else
for (i = 0; i < coding_category_raw_text; i++)
if (! (detect_info.rejected & (1 << coding_priorities[i])))
{
detect_info.found = 1 << coding_priorities[i];
id = coding_categories[coding_priorities[i]].id;
val = list1i (id);
break;
}
}
else
{
int mask = detect_info.rejected | detect_info.found;
int found = 0;
for (i = coding_category_raw_text - 1; i >= 0; i--)
{
category = coding_priorities[i];
if (! (mask & (1 << category)))
{
found |= 1 << category;
id = coding_categories[category].id;
if (id >= 0)
val = list1i (id);
}
}
for (i = coding_category_raw_text - 1; i >= 0; i--)
{
category = coding_priorities[i];
if (detect_info.found & (1 << category))
{
id = coding_categories[category].id;
val = Fcons (make_fixnum (id), val);
}
}
detect_info.found |= found;
}
}
else if (base_category == coding_category_utf_8_auto)
{
if (detect_coding_utf_8 (&coding, &detect_info))
{
struct coding_system *this;
if (detect_info.found & CATEGORY_MASK_UTF_8_SIG)
this = coding_categories + coding_category_utf_8_sig;
else
this = coding_categories + coding_category_utf_8_nosig;
val = list1i (this->id);
}
}
else if (base_category == coding_category_utf_16_auto)
{
if (detect_coding_utf_16 (&coding, &detect_info))
{
struct coding_system *this;
if (detect_info.found & CATEGORY_MASK_UTF_16_LE)
this = coding_categories + coding_category_utf_16_le;
else if (detect_info.found & CATEGORY_MASK_UTF_16_BE)
this = coding_categories + coding_category_utf_16_be;
else if (detect_info.rejected & CATEGORY_MASK_UTF_16_LE_NOSIG)
this = coding_categories + coding_category_utf_16_be_nosig;
else
this = coding_categories + coding_category_utf_16_le_nosig;
val = list1i (this->id);
}
}
else
{
detect_info.found = 1 << XFIXNUM (CODING_ATTR_CATEGORY (attrs));
val = list1i (coding.id);
}
/* Then, detect eol-format if necessary. */
{
int normal_eol = -1, utf_16_be_eol = -1, utf_16_le_eol = -1;
Lisp_Object tail;
if (VECTORP (eol_type))
{
if (detect_info.found & ~CATEGORY_MASK_UTF_16)
{
if (nul_byte_found)
normal_eol = EOL_SEEN_LF;
else
normal_eol = detect_eol (coding.source, src_bytes,
coding_category_raw_text);
}
if (detect_info.found & (CATEGORY_MASK_UTF_16_BE
| CATEGORY_MASK_UTF_16_BE_NOSIG))
utf_16_be_eol = detect_eol (coding.source, src_bytes,
coding_category_utf_16_be);
if (detect_info.found & (CATEGORY_MASK_UTF_16_LE
| CATEGORY_MASK_UTF_16_LE_NOSIG))
utf_16_le_eol = detect_eol (coding.source, src_bytes,
coding_category_utf_16_le);
}
else
{
if (EQ (eol_type, Qunix))
normal_eol = utf_16_be_eol = utf_16_le_eol = EOL_SEEN_LF;
else if (EQ (eol_type, Qdos))
normal_eol = utf_16_be_eol = utf_16_le_eol = EOL_SEEN_CRLF;
else
normal_eol = utf_16_be_eol = utf_16_le_eol = EOL_SEEN_CR;
}
for (tail = val; CONSP (tail); tail = XCDR (tail))
{
enum coding_category category;
int this_eol;
id = XFIXNUM (XCAR (tail));
attrs = CODING_ID_ATTRS (id);
category = XFIXNUM (CODING_ATTR_CATEGORY (attrs));
eol_type = CODING_ID_EOL_TYPE (id);
if (VECTORP (eol_type))
{
if (category == coding_category_utf_16_be
|| category == coding_category_utf_16_be_nosig)
this_eol = utf_16_be_eol;
else if (category == coding_category_utf_16_le
|| category == coding_category_utf_16_le_nosig)
this_eol = utf_16_le_eol;
else
this_eol = normal_eol;
if (this_eol == EOL_SEEN_LF)
XSETCAR (tail, AREF (eol_type, 0));
else if (this_eol == EOL_SEEN_CRLF)
XSETCAR (tail, AREF (eol_type, 1));
else if (this_eol == EOL_SEEN_CR)
XSETCAR (tail, AREF (eol_type, 2));
else
XSETCAR (tail, CODING_ID_NAME (id));
}
else
XSETCAR (tail, CODING_ID_NAME (id));
}
}
return (highest ? (CONSP (val) ? XCAR (val) : Qnil) : val);
}
DEFUN ("detect-coding-region", Fdetect_coding_region, Sdetect_coding_region,
2, 3, 0,
doc: /* Detect coding system of the text in the region between START and END.
Return a list of possible coding systems ordered by priority.
The coding systems to try and their priorities follows what
the function `coding-system-priority-list' (which see) returns.
If only ASCII characters are found (except for such ISO-2022 control
characters as ESC), it returns a list of single element `undecided'
or its subsidiary coding system according to a detected end-of-line
format.
If optional argument HIGHEST is non-nil, return the coding system of
highest priority. */)
(Lisp_Object start, Lisp_Object end, Lisp_Object highest)
{
ptrdiff_t from, to;
ptrdiff_t from_byte, to_byte;
validate_region (&start, &end);
from = XFIXNUM (start), to = XFIXNUM (end);
from_byte = CHAR_TO_BYTE (from);
to_byte = CHAR_TO_BYTE (to);
if (from < GPT && to >= GPT)
move_gap_both (to, to_byte);
return detect_coding_system (BYTE_POS_ADDR (from_byte),
to - from, to_byte - from_byte,
!NILP (highest),
!NILP (BVAR (current_buffer
, enable_multibyte_characters)),
Qnil);
}
DEFUN ("detect-coding-string", Fdetect_coding_string, Sdetect_coding_string,
1, 2, 0,
doc: /* Detect coding system of the text in STRING.
Return a list of possible coding systems ordered by priority.
The coding systems to try and their priorities follows what
the function `coding-system-priority-list' (which see) returns.
If only ASCII characters are found (except for such ISO-2022 control
characters as ESC), it returns a list of single element `undecided'
or its subsidiary coding system according to a detected end-of-line
format.
If optional argument HIGHEST is non-nil, return the coding system of
highest priority. */)
(Lisp_Object string, Lisp_Object highest)
{
CHECK_STRING (string);
return detect_coding_system (SDATA (string),
SCHARS (string), SBYTES (string),
!NILP (highest), STRING_MULTIBYTE (string),
Qnil);
}
static bool
char_encodable_p (int c, Lisp_Object attrs)
{
Lisp_Object tail;
struct charset *charset;
Lisp_Object translation_table;
translation_table = CODING_ATTR_TRANS_TBL (attrs);
if (! NILP (translation_table))
c = translate_char (translation_table, c);
for (tail = CODING_ATTR_CHARSET_LIST (attrs);
CONSP (tail); tail = XCDR (tail))
{
charset = CHARSET_FROM_ID (XFIXNUM (XCAR (tail)));
if (CHAR_CHARSET_P (c, charset))
break;
}
return (! NILP (tail));
}
/* Return a list of coding systems that safely encode the text between
START and END. If EXCLUDE is non-nil, it is a list of coding
systems not to check. The returned list doesn't contain any such
coding systems. In any case, if the text contains only ASCII or is
unibyte, return t. */
DEFUN ("find-coding-systems-region-internal",
Ffind_coding_systems_region_internal,
Sfind_coding_systems_region_internal, 2, 3, 0,
doc: /* Internal use only. */)
(Lisp_Object start, Lisp_Object end, Lisp_Object exclude)
{
Lisp_Object coding_attrs_list, safe_codings;
ptrdiff_t start_byte, end_byte;
const unsigned char *p, *pbeg, *pend;
int c;
Lisp_Object tail, elt, work_table;
if (STRINGP (start))
{
if (!STRING_MULTIBYTE (start)
|| SCHARS (start) == SBYTES (start))
return Qt;
start_byte = 0;
end_byte = SBYTES (start);
}
else
{
EMACS_INT s = fix_position (start);
EMACS_INT e = fix_position (end);
if (! (BEG <= s && s <= e && e <= Z))
args_out_of_range (start, end);
if (NILP (BVAR (current_buffer, enable_multibyte_characters)))
return Qt;
start_byte = CHAR_TO_BYTE (s);
end_byte = CHAR_TO_BYTE (e);
if (e - s == end_byte - start_byte)
return Qt;
if (s < GPT && GPT < e)
{
if (GPT - s < e - GPT)
move_gap_both (s, start_byte);
else
move_gap_both (e, end_byte);
}
}
coding_attrs_list = Qnil;
for (tail = Vcoding_system_list; CONSP (tail); tail = XCDR (tail))
if (NILP (exclude)
|| NILP (Fmemq (XCAR (tail), exclude)))
{
Lisp_Object attrs;
attrs = AREF (CODING_SYSTEM_SPEC (XCAR (tail)), 0);
if (EQ (XCAR (tail), CODING_ATTR_BASE_NAME (attrs)))
{
ASET (attrs, coding_attr_trans_tbl,
get_translation_table (attrs, 1, NULL));
coding_attrs_list = Fcons (attrs, coding_attrs_list);
}
}
if (STRINGP (start))
p = pbeg = SDATA (start);
else
p = pbeg = BYTE_POS_ADDR (start_byte);
pend = p + (end_byte - start_byte);
while (p < pend && ASCII_CHAR_P (*p)) p++;
while (p < pend && ASCII_CHAR_P (*(pend - 1))) pend--;
work_table = Fmake_char_table (Qnil, Qnil);
while (p < pend)
{
if (ASCII_CHAR_P (*p))
p++;
else
{
c = string_char_advance (&p);
if (!NILP (char_table_ref (work_table, c)))
/* This character was already checked. Ignore it. */
continue;
charset_map_loaded = 0;
for (tail = coding_attrs_list; CONSP (tail);)
{
elt = XCAR (tail);
if (NILP (elt))
tail = XCDR (tail);
else if (char_encodable_p (c, elt))
tail = XCDR (tail);
else if (CONSP (XCDR (tail)))
{
XSETCAR (tail, XCAR (XCDR (tail)));
XSETCDR (tail, XCDR (XCDR (tail)));
}
else
{
XSETCAR (tail, Qnil);
tail = XCDR (tail);
}
}
if (charset_map_loaded)
{
ptrdiff_t p_offset = p - pbeg, pend_offset = pend - pbeg;
if (STRINGP (start))
pbeg = SDATA (start);
else
pbeg = BYTE_POS_ADDR (start_byte);
p = pbeg + p_offset;
pend = pbeg + pend_offset;
}
char_table_set (work_table, c, Qt);
}
}
safe_codings = list2 (Qraw_text, Qno_conversion);
for (tail = coding_attrs_list; CONSP (tail); tail = XCDR (tail))
if (! NILP (XCAR (tail)))
safe_codings = Fcons (CODING_ATTR_BASE_NAME (XCAR (tail)), safe_codings);
return safe_codings;
}
DEFUN ("unencodable-char-position", Funencodable_char_position,
Sunencodable_char_position, 3, 5, 0,
doc: /* Return position of first un-encodable character in a region.
START and END specify the region and CODING-SYSTEM specifies the
encoding to check. Return nil if CODING-SYSTEM does encode the region.
If optional 4th argument COUNT is non-nil, it specifies at most how
many un-encodable characters to search. In this case, the value is a
list of positions.
If optional 5th argument STRING is non-nil, it is a string to search
for un-encodable characters. In that case, START and END are indexes
to the string and treated as in `substring'. */)
(Lisp_Object start, Lisp_Object end, Lisp_Object coding_system,
Lisp_Object count, Lisp_Object string)
{
EMACS_INT n;
struct coding_system coding;
Lisp_Object attrs, charset_list, translation_table;
Lisp_Object positions;
ptrdiff_t from, to;
const unsigned char *p, *stop, *pend;
bool ascii_compatible;
setup_coding_system (Fcheck_coding_system (coding_system), &coding);
attrs = CODING_ID_ATTRS (coding.id);
if (EQ (CODING_ATTR_TYPE (attrs), Qraw_text))
return Qnil;
ascii_compatible = ! NILP (CODING_ATTR_ASCII_COMPAT (attrs));
charset_list = CODING_ATTR_CHARSET_LIST (attrs);
translation_table = get_translation_table (attrs, 1, NULL);
if (NILP (string))
{
validate_region (&start, &end);
from = XFIXNUM (start);
to = XFIXNUM (end);
if (NILP (BVAR (current_buffer, enable_multibyte_characters))
|| (ascii_compatible
&& (to - from) == (CHAR_TO_BYTE (to) - (CHAR_TO_BYTE (from)))))
return Qnil;
p = CHAR_POS_ADDR (from);
pend = CHAR_POS_ADDR (to);
if (from < GPT && to >= GPT)
stop = GPT_ADDR;
else
stop = pend;
}
else
{
CHECK_STRING (string);
validate_subarray (string, start, end, SCHARS (string), &from, &to);
if (! STRING_MULTIBYTE (string))
return Qnil;
p = SDATA (string) + string_char_to_byte (string, from);
stop = pend = SDATA (string) + string_char_to_byte (string, to);
if (ascii_compatible && (to - from) == (pend - p))
return Qnil;
}
if (NILP (count))
n = 1;
else
{
CHECK_FIXNAT (count);
n = XFIXNUM (count);
}
positions = Qnil;
charset_map_loaded = 0;
while (1)
{
int c;
if (ascii_compatible)
while (p < stop && ASCII_CHAR_P (*p))
p++, from++;
if (p >= stop)
{
if (p >= pend)
break;
stop = pend;
p = GAP_END_ADDR;
}
c = string_char_advance (&p);
if (! (ASCII_CHAR_P (c) && ascii_compatible)
&& ! char_charset (translate_char (translation_table, c),
charset_list, NULL))
{
positions = Fcons (make_fixnum (from), positions);
n--;
if (n == 0)
break;
}
from++;
if (charset_map_loaded && NILP (string))
{
p = CHAR_POS_ADDR (from);
pend = CHAR_POS_ADDR (to);
if (from < GPT && to >= GPT)
stop = GPT_ADDR;
else
stop = pend;
charset_map_loaded = 0;
}
}
return (NILP (count) ? Fcar (positions) : Fnreverse (positions));
}
DEFUN ("check-coding-systems-region", Fcheck_coding_systems_region,
Scheck_coding_systems_region, 3, 3, 0,
doc: /* Check if text between START and END is encodable by CODING-SYSTEM-LIST.
START and END are buffer positions specifying the region.
CODING-SYSTEM-LIST is a list of coding systems to check.
If all coding systems in CODING-SYSTEM-LIST can encode the region, the
function returns nil.
If some of the coding systems cannot encode the whole region, value is
an alist, each element of which has the form (CODING-SYSTEM POS1 POS2 ...),
which means that CODING-SYSTEM cannot encode the text at buffer positions
POS1, POS2, ...
START may be a string. In that case, check if the string is
encodable, and the value contains character indices into the string
instead of buffer positions. END is ignored in this case.
