/* Basic character support.
Copyright (C) 2001-2018 Free Software Foundation, Inc.
Copyright (C) 1995, 1997, 1998, 2001 Electrotechnical Laboratory, JAPAN.
Licensed to the Free Software Foundation.
Copyright (C) 2003, 2004, 2005, 2006, 2007, 2008, 2009, 2010, 2011
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 . */
/* At first, see the document in `character.h' to understand the code
in this file. */
#include
#include
#include
#include
#include "lisp.h"
#include "character.h"
#include "buffer.h"
#include "composite.h"
#include "disptab.h"
/* Char-table of information about which character to unify to which
Unicode character. Mainly used by the macro MAYBE_UNIFY_CHAR. */
Lisp_Object Vchar_unify_table;
/* If character code C has modifier masks, reflect them to the
character code if possible. Return the resulting code. */
EMACS_INT
char_resolve_modifier_mask (EMACS_INT c)
{
/* A non-ASCII character can't reflect modifier bits to the code. */
if (! ASCII_CHAR_P ((c & ~CHAR_MODIFIER_MASK)))
return c;
/* For Meta, Shift, and Control modifiers, we need special care. */
if (c & CHAR_SHIFT)
{
/* Shift modifier is valid only with [A-Za-z]. */
if ((c & 0377) >= 'A' && (c & 0377) <= 'Z')
c &= ~CHAR_SHIFT;
else if ((c & 0377) >= 'a' && (c & 0377) <= 'z')
c = (c & ~CHAR_SHIFT) - ('a' - 'A');
/* Shift modifier for control characters and SPC is ignored. */
else if ((c & ~CHAR_MODIFIER_MASK) <= 0x20)
c &= ~CHAR_SHIFT;
}
if (c & CHAR_CTL)
{
/* Simulate the code in lread.c. */
/* Allow `\C- ' and `\C-?'. */
if ((c & 0377) == ' ')
c &= ~0177 & ~ CHAR_CTL;
else if ((c & 0377) == '?')
c = 0177 | (c & ~0177 & ~CHAR_CTL);
/* ASCII control chars are made from letters (both cases),
as well as the non-letters within 0100...0137. */
else if ((c & 0137) >= 0101 && (c & 0137) <= 0132)
c &= (037 | (~0177 & ~CHAR_CTL));
else if ((c & 0177) >= 0100 && (c & 0177) <= 0137)
c &= (037 | (~0177 & ~CHAR_CTL));
}
#if 0 /* This is outside the scope of this function. (bug#4751) */
if (c & CHAR_META)
{
/* Move the meta bit to the right place for a string. */
c = (c & ~CHAR_META) | 0x80;
}
#endif
return c;
}
/* Store multibyte form of character C at P. If C has modifier bits,
handle them appropriately. */
int
char_string (unsigned int c, unsigned char *p)
{
int bytes;
if (c & CHAR_MODIFIER_MASK)
{
c = char_resolve_modifier_mask (c);
/* If C still has any modifier bits, just ignore it. */
c &= ~CHAR_MODIFIER_MASK;
}
if (c <= MAX_3_BYTE_CHAR)
{
bytes = CHAR_STRING (c, p);
}
else if (c <= MAX_4_BYTE_CHAR)
{
p[0] = (0xF0 | (c >> 18));
p[1] = (0x80 | ((c >> 12) & 0x3F));
p[2] = (0x80 | ((c >> 6) & 0x3F));
p[3] = (0x80 | (c & 0x3F));
bytes = 4;
}
else if (c <= MAX_5_BYTE_CHAR)
{
p[0] = 0xF8;
p[1] = (0x80 | ((c >> 18) & 0x0F));
p[2] = (0x80 | ((c >> 12) & 0x3F));
p[3] = (0x80 | ((c >> 6) & 0x3F));
p[4] = (0x80 | (c & 0x3F));
bytes = 5;
}
else if (c <= MAX_CHAR)
{
c = CHAR_TO_BYTE8 (c);
bytes = BYTE8_STRING (c, p);
}
else
error ("Invalid character: %x", c);
return bytes;
}
/* Return a character whose multibyte form is at P. If LEN is not
NULL, it must be a pointer to integer. In that case, set *LEN to
the byte length of the multibyte form. If ADVANCED is not NULL, it
must be a pointer to unsigned char. In that case, set *ADVANCED to
the ending address (i.e., the starting address of the next
character) of the multibyte form. */
int
string_char (const unsigned char *p, const unsigned char **advanced, int *len)
