smol/src/chars.c

640 lines
15 KiB
C

/**************************************************************************
* chars.c -- This file is part of GNU nano. *
* *
* Copyright (C) 2001-2011, 2013-2019 Free Software Foundation, Inc. *
* Copyright (C) 2016-2018 Benno Schulenberg *
* *
* GNU nano 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 nano 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 this program. If not, see http://www.gnu.org/licenses/. *
* *
**************************************************************************/
#include "proto.h"
#include <ctype.h>
#include <string.h>
#ifdef ENABLE_UTF8
#include <wchar.h>
#include <wctype.h>
static bool use_utf8 = FALSE;
/* Whether we've enabled UTF-8 support. */
/* Enable UTF-8 support. */
void utf8_init(void)
{
use_utf8 = TRUE;
}
/* Is UTF-8 support enabled? */
bool using_utf8(void)
{
return use_utf8;
}
#endif /* ENABLE_UTF8 */
/* Concatenate two allocated strings, and free the second. */
char *addstrings(char* str1, size_t len1, char* str2, size_t len2)
{
str1 = charealloc(str1, len1 + len2 + 1);
str1[len1] = '\0';
strncat(&str1[len1], str2, len2);
free(str2);
return str1;
}
/* Return TRUE if the value of c is in byte range, and FALSE otherwise. */
bool is_byte(int c)
{
return ((unsigned int)c == (unsigned char)c);
}
/* This function is equivalent to isalpha() for multibyte characters. */
bool is_alpha_mbchar(const char *c)
{
#ifdef ENABLE_UTF8
if (use_utf8) {
wchar_t wc;
if (mbtowc(&wc, c, MAXCHARLEN) < 0)
return 0;
return iswalpha(wc);
} else
#endif
return isalpha((unsigned char)*c);
}
/* This function is equivalent to isalnum() for multibyte characters. */
bool is_alnum_mbchar(const char *c)
{
#ifdef ENABLE_UTF8
if (use_utf8) {
wchar_t wc;
if (mbtowc(&wc, c, MAXCHARLEN) < 0)
return 0;
return iswalnum(wc);
} else
#endif
return isalnum((unsigned char)*c);
}
/* This function is equivalent to isblank() for multibyte characters. */
bool is_blank_mbchar(const char *c)
{
#ifdef ENABLE_UTF8
if (use_utf8) {
wchar_t wc;
if (mbtowc(&wc, c, MAXCHARLEN) < 0)
return 0;
return iswblank(wc);
} else
#endif
return isblank((unsigned char)*c);
}
/* This function is equivalent to iscntrl(), except in that it only
* handles non-high-bit control characters. */
bool is_ascii_cntrl_char(int c)
{
return (0 <= c && c < 32);
}
/* This function is equivalent to iscntrl() for multibyte characters,
* except in that it also handles multibyte control characters with
* their high bits set. */
bool is_cntrl_mbchar(const char *c)
{
#ifdef ENABLE_UTF8
if (use_utf8) {
return ((c[0] & 0xE0) == 0 || c[0] == 127 ||
((signed char)c[0] == -62 && (signed char)c[1] < -96));
} else
#endif
return (((unsigned char)*c & 0x60) == 0 || (unsigned char)*c == 127);
}
/* This function is equivalent to ispunct() for multibyte characters. */
bool is_punct_mbchar(const char *c)
{
#ifdef ENABLE_UTF8
if (use_utf8) {
wchar_t wc;
if (mbtowc(&wc, c, MAXCHARLEN) < 0)
return 0;
return iswpunct(wc);
} else
#endif
return ispunct((unsigned char)*c);
}
/* Return TRUE when the given multibyte character c is a word-forming
* character (that is: alphanumeric, or specified in wordchars, or
* punctuation when allow_punct is TRUE), and FALSE otherwise. */
bool is_word_mbchar(const char *c, bool allow_punct)
{
if (*c == '\0')
return FALSE;
if (is_alnum_mbchar(c))
return TRUE;
if (word_chars != NULL && *word_chars != '\0') {
char symbol[MAXCHARLEN + 1];
int symlen = parse_mbchar(c, symbol, NULL);
symbol[symlen] = '\0';