If the current buffer (or START if it is a string) is unibyte, the value
is nil. */)
(Lisp_Object start, Lisp_Object end, Lisp_Object coding_system_list)
{
Lisp_Object list;
ptrdiff_t start_byte, end_byte;
ptrdiff_t pos;
const unsigned char *p, *pbeg, *pend;
int c;
Lisp_Object tail, elt, attrs;
if (STRINGP (start))
{
if (!STRING_MULTIBYTE (start)
|| SCHARS (start) == SBYTES (start))
return Qnil;
start_byte = 0;
end_byte = SBYTES (start);
pos = 0;
}
else
{
EMACS_INT s = fix_position (start);
EMACS_INT e = fix_position (end);
if (! (BEG <= s && s <= e && e <= Z))
args_out_of_range (start, end);
if (NILP (BVAR (current_buffer, enable_multibyte_characters)))
return Qnil;
start_byte = CHAR_TO_BYTE (s);
end_byte = CHAR_TO_BYTE (e);
if (e - s == end_byte - start_byte)
return Qnil;
if (s < GPT && GPT < e)
{
if (GPT - s < e - GPT)
move_gap_both (s, start_byte);
else
move_gap_both (e, end_byte);
}
pos = s;
}
list = Qnil;
for (tail = coding_system_list; CONSP (tail); tail = XCDR (tail))
{
elt = XCAR (tail);
Lisp_Object spec = CODING_SYSTEM_SPEC (elt);
if (!VECTORP (spec))
xsignal1 (Qcoding_system_error, elt);
attrs = AREF (spec, 0);
ASET (attrs, coding_attr_trans_tbl,
get_translation_table (attrs, 1, NULL));
list = Fcons (list2 (elt, attrs), list);
}
if (STRINGP (start))
p = pbeg = SDATA (start);
else
p = pbeg = BYTE_POS_ADDR (start_byte);
pend = p + (end_byte - start_byte);
while (p < pend && ASCII_CHAR_P (*p)) p++, pos++;
while (p < pend && ASCII_CHAR_P (*(pend - 1))) pend--;
while (p < pend)
{
if (ASCII_CHAR_P (*p))
p++;
else
{
c = string_char_advance (&p);
charset_map_loaded = 0;
for (tail = list; CONSP (tail); tail = XCDR (tail))
{
elt = XCDR (XCAR (tail));
if (! char_encodable_p (c, XCAR (elt)))
XSETCDR (elt, Fcons (make_fixnum (pos), XCDR (elt)));
}
if (charset_map_loaded)
{
ptrdiff_t p_offset = p - pbeg, pend_offset = pend - pbeg;
if (STRINGP (start))
pbeg = SDATA (start);
else
pbeg = BYTE_POS_ADDR (start_byte);
p = pbeg + p_offset;
pend = pbeg + pend_offset;
}
}
pos++;
}
tail = list;
list = Qnil;
for (; CONSP (tail); tail = XCDR (tail))
{
elt = XCAR (tail);
if (CONSP (XCDR (XCDR (elt))))
list = Fcons (Fcons (XCAR (elt), Fnreverse (XCDR (XCDR (elt)))),
list);
}
return list;
}
static Lisp_Object
code_convert_region (Lisp_Object start, Lisp_Object end,
Lisp_Object coding_system, Lisp_Object dst_object,
bool encodep, bool norecord)
{
struct coding_system coding;
ptrdiff_t from, from_byte, to, to_byte;
Lisp_Object src_object;
if (NILP (coding_system))
coding_system = Qno_conversion;
else
CHECK_CODING_SYSTEM (coding_system);
src_object = Fcurrent_buffer ();
if (NILP (dst_object))
dst_object = src_object;
else if (! EQ (dst_object, Qt))
CHECK_BUFFER (dst_object);
validate_region (&start, &end);
from = XFIXNAT (start);
from_byte = CHAR_TO_BYTE (from);
to = XFIXNAT (end);
to_byte = CHAR_TO_BYTE (to);
setup_coding_system (coding_system, &coding);
coding.mode |= CODING_MODE_LAST_BLOCK;
if (BUFFERP (dst_object) && !EQ (dst_object, src_object))
{
struct buffer *buf = XBUFFER (dst_object);
ptrdiff_t buf_pt = BUF_PT (buf);
invalidate_buffer_caches (buf, buf_pt, buf_pt);
}
if (encodep)
encode_coding_object (&coding, src_object, from, from_byte, to, to_byte,
dst_object);
else
decode_coding_object (&coding, src_object, from, from_byte, to, to_byte,
dst_object);
if (! norecord)
Vlast_coding_system_used = CODING_ID_NAME (coding.id);
return (BUFFERP (dst_object)
? make_fixnum (coding.produced_char)
: coding.dst_object);
}
DEFUN ("decode-coding-region", Fdecode_coding_region, Sdecode_coding_region,
3, 4, "r\nzCoding system: ",
doc: /* Decode the current region from the specified coding system.
What's meant by \"decoding\" is transforming bytes into text
(characters). If, for instance, you have a region that contains data
that represents the two bytes #xc2 #xa9, after calling this function
with the utf-8 coding system, the region will contain the single
character ?\\N{COPYRIGHT SIGN}.
When called from a program, takes four arguments:
START, END, CODING-SYSTEM, and DESTINATION.
START and END are buffer positions.
Optional 4th arguments DESTINATION specifies where the decoded text goes.
If nil, the region between START and END is replaced by the decoded text.
If buffer, the decoded text is inserted in that buffer after point (point
does not move). If that buffer is unibyte, it receives the individual
bytes of the internal representation of the decoded text.
In those cases, the length of the decoded text is returned.
If DESTINATION is t, the decoded text is returned.
This function sets `last-coding-system-used' to the precise coding system
used (which may be different from CODING-SYSTEM if CODING-SYSTEM is
not fully specified.) */)
(Lisp_Object start, Lisp_Object end, Lisp_Object coding_system, Lisp_Object destination)
{
return code_convert_region (start, end, coding_system, destination, 0, 0);
}
DEFUN ("encode-coding-region", Fencode_coding_region, Sencode_coding_region,
3, 4, "r\nzCoding system: ",
doc: /* Encode the current region by specified coding system.
What's meant by \"encoding\" is transforming textual data (characters)
into bytes. If, for instance, you have a region that contains the
single character ?\\N{COPYRIGHT SIGN}, after calling this function with
the utf-8 coding system, the data in the region will represent the two
bytes #xc2 #xa9.
When called from a program, takes four arguments:
START, END, CODING-SYSTEM and DESTINATION.
START and END are buffer positions.
Optional 4th argument DESTINATION specifies where the encoded text goes.
If nil, the region between START and END is replaced by the encoded text.
If buffer, the encoded text is inserted in that buffer after point (point
does not move).
In those cases, the length of the encoded text is returned.
If DESTINATION is t, the encoded text is returned.
This function sets `last-coding-system-used' to the precise coding system
used (which may be different from CODING-SYSTEM if CODING-SYSTEM is
not fully specified.) */)
(Lisp_Object start, Lisp_Object end, Lisp_Object coding_system, Lisp_Object destination)
{
return code_convert_region (start, end, coding_system, destination, 1, 0);
}
/* Whether STRING only contains chars in the 0..127 range. */
static bool
string_ascii_p (Lisp_Object string)
{
ptrdiff_t nbytes = SBYTES (string);
for (ptrdiff_t i = 0; i < nbytes; i++)
if (SREF (string, i) > 127)
return false;
return true;
}
Lisp_Object
code_convert_string (Lisp_Object string, Lisp_Object coding_system,
Lisp_Object dst_object, bool encodep, bool nocopy,
bool norecord)
{
struct coding_system coding;
ptrdiff_t chars, bytes;
CHECK_STRING (string);
if (NILP (coding_system))
{
if (! norecord)
Vlast_coding_system_used = Qno_conversion;
if (NILP (dst_object))
return nocopy ? string : Fcopy_sequence (string);
}
if (NILP (coding_system))
coding_system = Qno_conversion;
else
CHECK_CODING_SYSTEM (coding_system);
if (NILP (dst_object))
dst_object = Qt;
else if (! EQ (dst_object, Qt))
CHECK_BUFFER (dst_object);
setup_coding_system (coding_system, &coding);
coding.mode |= CODING_MODE_LAST_BLOCK;
chars = SCHARS (string);
bytes = SBYTES (string);
if (EQ (dst_object, Qt))
{
/* Fast path for ASCII-only input and an ASCII-compatible coding:
act as identity if no EOL conversion is needed. */
Lisp_Object attrs = CODING_ID_ATTRS (coding.id);
if (! NILP (CODING_ATTR_ASCII_COMPAT (attrs))
&& (STRING_MULTIBYTE (string)
? (chars == bytes) : string_ascii_p (string))
&& (EQ (CODING_ID_EOL_TYPE (coding.id), Qunix)
|| inhibit_eol_conversion
|| ! memchr (SDATA (string), encodep ? '\n' : '\r', bytes)))
{
if (! norecord)
Vlast_coding_system_used = coding_system;
return (nocopy
? string
: (encodep
? make_unibyte_string (SSDATA (string), bytes)
: make_multibyte_string (SSDATA (string), bytes, bytes)));
}
}
else if (BUFFERP (dst_object))
{
struct buffer *buf = XBUFFER (dst_object);
ptrdiff_t buf_pt = BUF_PT (buf);
invalidate_buffer_caches (buf, buf_pt, buf_pt);
}
if (encodep)
encode_coding_object (&coding, string, 0, 0, chars, bytes, dst_object);
else
decode_coding_object (&coding, string, 0, 0, chars, bytes, dst_object);
if (! norecord)
Vlast_coding_system_used = CODING_ID_NAME (coding.id);
return (BUFFERP (dst_object)
? make_fixnum (coding.produced_char)
: coding.dst_object);
}
/* Encode or decode STRING according to CODING_SYSTEM.
Do not set Vlast_coding_system_used. */
Lisp_Object
code_convert_string_norecord (Lisp_Object string, Lisp_Object coding_system,
bool encodep)
{
return code_convert_string (string, coding_system, Qt, encodep, 0, 1);
}
/* Return the gap address of BUFFER. If the gap size is less than
NBYTES, enlarge the gap in advance. */
static unsigned char *
get_buffer_gap_address (Lisp_Object buffer, ptrdiff_t nbytes)
{
struct buffer *buf = XBUFFER (buffer);
if (BUF_GPT (buf) != BUF_PT (buf))
{
struct buffer *oldb = current_buffer;
current_buffer = buf;
move_gap_both (PT, PT_BYTE);
current_buffer = oldb;
}
if (BUF_GAP_SIZE (buf) < nbytes)
make_gap_1 (buf, nbytes);
return BUF_GPT_ADDR (buf);
}
/* Return a pointer to the byte sequence for C, and its byte length in
LEN. This function is used to get a byte sequence for HANDLE_8_BIT
and HANDLE_OVER_UNI arguments of encode_string_utf_8 and
decode_string_utf_8 when those arguments are given by
characters. */
static unsigned char *
get_char_bytes (int c, int *len)
{
/* Use two caches, since encode/decode_string_utf_8 are called
repeatedly with the same values for HANDLE_8_BIT and
HANDLE_OVER_UNI arguments. */
static int chars[2];
static unsigned char bytes[2][6];
static int nbytes[2];
static int last_index;
if (chars[last_index] == c)
{
*len = nbytes[last_index];
return bytes[last_index];
}
if (chars[1 - last_index] == c)
{
*len = nbytes[1 - last_index];
return bytes[1 - last_index];
}
last_index = 1 - last_index;
chars[last_index] = c;
*len = nbytes[last_index] = CHAR_STRING (c, bytes[last_index]);
return bytes[last_index];
}
/* Encode STRING by the coding system utf-8-unix.
This function is optimized for speed when the input string is
already a valid sequence of Unicode codepoints in the internal
representation, i.e. there are neither 8-bit raw bytes nor
characters beyond the Unicode range in the string's contents.
Ignore any :pre-write-conversion and :encode-translation-table
properties.
Assume that arguments have values as described below.
The validity must be enforced and ensured by the caller.
STRING is a multibyte string or an ASCII-only unibyte string.
BUFFER is a unibyte buffer or Qnil.
If BUFFER is a unibyte buffer, insert the encoded result
after point of the buffer, and return the number of
inserted characters. The caller should have made BUFFER ready for
modifying in advance (e.g., by calling invalidate_buffer_caches).
If BUFFER is nil, return a unibyte string from the encoded result.
If NOCOPY is non-zero, and if STRING contains only Unicode
characters (i.e., the encoding does not change the byte sequence),
return STRING even if it is multibyte. WARNING: This will return a
_multibyte_ string, something that callers might not expect, especially
if STRING is not pure-ASCII; only use NOCOPY non-zero if the caller
will only use the byte sequence of the encoded result accessed by
SDATA or SSDATA, and the original STRING will _not_ be modified after
the encoding. When in doubt, always pass NOCOPY as zero. You _have_
been warned!
HANDLE-8-BIT and HANDLE-OVER-UNI specify how to handle a non-Unicode
character in STRING. The former is for an eight-bit character (represented
by a 2-byte overlong sequence in a multibyte STRING). The latter is
for a codepoint beyond the end of the Unicode range (a character whose
code is greater than the maximum Unicode character 0x10FFFF, represented
by a 4 or 5-byte sequence in a multibyte STRING).
If these two arguments are unibyte strings (typically
"\357\277\275", the UTF-8 sequence for the Unicode REPLACEMENT
CHARACTER #xFFFD), encode a non-Unicode character into that
unibyte sequence.
If the two arguments are characters, encode a non-Unicode
character as the respective argument characters.
If they are Qignored, skip a non-Unicode character.
If HANDLE-8-BIT is Qt, encode eight-bit characters into single bytes
of the same value, like the usual Emacs encoding does.
If HANDLE-OVER-UNI is Qt, encode characters beyond the Unicode
range into the same 4 or 5-byte sequence as used by Emacs
internally, like the usual Emacs encoding does.