{
int c;
const unsigned char *saved_p = p;
if (*p < 0x80 || ! (*p & 0x20) || ! (*p & 0x10))
{
/* 1-, 2-, and 3-byte sequences can be handled by the macro. */
c = STRING_CHAR_ADVANCE (p);
}
else if (! (*p & 0x08))
{
/* A 4-byte sequence of this form:
11110xxx 10xxxxxx 10xxxxxx 10xxxxxx */
c = ((((p)[0] & 0x7) << 18)
| (((p)[1] & 0x3F) << 12)
| (((p)[2] & 0x3F) << 6)
| ((p)[3] & 0x3F));
p += 4;
}
else
{
/* A 5-byte sequence of this form:
111110xx 10xxxxxx 10xxxxxx 10xxxxxx 10xxxxxx
Note that the top 4 `x's are always 0, so shifting p[1] can
never exceed the maximum valid character codepoint. */
c = (/* (((p)[0] & 0x3) << 24) ... always 0, so no need to shift. */
(((p)[1] & 0x3F) << 18)
| (((p)[2] & 0x3F) << 12)
| (((p)[3] & 0x3F) << 6)
| ((p)[4] & 0x3F));
p += 5;
}
if (len)
*len = p - saved_p;
if (advanced)
*advanced = p;
return c;
}
/* Translate character C by translation table TABLE. If no translation is
found in TABLE, return the untranslated character. If TABLE is a list,
elements are char tables. In that case, recursively translate C by all the
tables in the list. */
int
translate_char (Lisp_Object table, int c)
{
if (CHAR_TABLE_P (table))
{
Lisp_Object ch;
ch = CHAR_TABLE_REF (table, c);
if (CHARACTERP (ch))
c = XINT (ch);
}
else
{
for (; CONSP (table); table = XCDR (table))
c = translate_char (XCAR (table), c);
}
return c;
}
DEFUN ("characterp", Fcharacterp, Scharacterp, 1, 2, 0,
doc: /* Return non-nil if OBJECT is a character.
In Emacs Lisp, characters are represented by character codes, which
are non-negative integers. The function `max-char' returns the
maximum character code.
usage: (characterp OBJECT) */
attributes: const)
(Lisp_Object object, Lisp_Object ignore)
{
return (CHARACTERP (object) ? Qt : Qnil);
}
DEFUN ("max-char", Fmax_char, Smax_char, 0, 0, 0,
doc: /* Return the character of the maximum code. */
attributes: const)
(void)
{
return make_number (MAX_CHAR);
}
DEFUN ("unibyte-char-to-multibyte", Funibyte_char_to_multibyte,
Sunibyte_char_to_multibyte, 1, 1, 0,
doc: /* Convert the byte CH to multibyte character. */)
(Lisp_Object ch)
{
int c;
CHECK_CHARACTER (ch);
c = XFASTINT (ch);
if (c >= 0x100)
error ("Not a unibyte character: %d", c);
MAKE_CHAR_MULTIBYTE (c);
return make_number (c);
}
DEFUN ("multibyte-char-to-unibyte", Fmultibyte_char_to_unibyte,
Smultibyte_char_to_unibyte, 1, 1, 0,
doc: /* Convert the multibyte character CH to a byte.
If the multibyte character does not represent a byte, return -1. */)
(Lisp_Object ch)
{
int cm;
CHECK_CHARACTER (ch);
cm = XFASTINT (ch);
if (cm < 256)
/* Can't distinguish a byte read from a unibyte buffer from
a latin1 char, so let's let it slide. */
return ch;
else
{
int cu = CHAR_TO_BYTE_SAFE (cm);
return make_number (cu);
}
}
/* Return width (columns) of C considering the buffer display table DP. */
static ptrdiff_t
char_width (int c, struct Lisp_Char_Table *dp)
{
ptrdiff_t width = CHARACTER_WIDTH (c);
if (dp)
{
Lisp_Object disp = DISP_CHAR_VECTOR (dp, c), ch;
int i;
if (VECTORP (disp))
for (i = 0, width = 0; i < ASIZE (disp); i++)
{
ch = AREF (disp, i);
if (CHARACTERP (ch))
{
int w = CHARACTER_WIDTH (XFASTINT (ch));
if (INT_ADD_WRAPV (width, w, &width))
string_overflow ();
}
}
}
return width;
}
DEFUN ("char-width", Fchar_width, Schar_width, 1, 1, 0,
doc: /* Return width of CHAR when displayed in the current buffer.
The width is measured by how many columns it occupies on the screen.