return (strstr(word_chars, symbol) != NULL);
}
return (allow_punct && is_punct_mbchar(c));
}
/* Return the visible representation of control character c. */
char control_rep(const signed char c)
{
if (c == DEL_CODE)
return '?';
else if (c == -97)
return '=';
else if (c < 0)
return c + 224;
else
return c + 64;
}
/* Return the visible representation of multibyte control character c. */
char control_mbrep(const char *c, bool isdata)
{
/* An embedded newline is an encoded NUL if it is data. */
if (*c == '\n' && (isdata || as_an_at))
return '@';
#ifdef ENABLE_UTF8
if (use_utf8) {
if ((unsigned char)c[0] < 128)
return control_rep(c[0]);
else
return control_rep(c[1]);
} else
#endif
return control_rep(*c);
}
/* Assess how many bytes the given (multibyte) character occupies. Return -1
* if the byte sequence is invalid, and return the number of bytes minus 8
* when it encodes an invalid codepoint. Also, in the second parameter,
* return the number of columns that the character occupies. */
int length_of_char(const char *c, int *width)
{
#ifdef ENABLE_UTF8
if (use_utf8) {
wchar_t wc;
int charlen = mbtowc(&wc, c, MAXCHARLEN);
/* If the sequence is invalid... */
if (charlen < 0)
return -1;
/* If the codepoint is invalid... */
if (!is_valid_unicode(wc))
return charlen - 8;
else {
*width = wcwidth(wc);
/* If the codepoint is unassigned, assume a width of one. */
if (*width < 0)
*width = 1;
return charlen;
}
} else
#endif
return 1;
}
/* This function is equivalent to wcwidth() for multibyte characters. */
int mbwidth(const char *c)
{
#ifdef ENABLE_UTF8
if (use_utf8) {
wchar_t wc;
int width;
if (mbtowc(&wc, c, MAXCHARLEN) < 0)
return 1;
width = wcwidth(wc);
if (width == -1)
return 1;
return width;
} else
#endif
return 1;
}
/* Convert the Unicode value in chr to a multibyte character, if possible.
* If the conversion succeeds, return the (dynamically allocated) multibyte
* character and its length. Otherwise, return an undefined (dynamically
* allocated) multibyte character and a length of zero. */
char *make_mbchar(long chr, int *chr_mb_len)
{
char *chr_mb;
#ifdef ENABLE_UTF8
if (use_utf8) {
chr_mb = charalloc(MAXCHARLEN);
*chr_mb_len = wctomb(chr_mb, (wchar_t)chr);
/* Reject invalid Unicode characters. */
if (*chr_mb_len < 0 || !is_valid_unicode((wchar_t)chr)) {
IGNORE_CALL_RESULT(wctomb(NULL, 0));
*chr_mb_len = 0;
}
} else
#endif
{
*chr_mb_len = 1;
chr_mb = mallocstrncpy(NULL, (char *)&chr, 1);
}
return chr_mb;
}
/* Parse a multibyte character from buf. Return the number of bytes
* used. If chr isn't NULL, store the multibyte character in it. If
* col isn't NULL, add the character's width (in columns) to it. */
int parse_mbchar(const char *buf, char *chr, size_t *col)
{
int length;
#ifdef ENABLE_UTF8
/* If this is a UTF-8 starter byte, get the number of bytes of the character. */
if ((signed char)*buf < 0) {
length = mblen(buf, MAXCHARLEN);
/* When the multibyte sequence is invalid, only take the first byte. */
if (length <= 0)
length = 1;
} else
#endif
length = 1;
/* When requested, store the multibyte character in chr. */
if (chr != NULL)
for (int i = 0; i < length; i++)
chr[i] = buf[i];
/* When requested, add the width of the character to col. */
if (col != NULL) {
/* If we have a tab, compute its width in columns based on the
* current value of col. */
if (*buf == '\t')
*col += tabsize - *col % tabsize;
/* If we have a control character, it's two columns wide: one
* column for the "^", and one for the visible character. */
else if (is_cntrl_mbchar(buf))
*col += 2;