If the two arguments are Qnil, return Qnil if STRING has a
non-Unicode character. This allows the caller to signal an error
if such input strings are not allowed. */
Lisp_Object
encode_string_utf_8 (Lisp_Object string, Lisp_Object buffer,
bool nocopy, Lisp_Object handle_8_bit,
Lisp_Object handle_over_uni)
{
ptrdiff_t nchars = SCHARS (string), nbytes = SBYTES (string);
if (NILP (buffer) && nchars == nbytes && nocopy)
/* STRING contains only ASCII characters. */
return string;
ptrdiff_t num_8_bit = 0; /* number of eight-bit chars in STRING */
/* The following two vars are counted only if handle_over_uni is not Qt. */
ptrdiff_t num_over_4 = 0; /* number of 4-byte non-Unicode chars in STRING */
ptrdiff_t num_over_5 = 0; /* number of 5-byte non-Unicode chars in STRING */
ptrdiff_t outbytes; /* number of bytes of decoding result */
unsigned char *p = SDATA (string);
unsigned char *pend = p + nbytes;
unsigned char *src = NULL, *dst = NULL;
unsigned char *replace_8_bit = NULL, *replace_over_uni = NULL;
int replace_8_bit_len = 0, replace_over_uni_len = 0;
Lisp_Object val; /* the return value */
/* Scan bytes in STRING twice. The first scan is to count non-Unicode
characters, and the second scan is to encode STRING. If the
encoding is trivial (no need of changing the byte sequence),
the second scan is avoided. */
for (int scan_count = 0; scan_count < 2; scan_count++)
{
while (p < pend)
{
if (nchars == pend - p)
/* There is no multibyte character remaining. */
break;
int c = *p;
int len = BYTES_BY_CHAR_HEAD (c);
nchars--;
if (len == 1
|| len == 3
|| (len == 2 ? ! CHAR_BYTE8_HEAD_P (c)
: (EQ (handle_over_uni, Qt)
|| (len == 4
&& STRING_CHAR (p) <= MAX_UNICODE_CHAR))))
{
p += len;
continue;
}
/* A character to change the byte sequence on encoding was
found. A rare case. */
if (len == 2)
{
/* Handle an eight-bit character by handle_8_bit. */
if (scan_count == 0)
{
if (NILP (handle_8_bit))
return Qnil;
num_8_bit++;
}
else
{
if (src < p)
{
memcpy (dst, src, p - src);
dst += p - src;
}
if (replace_8_bit_len > 0)
{
memcpy (dst, replace_8_bit, replace_8_bit_len);
dst += replace_8_bit_len;
}
else if (EQ (handle_8_bit, Qt))
{
int char8 = STRING_CHAR (p);
*dst++ = CHAR_TO_BYTE8 (char8);
}
}
}
else /* len == 4 or 5 */
{
/* Handle an over-unicode character by handle_over_uni. */
if (scan_count == 0)
{
if (NILP (handle_over_uni))
return Qnil;
if (len == 4)
num_over_4++;
else
num_over_5++;
}
else
{
if (src < p)
{
memcpy (dst, src, p - src);
dst += p - src;
}
if (replace_over_uni_len > 0)
{
memcpy (dst, replace_over_uni, replace_over_uni_len);
dst += replace_over_uni_len;
}
}
}
p += len;
src = p;
}
if (scan_count == 0)
{
/* End of the first scan. */
outbytes = nbytes;
if (num_8_bit == 0
&& (num_over_4 + num_over_5 == 0 || EQ (handle_over_uni, Qt)))
{
/* We can break the loop because there is no need of
changing the byte sequence. This is the typical
case. */
scan_count = 1;
}
else
{
/* Prepare for handling non-Unicode characters during
the next scan. */
if (num_8_bit > 0)
{
if (CHARACTERP (handle_8_bit))
replace_8_bit = get_char_bytes (XFIXNUM (handle_8_bit),
&replace_8_bit_len);
else if (STRINGP (handle_8_bit))
{
replace_8_bit = SDATA (handle_8_bit);
replace_8_bit_len = SBYTES (handle_8_bit);
}
if (replace_8_bit)
outbytes += (replace_8_bit_len - 2) * num_8_bit;
else if (EQ (handle_8_bit, Qignored))
outbytes -= 2 * num_8_bit;
else if (EQ (handle_8_bit, Qt))
outbytes -= num_8_bit;
else
return Qnil;
}
if (num_over_4 + num_over_5 > 0)
{
if (CHARACTERP (handle_over_uni))
replace_over_uni = get_char_bytes (XFIXNUM (handle_over_uni),
&replace_over_uni_len);
else if (STRINGP (handle_over_uni))
{
replace_over_uni = SDATA (handle_over_uni);
replace_over_uni_len = SBYTES (handle_over_uni);
}
if (num_over_4 > 0)
{
if (replace_over_uni)
outbytes += (replace_over_uni_len - 4) * num_over_4;
else if (EQ (handle_over_uni, Qignored))
outbytes -= 4 * num_over_4;
else if (! EQ (handle_over_uni, Qt))
return Qnil;
}
if (num_over_5 > 0)
{
if (replace_over_uni)
outbytes += (replace_over_uni_len - 5) * num_over_5;
else if (EQ (handle_over_uni, Qignored))
outbytes -= 5 * num_over_5;
else if (! EQ (handle_over_uni, Qt))
return Qnil;
}
}
}
/* Prepare return value and space to store the encoded bytes. */
if (BUFFERP (buffer))
{
val = make_fixnum (outbytes);
dst = get_buffer_gap_address (buffer, nbytes);
}
else
{
if (nocopy && (num_8_bit + num_over_4 + num_over_5) == 0)
return string;
val = make_uninit_string (outbytes);
dst = SDATA (val);
}
p = src = SDATA (string);
}
}
if (src < pend)
memcpy (dst, src, pend - src);
if (BUFFERP (buffer))
{
struct buffer *oldb = current_buffer;
current_buffer = XBUFFER (buffer);
insert_from_gap (outbytes, outbytes, false);
current_buffer = oldb;
}
return val;
}
/* Decode input string by the coding system utf-8-unix.
This function is optimized for speed when the input string is
already a valid UTF-8 sequence, i.e. there are neither 8-bit raw
bytes nor any UTF-8 sequences longer than 4 bytes in the string's
contents.
Ignore any :post-read-conversion and :decode-translation-table
properties.
Assume that arguments have values as described below.
The validity must be enforced and ensured by the caller.
STRING is a unibyte string, an ASCII-only multibyte string, or Qnil.
If STRING is Qnil, the input is a C string pointed by STR whose
length in bytes is in STR_LEN.
BUFFER is a multibyte buffer or Qnil.
If BUFFER is a multibyte buffer, insert the decoding result of
Unicode characters after point of the buffer, and return the number
of inserted characters. The caller should have made BUFFER ready
for modifying in advance (e.g., by calling invalidate_buffer_caches).
If BUFFER is Qnil, return a multibyte string from the decoded result.
NOCOPY non-zero means it is OK to return the input STRING if it
contains only ASCII characters or only valid UTF-8 sequences of 2
to 4 bytes. WARNING: This will return a _unibyte_ string, something
that callers might not expect, especially if STRING is not
pure-ASCII; only use NOCOPY non-zero if the caller will only use
the byte sequence of the decoded result accessed via SDATA or
SSDATA, and if the original STRING will _not_ be modified after the
decoding. When in doubt, always pass NOCOPY as zero. You _have_
been warned!
If STRING is Qnil, and the original string is passed via STR, NOCOPY
is ignored.
HANDLE-8-BIT and HANDLE-OVER-UNI specify how to handle a invalid
byte sequence. The former is for a 1-byte invalid sequence that
violates the fundamental UTF-8 encoding rules. The latter is for a
4 or 5-byte overlong sequences that Emacs internally uses to
represent characters beyond the Unicode range (characters whose
codepoints are greater than #x10FFFF). Note that this function does
not in general treat such overlong UTF-8 sequences as invalid.
If these two arguments are strings (typically a 1-char string of
the Unicode REPLACEMENT CHARACTER #xFFFD), decode an invalid byte
sequence into that string. They must be multibyte strings if they
contain a non-ASCII character.
If the two arguments are characters, decode an invalid byte
sequence into the corresponding multibyte representation of the
respective character.
If they are Qignored, skip an invalid byte sequence without
producing anything in the decoded string.
If HANDLE-8-BIT is Qt, decode a 1-byte invalid sequence into the
corresponding eight-bit multibyte representation, like the usual
Emacs decoding does.
If HANDLE-OVER-UNI is Qt, decode a 4 or 5-byte overlong sequence
that follows Emacs' internal representation for a character beyond
Unicode range into the corresponding character, like the usual
Emacs decoding does.
If the two arguments are Qnil, return Qnil if the input string has
raw bytes or overlong sequences. This allows the caller to signal
an error if such inputs are not allowed. */
Lisp_Object
decode_string_utf_8 (Lisp_Object string, const char *str, ptrdiff_t str_len,
Lisp_Object buffer, bool nocopy,
Lisp_Object handle_8_bit, Lisp_Object handle_over_uni)
{
/* This is like BYTES_BY_CHAR_HEAD, but it is assured that C >= 0x80
and it returns 0 for an invalid sequence. */
#define UTF_8_SEQUENCE_LENGTH(c) \
((c) < 0xC2 ? 0 \
: (c) < 0xE0 ? 2 \
: (c) < 0xF0 ? 3 \
: (c) < 0xF8 ? 4 \
: (c) == 0xF8 ? 5 \
: 0)
ptrdiff_t nbytes = STRINGP (string) ? SBYTES (string) : str_len;
unsigned char *p = STRINGP (string) ? SDATA (string) : (unsigned char *) str;
unsigned char *str_orig = p;
unsigned char *pend = p + nbytes;
ptrdiff_t num_8_bit = 0; /* number of invalid 1-byte sequences */
ptrdiff_t num_over_4 = 0; /* number of invalid 4-byte sequences */
ptrdiff_t num_over_5 = 0; /* number of invalid 5-byte sequences */
ptrdiff_t outbytes = nbytes; /* number of decoded bytes */
ptrdiff_t outchars = 0; /* number of decoded characters */
unsigned char *src = NULL, *dst = NULL;
bool change_byte_sequence = false;
/* Scan input bytes twice. The first scan is to count invalid
sequences, and the second scan is to decode input. If the
decoding is trivial (no need of changing the byte sequence),
the second scan is avoided. */
while (p < pend)
{
src = p;
/* Try short cut for an ASCII-only case. */
while (p < pend && *p < 0x80) p++;
outchars += (p - src);
if (p == pend)
break;
int c = *p;
outchars++;
int len = UTF_8_SEQUENCE_LENGTH (c);
/* len == 0, 2, 3, 4, 5. */
if (UTF_8_EXTRA_OCTET_P (p[1])
&& (len == 2
|| (UTF_8_EXTRA_OCTET_P (p[2])
&& (len == 3
|| (UTF_8_EXTRA_OCTET_P (p[3])
&& len == 4
&& STRING_CHAR (p) <= MAX_UNICODE_CHAR)))))
{
p += len;
continue;
}
/* A sequence to change on decoding was found. A rare case. */
if (len == 0)
{
if (NILP (handle_8_bit))
return Qnil;
num_8_bit++;
len = 1;
}
else /* len == 4 or 5 */
{
if (NILP (handle_over_uni))
return Qnil;
if (len == 4)
num_over_4++;
else
num_over_5++;
}
change_byte_sequence = true;
p += len;
}
Lisp_Object val; /* the return value */
if (! change_byte_sequence
&& NILP (buffer))
{
if (nocopy && STRINGP (string))
return string;
val = make_uninit_multibyte_string (outchars, outbytes);
memcpy (SDATA (val), str_orig, pend - str_orig);
return val;
}
/* Count the number of resulting chars and bytes. */
unsigned char *replace_8_bit = NULL, *replace_over_uni = NULL;
int replace_8_bit_len = 0, replace_over_uni_len = 0;
if (change_byte_sequence)
{
if (num_8_bit > 0)
{
if (CHARACTERP (handle_8_bit))
replace_8_bit = get_char_bytes (XFIXNUM (handle_8_bit),
&replace_8_bit_len);
else if (STRINGP (handle_8_bit))
{
replace_8_bit = SDATA (handle_8_bit);
replace_8_bit_len = SBYTES (handle_8_bit);
}
if (replace_8_bit)
outbytes += (replace_8_bit_len - 1) * num_8_bit;
else if (EQ (handle_8_bit, Qignored))
{
outbytes -= num_8_bit;
outchars -= num_8_bit;
}
else /* EQ (handle_8_bit, Qt)) */
outbytes += num_8_bit;
}
else if (num_over_4 + num_over_5 > 0)
{
if (CHARACTERP (handle_over_uni))
replace_over_uni = get_char_bytes (XFIXNUM (handle_over_uni),
&replace_over_uni_len);
else if (STRINGP (handle_over_uni))
{
replace_over_uni = SDATA (handle_over_uni);
replace_over_uni_len = SBYTES (handle_over_uni);
}
if (num_over_4 > 0)
{
if (replace_over_uni)
outbytes += (replace_over_uni_len - 4) * num_over_4;
else if (EQ (handle_over_uni, Qignored))
{
outbytes -= 4 * num_over_4;
outchars -= num_over_4;
}
}
if (num_over_5 > 0)
{
if (replace_over_uni)
outbytes += (replace_over_uni_len - 5) * num_over_5;
else if (EQ (handle_over_uni, Qignored))
{
outbytes -= 5 * num_over_5;
outchars -= num_over_5;
}
}
}
}
/* Prepare return value and space to store the decoded bytes. */
if (BUFFERP (buffer))
{
val = make_fixnum (outchars);
dst = get_buffer_gap_address (buffer, outbytes);
}
else
{
if (nocopy && (num_8_bit + num_over_4 + num_over_5) == 0
&& STRINGP (string))
return string;
val = make_uninit_multibyte_string (outchars, outbytes);
dst = SDATA (val);
}
src = str_orig;
if (change_byte_sequence)
{
p = src;
while (p < pend)
{
/* Try short cut for an ASCII-only case. */
/* while (p < pend && *p < 0x80) p++; */
/* if (p == pend) */
/* break; */
int c = *p;
if (c < 0x80)
{
p++;
continue;
}
int len = UTF_8_SEQUENCE_LENGTH (c);
if (len > 1)
{
int mlen;
for (mlen = 1; mlen < len && UTF_8_EXTRA_OCTET_P (p[mlen]);
mlen++);
if (mlen == len
&& (len <= 3
|| (len == 4 && STRING_CHAR (p) <= MAX_UNICODE_CHAR)
|| EQ (handle_over_uni, Qt)))
{
p += len;
continue;
}
}
if (src < p)
{
memcpy (dst, src, p - src);
dst += p - src;
}
if (len == 0)
{
if (replace_8_bit)
{
memcpy (dst, replace_8_bit, replace_8_bit_len);
dst += replace_8_bit_len;
}
else if (EQ (handle_8_bit, Qt))
{
dst += BYTE8_STRING (c, dst);
}
len = 1;
}
else /* len == 4 or 5 */
{
/* Handle p[0]... by handle_over_uni. */
if (replace_over_uni)
{
memcpy (dst, replace_over_uni, replace_over_uni_len);
dst += replace_over_uni_len;
}
}
p += len;
src = p;
}
}
if (src < pend)
memcpy (dst, src, pend - src);
if (BUFFERP (buffer))
{
struct buffer *oldb = current_buffer;
current_buffer = XBUFFER (buffer);
insert_from_gap (outchars, outbytes, false);
current_buffer = oldb;
}
return val;
}
/* #define ENABLE_UTF_8_CONVERTER_TEST */
#ifdef ENABLE_UTF_8_CONVERTER_TEST
/* These functions are useful for testing and benchmarking
encode_string_utf_8 and decode_string_utf_8. */
/* ENCODE_METHOD specifies which internal decoder to use.
If it is Qnil, use encode_string_utf_8.
Otherwise, use code_convert_string.