Tab is taken to occupy `tab-width' columns.
usage: (char-width CHAR) */)
(Lisp_Object ch)
{
int c;
ptrdiff_t width;
CHECK_CHARACTER (ch);
c = XINT (ch);
width = char_width (c, buffer_display_table ());
return make_number (width);
}
/* Return width of string STR of length LEN when displayed in the
current buffer. The width is measured by how many columns it
occupies on the screen. If PRECISION > 0, return the width of
longest substring that doesn't exceed PRECISION, and set number of
characters and bytes of the substring in *NCHARS and *NBYTES
respectively. */
ptrdiff_t
c_string_width (const unsigned char *str, ptrdiff_t len, int precision,
ptrdiff_t *nchars, ptrdiff_t *nbytes)
{
ptrdiff_t i = 0, i_byte = 0;
ptrdiff_t width = 0;
struct Lisp_Char_Table *dp = buffer_display_table ();
while (i_byte < len)
{
int bytes;
int c = STRING_CHAR_AND_LENGTH (str + i_byte, bytes);
ptrdiff_t thiswidth = char_width (c, dp);
if (0 < precision && precision - width < thiswidth)
{
*nchars = i;
*nbytes = i_byte;
return width;
}
if (INT_ADD_WRAPV (thiswidth, width, &width))
string_overflow ();
i++;
i_byte += bytes;
}
if (precision > 0)
{
*nchars = i;
*nbytes = i_byte;
}
return width;
}
/* Return width of string STR of length LEN when displayed in the
current buffer. The width is measured by how many columns it
occupies on the screen. */
ptrdiff_t
strwidth (const char *str, ptrdiff_t len)
{
return c_string_width ((const unsigned char *) str, len, -1, NULL, NULL);
}
/* Return width of Lisp string STRING when displayed in the current
buffer. The width is measured by how many columns it occupies on
the screen while paying attention to compositions. If PRECISION >
0, return the width of longest substring that doesn't exceed
PRECISION, and set number of characters and bytes of the substring
in *NCHARS and *NBYTES respectively. */
ptrdiff_t
lisp_string_width (Lisp_Object string, ptrdiff_t precision,
ptrdiff_t *nchars, ptrdiff_t *nbytes)
{
ptrdiff_t len = SCHARS (string);
/* This set multibyte to 0 even if STRING is multibyte when it
contains only ascii and eight-bit-graphic, but that's
intentional. */
bool multibyte = len < SBYTES (string);
unsigned char *str = SDATA (string);
ptrdiff_t i = 0, i_byte = 0;
ptrdiff_t width = 0;
struct Lisp_Char_Table *dp = buffer_display_table ();
while (i < len)
{
ptrdiff_t chars, bytes, thiswidth;
Lisp_Object val;
ptrdiff_t cmp_id;
ptrdiff_t ignore, end;
if (find_composition (i, -1, &ignore, &end, &val, string)
&& ((cmp_id = get_composition_id (i, i_byte, end - i, val, string))
>= 0))
{
thiswidth = composition_table[cmp_id]->width;
chars = end - i;
bytes = string_char_to_byte (string, end) - i_byte;
}
else
{
int c;
if (multibyte)
{
int cbytes;
c = STRING_CHAR_AND_LENGTH (str + i_byte, cbytes);
bytes = cbytes;
}
else
c = str[i_byte], bytes = 1;
chars = 1;
thiswidth = char_width (c, dp);
}
if (0 < precision && precision - width < thiswidth)
{
*nchars = i;
*nbytes = i_byte;
return width;
}
if (INT_ADD_WRAPV (thiswidth, width, &width))
string_overflow ();
i += chars;
i_byte += bytes;
}
if (precision > 0)
{
*nchars = i;
*nbytes = i_byte;
}
return width;
}
DEFUN ("string-width", Fstring_width, Sstring_width, 1, 1, 0,
doc: /* Return width of STRING when displayed in the current buffer.
Width is measured by how many columns it occupies on the screen.
When calculating width of a multibyte character in STRING,
only the base leading-code is considered; the validity of
the following bytes is not checked. Tabs in STRING are always
taken to occupy `tab-width' columns.
usage: (string-width STRING) */)
(Lisp_Object str)
{
Lisp_Object val;
CHECK_STRING (str);
XSETFASTINT (val, lisp_string_width (str, -1, NULL, NULL));
return val;
}
/* Return the number of characters in the NBYTES bytes at PTR.
This works by looking at the contents and checking for multibyte
sequences while assuming that there's no invalid sequence.