/* If we have a normal character, get its width normally. */
else if (length == 1)
*col += 1;
#ifdef ENABLE_UTF8
else
*col += mbwidth(buf);
#endif
}
return length;
}
/* Return the index in buf of the beginning of the multibyte character
* before the one at pos. */
size_t move_mbleft(const char *buf, size_t pos)
{
#ifdef ENABLE_UTF8
if (use_utf8) {
size_t before, char_len = 0;
if (pos < 4)
before = 0;
else {
const char *ptr = buf + pos;
/* Probe for a valid starter byte in the preceding four bytes. */
if ((signed char)*(--ptr) > -65)
before = pos - 1;
else if ((signed char)*(--ptr) > -65)
before = pos - 2;
else if ((signed char)*(--ptr) > -65)
before = pos - 3;
else if ((signed char)*(--ptr) > -65)
before = pos - 4;
else
before = pos - 1;
}
/* Move forward again until we reach the original character,
* so we know the length of its preceding character. */
while (before < pos) {
char_len = parse_mbchar(buf + before, NULL, NULL);
before += char_len;
}
return before - char_len;
} else
#endif
return (pos == 0 ? 0 : pos - 1);
}
/* Return the index in buf of the beginning of the multibyte character
* after the one at pos. */
size_t move_mbright(const char *buf, size_t pos)
{
return pos + parse_mbchar(buf + pos, NULL, NULL);
}
/* This function is equivalent to strcasecmp() for multibyte strings. */
int mbstrcasecmp(const char *s1, const char *s2)
{
return mbstrncasecmp(s1, s2, HIGHEST_POSITIVE);
}
/* This function is equivalent to strncasecmp() for multibyte strings. */
int mbstrncasecmp(const char *s1, const char *s2, size_t n)
{
#ifdef ENABLE_UTF8
if (use_utf8) {
wchar_t wc1, wc2;
while (*s1 != '\0' && *s2 != '\0' && n > 0) {
bool bad1 = (mbtowc(&wc1, s1, MAXCHARLEN) < 0);
bool bad2 = (mbtowc(&wc2, s2, MAXCHARLEN) < 0);
if (bad1 || bad2) {
if (*s1 != *s2)
return (unsigned char)*s1 - (unsigned char)*s2;
if (bad1 != bad2)
return (bad1 ? 1 : -1);
} else {
int difference = towlower(wc1) - towlower(wc2);
if (difference != 0)
return difference;
}
s1 += move_mbright(s1, 0);
s2 += move_mbright(s2, 0);
n--;
}
return (n > 0) ? ((unsigned char)*s1 - (unsigned char)*s2) : 0;
} else
#endif
return strncasecmp(s1, s2, n);
}
/* This function is equivalent to strcasestr() for multibyte strings. */
char *mbstrcasestr(const char *haystack, const char *needle)
{
#ifdef ENABLE_UTF8
if (use_utf8) {
size_t needle_len = mbstrlen(needle);
while (*haystack != '\0') {
if (mbstrncasecmp(haystack, needle, needle_len) == 0)
return (char *)haystack;
haystack += move_mbright(haystack, 0);
}
return NULL;
} else
#endif
return (char *) strcasestr(haystack, needle);
}
/* This function is equivalent to strstr(), except in that it scans the
* string in reverse, starting at pointer. */
char *revstrstr(const char *haystack, const char *needle,
const char *pointer)
{
size_t needle_len = strlen(needle);
size_t tail_len = strlen(pointer);
if (tail_len < needle_len)
pointer += tail_len - needle_len;
while (pointer >= haystack) {
if (strncmp(pointer, needle, needle_len) == 0)
return (char *)pointer;
pointer--;
}
return NULL;
}
/* This function is equivalent to strcasestr(), except in that it scans
* the string in reverse, starting at pointer. */
char *revstrcasestr(const char *haystack, const char *needle,
const char *pointer)
{
size_t needle_len = strlen(needle);
size_t tail_len = strlen(pointer);
if (tail_len < needle_len)
pointer += tail_len - needle_len;
while (pointer >= haystack) {
if (strncasecmp(pointer, needle, needle_len) == 0)
return (char *)pointer;
pointer--;
}
return NULL;