COUNT, if integer, specifies how many times to call those functions
with the same arguments (for benchmarking). */
DEFUN ("internal-encode-string-utf-8", Finternal_encode_string_utf_8,
Sinternal_encode_string_utf_8, 7, 7, 0,
doc: /* Internal use only.*/)
(Lisp_Object string, Lisp_Object buffer, Lisp_Object nocopy,
Lisp_Object handle_8_bit, Lisp_Object handle_over_uni,
Lisp_Object encode_method, Lisp_Object count)
{
int repeat_count;
Lisp_Object val;
/* Check arguments. Return Qnil when an argument is invalid. */
if (! STRINGP (string))
return Qnil;
if (! NILP (buffer)
&& (! BUFFERP (buffer)
|| ! NILP (BVAR (XBUFFER (buffer), enable_multibyte_characters))))
return Qnil;
if (! NILP (handle_8_bit) && ! EQ (handle_8_bit, Qt)
&& ! EQ (handle_8_bit, Qignored)
&& ! CHARACTERP (handle_8_bit)
&& (! STRINGP (handle_8_bit) || STRING_MULTIBYTE (handle_8_bit)))
return Qnil;
if (! NILP (handle_over_uni) && ! EQ (handle_over_uni, Qt)
&& ! EQ (handle_over_uni, Qignored)
&& ! CHARACTERP (handle_over_uni)
&& (! STRINGP (handle_over_uni) || STRING_MULTIBYTE (handle_over_uni)))
return Qnil;
CHECK_FIXNUM (count);
repeat_count = XFIXNUM (count);
val = Qnil;
/* Run an encoder according to ENCODE_METHOD. */
if (NILP (encode_method))
{
for (int i = 0; i < repeat_count; i++)
val = encode_string_utf_8 (string, buffer, ! NILP (nocopy),
handle_8_bit, handle_over_uni);
}
else
{
for (int i = 0; i < repeat_count; i++)
val = code_convert_string (string, Qutf_8_unix, Qnil, true,
! NILP (nocopy), true);
}
return val;
}
/* DECODE_METHOD specifies which internal decoder to use.
If it is Qnil, use decode_string_utf_8.
If it is Qt, use code_convert_string.
Otherwise, use make_string_from_utf8.
COUNT, if integer, specifies how many times to call those functions
with the same arguments (for benchmarking). */
DEFUN ("internal-decode-string-utf-8", Finternal_decode_string_utf_8,
Sinternal_decode_string_utf_8, 7, 7, 0,
doc: /* Internal use only.*/)
(Lisp_Object string, Lisp_Object buffer, Lisp_Object nocopy,
Lisp_Object handle_8_bit, Lisp_Object handle_over_uni,
Lisp_Object decode_method, Lisp_Object count)
{
int repeat_count;
Lisp_Object val;
/* Check arguments. Return Qnil when an argument is invalid. */
if (! STRINGP (string))
return Qnil;
if (! NILP (buffer)
&& (! BUFFERP (buffer)
|| NILP (BVAR (XBUFFER (buffer), enable_multibyte_characters))))
return Qnil;
if (! NILP (handle_8_bit) && ! EQ (handle_8_bit, Qt)
&& ! EQ (handle_8_bit, Qignored)
&& ! CHARACTERP (handle_8_bit)
&& (! STRINGP (handle_8_bit) || ! STRING_MULTIBYTE (handle_8_bit)))
return Qnil;
if (! NILP (handle_over_uni) && ! EQ (handle_over_uni, Qt)
&& ! EQ (handle_over_uni, Qignored)
&& ! CHARACTERP (handle_over_uni)
&& (! STRINGP (handle_over_uni) || ! STRING_MULTIBYTE (handle_over_uni)))
return Qnil;
CHECK_FIXNUM (count);
repeat_count = XFIXNUM (count);
val = Qnil;
/* Run a decoder according to DECODE_METHOD. */
if (NILP (decode_method))
{
for (int i = 0; i < repeat_count; i++)
val = decode_string_utf_8 (string, buffer, ! NILP (nocopy),
handle_8_bit, handle_over_uni);
}
else if (EQ (decode_method, Qt))
{
if (! BUFFERP (buffer))
buffer = Qt;
for (int i = 0; i < repeat_count; i++)
val = code_convert_string (string, Qutf_8_unix, buffer, false,
! NILP (nocopy), true);
}
else if (! NILP (decode_method))
{
for (int i = 0; i < repeat_count; i++)
val = make_string_from_utf8 ((char *) SDATA (string), SBYTES (string));
}
return val;
}
#endif /* ENABLE_UTF_8_CONVERTER_TEST */
/* Encode or decode STRING using CODING_SYSTEM, with the possibility of
returning STRING itself if it equals the result.
Do not set Vlast_coding_system_used. */
static Lisp_Object
convert_string_nocopy (Lisp_Object string, Lisp_Object coding_system,
bool encodep)
{
return code_convert_string (string, coding_system, Qt, encodep, 1, 1);
}
/* Encode or decode a file name, to or from a unibyte string suitable
for passing to C library functions. */
Lisp_Object
decode_file_name (Lisp_Object fname)
{
#ifdef WINDOWSNT
/* The w32 build pretends to use UTF-8 for file-name encoding, and
converts the file names either to UTF-16LE or to the system ANSI
codepage internally, depending on the underlying OS; see w32.c. */
if (! NILP (Fcoding_system_p (Qutf_8)))
return convert_string_nocopy (fname, Qutf_8, 0);
return fname;
#else /* !WINDOWSNT */
if (! NILP (Vfile_name_coding_system))
return convert_string_nocopy (fname, Vfile_name_coding_system, 0);
else if (! NILP (Vdefault_file_name_coding_system))
return convert_string_nocopy (fname, Vdefault_file_name_coding_system, 0);
else
return fname;
#endif
}
Lisp_Object
encode_file_name (Lisp_Object fname)
{
/* This is especially important during bootstrap and dumping, when
file-name encoding is not yet known, and therefore any non-ASCII
file names are unibyte strings, and could only be thrashed if we
try to encode them. */
if (!STRING_MULTIBYTE (fname))
return fname;
#ifdef WINDOWSNT
/* The w32 build pretends to use UTF-8 for file-name encoding, and
converts the file names either to UTF-16LE or to the system ANSI
codepage internally, depending on the underlying OS; see w32.c. */
if (! NILP (Fcoding_system_p (Qutf_8)))
return convert_string_nocopy (fname, Qutf_8, 1);
return fname;
#else /* !WINDOWSNT */
if (! NILP (Vfile_name_coding_system))
return convert_string_nocopy (fname, Vfile_name_coding_system, 1);
else if (! NILP (Vdefault_file_name_coding_system))
return convert_string_nocopy (fname, Vdefault_file_name_coding_system, 1);
else
return fname;
#endif
}
DEFUN ("decode-coding-string", Fdecode_coding_string, Sdecode_coding_string,
2, 4, 0,
doc: /* Decode STRING which is encoded in CODING-SYSTEM, and return the result.
Optional third arg NOCOPY non-nil means it is OK to return STRING itself
if the decoding operation is trivial.
Optional fourth arg BUFFER non-nil means that the decoded text is
inserted in that buffer after point (point does not move). In this
case, the return value is the length of the decoded text. If that
buffer is unibyte, it receives the individual bytes of the internal
representation of the decoded text.
This function sets `last-coding-system-used' to the precise coding system
used (which may be different from CODING-SYSTEM if CODING-SYSTEM is
not fully specified.) The function does not change the match data. */)
(Lisp_Object string, Lisp_Object coding_system, Lisp_Object nocopy, Lisp_Object buffer)
{
return code_convert_string (string, coding_system, buffer,
0, ! NILP (nocopy), 0);
}
DEFUN ("encode-coding-string", Fencode_coding_string, Sencode_coding_string,
2, 4, 0,
doc: /* Encode STRING to CODING-SYSTEM, and return the result.
Optional third arg NOCOPY non-nil means it is OK to return STRING
itself if the encoding operation is trivial.
Optional fourth arg BUFFER non-nil means that the encoded text is
inserted in that buffer after point (point does not move). In this
case, the return value is the length of the encoded text.
This function sets `last-coding-system-used' to the precise coding system
used (which may be different from CODING-SYSTEM if CODING-SYSTEM is
not fully specified.) The function does not change the match data. */)
(Lisp_Object string, Lisp_Object coding_system, Lisp_Object nocopy, Lisp_Object buffer)
{
return code_convert_string (string, coding_system, buffer,
1, ! NILP (nocopy), 0);
}
DEFUN ("decode-sjis-char", Fdecode_sjis_char, Sdecode_sjis_char, 1, 1, 0,
doc: /* Decode a Japanese character which has CODE in shift_jis encoding.
Return the corresponding character. */)
(Lisp_Object code)
{
Lisp_Object spec, attrs, val;
struct charset *charset_roman, *charset_kanji, *charset_kana, *charset;
EMACS_INT ch;
int c;
CHECK_FIXNAT (code);
ch = XFIXNAT (code);
CHECK_CODING_SYSTEM_GET_SPEC (Vsjis_coding_system, spec);
attrs = AREF (spec, 0);
if (ASCII_CHAR_P (ch)
&& ! NILP (CODING_ATTR_ASCII_COMPAT (attrs)))
return code;
val = CODING_ATTR_CHARSET_LIST (attrs);
charset_roman = CHARSET_FROM_ID (XFIXNUM (XCAR (val))), val = XCDR (val);
charset_kana = CHARSET_FROM_ID (XFIXNUM (XCAR (val))), val = XCDR (val);
charset_kanji = CHARSET_FROM_ID (XFIXNUM (XCAR (val)));
if (ch <= 0x7F)
{
c = ch;
charset = charset_roman;
}
else if (ch >= 0xA0 && ch < 0xDF)
{
c = ch - 0x80;
charset = charset_kana;
}
else
{
EMACS_INT c1 = ch >> 8;
int c2 = ch & 0xFF;
if (c1 < 0x81 || (c1 > 0x9F && c1 < 0xE0) || c1 > 0xEF
|| c2 < 0x40 || c2 == 0x7F || c2 > 0xFC)
error ("Invalid code: %"pI"d", ch);
c = ch;
SJIS_TO_JIS (c);
charset = charset_kanji;
}
c = DECODE_CHAR (charset, c);
if (c < 0)
error ("Invalid code: %"pI"d", ch);
return make_fixnum (c);
}
DEFUN ("encode-sjis-char", Fencode_sjis_char, Sencode_sjis_char, 1, 1, 0,
doc: /* Encode a Japanese character CH to shift_jis encoding.
Return the corresponding code in SJIS. */)
(Lisp_Object ch)
{
Lisp_Object spec, attrs, charset_list;
int c;
struct charset *charset;
unsigned code;
CHECK_CHARACTER (ch);
c = XFIXNAT (ch);
CHECK_CODING_SYSTEM_GET_SPEC (Vsjis_coding_system, spec);
attrs = AREF (spec, 0);
if (ASCII_CHAR_P (c)
&& ! NILP (CODING_ATTR_ASCII_COMPAT (attrs)))
return ch;
charset_list = CODING_ATTR_CHARSET_LIST (attrs);
charset = char_charset (c, charset_list, &code);
if (code == CHARSET_INVALID_CODE (charset))
error ("Can't encode by shift_jis encoding: %c", c);
JIS_TO_SJIS (code);
return make_fixnum (code);
}
DEFUN ("decode-big5-char", Fdecode_big5_char, Sdecode_big5_char, 1, 1, 0,
doc: /* Decode a Big5 character which has CODE in BIG5 coding system.
Return the corresponding character. */)
(Lisp_Object code)
{
Lisp_Object spec, attrs, val;
struct charset *charset_roman, *charset_big5, *charset;
EMACS_INT ch;
int c;
CHECK_FIXNAT (code);
ch = XFIXNAT (code);
CHECK_CODING_SYSTEM_GET_SPEC (Vbig5_coding_system, spec);
attrs = AREF (spec, 0);
if (ASCII_CHAR_P (ch)
&& ! NILP (CODING_ATTR_ASCII_COMPAT (attrs)))
return code;
val = CODING_ATTR_CHARSET_LIST (attrs);
charset_roman = CHARSET_FROM_ID (XFIXNUM (XCAR (val))), val = XCDR (val);
charset_big5 = CHARSET_FROM_ID (XFIXNUM (XCAR (val)));
if (ch <= 0x7F)
{
c = ch;
charset = charset_roman;
}
else
{
EMACS_INT b1 = ch >> 8;
int b2 = ch & 0x7F;
if (b1 < 0xA1 || b1 > 0xFE
|| b2 < 0x40 || (b2 > 0x7E && b2 < 0xA1) || b2 > 0xFE)
error ("Invalid code: %"pI"d", ch);
c = ch;
charset = charset_big5;
}
c = DECODE_CHAR (charset, c);
if (c < 0)
error ("Invalid code: %"pI"d", ch);
return make_fixnum (c);
}
DEFUN ("encode-big5-char", Fencode_big5_char, Sencode_big5_char, 1, 1, 0,
doc: /* Encode the Big5 character CH to BIG5 coding system.
Return the corresponding character code in Big5. */)
(Lisp_Object ch)
{
Lisp_Object spec, attrs, charset_list;
struct charset *charset;
int c;
unsigned code;
CHECK_CHARACTER (ch);
c = XFIXNAT (ch);
CHECK_CODING_SYSTEM_GET_SPEC (Vbig5_coding_system, spec);
attrs = AREF (spec, 0);
if (ASCII_CHAR_P (c)
&& ! NILP (CODING_ATTR_ASCII_COMPAT (attrs)))
return ch;
charset_list = CODING_ATTR_CHARSET_LIST (attrs);
charset = char_charset (c, charset_list, &code);
if (code == CHARSET_INVALID_CODE (charset))
error ("Can't encode by Big5 encoding: %c", c);
return make_fixnum (code);
}
DEFUN ("set-terminal-coding-system-internal", Fset_terminal_coding_system_internal,
Sset_terminal_coding_system_internal, 1, 2, 0,
doc: /* Internal use only. */)
(Lisp_Object coding_system, Lisp_Object terminal)
{
struct terminal *term = decode_live_terminal (terminal);
struct coding_system *terminal_coding = TERMINAL_TERMINAL_CODING (term);
CHECK_SYMBOL (coding_system);
setup_coding_system (Fcheck_coding_system (coding_system), terminal_coding);
/* We had better not send unsafe characters to terminal. */
terminal_coding->mode |= CODING_MODE_SAFE_ENCODING;
/* Character composition should be disabled. */
terminal_coding->common_flags &= ~CODING_ANNOTATE_COMPOSITION_MASK;
terminal_coding->src_multibyte = 1;
terminal_coding->dst_multibyte = 0;
tset_charset_list
(term, (terminal_coding->common_flags & CODING_REQUIRE_ENCODING_MASK
? coding_charset_list (terminal_coding)
: list1i (charset_ascii)));
return Qnil;
}
DEFUN ("set-safe-terminal-coding-system-internal",
Fset_safe_terminal_coding_system_internal,
Sset_safe_terminal_coding_system_internal, 1, 1, 0,
doc: /* Internal use only. */)
(Lisp_Object coding_system)
{
CHECK_SYMBOL (coding_system);
setup_coding_system (Fcheck_coding_system (coding_system),
&safe_terminal_coding);
/* Character composition should be disabled. */
safe_terminal_coding.common_flags &= ~CODING_ANNOTATE_COMPOSITION_MASK;
safe_terminal_coding.src_multibyte = 1;
safe_terminal_coding.dst_multibyte = 0;
return Qnil;
}
DEFUN ("terminal-coding-system", Fterminal_coding_system,
Sterminal_coding_system, 0, 1, 0,
doc: /* Return coding system specified for terminal output on the given terminal.