However, if the current buffer has enable-multibyte-characters =
nil, we treat each byte as a character. */
ptrdiff_t
chars_in_text (const unsigned char *ptr, ptrdiff_t nbytes)
{
/* current_buffer is null at early stages of Emacs initialization. */
if (current_buffer == 0
|| NILP (BVAR (current_buffer, enable_multibyte_characters)))
return nbytes;
return multibyte_chars_in_text (ptr, nbytes);
}
/* Return the number of characters in the NBYTES bytes at PTR.
This works by looking at the contents and checking for multibyte
sequences while assuming that there's no invalid sequence. It
ignores enable-multibyte-characters. */
ptrdiff_t
multibyte_chars_in_text (const unsigned char *ptr, ptrdiff_t nbytes)
{
const unsigned char *endp = ptr + nbytes;
ptrdiff_t chars = 0;
while (ptr < endp)
{
int len = MULTIBYTE_LENGTH (ptr, endp);
if (len == 0)
emacs_abort ();
ptr += len;
chars++;
}
return chars;
}
/* Parse unibyte text at STR of LEN bytes as a multibyte text, count
characters and bytes in it, and store them in *NCHARS and *NBYTES
respectively. On counting bytes, pay attention to that 8-bit
characters not constructing a valid multibyte sequence are
represented by 2-byte in a multibyte text. */
void
parse_str_as_multibyte (const unsigned char *str, ptrdiff_t len,
ptrdiff_t *nchars, ptrdiff_t *nbytes)
{
const unsigned char *endp = str + len;
int n;
ptrdiff_t chars = 0, bytes = 0;
if (len >= MAX_MULTIBYTE_LENGTH)
{
const unsigned char *adjusted_endp = endp - MAX_MULTIBYTE_LENGTH;
while (str < adjusted_endp)
{
if (! CHAR_BYTE8_HEAD_P (*str)
&& (n = MULTIBYTE_LENGTH_NO_CHECK (str)) > 0)
str += n, bytes += n;
else
str++, bytes += 2;
chars++;
}
}
while (str < endp)
{
if (! CHAR_BYTE8_HEAD_P (*str)
&& (n = MULTIBYTE_LENGTH (str, endp)) > 0)
str += n, bytes += n;
else
str++, bytes += 2;
chars++;
}
*nchars = chars;
*nbytes = bytes;
return;
}
/* Arrange unibyte text at STR of NBYTES bytes as a multibyte text.
It actually converts only such 8-bit characters that don't construct
a multibyte sequence to multibyte forms of Latin-1 characters. If
NCHARS is nonzero, set *NCHARS to the number of characters in the
text. It is assured that we can use LEN bytes at STR as a work
area and that is enough. Return the number of bytes of the
resulting text. */
ptrdiff_t
str_as_multibyte (unsigned char *str, ptrdiff_t len, ptrdiff_t nbytes,
ptrdiff_t *nchars)
{
unsigned char *p = str, *endp = str + nbytes;
unsigned char *to;
ptrdiff_t chars = 0;
int n;
if (nbytes >= MAX_MULTIBYTE_LENGTH)
{
unsigned char *adjusted_endp = endp - MAX_MULTIBYTE_LENGTH;
while (p < adjusted_endp
&& ! CHAR_BYTE8_HEAD_P (*p)
&& (n = MULTIBYTE_LENGTH_NO_CHECK (p)) > 0)
p += n, chars++;
}
while (p < endp
&& ! CHAR_BYTE8_HEAD_P (*p)
&& (n = MULTIBYTE_LENGTH (p, endp)) > 0)
p += n, chars++;
if (nchars)
*nchars = chars;
if (p == endp)
return nbytes;
to = p;
nbytes = endp - p;
endp = str + len;
memmove (endp - nbytes, p, nbytes);
p = endp - nbytes;
if (nbytes >= MAX_MULTIBYTE_LENGTH)
{
unsigned char *adjusted_endp = endp - MAX_MULTIBYTE_LENGTH;
while (p < adjusted_endp)
{
if (! CHAR_BYTE8_HEAD_P (*p)
&& (n = MULTIBYTE_LENGTH_NO_CHECK (p)) > 0)
{
while (n--)
*to++ = *p++;
}
else
{
int c = *p++;
c = BYTE8_TO_CHAR (c);