}
/* This function is equivalent to strcasestr() for multibyte strings,
* except in that it scans the string in reverse, starting at pointer. */
char *mbrevstrcasestr(const char *haystack, const char *needle,
const char *pointer)
{
#ifdef ENABLE_UTF8
if (use_utf8) {
size_t needle_len = mbstrlen(needle);
size_t tail_len = mbstrlen(pointer);
if (tail_len < needle_len)
pointer += tail_len - needle_len;
if (pointer < haystack)
return NULL;
while (TRUE) {
if (mbstrncasecmp(pointer, needle, needle_len) == 0)
return (char *)pointer;
if (pointer == haystack)
return NULL;
pointer = haystack + move_mbleft(haystack, pointer - haystack);
}
} else
#endif
return revstrcasestr(haystack, needle, pointer);
}
/* Count the number of (multibyte) characters in the given string. */
size_t mbstrlen(const char *s)
{
size_t maxlen = (size_t)-1;
#ifdef ENABLE_UTF8
if (use_utf8) {
size_t n = 0;
while (*s != '\0' && maxlen > 0) {
if ((signed char)*s < 0) {
int length = mblen(s, MAXCHARLEN);
s += (length < 0 ? 1 : length);
} else
s++;
maxlen--;
n++;
}
return n;
} else
#endif
return strnlen(s, maxlen);
}
#if !defined(NANO_TINY) || defined(ENABLE_JUSTIFY)
/* This function is equivalent to strchr() for multibyte strings. */
char *mbstrchr(const char *s, const char *c)
{
#ifdef ENABLE_UTF8
if (use_utf8) {
bool bad_s_mb = FALSE, bad_c_mb = FALSE;
char symbol[MAXCHARLEN];
const char *q = s;
wchar_t ws, wc;
if (mbtowc(&wc, c, MAXCHARLEN) < 0) {
wc = (unsigned char)*c;
bad_c_mb = TRUE;
}
while (*s != '\0') {
int sym_len = parse_mbchar(s, symbol, NULL);
if (mbtowc(&ws, symbol, sym_len) < 0) {
ws = (unsigned char)*s;
bad_s_mb = TRUE;
}
if (bad_s_mb == bad_c_mb && ws == wc)
break;
s += sym_len;
q += sym_len;
}
if (*s == '\0')
q = NULL;
return (char *)q;
} else
#endif
return (char *) strchr(s, *c);
}
#endif /* !NANO_TINY || ENABLE_JUSTIFY */
#ifndef NANO_TINY
/* Locate, in the given string, the first occurrence of any of
* the characters in accept, searching forward. */
char *mbstrpbrk(const char *string, const char *accept)
{
while (*string != '\0') {
if (mbstrchr(accept, string) != NULL)
return (char *)string;
string += move_mbright(string, 0);
}
return NULL;
}
/* Locate, in the string that starts at head, the first occurrence of any of
* the characters in accept, starting from pointer and searching backwards. */
char *mbrevstrpbrk(const char *head, const char *accept, const char *pointer)
{
if (*pointer == '\0') {
if (pointer == head)
return NULL;
pointer = head + move_mbleft(head, pointer - head);
}
while (TRUE) {
if (mbstrchr(accept, pointer) != NULL)
return (char *)pointer;
/* If we've reached the head of the string, we found nothing. */
if (pointer == head)
return NULL;
pointer = head + move_mbleft(head, pointer - head);
}
}
#endif /* !NANO_TINY */
#if defined(ENABLE_NANORC) && (!defined(NANO_TINY) || defined(ENABLE_JUSTIFY))
/* Return TRUE if the given string contains at least one blank character,
* and FALSE otherwise. */
bool has_blank_char(const char *string)
{
char symbol[MAXCHARLEN];
while (*string != '\0') {
string += parse_mbchar(string, symbol, NULL);
if (is_blank_mbchar(symbol))
return TRUE;
}
return FALSE;
}
#endif /* ENABLE_NANORC && (!NANO_TINY || ENABLE_JUSTIFY) */
#ifdef ENABLE_UTF8
/* Return TRUE if wc is valid Unicode, and FALSE otherwise. */
bool is_valid_unicode(wchar_t wc)
{
return ((0 <= wc && wc <= 0xD7FF) ||
(0xE000 <= wc && wc <= 0xFDCF) ||
(0xFDF0 <= wc && wc <= 0xFFFD) ||
(0xFFFF < wc && wc <= 0x10FFFF && (wc & 0xFFFF) <= 0xFFFD));
}
#endif