TERMINAL may be a terminal object, a frame, or nil for the selected
frame's terminal device. */)
(Lisp_Object terminal)
{
struct coding_system *terminal_coding
= TERMINAL_TERMINAL_CODING (decode_live_terminal (terminal));
Lisp_Object coding_system = CODING_ID_NAME (terminal_coding->id);
/* For backward compatibility, return nil if it is `undecided'. */
return (! EQ (coding_system, Qundecided) ? coding_system : Qnil);
}
DEFUN ("set-keyboard-coding-system-internal", Fset_keyboard_coding_system_internal,
Sset_keyboard_coding_system_internal, 1, 2, 0,
doc: /* Internal use only. */)
(Lisp_Object coding_system, Lisp_Object terminal)
{
struct terminal *t = decode_live_terminal (terminal);
CHECK_SYMBOL (coding_system);
if (NILP (coding_system))
coding_system = Qno_conversion;
else
Fcheck_coding_system (coding_system);
setup_coding_system (coding_system, TERMINAL_KEYBOARD_CODING (t));
/* Character composition should be disabled. */
TERMINAL_KEYBOARD_CODING (t)->common_flags
&= ~CODING_ANNOTATE_COMPOSITION_MASK;
return Qnil;
}
DEFUN ("keyboard-coding-system",
Fkeyboard_coding_system, Skeyboard_coding_system, 0, 1, 0,
doc: /* Return coding system specified for decoding keyboard input. */)
(Lisp_Object terminal)
{
return CODING_ID_NAME (TERMINAL_KEYBOARD_CODING
(decode_live_terminal (terminal))->id);
}
DEFUN ("find-operation-coding-system", Ffind_operation_coding_system,
Sfind_operation_coding_system, 1, MANY, 0,
doc: /* Choose a coding system for an operation based on the target name.
The value names a pair of coding systems: (DECODING-SYSTEM . ENCODING-SYSTEM).
DECODING-SYSTEM is the coding system to use for decoding
\(in case OPERATION does decoding), and ENCODING-SYSTEM is the coding system
for encoding (in case OPERATION does encoding).
The first argument OPERATION specifies an I/O primitive:
For file I/O, `insert-file-contents' or `write-region'.
For process I/O, `call-process', `call-process-region', or `start-process'.
For network I/O, `open-network-stream'.
The remaining arguments should be the same arguments that were passed
to the primitive. Depending on which primitive, one of those arguments
is selected as the TARGET. For example, if OPERATION does file I/O,
whichever argument specifies the file name is TARGET.
TARGET has a meaning which depends on OPERATION:
For file I/O, TARGET is a file name (except for the special case below).
For process I/O, TARGET is a process name.
For network I/O, TARGET is a service name or a port number.
This function looks up what is specified for TARGET in
`file-coding-system-alist', `process-coding-system-alist',
or `network-coding-system-alist' depending on OPERATION.
They may specify a coding system, a cons of coding systems,
or a function symbol to call.
In the last case, we call the function with one argument,
which is a list of all the arguments given to this function.
If the function can't decide a coding system, it can return
`undecided' so that the normal code-detection is performed.
If OPERATION is `insert-file-contents', the argument corresponding to
TARGET may be a cons (FILENAME . BUFFER). In that case, FILENAME is a
file name to look up, and BUFFER is a buffer that contains the file's
contents (not yet decoded). If `file-coding-system-alist' specifies a
function to call for FILENAME, that function should examine the
contents of BUFFER instead of reading the file.
usage: (find-operation-coding-system OPERATION ARGUMENTS...) */)
(ptrdiff_t nargs, Lisp_Object *args)
{
Lisp_Object operation, target_idx, target, val;
register Lisp_Object chain;
if (nargs < 2)
error ("Too few arguments");
operation = args[0];
if (!SYMBOLP (operation)
|| (target_idx = Fget (operation, Qtarget_idx), !FIXNATP (target_idx)))
error ("Invalid first argument");
if (nargs <= 1 + XFIXNAT (target_idx))
error ("Too few arguments for operation `%s'",
SDATA (SYMBOL_NAME (operation)));
target = args[XFIXNAT (target_idx) + 1];
if (!(STRINGP (target)
|| (EQ (operation, Qinsert_file_contents) && CONSP (target)
&& STRINGP (XCAR (target)) && BUFFERP (XCDR (target)))
|| (EQ (operation, Qopen_network_stream)
&& (FIXNUMP (target) || EQ (target, Qt)))))
error ("Invalid argument %"pI"d of operation `%s'",
XFIXNAT (target_idx) + 1, SDATA (SYMBOL_NAME (operation)));
if (CONSP (target))
target = XCAR (target);
chain = ((EQ (operation, Qinsert_file_contents)
|| EQ (operation, Qwrite_region))
? Vfile_coding_system_alist
: (EQ (operation, Qopen_network_stream)
? Vnetwork_coding_system_alist
: Vprocess_coding_system_alist));
if (NILP (chain))
return Qnil;
for (; CONSP (chain); chain = XCDR (chain))
{
Lisp_Object elt;
elt = XCAR (chain);
if (CONSP (elt)
&& ((STRINGP (target)
&& STRINGP (XCAR (elt))
&& fast_string_match (XCAR (elt), target) >= 0)
|| (FIXNUMP (target) && EQ (target, XCAR (elt)))))
{
val = XCDR (elt);
/* Here, if VAL is both a valid coding system and a valid
function symbol, we return VAL as a coding system. */
if (CONSP (val))
return val;
if (! SYMBOLP (val))
return Qnil;
if (! NILP (Fcoding_system_p (val)))
return Fcons (val, val);
if (! NILP (Ffboundp (val)))
{
/* We use call1 rather than safe_call1
so as to get bug reports about functions called here
which don't handle the current interface. */
val = call1 (val, Flist (nargs, args));
if (CONSP (val))
return val;
if (SYMBOLP (val) && ! NILP (Fcoding_system_p (val)))
return Fcons (val, val);
}
return Qnil;
}
}
return Qnil;
}
DEFUN ("set-coding-system-priority", Fset_coding_system_priority,
Sset_coding_system_priority, 0, MANY, 0,
doc: /* Assign higher priority to the coding systems given as arguments.
If multiple coding systems belong to the same category,
all but the first one are ignored.
usage: (set-coding-system-priority &rest coding-systems) */)
(ptrdiff_t nargs, Lisp_Object *args)
{
ptrdiff_t i, j;
bool changed[coding_category_max];
enum coding_category priorities[coding_category_max];
memset (changed, 0, sizeof changed);
for (i = j = 0; i < nargs; i++)
{
enum coding_category category;
Lisp_Object spec, attrs;
CHECK_CODING_SYSTEM_GET_SPEC (args[i], spec);
attrs = AREF (spec, 0);
category = XFIXNUM (CODING_ATTR_CATEGORY (attrs));
if (changed[category])
/* Ignore this coding system because a coding system of the
same category already had a higher priority. */
continue;
changed[category] = 1;
priorities[j++] = category;
if (coding_categories[category].id >= 0
&& ! EQ (args[i], CODING_ID_NAME (coding_categories[category].id)))
setup_coding_system (args[i], &coding_categories[category]);
Fset (AREF (Vcoding_category_table, category), args[i]);
}
/* Now we have decided top J priorities. Reflect the order of the
original priorities to the remaining priorities. */
for (i = j, j = 0; i < coding_category_max; i++, j++)
{
while (j < coding_category_max
&& changed[coding_priorities[j]])
j++;
if (j == coding_category_max)
emacs_abort ();
priorities[i] = coding_priorities[j];
}
memcpy (coding_priorities, priorities, sizeof priorities);
/* Update `coding-category-list'. */
Vcoding_category_list = Qnil;
for (i = coding_category_max; i-- > 0; )
Vcoding_category_list
= Fcons (AREF (Vcoding_category_table, priorities[i]),
Vcoding_category_list);
return Qnil;
}
DEFUN ("coding-system-priority-list", Fcoding_system_priority_list,
Scoding_system_priority_list, 0, 1, 0,
doc: /* Return a list of coding systems ordered by their priorities.
The list contains a subset of coding systems; i.e. coding systems
assigned to each coding category (see `coding-category-list').
HIGHESTP non-nil means just return the highest priority one. */)
(Lisp_Object highestp)
{
int i;
Lisp_Object val;
for (i = 0, val = Qnil; i < coding_category_max; i++)
{
enum coding_category category = coding_priorities[i];
int id = coding_categories[category].id;
Lisp_Object attrs;
if (id < 0)
continue;
attrs = CODING_ID_ATTRS (id);
if (! NILP (highestp))
return CODING_ATTR_BASE_NAME (attrs);
val = Fcons (CODING_ATTR_BASE_NAME (attrs), val);
}
return Fnreverse (val);
}
static const char *const suffixes[] = { "-unix", "-dos", "-mac" };
static Lisp_Object
make_subsidiaries (Lisp_Object base)
{
Lisp_Object subsidiaries;
ptrdiff_t base_name_len = SBYTES (SYMBOL_NAME (base));
USE_SAFE_ALLOCA;
char *buf = SAFE_ALLOCA (base_name_len + 6);
int i;
memcpy (buf, SDATA (SYMBOL_NAME (base)), base_name_len);
subsidiaries = make_uninit_vector (3);
for (i = 0; i < 3; i++)
{
strcpy (buf + base_name_len, suffixes[i]);
ASET (subsidiaries, i, intern (buf));
}
SAFE_FREE ();
return subsidiaries;
}
DEFUN ("define-coding-system-internal", Fdefine_coding_system_internal,
Sdefine_coding_system_internal, coding_arg_max, MANY, 0,
doc: /* For internal use only.
usage: (define-coding-system-internal ...) */)
(ptrdiff_t nargs, Lisp_Object *args)
{
enum coding_category category;
int max_charset_id = 0;
if (nargs < coding_arg_max)
goto short_args;
Lisp_Object attrs = make_nil_vector (coding_attr_last_index);
Lisp_Object name = args[coding_arg_name];
CHECK_SYMBOL (name);
ASET (attrs, coding_attr_base_name, name);
Lisp_Object val = args[coding_arg_mnemonic];
if (! STRINGP (val))
CHECK_CHARACTER (val);
ASET (attrs, coding_attr_mnemonic, val);
Lisp_Object coding_type = args[coding_arg_coding_type];
CHECK_SYMBOL (coding_type);
ASET (attrs, coding_attr_type, coding_type);
Lisp_Object charset_list = args[coding_arg_charset_list];
if (SYMBOLP (charset_list))
{
if (EQ (charset_list, Qiso_2022))
{
if (! EQ (coding_type, Qiso_2022))
error ("Invalid charset-list");
charset_list = Viso_2022_charset_list;
}
else if (EQ (charset_list, Qemacs_mule))
{
if (! EQ (coding_type, Qemacs_mule))
error ("Invalid charset-list");
charset_list = Vemacs_mule_charset_list;
}
for (Lisp_Object tail = charset_list; CONSP (tail); tail = XCDR (tail))
{
if (! RANGED_FIXNUMP (0, XCAR (tail), INT_MAX - 1))
error ("Invalid charset-list");
if (max_charset_id < XFIXNAT (XCAR (tail)))
max_charset_id = XFIXNAT (XCAR (tail));
}
}
else
{
charset_list = Fcopy_sequence (charset_list);
for (Lisp_Object tail = charset_list; CONSP (tail); tail = XCDR (tail))
{
struct charset *charset;
val = XCAR (tail);
CHECK_CHARSET_GET_CHARSET (val, charset);
if (EQ (coding_type, Qiso_2022)
? CHARSET_ISO_FINAL (charset) < 0
: EQ (coding_type, Qemacs_mule)
? CHARSET_EMACS_MULE_ID (charset) < 0
: 0)
error ("Can't handle charset `%s'",
SDATA (SYMBOL_NAME (CHARSET_NAME (charset))));
XSETCAR (tail, make_fixnum (charset->id));
if (max_charset_id < charset->id)
max_charset_id = charset->id;
}
}
ASET (attrs, coding_attr_charset_list, charset_list);
Lisp_Object safe_charsets = make_uninit_string (max_charset_id + 1);
memset (SDATA (safe_charsets), 255, max_charset_id + 1);
for (Lisp_Object tail = charset_list; CONSP (tail); tail = XCDR (tail))
SSET (safe_charsets, XFIXNAT (XCAR (tail)), 0);
ASET (attrs, coding_attr_safe_charsets, safe_charsets);
ASET (attrs, coding_attr_ascii_compat, args[coding_arg_ascii_compatible_p]);
val = args[coding_arg_decode_translation_table];
if (! CHAR_TABLE_P (val) && ! CONSP (val))
CHECK_SYMBOL (val);
ASET (attrs, coding_attr_decode_tbl, val);
val = args[coding_arg_encode_translation_table];
if (! CHAR_TABLE_P (val) && ! CONSP (val))
CHECK_SYMBOL (val);
ASET (attrs, coding_attr_encode_tbl, val);
val = args[coding_arg_post_read_conversion];
CHECK_SYMBOL (val);
ASET (attrs, coding_attr_post_read, val);
val = args[coding_arg_pre_write_conversion];
CHECK_SYMBOL (val);
ASET (attrs, coding_attr_pre_write, val);
val = args[coding_arg_default_char];
if (NILP (val))
ASET (attrs, coding_attr_default_char, make_fixnum (' '));
else
{
CHECK_CHARACTER (val);
ASET (attrs, coding_attr_default_char, val);
}
val = args[coding_arg_for_unibyte];
ASET (attrs, coding_attr_for_unibyte, NILP (val) ? Qnil : Qt);
val = args[coding_arg_plist];
CHECK_LIST (val);
ASET (attrs, coding_attr_plist, val);
if (EQ (coding_type, Qcharset))
{
/* Generate a lisp vector of 256 elements. Each element is nil,
integer, or a list of charset IDs.
If Nth element is nil, the byte code N is invalid in this
coding system.
If Nth element is a number NUM, N is the first byte of a
charset whose ID is NUM.