to += CHAR_STRING (c, to);
}
}
chars++;
}
while (p < endp)
{
if (! CHAR_BYTE8_HEAD_P (*p)
&& (n = MULTIBYTE_LENGTH (p, endp)) > 0)
{
while (n--)
*to++ = *p++;
}
else
{
int c = *p++;
c = BYTE8_TO_CHAR (c);
to += CHAR_STRING (c, to);
}
chars++;
}
if (nchars)
*nchars = chars;
return (to - str);
}
/* Parse unibyte string at STR of LEN bytes, and return the number of
bytes it may occupy when converted to multibyte string by
`str_to_multibyte'. */
ptrdiff_t
count_size_as_multibyte (const unsigned char *str, ptrdiff_t len)
{
const unsigned char *endp = str + len;
ptrdiff_t bytes;
for (bytes = 0; str < endp; str++)
{
int n = *str < 0x80 ? 1 : 2;
if (INT_ADD_WRAPV (bytes, n, &bytes))
string_overflow ();
}
return bytes;
}
/* Convert unibyte text at STR of BYTES bytes to a multibyte text
that contains the same single-byte characters. It actually
converts all 8-bit characters to multibyte forms. It is assured
that we can use LEN bytes at STR as a work area and that is
enough. */
ptrdiff_t
str_to_multibyte (unsigned char *str, ptrdiff_t len, ptrdiff_t bytes)
{
unsigned char *p = str, *endp = str + bytes;
unsigned char *to;
while (p < endp && *p < 0x80) p++;
if (p == endp)
return bytes;
to = p;
bytes = endp - p;
endp = str + len;
memmove (endp - bytes, p, bytes);
p = endp - bytes;
while (p < endp)
{
int c = *p++;
if (c >= 0x80)
c = BYTE8_TO_CHAR (c);
to += CHAR_STRING (c, to);
}
return (to - str);
}
/* Arrange multibyte text at STR of LEN bytes as a unibyte text. It
actually converts characters in the range 0x80..0xFF to
unibyte. */
ptrdiff_t
str_as_unibyte (unsigned char *str, ptrdiff_t bytes)
{
const unsigned char *p = str, *endp = str + bytes;
unsigned char *to;
int c, len;
while (p < endp)
{
c = *p;
len = BYTES_BY_CHAR_HEAD (c);
if (CHAR_BYTE8_HEAD_P (c))
break;
p += len;
}
to = str + (p - str);
while (p < endp)
{
c = *p;
len = BYTES_BY_CHAR_HEAD (c);
if (CHAR_BYTE8_HEAD_P (c))
{
c = STRING_CHAR_ADVANCE (p);
*to++ = CHAR_TO_BYTE8 (c);
}
else
{
while (len--) *to++ = *p++;
}
}
return (to - str);
}
/* Convert eight-bit chars in SRC (in multibyte form) to the
corresponding byte and store in DST. CHARS is the number of
characters in SRC. The value is the number of bytes stored in DST.
Usually, the value is the same as CHARS, but is less than it if SRC
contains a non-ASCII, non-eight-bit character. */
ptrdiff_t
str_to_unibyte (const unsigned char *src, unsigned char *dst, ptrdiff_t chars)
{
ptrdiff_t i;
for (i = 0; i < chars; i++)
{
int c = STRING_CHAR_ADVANCE (src);
if (CHAR_BYTE8_P (c))
c = CHAR_TO_BYTE8 (c);
else if (! ASCII_CHAR_P (c))
return i;
*dst++ = c;
}
return i;
}
static ptrdiff_t
string_count_byte8 (Lisp_Object string)
{
bool multibyte = STRING_MULTIBYTE (string);
ptrdiff_t nbytes = SBYTES (string);
unsigned char *p = SDATA (string);
unsigned char *pend = p + nbytes;
ptrdiff_t count = 0;
int c, len;
if (multibyte)
while (p < pend)
{
c = *p;
len = BYTES_BY_CHAR_HEAD (c);
if (CHAR_BYTE8_HEAD_P (c))
count++;
p += len;
}
else
while (p < pend)
{
if (*p++ >= 0x80)
count++;
}
return count;
}
Lisp_Object
string_escape_byte8 (Lisp_Object string)
{
ptrdiff_t nchars = SCHARS (string);
ptrdiff_t nbytes = SBYTES (string);
bool multibyte = STRING_MULTIBYTE (string);
ptrdiff_t byte8_count;
ptrdiff_t thrice_byte8_count, uninit_nchars, uninit_nbytes;
const unsigned char *src, *src_end;
unsigned char *dst;
Lisp_Object val;
int c, len;
if (multibyte && nchars == nbytes)
return string;
byte8_count = string_count_byte8 (string);
if (byte8_count == 0)
return string;
if (INT_MULTIPLY_WRAPV (byte8_count, 3, &thrice_byte8_count))
string_overflow ();
if (multibyte)
{
/* Convert 2-byte sequence of byte8 chars to 4-byte octal. */
if (INT_ADD_WRAPV (nchars, thrice_byte8_count, &uninit_nchars)
|| INT_ADD_WRAPV (nbytes, 2 * byte8_count, &uninit_nbytes))
string_overflow ();
val = make_uninit_multibyte_string (uninit_nchars, uninit_nbytes);
}
else
{
/* Convert 1-byte sequence of byte8 chars to 4-byte octal. */
if (INT_ADD_WRAPV (thrice_byte8_count, nbytes, &uninit_nbytes))
string_overflow ();
val = make_uninit_string (uninit_nbytes);
}
src = SDATA (string);
src_end = src + nbytes;
dst = SDATA (val);
if (multibyte)
while (src < src_end)
{
c = *src;
len = BYTES_BY_CHAR_HEAD (c);
if (CHAR_BYTE8_HEAD_P (c))
{
c = STRING_CHAR_ADVANCE (src);
c = CHAR_TO_BYTE8 (c);
dst += sprintf ((char *) dst, "\\%03o", c + 0u);
}
else
while (len--) *dst++ = *src++;
}
else
while (src < src_end)
{
c = *src++;
if (c >= 0x80)
dst += sprintf ((char *) dst, "\\%03o", c + 0u);
else
*dst++ = c;
}
return val;
}
DEFUN ("string", Fstring, Sstring, 0, MANY, 0,
doc: /*
Concatenate all the argument characters and make the result a string.
usage: (string &rest CHARACTERS) */)
(ptrdiff_t n, Lisp_Object *args)
{
ptrdiff_t i;
int c;
unsigned char *buf, *p;
Lisp_Object str;
USE_SAFE_ALLOCA;
SAFE_NALLOCA (buf, MAX_MULTIBYTE_LENGTH, n);
p = buf;
for (i = 0; i < n; i++)
{
CHECK_CHARACTER (args[i]);
c = XINT (args[i]);
p += CHAR_STRING (c, p);
}
str = make_string_from_bytes ((char *) buf, n, p - buf);
SAFE_FREE ();
return str;
}
DEFUN ("unibyte-string", Funibyte_string, Sunibyte_string, 0, MANY, 0,
doc: /* Concatenate all the argument bytes and make the result a unibyte string.
usage: (unibyte-string &rest BYTES) */)
(ptrdiff_t n, Lisp_Object *args)
{
ptrdiff_t i;
Lisp_Object str;
USE_SAFE_ALLOCA;
unsigned char *buf = SAFE_ALLOCA (n);
unsigned char *p = buf;
for (i = 0; i < n; i++)
{
CHECK_RANGED_INTEGER (args[i], 0, 255);
*p++ = XINT (args[i]);
}
str = make_string_from_bytes ((char *) buf, n, p - buf);
SAFE_FREE ();
return str;
}
DEFUN ("char-resolve-modifiers", Fchar_resolve_modifiers,
Schar_resolve_modifiers, 1, 1, 0,
doc: /* Resolve modifiers in the character CHAR.
The value is a character with modifiers resolved into the character
code. Unresolved modifiers are kept in the value.
usage: (char-resolve-modifiers CHAR) */)
(Lisp_Object character)
{
EMACS_INT c;
CHECK_NUMBER (character);
c = XINT (character);
return make_number (char_resolve_modifier_mask (c));
}
DEFUN ("get-byte", Fget_byte, Sget_byte, 0, 2, 0,
doc: /* Return a byte value of a character at point.
Optional 1st arg POSITION, if non-nil, is a position of a character to get
a byte value.
Optional 2nd arg STRING, if non-nil, is a string of which first
character is a target to get a byte value. In this case, POSITION, if
non-nil, is an index of a target character in the string.