If Nth element is a list of charset IDs, N is the first byte
of one of them. The list is sorted by dimensions of the
charsets. A charset of smaller dimension comes first. */
val = make_nil_vector (256);
for (Lisp_Object tail = charset_list; CONSP (tail); tail = XCDR (tail))
{
struct charset *charset = CHARSET_FROM_ID (XFIXNAT (XCAR (tail)));
int dim = CHARSET_DIMENSION (charset);
int idx = (dim - 1) * 4;
if (CHARSET_ASCII_COMPATIBLE_P (charset))
ASET (attrs, coding_attr_ascii_compat, Qt);
for (int i = charset->code_space[idx];
i <= charset->code_space[idx + 1]; i++)
{
Lisp_Object tmp, tmp2;
int dim2;
tmp = AREF (val, i);
if (NILP (tmp))
tmp = XCAR (tail);
else if (FIXNATP (tmp))
{
dim2 = CHARSET_DIMENSION (CHARSET_FROM_ID (XFIXNAT (tmp)));
if (dim < dim2)
tmp = list2 (XCAR (tail), tmp);
else
tmp = list2 (tmp, XCAR (tail));
}
else
{
for (tmp2 = tmp; CONSP (tmp2); tmp2 = XCDR (tmp2))
{
dim2 = CHARSET_DIMENSION (CHARSET_FROM_ID (XFIXNAT (XCAR (tmp2))));
if (dim < dim2)
break;
}
if (NILP (tmp2))
tmp = nconc2 (tmp, list1 (XCAR (tail)));
else
{
XSETCDR (tmp2, Fcons (XCAR (tmp2), XCDR (tmp2)));
XSETCAR (tmp2, XCAR (tail));
}
}
ASET (val, i, tmp);
}
}
ASET (attrs, coding_attr_charset_valids, val);
category = coding_category_charset;
}
else if (EQ (coding_type, Qccl))
{
Lisp_Object valids;
if (nargs < coding_arg_ccl_max)
goto short_args;
val = args[coding_arg_ccl_decoder];
CHECK_CCL_PROGRAM (val);
if (VECTORP (val))
val = Fcopy_sequence (val);
ASET (attrs, coding_attr_ccl_decoder, val);
val = args[coding_arg_ccl_encoder];
CHECK_CCL_PROGRAM (val);
if (VECTORP (val))
val = Fcopy_sequence (val);
ASET (attrs, coding_attr_ccl_encoder, val);
val = args[coding_arg_ccl_valids];
valids = Fmake_string (make_fixnum (256), make_fixnum (0), Qnil);
for (Lisp_Object tail = val; CONSP (tail); tail = XCDR (tail))
{
int from, to;
val = XCAR (tail);
if (FIXNUMP (val))
{
if (! (0 <= XFIXNUM (val) && XFIXNUM (val) <= 255))
args_out_of_range_3 (val, make_fixnum (0), make_fixnum (255));
from = to = XFIXNUM (val);
}
else
{
CHECK_CONS (val);
from = check_integer_range (XCAR (val), 0, 255);
to = check_integer_range (XCDR (val), from, 255);
}
for (int i = from; i <= to; i++)
SSET (valids, i, 1);
}
ASET (attrs, coding_attr_ccl_valids, valids);
category = coding_category_ccl;
}
else if (EQ (coding_type, Qutf_16))
{
Lisp_Object bom, endian;
ASET (attrs, coding_attr_ascii_compat, Qnil);
if (nargs < coding_arg_utf16_max)
goto short_args;
bom = args[coding_arg_utf16_bom];
if (! NILP (bom) && ! EQ (bom, Qt))
{
CHECK_CONS (bom);
val = XCAR (bom);
CHECK_CODING_SYSTEM (val);
val = XCDR (bom);
CHECK_CODING_SYSTEM (val);
}
ASET (attrs, coding_attr_utf_bom, bom);
endian = args[coding_arg_utf16_endian];
CHECK_SYMBOL (endian);
if (NILP (endian))
endian = Qbig;
else if (! EQ (endian, Qbig) && ! EQ (endian, Qlittle))
error ("Invalid endian: %s", SDATA (SYMBOL_NAME (endian)));
ASET (attrs, coding_attr_utf_16_endian, endian);
category = (CONSP (bom)
? coding_category_utf_16_auto
: NILP (bom)
? (EQ (endian, Qbig)
? coding_category_utf_16_be_nosig
: coding_category_utf_16_le_nosig)
: (EQ (endian, Qbig)
? coding_category_utf_16_be
: coding_category_utf_16_le));
}
else if (EQ (coding_type, Qiso_2022))
{
Lisp_Object initial, reg_usage, request, flags;
if (nargs < coding_arg_iso2022_max)
goto short_args;
initial = Fcopy_sequence (args[coding_arg_iso2022_initial]);
CHECK_VECTOR (initial);
for (int i = 0; i < 4; i++)
{
val = AREF (initial, i);
if (! NILP (val))
{
struct charset *charset;
CHECK_CHARSET_GET_CHARSET (val, charset);
ASET (initial, i, make_fixnum (CHARSET_ID (charset)));
if (i == 0 && CHARSET_ASCII_COMPATIBLE_P (charset))
ASET (attrs, coding_attr_ascii_compat, Qt);
}
else
ASET (initial, i, make_fixnum (-1));
}
reg_usage = args[coding_arg_iso2022_reg_usage];
CHECK_CONS (reg_usage);
CHECK_FIXNUM (XCAR (reg_usage));
CHECK_FIXNUM (XCDR (reg_usage));
request = Fcopy_sequence (args[coding_arg_iso2022_request]);
for (Lisp_Object tail = request; CONSP (tail); tail = XCDR (tail))
{
int id;
val = XCAR (tail);
CHECK_CONS (val);
CHECK_CHARSET_GET_ID (XCAR (val), id);
check_integer_range (XCDR (val), 0, 3);
XSETCAR (val, make_fixnum (id));
}
flags = args[coding_arg_iso2022_flags];
CHECK_FIXNAT (flags);
int i = XFIXNUM (flags) & INT_MAX;
if (EQ (args[coding_arg_charset_list], Qiso_2022))
i |= CODING_ISO_FLAG_FULL_SUPPORT;
flags = make_fixnum (i);
ASET (attrs, coding_attr_iso_initial, initial);
ASET (attrs, coding_attr_iso_usage, reg_usage);
ASET (attrs, coding_attr_iso_request, request);
ASET (attrs, coding_attr_iso_flags, flags);
setup_iso_safe_charsets (attrs);
if (i & CODING_ISO_FLAG_SEVEN_BITS)
category = ((i & (CODING_ISO_FLAG_LOCKING_SHIFT
| CODING_ISO_FLAG_SINGLE_SHIFT))
? coding_category_iso_7_else
: EQ (args[coding_arg_charset_list], Qiso_2022)
? coding_category_iso_7
: coding_category_iso_7_tight);
else
{
int id = XFIXNUM (AREF (initial, 1));
category = (((i & CODING_ISO_FLAG_LOCKING_SHIFT)
|| EQ (args[coding_arg_charset_list], Qiso_2022)
|| id < 0)
? coding_category_iso_8_else
: (CHARSET_DIMENSION (CHARSET_FROM_ID (id)) == 1)
? coding_category_iso_8_1
: coding_category_iso_8_2);
}
if (category != coding_category_iso_8_1
&& category != coding_category_iso_8_2)
ASET (attrs, coding_attr_ascii_compat, Qnil);
}
else if (EQ (coding_type, Qemacs_mule))
{
if (EQ (args[coding_arg_charset_list], Qemacs_mule))
ASET (attrs, coding_attr_emacs_mule_full, Qt);
ASET (attrs, coding_attr_ascii_compat, Qt);
category = coding_category_emacs_mule;
}
else if (EQ (coding_type, Qshift_jis))
{
ptrdiff_t charset_list_len = list_length (charset_list);
if (charset_list_len != 3 && charset_list_len != 4)
error ("There should be three or four charsets");
struct charset *charset = CHARSET_FROM_ID (XFIXNUM (XCAR (charset_list)));
if (CHARSET_DIMENSION (charset) != 1)
error ("Dimension of charset %s is not one",
SDATA (SYMBOL_NAME (CHARSET_NAME (charset))));
if (CHARSET_ASCII_COMPATIBLE_P (charset))
ASET (attrs, coding_attr_ascii_compat, Qt);
charset_list = XCDR (charset_list);
charset = CHARSET_FROM_ID (XFIXNUM (XCAR (charset_list)));
if (CHARSET_DIMENSION (charset) != 1)
error ("Dimension of charset %s is not one",
SDATA (SYMBOL_NAME (CHARSET_NAME (charset))));
charset_list = XCDR (charset_list);
charset = CHARSET_FROM_ID (XFIXNUM (XCAR (charset_list)));
if (CHARSET_DIMENSION (charset) != 2)
error ("Dimension of charset %s is not two",
SDATA (SYMBOL_NAME (CHARSET_NAME (charset))));
charset_list = XCDR (charset_list);
if (! NILP (charset_list))
{
charset = CHARSET_FROM_ID (XFIXNUM (XCAR (charset_list)));
if (CHARSET_DIMENSION (charset) != 2)
error ("Dimension of charset %s is not two",
SDATA (SYMBOL_NAME (CHARSET_NAME (charset))));
}
category = coding_category_sjis;
Vsjis_coding_system = name;
}
else if (EQ (coding_type, Qbig5))
{
struct charset *charset;
if (list_length (charset_list) != 2)
error ("There should be just two charsets");
charset = CHARSET_FROM_ID (XFIXNUM (XCAR (charset_list)));
if (CHARSET_DIMENSION (charset) != 1)
error ("Dimension of charset %s is not one",
SDATA (SYMBOL_NAME (CHARSET_NAME (charset))));
if (CHARSET_ASCII_COMPATIBLE_P (charset))
ASET (attrs, coding_attr_ascii_compat, Qt);
charset_list = XCDR (charset_list);
charset = CHARSET_FROM_ID (XFIXNUM (XCAR (charset_list)));
if (CHARSET_DIMENSION (charset) != 2)
error ("Dimension of charset %s is not two",
SDATA (SYMBOL_NAME (CHARSET_NAME (charset))));
category = coding_category_big5;
Vbig5_coding_system = name;
}
else if (EQ (coding_type, Qraw_text))
{
category = coding_category_raw_text;
ASET (attrs, coding_attr_ascii_compat, Qt);
}
else if (EQ (coding_type, Qutf_8))
{
Lisp_Object bom;
if (nargs < coding_arg_utf8_max)
goto short_args;
bom = args[coding_arg_utf8_bom];
if (! NILP (bom) && ! EQ (bom, Qt))
{
CHECK_CONS (bom);
val = XCAR (bom);
CHECK_CODING_SYSTEM (val);
val = XCDR (bom);
CHECK_CODING_SYSTEM (val);
}
ASET (attrs, coding_attr_utf_bom, bom);
if (NILP (bom))
ASET (attrs, coding_attr_ascii_compat, Qt);
category = (CONSP (bom) ? coding_category_utf_8_auto
: NILP (bom) ? coding_category_utf_8_nosig
: coding_category_utf_8_sig);
}
else if (EQ (coding_type, Qundecided))
{
if (nargs < coding_arg_undecided_max)
goto short_args;
ASET (attrs, coding_attr_undecided_inhibit_nul_byte_detection,
args[coding_arg_undecided_inhibit_nul_byte_detection]);
ASET (attrs, coding_attr_undecided_inhibit_iso_escape_detection,
args[coding_arg_undecided_inhibit_iso_escape_detection]);
ASET (attrs, coding_attr_undecided_prefer_utf_8,
args[coding_arg_undecided_prefer_utf_8]);
category = coding_category_undecided;
}
else
error ("Invalid coding system type: %s",
SDATA (SYMBOL_NAME (coding_type)));
ASET (attrs, coding_attr_category, make_fixnum (category));
ASET (attrs, coding_attr_plist,
Fcons (QCcategory,
Fcons (AREF (Vcoding_category_table, category),
CODING_ATTR_PLIST (attrs))));
ASET (attrs, coding_attr_plist,
Fcons (QCascii_compatible_p,
Fcons (CODING_ATTR_ASCII_COMPAT (attrs),
CODING_ATTR_PLIST (attrs))));
Lisp_Object eol_type = args[coding_arg_eol_type];
if (! NILP (eol_type)
&& ! EQ (eol_type, Qunix)
&& ! EQ (eol_type, Qdos)
&& ! EQ (eol_type, Qmac))
error ("Invalid eol-type");
Lisp_Object aliases = list1 (name);
if (NILP (eol_type))
{
eol_type = make_subsidiaries (name);
for (int i = 0; i < 3; i++)
{
Lisp_Object this_spec, this_name, this_aliases, this_eol_type;
this_name = AREF (eol_type, i);
this_aliases = list1 (this_name);
this_eol_type = (i == 0 ? Qunix : i == 1 ? Qdos : Qmac);
this_spec = make_uninit_vector (3);
ASET (this_spec, 0, attrs);
ASET (this_spec, 1, this_aliases);
ASET (this_spec, 2, this_eol_type);
Fputhash (this_name, this_spec, Vcoding_system_hash_table);
Vcoding_system_list = Fcons (this_name, Vcoding_system_list);
val = Fassoc (Fsymbol_name (this_name), Vcoding_system_alist, Qnil);
if (NILP (val))
Vcoding_system_alist
= Fcons (Fcons (Fsymbol_name (this_name), Qnil),
Vcoding_system_alist);
}
}
Lisp_Object spec_vec = make_uninit_vector (3);
ASET (spec_vec, 0, attrs);
ASET (spec_vec, 1, aliases);
ASET (spec_vec, 2, eol_type);
Fputhash (name, spec_vec, Vcoding_system_hash_table);
Vcoding_system_list = Fcons (name, Vcoding_system_list);
val = Fassoc (Fsymbol_name (name), Vcoding_system_alist, Qnil);
if (NILP (val))
Vcoding_system_alist = Fcons (Fcons (Fsymbol_name (name), Qnil),
Vcoding_system_alist);
int id = coding_categories[category].id;
if (id < 0 || EQ (name, CODING_ID_NAME (id)))
setup_coding_system (name, &coding_categories[category]);
return Qnil;
short_args:
Fsignal (Qwrong_number_of_arguments,
Fcons (intern ("define-coding-system-internal"),
make_fixnum (nargs)));
}
DEFUN ("coding-system-put", Fcoding_system_put, Scoding_system_put,
3, 3, 0,
doc: /* Change value in CODING-SYSTEM's property list PROP to VAL. */)
(Lisp_Object coding_system, Lisp_Object prop, Lisp_Object val)
{
Lisp_Object spec, attrs;
CHECK_CODING_SYSTEM_GET_SPEC (coding_system, spec);
attrs = AREF (spec, 0);
if (EQ (prop, QCmnemonic))
{
if (! STRINGP (val))
CHECK_CHARACTER (val);
ASET (attrs, coding_attr_mnemonic, val);
}
else if (EQ (prop, QCdefault_char))
{
if (NILP (val))
val = make_fixnum (' ');
else
CHECK_CHARACTER (val);
ASET (attrs, coding_attr_default_char, val);
}
else if (EQ (prop, QCdecode_translation_table))
{
if (! CHAR_TABLE_P (val) && ! CONSP (val))
CHECK_SYMBOL (val);
ASET (attrs, coding_attr_decode_tbl, val);
}
else if (EQ (prop, QCencode_translation_table))
{
if (! CHAR_TABLE_P (val) && ! CONSP (val))
CHECK_SYMBOL (val);
ASET (attrs, coding_attr_encode_tbl, val);
}
else if (EQ (prop, QCpost_read_conversion))
{
CHECK_SYMBOL (val);
ASET (attrs, coding_attr_post_read, val);
}
else if (EQ (prop, QCpre_write_conversion))
{
CHECK_SYMBOL (val);
ASET (attrs, coding_attr_pre_write, val);
}
else if (EQ (prop, QCascii_compatible_p))
{
ASET (attrs, coding_attr_ascii_compat, val);
}
ASET (attrs, coding_attr_plist,
Fplist_put (CODING_ATTR_PLIST (attrs), prop, val));
return val;
}
DEFUN ("define-coding-system-alias", Fdefine_coding_system_alias,
Sdefine_coding_system_alias, 2, 2, 0,
doc: /* Define ALIAS as an alias for CODING-SYSTEM. */)
(Lisp_Object alias, Lisp_Object coding_system)
{
Lisp_Object spec, aliases, eol_type, val;
CHECK_SYMBOL (alias);
CHECK_CODING_SYSTEM_GET_SPEC (coding_system, spec);
aliases = AREF (spec, 1);
/* ALIASES should be a list of length more than zero, and the first
element is a base coding system. Append ALIAS at the tail of the
list. */
while (!NILP (XCDR (aliases)))
aliases = XCDR (aliases);
XSETCDR (aliases, list1 (alias));
eol_type = AREF (spec, 2);
if (VECTORP (eol_type))
{
Lisp_Object subsidiaries;
int i;
subsidiaries = make_subsidiaries (alias);
for (i = 0; i < 3; i++)
Fdefine_coding_system_alias (AREF (subsidiaries, i),
AREF (eol_type, i));
}
Fputhash (alias, spec, Vcoding_system_hash_table);
Vcoding_system_list = Fcons (alias, Vcoding_system_list);
val = Fassoc (Fsymbol_name (alias), Vcoding_system_alist, Qnil);
if (NILP (val))
Vcoding_system_alist = Fcons (Fcons (Fsymbol_name (alias), Qnil),
Vcoding_system_alist);
return Qnil;
}
DEFUN ("coding-system-base", Fcoding_system_base, Scoding_system_base,
1, 1, 0,
doc: /* Return the base of CODING-SYSTEM.