If the current buffer (or STRING) is multibyte, and the target
character is not ASCII nor 8-bit character, an error is signaled. */)
(Lisp_Object position, Lisp_Object string)
{
int c;
ptrdiff_t pos;
unsigned char *p;
if (NILP (string))
{
if (NILP (position))
{
p = PT_ADDR;
}
else
{
CHECK_NUMBER_COERCE_MARKER (position);
if (XINT (position) < BEGV || XINT (position) >= ZV)
args_out_of_range_3 (position, make_number (BEGV), make_number (ZV));
pos = XFASTINT (position);
p = CHAR_POS_ADDR (pos);
}
if (NILP (BVAR (current_buffer, enable_multibyte_characters)))
return make_number (*p);
}
else
{
CHECK_STRING (string);
if (NILP (position))
{
p = SDATA (string);
}
else
{
CHECK_NATNUM (position);
if (XINT (position) >= SCHARS (string))
args_out_of_range (string, position);
pos = XFASTINT (position);
p = SDATA (string) + string_char_to_byte (string, pos);
}
if (! STRING_MULTIBYTE (string))
return make_number (*p);
}
c = STRING_CHAR (p);
if (CHAR_BYTE8_P (c))
c = CHAR_TO_BYTE8 (c);
else if (! ASCII_CHAR_P (c))
error ("Not an ASCII nor an 8-bit character: %d", c);
return make_number (c);
}
/* Return true if C is an alphabetic character. */
bool
alphabeticp (int c)
{
Lisp_Object category = CHAR_TABLE_REF (Vunicode_category_table, c);
if (! INTEGERP (category))
return false;
EMACS_INT gen_cat = XINT (category);
/* See UTS #18. There are additional characters that should be
here, those designated as Other_uppercase, Other_lowercase,
and Other_alphabetic; FIXME. */
return (gen_cat == UNICODE_CATEGORY_Lu
|| gen_cat == UNICODE_CATEGORY_Ll
|| gen_cat == UNICODE_CATEGORY_Lt
|| gen_cat == UNICODE_CATEGORY_Lm
|| gen_cat == UNICODE_CATEGORY_Lo
|| gen_cat == UNICODE_CATEGORY_Mn
|| gen_cat == UNICODE_CATEGORY_Mc
|| gen_cat == UNICODE_CATEGORY_Me
|| gen_cat == UNICODE_CATEGORY_Nl);
}
/* Return true if C is a alphabetic or decimal-number character. */
bool
alphanumericp (int c)
{
Lisp_Object category = CHAR_TABLE_REF (Vunicode_category_table, c);
if (! INTEGERP (category))
return false;
EMACS_INT gen_cat = XINT (category);
/* See UTS #18. Same comment as for alphabeticp applies. FIXME. */
return (gen_cat == UNICODE_CATEGORY_Lu
|| gen_cat == UNICODE_CATEGORY_Ll
|| gen_cat == UNICODE_CATEGORY_Lt
|| gen_cat == UNICODE_CATEGORY_Lm
|| gen_cat == UNICODE_CATEGORY_Lo
|| gen_cat == UNICODE_CATEGORY_Mn
|| gen_cat == UNICODE_CATEGORY_Mc
|| gen_cat == UNICODE_CATEGORY_Me
|| gen_cat == UNICODE_CATEGORY_Nl
|| gen_cat == UNICODE_CATEGORY_Nd);
}
/* Return true if C is a graphic character. */
bool
graphicp (int c)
{
Lisp_Object category = CHAR_TABLE_REF (Vunicode_category_table, c);
if (! INTEGERP (category))
return false;
EMACS_INT gen_cat = XINT (category);
/* See UTS #18. */
return (!(gen_cat == UNICODE_CATEGORY_Zs /* space separator */
|| gen_cat == UNICODE_CATEGORY_Zl /* line separator */
|| gen_cat == UNICODE_CATEGORY_Zp /* paragraph separator */
|| gen_cat == UNICODE_CATEGORY_Cc /* control */
|| gen_cat == UNICODE_CATEGORY_Cs /* surrogate */
|| gen_cat == UNICODE_CATEGORY_Cn)); /* unassigned */
}
/* Return true if C is a printable character. */
bool
printablep (int c)
{
Lisp_Object category = CHAR_TABLE_REF (Vunicode_category_table, c);
if (! INTEGERP (category))
return false;
EMACS_INT gen_cat = XINT (category);
/* See UTS #18. */
return (!(gen_cat == UNICODE_CATEGORY_Cc /* control */
|| gen_cat == UNICODE_CATEGORY_Cs /* surrogate */
|| gen_cat == UNICODE_CATEGORY_Cn)); /* unassigned */
}
/* Return true if C is a horizontal whitespace character, as defined
by http://www.unicode.org/reports/tr18/tr18-19.html#blank. */
bool
blankp (int c)
{
Lisp_Object category = CHAR_TABLE_REF (Vunicode_category_table, c);
if (! INTEGERP (category))
return false;