Any alias or subsidiary coding system is not a base coding system. */)
(Lisp_Object coding_system)
{
Lisp_Object spec, attrs;
if (NILP (coding_system))
return (Qno_conversion);
CHECK_CODING_SYSTEM_GET_SPEC (coding_system, spec);
attrs = AREF (spec, 0);
return CODING_ATTR_BASE_NAME (attrs);
}
DEFUN ("coding-system-plist", Fcoding_system_plist, Scoding_system_plist,
1, 1, 0,
doc: /* Return the property list of CODING-SYSTEM. */)
(Lisp_Object coding_system)
{
Lisp_Object spec, attrs;
if (NILP (coding_system))
coding_system = Qno_conversion;
CHECK_CODING_SYSTEM_GET_SPEC (coding_system, spec);
attrs = AREF (spec, 0);
return CODING_ATTR_PLIST (attrs);
}
DEFUN ("coding-system-aliases", Fcoding_system_aliases, Scoding_system_aliases,
1, 1, 0,
doc: /* Return the list of aliases of CODING-SYSTEM. */)
(Lisp_Object coding_system)
{
Lisp_Object spec;
if (NILP (coding_system))
coding_system = Qno_conversion;
CHECK_CODING_SYSTEM_GET_SPEC (coding_system, spec);
return AREF (spec, 1);
}
DEFUN ("coding-system-eol-type", Fcoding_system_eol_type,
Scoding_system_eol_type, 1, 1, 0,
doc: /* Return eol-type of CODING-SYSTEM.
An eol-type is an integer 0, 1, 2, or a vector of coding systems.
Integer values 0, 1, and 2 indicate a format of end-of-line; LF, CRLF,
and CR respectively.
A vector value indicates that a format of end-of-line should be
detected automatically. Nth element of the vector is the subsidiary
coding system whose eol-type is N. */)
(Lisp_Object coding_system)
{
Lisp_Object spec, eol_type;
int n;
if (NILP (coding_system))
coding_system = Qno_conversion;
if (! CODING_SYSTEM_P (coding_system))
return Qnil;
spec = CODING_SYSTEM_SPEC (coding_system);
eol_type = AREF (spec, 2);
if (VECTORP (eol_type))
return Fcopy_sequence (eol_type);
n = EQ (eol_type, Qunix) ? 0 : EQ (eol_type, Qdos) ? 1 : 2;
return make_fixnum (n);
}
/*** 9. Post-amble ***/
void
init_coding_once (void)
{
int i;
for (i = 0; i < coding_category_max; i++)
{
coding_categories[i].id = -1;
coding_priorities[i] = i;
}
PDUMPER_REMEMBER_SCALAR (coding_categories);
PDUMPER_REMEMBER_SCALAR (coding_priorities);
/* ISO2022 specific initialize routine. */
for (i = 0; i < 0x20; i++)
iso_code_class[i] = ISO_control_0;
for (i = 0x21; i < 0x7F; i++)
iso_code_class[i] = ISO_graphic_plane_0;
for (i = 0x80; i < 0xA0; i++)
iso_code_class[i] = ISO_control_1;
for (i = 0xA1; i < 0xFF; i++)
iso_code_class[i] = ISO_graphic_plane_1;
iso_code_class[0x20] = iso_code_class[0x7F] = ISO_0x20_or_0x7F;
iso_code_class[0xA0] = iso_code_class[0xFF] = ISO_0xA0_or_0xFF;
iso_code_class[ISO_CODE_SO] = ISO_shift_out;
iso_code_class[ISO_CODE_SI] = ISO_shift_in;
iso_code_class[ISO_CODE_SS2_7] = ISO_single_shift_2_7;
iso_code_class[ISO_CODE_ESC] = ISO_escape;
iso_code_class[ISO_CODE_SS2] = ISO_single_shift_2;
iso_code_class[ISO_CODE_SS3] = ISO_single_shift_3;
iso_code_class[ISO_CODE_CSI] = ISO_control_sequence_introducer;
PDUMPER_REMEMBER_SCALAR (iso_code_class);
for (i = 0; i < 256; i++)
{
emacs_mule_bytes[i] = 1;
}
emacs_mule_bytes[EMACS_MULE_LEADING_CODE_PRIVATE_11] = 3;
emacs_mule_bytes[EMACS_MULE_LEADING_CODE_PRIVATE_12] = 3;
emacs_mule_bytes[EMACS_MULE_LEADING_CODE_PRIVATE_21] = 4;
emacs_mule_bytes[EMACS_MULE_LEADING_CODE_PRIVATE_22] = 4;
PDUMPER_REMEMBER_SCALAR (emacs_mule_bytes);
}
static void reset_coding_after_pdumper_load (void);
void
syms_of_coding (void)
{
staticpro (&Vcoding_system_hash_table);
Vcoding_system_hash_table = CALLN (Fmake_hash_table, QCtest, Qeq);
staticpro (&Vsjis_coding_system);
Vsjis_coding_system = Qnil;
staticpro (&Vbig5_coding_system);
Vbig5_coding_system = Qnil;
staticpro (&Vcode_conversion_reused_workbuf);
Vcode_conversion_reused_workbuf = Qnil;
staticpro (&Vcode_conversion_workbuf_name);
Vcode_conversion_workbuf_name = build_pure_c_string (" *code-conversion-work*");
reused_workbuf_in_use = 0;
PDUMPER_REMEMBER_SCALAR (reused_workbuf_in_use);
DEFSYM (Qcharset, "charset");
DEFSYM (Qtarget_idx, "target-idx");
DEFSYM (Qcoding_system_history, "coding-system-history");
Fset (Qcoding_system_history, Qnil);
/* Target FILENAME is the first argument. */
Fput (Qinsert_file_contents, Qtarget_idx, make_fixnum (0));
/* Target FILENAME is the third argument. */
Fput (Qwrite_region, Qtarget_idx, make_fixnum (2));
DEFSYM (Qcall_process, "call-process");
/* Target PROGRAM is the first argument. */
Fput (Qcall_process, Qtarget_idx, make_fixnum (0));
DEFSYM (Qcall_process_region, "call-process-region");
/* Target PROGRAM is the third argument. */
Fput (Qcall_process_region, Qtarget_idx, make_fixnum (2));
DEFSYM (Qstart_process, "start-process");
/* Target PROGRAM is the third argument. */
Fput (Qstart_process, Qtarget_idx, make_fixnum (2));
DEFSYM (Qopen_network_stream, "open-network-stream");
/* Target SERVICE is the fourth argument. */
Fput (Qopen_network_stream, Qtarget_idx, make_fixnum (3));
DEFSYM (Qunix, "unix");
DEFSYM (Qdos, "dos");
DEFSYM (Qmac, "mac");
DEFSYM (Qbuffer_file_coding_system, "buffer-file-coding-system");
DEFSYM (Qundecided, "undecided");
DEFSYM (Qno_conversion, "no-conversion");
DEFSYM (Qraw_text, "raw-text");
DEFSYM (Qus_ascii, "us-ascii");
DEFSYM (Qiso_2022, "iso-2022");
DEFSYM (Qutf_8, "utf-8");
DEFSYM (Qutf_8_unix, "utf-8-unix");
DEFSYM (Qutf_8_emacs, "utf-8-emacs");
#if defined (WINDOWSNT) || defined (CYGWIN)
/* No, not utf-16-le: that one has a BOM. */
DEFSYM (Qutf_16le, "utf-16le");
#endif
DEFSYM (Qutf_16, "utf-16");
DEFSYM (Qbig, "big");
DEFSYM (Qlittle, "little");
DEFSYM (Qshift_jis, "shift-jis");
DEFSYM (Qbig5, "big5");
DEFSYM (Qcoding_system_p, "coding-system-p");
/* Error signaled when there's a problem with detecting a coding system. */
DEFSYM (Qcoding_system_error, "coding-system-error");
Fput (Qcoding_system_error, Qerror_conditions,
pure_list (Qcoding_system_error, Qerror));
Fput (Qcoding_system_error, Qerror_message,
build_pure_c_string ("Invalid coding system"));
DEFSYM (Qtranslation_table, "translation-table");
Fput (Qtranslation_table, Qchar_table_extra_slots, make_fixnum (2));
DEFSYM (Qtranslation_table_id, "translation-table-id");
/* Coding system emacs-mule and raw-text are for converting only
end-of-line format. */
DEFSYM (Qemacs_mule, "emacs-mule");
DEFSYM (QCcategory, ":category");
DEFSYM (QCmnemonic, ":mnemonic");
DEFSYM (QCdefault_char, ":default-char");
DEFSYM (QCdecode_translation_table, ":decode-translation-table");
DEFSYM (QCencode_translation_table, ":encode-translation-table");
DEFSYM (QCpost_read_conversion, ":post-read-conversion");
DEFSYM (QCpre_write_conversion, ":pre-write-conversion");
DEFSYM (QCascii_compatible_p, ":ascii-compatible-p");
Vcoding_category_table = make_nil_vector (coding_category_max);
staticpro (&Vcoding_category_table);
/* Followings are target of code detection. */
ASET (Vcoding_category_table, coding_category_iso_7,
intern_c_string ("coding-category-iso-7"));
ASET (Vcoding_category_table, coding_category_iso_7_tight,
intern_c_string ("coding-category-iso-7-tight"));
ASET (Vcoding_category_table, coding_category_iso_8_1,
intern_c_string ("coding-category-iso-8-1"));
ASET (Vcoding_category_table, coding_category_iso_8_2,
intern_c_string ("coding-category-iso-8-2"));
ASET (Vcoding_category_table, coding_category_iso_7_else,
intern_c_string ("coding-category-iso-7-else"));
ASET (Vcoding_category_table, coding_category_iso_8_else,
intern_c_string ("coding-category-iso-8-else"));
ASET (Vcoding_category_table, coding_category_utf_8_auto,
intern_c_string ("coding-category-utf-8-auto"));
ASET (Vcoding_category_table, coding_category_utf_8_nosig,
intern_c_string ("coding-category-utf-8"));
ASET (Vcoding_category_table, coding_category_utf_8_sig,
intern_c_string ("coding-category-utf-8-sig"));
ASET (Vcoding_category_table, coding_category_utf_16_be,
intern_c_string ("coding-category-utf-16-be"));
ASET (Vcoding_category_table, coding_category_utf_16_auto,
intern_c_string ("coding-category-utf-16-auto"));
ASET (Vcoding_category_table, coding_category_utf_16_le,
intern_c_string ("coding-category-utf-16-le"));
ASET (Vcoding_category_table, coding_category_utf_16_be_nosig,
intern_c_string ("coding-category-utf-16-be-nosig"));
ASET (Vcoding_category_table, coding_category_utf_16_le_nosig,
intern_c_string ("coding-category-utf-16-le-nosig"));
ASET (Vcoding_category_table, coding_category_charset,
intern_c_string ("coding-category-charset"));
ASET (Vcoding_category_table, coding_category_sjis,
intern_c_string ("coding-category-sjis"));
ASET (Vcoding_category_table, coding_category_big5,
intern_c_string ("coding-category-big5"));
ASET (Vcoding_category_table, coding_category_ccl,
intern_c_string ("coding-category-ccl"));
ASET (Vcoding_category_table, coding_category_emacs_mule,
intern_c_string ("coding-category-emacs-mule"));
/* Followings are NOT target of code detection. */
ASET (Vcoding_category_table, coding_category_raw_text,
intern_c_string ("coding-category-raw-text"));
ASET (Vcoding_category_table, coding_category_undecided,
intern_c_string ("coding-category-undecided"));
DEFSYM (Qinsufficient_source, "insufficient-source");
DEFSYM (Qinvalid_source, "invalid-source");
DEFSYM (Qinterrupted, "interrupted");
/* If a symbol has this property, evaluate the value to define the
symbol as a coding system. */
DEFSYM (Qcoding_system_define_form, "coding-system-define-form");
DEFSYM (Qignored, "ignored");
DEFSYM (Qutf_8_string_p, "utf-8-string-p");
defsubr (&Scoding_system_p);
defsubr (&Sread_coding_system);
defsubr (&Sread_non_nil_coding_system);
defsubr (&Scheck_coding_system);
defsubr (&Sdetect_coding_region);
defsubr (&Sdetect_coding_string);
defsubr (&Sfind_coding_systems_region_internal);
defsubr (&Sunencodable_char_position);
defsubr (&Scheck_coding_systems_region);
defsubr (&Sdecode_coding_region);
defsubr (&Sencode_coding_region);
defsubr (&Sdecode_coding_string);
defsubr (&Sencode_coding_string);
#ifdef ENABLE_UTF_8_CONVERTER_TEST
defsubr (&Sinternal_encode_string_utf_8);
defsubr (&Sinternal_decode_string_utf_8);
#endif /* ENABLE_UTF_8_CONVERTER_TEST */
defsubr (&Sdecode_sjis_char);
defsubr (&Sencode_sjis_char);
defsubr (&Sdecode_big5_char);
defsubr (&Sencode_big5_char);
defsubr (&Sset_terminal_coding_system_internal);
defsubr (&Sset_safe_terminal_coding_system_internal);
defsubr (&Sterminal_coding_system);
defsubr (&Sset_keyboard_coding_system_internal);
defsubr (&Skeyboard_coding_system);
defsubr (&Sfind_operation_coding_system);
defsubr (&Sset_coding_system_priority);
defsubr (&Sdefine_coding_system_internal);
defsubr (&Sdefine_coding_system_alias);
defsubr (&Scoding_system_put);
defsubr (&Scoding_system_base);
defsubr (&Scoding_system_plist);
defsubr (&Scoding_system_aliases);
defsubr (&Scoding_system_eol_type);
defsubr (&Scoding_system_priority_list);
DEFVAR_LISP ("coding-system-list", Vcoding_system_list,
doc: /* List of coding systems.
Do not alter the value of this variable manually. This variable should be
updated by the functions `define-coding-system' and
`define-coding-system-alias'. */);
Vcoding_system_list = Qnil;
DEFVAR_LISP ("coding-system-alist", Vcoding_system_alist,
doc: /* Alist of coding system names.
Each element is one element list of coding system name.
This variable is given to `completing-read' as COLLECTION argument.
Do not alter the value of this variable manually. This variable should be
updated by `define-coding-system-alias'. */);
Vcoding_system_alist = Qnil;
DEFVAR_LISP ("coding-category-list", Vcoding_category_list,
doc: /* List of coding-categories (symbols) ordered by priority.
On detecting a coding system, Emacs tries code detection algorithms
associated with each coding-category one by one in this order. When
one algorithm agrees with a byte sequence of source text, the coding
system bound to the corresponding coding-category is selected.
Don't modify this variable directly, but use `set-coding-system-priority'. */);
{
int i;
Vcoding_category_list = Qnil;
for (i = coding_category_max - 1; i >= 0; i--)
Vcoding_category_list
= Fcons (AREF (Vcoding_category_table, i),
Vcoding_category_list);
}
DEFVAR_LISP ("coding-system-for-read", Vcoding_system_for_read,
doc: /* Specify the coding system for read operations.
It is useful to bind this variable with `let', but do not set it globally.
If the value is a coding system, it is used for decoding on read operation.
If not, an appropriate element is used from one of the coding system alists.
There are three such tables: `file-coding-system-alist',
`process-coding-system-alist', and `network-coding-system-alist'. */);
Vcoding_system_for_read = Qnil;
DEFVAR_LISP ("coding-system-for-write", Vcoding_system_for_write,
doc: /* Specify the coding system for write operations.
Programs bind this variable with `let', but you should not set it globally.
If the value is a coding system, it is used for encoding of output,
when writing it to a file and when sending it to a file or subprocess.
If this does not specify a coding system, an appropriate element
is used from one of the coding system alists.
There are three such tables: `file-coding-system-alist',
`process-coding-system-alist', and `network-coding-system-alist'.
For output to files, if the above procedure does not specify a coding system,
the value of `buffer-file-coding-system' is used. */);
Vcoding_system_for_write = Qnil;
DEFVAR_LISP ("last-coding-system-used", Vlast_coding_system_used,
doc: /*
Coding system used in the latest file or process I/O. */);
Vlast_coding_system_used = Qnil;
DEFVAR_LISP ("last-code-conversion-error", Vlast_code_conversion_error,
doc: /*
Error status of the last code conversion.
When an error was detected in the last code conversion, this variable
is set to one of the following symbols.
`insufficient-source'
`inconsistent-eol'
`invalid-source'
`interrupted'
`insufficient-memory'
When no error was detected, the value doesn't change. So, to check
the error status of a code conversion by this variable, you must
explicitly set this variable to nil before performing code
conversion. */);
Vlast_code_conversion_error = Qnil;
DEFVAR_BOOL ("inhibit-eol-conversion", inhibit_eol_conversion,
doc: /*
Non-nil means always inhibit code conversion of end-of-line format.
See info node `Coding Systems' and info node `Text and Binary' concerning
such conversion. */);
inhibit_eol_conversion = 0;
DEFVAR_BOOL ("inherit-process-coding-system", inherit_process_coding_system,
doc: /*
Non-nil means process buffer inherits coding system of process output.
Bind it to t if the process output is to be treated as if it were a file
read from some filesystem. */);
inherit_process_coding_system = 0;
DEFVAR_LISP ("file-coding-system-alist", Vfile_coding_system_alist,
doc: /*
Alist to decide a coding system to use for a file I/O operation.
The format is ((PATTERN . VAL) ...),
where PATTERN is a regular expression matching a file name,
VAL is a coding system, a cons of coding systems, or a function symbol.
If VAL is a coding system, it is used for both decoding and encoding
the file contents.
If VAL is a cons of coding systems, the car part is used for decoding,
and the cdr part is used for encoding.
If VAL is a function symbol, the function must return a coding system
or a cons of coding systems which are used as above. The function is
called with an argument that is a list of the arguments with which
`find-operation-coding-system' was called. If the function can't decide
a coding system, it can return `undecided' so that the normal
code-detection is performed.
See also the function `find-operation-coding-system'
and the variable `auto-coding-alist'. */);
Vfile_coding_system_alist = Qnil;
DEFVAR_LISP ("process-coding-system-alist", Vprocess_coding_system_alist,
doc: /*
Alist to decide a coding system to use for a process I/O operation.
The format is ((PATTERN . VAL) ...),
where PATTERN is a regular expression matching a program name,
VAL is a coding system, a cons of coding systems, or a function symbol.
If VAL is a coding system, it is used for both decoding what received
from the program and encoding what sent to the program.
If VAL is a cons of coding systems, the car part is used for decoding,
and the cdr part is used for encoding.
If VAL is a function symbol, the function must return a coding system
or a cons of coding systems which are used as above.
See also the function `find-operation-coding-system'. */);
Vprocess_coding_system_alist = Qnil;
DEFVAR_LISP ("network-coding-system-alist", Vnetwork_coding_system_alist,
doc: /*
Alist to decide a coding system to use for a network I/O operation.
The format is ((PATTERN . VAL) ...),
where PATTERN is a regular expression matching a network service name
or is a port number to connect to,
VAL is a coding system, a cons of coding systems, or a function symbol.
If VAL is a coding system, it is used for both decoding what received
from the network stream and encoding what sent to the network stream.
If VAL is a cons of coding systems, the car part is used for decoding,
and the cdr part is used for encoding.
If VAL is a function symbol, the function must return a coding system
or a cons of coding systems which are used as above.
See also the function `find-operation-coding-system'. */);
Vnetwork_coding_system_alist = Qnil;
DEFVAR_LISP ("locale-coding-system", Vlocale_coding_system,
doc: /* Coding system to use with system messages.
Also used for decoding keyboard input on X Window system, and for
encoding standard output and error streams. */);
Vlocale_coding_system = Qnil;
/* The eol mnemonics are reset in startup.el system-dependently. */
DEFVAR_LISP ("eol-mnemonic-unix", eol_mnemonic_unix,
doc: /*
String displayed in mode line for UNIX-like (LF) end-of-line format. */);
eol_mnemonic_unix = build_pure_c_string (":");
DEFVAR_LISP ("eol-mnemonic-dos", eol_mnemonic_dos,
doc: /*
String displayed in mode line for DOS-like (CRLF) end-of-line format. */);
eol_mnemonic_dos = build_pure_c_string ("\\");
DEFVAR_LISP ("eol-mnemonic-mac", eol_mnemonic_mac,
doc: /*
String displayed in mode line for MAC-like (CR) end-of-line format. */);
eol_mnemonic_mac = build_pure_c_string ("/");
DEFVAR_LISP ("eol-mnemonic-undecided", eol_mnemonic_undecided,
doc: /*
String displayed in mode line when end-of-line format is not yet determined. */);
eol_mnemonic_undecided = build_pure_c_string (":");
DEFVAR_LISP ("enable-character-translation", Venable_character_translation,
doc: /*
Non-nil enables character translation while encoding and decoding. */);
Venable_character_translation = Qt;
DEFVAR_LISP ("standard-translation-table-for-decode",
Vstandard_translation_table_for_decode,
doc: /* Table for translating characters while decoding. */);
Vstandard_translation_table_for_decode = Qnil;
DEFVAR_LISP ("standard-translation-table-for-encode",
Vstandard_translation_table_for_encode,
doc: /* Table for translating characters while encoding. */);
Vstandard_translation_table_for_encode = Qnil;
DEFVAR_LISP ("charset-revision-table", Vcharset_revision_table,
doc: /* Alist of charsets vs revision numbers.
While encoding, if a charset (car part of an element) is found,
designate it with the escape sequence identifying revision (cdr part
of the element). */);
Vcharset_revision_table = Qnil;
DEFVAR_LISP ("default-process-coding-system",
Vdefault_process_coding_system,
doc: /* Cons of coding systems used for process I/O by default.
The car part is used for decoding a process output,
the cdr part is used for encoding a text to be sent to a process. */);
Vdefault_process_coding_system = Qnil;
DEFVAR_LISP ("latin-extra-code-table", Vlatin_extra_code_table,
doc: /*
Table of extra Latin codes in the range 128..159 (inclusive).
This is a vector of length 256.
If Nth element is non-nil, the existence of code N in a file
\(or output of subprocess) doesn't prevent it to be detected as
a coding system of ISO 2022 variant which has a flag
`accept-latin-extra-code' t (e.g. iso-latin-1) on reading a file
or reading output of a subprocess.
Only 128th through 159th elements have a meaning. */);
Vlatin_extra_code_table = make_nil_vector (256);
DEFVAR_LISP ("select-safe-coding-system-function",
Vselect_safe_coding_system_function,
doc: /*
Function to call to select safe coding system for encoding a text.
If set, this function is called to force a user to select a proper
coding system which can encode the text in the case that a default
coding system used in each operation can't encode the text. The
function should take care that the buffer is not modified while
the coding system is being selected.
The default value is `select-safe-coding-system' (which see). */);
Vselect_safe_coding_system_function = Qnil;
DEFVAR_BOOL ("coding-system-require-warning",
coding_system_require_warning,
doc: /* Internal use only.
If non-nil, on writing a file, `select-safe-coding-system-function' is
called even if `coding-system-for-write' is non-nil. The command
`universal-coding-system-argument' binds this variable to t temporarily. */);
coding_system_require_warning = 0;
DEFVAR_BOOL ("inhibit-iso-escape-detection",
inhibit_iso_escape_detection,
doc: /*
If non-nil, Emacs ignores ISO-2022 escape sequences during code detection.
When Emacs reads text, it tries to detect how the text is encoded.
This code detection is sensitive to escape sequences. If Emacs sees
a valid ISO-2022 escape sequence, it assumes the text is encoded in one
of the ISO2022 encodings, and decodes text by the corresponding coding
system (e.g. `iso-2022-7bit').
However, there may be a case that you want to read escape sequences in
a file as is. In such a case, you can set this variable to non-nil.
Then the code detection will ignore any escape sequences, and no text is
detected as encoded in some ISO-2022 encoding. The result is that all
escape sequences become visible in a buffer.
The default value is nil, and it is strongly recommended not to change
it. That is because many Emacs Lisp source files that contain
non-ASCII characters are encoded by the coding system `iso-2022-7bit'
in Emacs's distribution, and they won't be decoded correctly on
reading if you suppress escape sequence detection.
The other way to read escape sequences in a file without decoding is
to explicitly specify some coding system that doesn't use ISO-2022
escape sequence (e.g., `latin-1') on reading by \\[universal-coding-system-argument]. */);
inhibit_iso_escape_detection = 0;
DEFVAR_BOOL ("inhibit-nul-byte-detection",
inhibit_nul_byte_detection,
doc: /* If non-nil, Emacs ignores NUL bytes on code detection.
By default, Emacs treats it as binary data, and does not attempt to
decode it. The effect is as if you specified `no-conversion' for
reading that text.
Set this to non-nil when a regular text happens to include NUL bytes.
Examples are Index nodes of Info files and NUL-byte delimited output
from GNU Find and GNU Grep. Emacs will then ignore the NUL bytes and
decode text as usual. */);
inhibit_nul_byte_detection = 0;
DEFVAR_BOOL ("disable-ascii-optimization", disable_ascii_optimization,
doc: /* If non-nil, Emacs does not optimize code decoder for ASCII files.
Internal use only. Remove after the experimental optimizer becomes stable. */);
disable_ascii_optimization = 0;
DEFVAR_LISP ("translation-table-for-input", Vtranslation_table_for_input,
doc: /* Char table for translating self-inserting characters.
This is applied to the result of input methods, not their input.
See also `keyboard-translate-table'.
Use of this variable for character code unification was rendered
obsolete in Emacs 23.1 and later, since Unicode is now the basis of
internal character representation. */);
Vtranslation_table_for_input = Qnil;
Lisp_Object args[coding_arg_undecided_max];
memclear (args, sizeof args);
Lisp_Object plist[] =
{
QCname,
args[coding_arg_name] = Qno_conversion,
QCmnemonic,
args[coding_arg_mnemonic] = make_fixnum ('='),
intern_c_string (":coding-type"),
args[coding_arg_coding_type] = Qraw_text,
QCascii_compatible_p,
args[coding_arg_ascii_compatible_p] = Qt,
QCdefault_char,
args[coding_arg_default_char] = make_fixnum (0),
intern_c_string (":for-unibyte"),
args[coding_arg_for_unibyte] = Qt,
intern_c_string (":docstring"),
(build_pure_c_string
("Do no conversion.\n"
"\n"
"When you visit a file with this coding, the file is read into a\n"
"unibyte buffer as is, thus each byte of a file is treated as a\n"
"character.")),
intern_c_string (":eol-type"),
args[coding_arg_eol_type] = Qunix,
};
args[coding_arg_plist] = CALLMANY (Flist, plist);
Fdefine_coding_system_internal (coding_arg_max, args);
plist[1] = args[coding_arg_name] = Qundecided;
plist[3] = args[coding_arg_mnemonic] = make_fixnum ('-');
plist[5] = args[coding_arg_coding_type] = Qundecided;
/* This is already set.
plist[7] = args[coding_arg_ascii_compatible_p] = Qt; */
plist[8] = intern_c_string (":charset-list");
plist[9] = args[coding_arg_charset_list] = list1 (Qascii);
plist[11] = args[coding_arg_for_unibyte] = Qnil;
plist[13] = build_pure_c_string ("No conversion on encoding, "
"automatic conversion on decoding.");
plist[15] = args[coding_arg_eol_type] = Qnil;
args[coding_arg_plist] = CALLMANY (Flist, plist);
args[coding_arg_undecided_inhibit_nul_byte_detection] = make_fixnum (0);
args[coding_arg_undecided_inhibit_iso_escape_detection] = make_fixnum (0);
Fdefine_coding_system_internal (coding_arg_undecided_max, args);
setup_coding_system (Qno_conversion, &safe_terminal_coding);
for (int i = 0; i < coding_category_max; i++)
Fset (AREF (Vcoding_category_table, i), Qno_conversion);
pdumper_do_now_and_after_load (reset_coding_after_pdumper_load);
}
static void
reset_coding_after_pdumper_load (void)
{
if (!dumped_with_pdumper_p ())
return;
for (struct coding_system *this = &coding_categories[0];
this < &coding_categories[coding_category_max];
++this)
{
int id = this->id;
if (id >= 0)
{
/* Need to rebuild the coding system object because we
persisted it as a scalar and it's full of gunk that's now
invalid. */
memset (this, 0, sizeof (*this));
setup_coding_system (CODING_ID_NAME (id), this);
}
}
/* In temacs the below is done by mule-conf.el, because we need to
define us-ascii first. But in dumped Emacs us-ascii is restored
by the above loop, and mule-conf.el will not be loaded, so we set
it up now; otherwise safe_terminal_coding will remain zeroed. */
Fset_safe_terminal_coding_system_internal (Qus_ascii);
}