return XINT (category) == UNICODE_CATEGORY_Zs; /* separator, space */
}
signed char HEXDIGIT_CONST hexdigit[UCHAR_MAX + 1] =
{
#if HEXDIGIT_IS_CONST
[0 ... UCHAR_MAX] = -1,
#endif
['0'] = 0, ['1'] = 1, ['2'] = 2, ['3'] = 3, ['4'] = 4,
['5'] = 5, ['6'] = 6, ['7'] = 7, ['8'] = 8, ['9'] = 9,
['A'] = 10, ['B'] = 11, ['C'] = 12, ['D'] = 13, ['E'] = 14, ['F'] = 15,
['a'] = 10, ['b'] = 11, ['c'] = 12, ['d'] = 13, ['e'] = 14, ['f'] = 15
};
void
syms_of_character (void)
{
#if !HEXDIGIT_IS_CONST
/* Set the non-hex digit values to -1. */
for (int i = 0; i <= UCHAR_MAX; i++)
hexdigit[i] -= i != '0' && !hexdigit[i];
#endif
DEFSYM (Qcharacterp, "characterp");
DEFSYM (Qauto_fill_chars, "auto-fill-chars");
staticpro (&Vchar_unify_table);
Vchar_unify_table = Qnil;
defsubr (&Smax_char);
defsubr (&Scharacterp);
defsubr (&Sunibyte_char_to_multibyte);
defsubr (&Smultibyte_char_to_unibyte);
defsubr (&Schar_width);
defsubr (&Sstring_width);
defsubr (&Sstring);
defsubr (&Sunibyte_string);
defsubr (&Schar_resolve_modifiers);
defsubr (&Sget_byte);
DEFVAR_LISP ("translation-table-vector", Vtranslation_table_vector,
doc: /*
Vector recording all translation tables ever defined.
Each element is a pair (SYMBOL . TABLE) relating the table to the
symbol naming it. The ID of a translation table is an index into this vector. */);
Vtranslation_table_vector = Fmake_vector (make_number (16), Qnil);
DEFVAR_LISP ("auto-fill-chars", Vauto_fill_chars,
doc: /*
A char-table for characters which invoke auto-filling.
Such characters have value t in this table. */);
Vauto_fill_chars = Fmake_char_table (Qauto_fill_chars, Qnil);
CHAR_TABLE_SET (Vauto_fill_chars, ' ', Qt);
CHAR_TABLE_SET (Vauto_fill_chars, '\n', Qt);
DEFVAR_LISP ("char-width-table", Vchar_width_table,
doc: /*
A char-table for width (columns) of each character. */);
Vchar_width_table = Fmake_char_table (Qnil, make_number (1));
char_table_set_range (Vchar_width_table, 0x80, 0x9F, make_number (4));
char_table_set_range (Vchar_width_table, MAX_5_BYTE_CHAR + 1, MAX_CHAR,
make_number (4));
DEFVAR_LISP ("printable-chars", Vprintable_chars,
doc: /* A char-table for each printable character. */);
Vprintable_chars = Fmake_char_table (Qnil, Qnil);
Fset_char_table_range (Vprintable_chars,
Fcons (make_number (32), make_number (126)), Qt);
Fset_char_table_range (Vprintable_chars,
Fcons (make_number (160),
make_number (MAX_5_BYTE_CHAR)), Qt);
DEFVAR_LISP ("char-script-table", Vchar_script_table,
doc: /* Char table of script symbols.
It has one extra slot whose value is a list of script symbols. */);
DEFSYM (Qchar_script_table, "char-script-table");
Fput (Qchar_script_table, Qchar_table_extra_slots, make_number (1));
Vchar_script_table = Fmake_char_table (Qchar_script_table, Qnil);
DEFVAR_LISP ("script-representative-chars", Vscript_representative_chars,
doc: /* Alist of scripts vs the representative characters.
Each element is a cons (SCRIPT . CHARS).
SCRIPT is a symbol representing a script or a subgroup of a script.
CHARS is a list or a vector of characters.
If it is a list, all characters in the list are necessary for supporting SCRIPT.
If it is a vector, one of the characters in the vector is necessary.
This variable is used to find a font for a specific script. */);
Vscript_representative_chars = Qnil;
DEFVAR_LISP ("unicode-category-table", Vunicode_category_table,
doc: /* Char table of Unicode's "General Category".
All Unicode characters have one of the following values (symbol):
Lu, Ll, Lt, Lm, Lo, Mn, Mc, Me, Nd, Nl, No, Pc, Pd, Ps, Pe, Pi, Pf, Po,
Sm, Sc, Sk, So, Zs, Zl, Zp, Cc, Cf, Cs, Co, Cn
See The Unicode Standard for the meaning of those values. */);
/* The correct char-table is setup in characters.el. */
Vunicode_category_table = Qnil;
}