/************************************************************************** * chars.c -- This file is part of GNU nano. * * * * Copyright (C) 2001-2011, 2013-2020 Free Software Foundation, Inc. * * Copyright (C) 2016-2019 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 "prototypes.h" #include #include #ifdef ENABLE_UTF8 #include #include 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 */ #ifdef ENABLE_SPELLER /* Return TRUE when the given character is some kind of letter. */ bool is_alpha_char(const char *c) { #ifdef ENABLE_UTF8 wchar_t wc; if (mbtowc(&wc, c, MAXCHARLEN) < 0) return FALSE; return iswalpha(wc); #else return isalpha((unsigned char)*c); #endif } #endif /* ENABLE_SPELLER */ /* Return TRUE when the given character is some kind of letter or a digit. */ bool is_alnum_char(const char *c) { #ifdef ENABLE_UTF8 wchar_t wc; if (mbtowc(&wc, c, MAXCHARLEN) < 0) return FALSE; return iswalnum(wc); #else return isalnum((unsigned char)*c); #endif } /* Return TRUE when the given character is space or tab or other whitespace. */ bool is_blank_char(const char *c) { #ifdef ENABLE_UTF8 wchar_t wc; if ((signed char)*c >= 0) return (*c == ' ' || *c == '\t'); if (mbtowc(&wc, c, MAXCHARLEN) < 0) return FALSE; return iswblank(wc); #else return isblank((unsigned char)*c); #endif } /* Return TRUE when the given character is a control character. */ bool is_cntrl_char(const char *c) { #ifdef ENABLE_UTF8 if (use_utf8) { return ((c[0] & 0xE0) == 0 || c[0] == DEL_CODE || ((signed char)c[0] == -62 && (signed char)c[1] < -96)); } else #endif return ((*c & 0x60) == 0 || *c == DEL_CODE); } /* Return TRUE when the given character is a punctuation character. */ bool is_punct_char(const char *c) { #ifdef ENABLE_UTF8 wchar_t wc; if (mbtowc(&wc, c, MAXCHARLEN) < 0) return FALSE; return iswpunct(wc); #else return ispunct((unsigned char)*c); #endif } /* Return TRUE when the given character is word-forming (it is alphanumeric or * specified in 'wordchars', or it is punctuation when allow_punct is TRUE). */ bool is_word_char(const char *c, bool allow_punct) { if (*c == '\0') return FALSE; if (is_alnum_char(c)) return TRUE; if (allow_punct && is_punct_char(c)) return TRUE; if (word_chars != NULL && *word_chars != '\0') { char symbol[MAXCHARLEN + 1]; int symlen = collect_char(c, symbol); symbol[symlen] = '\0'; return (strstr(word_chars, symbol) != NULL); } else return FALSE; } /* 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); } #ifdef ENABLE_UTF8 /* Return the width in columns of the given (multibyte) character. */ int mbwidth(const char *c) { /* Ask for the width only when the character isn't plain ASCII. */ if ((signed char)*c <= 0) { wchar_t wc; int width; if (mbtowc(&wc, c, MAXCHARLEN) < 0) return 1; width = wcwidth(wc); if (width < 0) return 1; return width; } else return 1; } /* Convert the given Unicode value to a multibyte character, if possible. * If the conversion succeeds, return the (dynamically allocated) multibyte * character and its length. Otherwise, return a length of zero. */ char *make_mbchar(long code, int *length) { char *mb_char = nmalloc(MAXCHARLEN); *length = wctomb(mb_char, (wchar_t)code); /* Reject invalid Unicode characters. */ if (*length < 0 || !is_valid_unicode((wchar_t)code)) { IGNORE_CALL_RESULT(wctomb(NULL, 0)); *length = 0; } return mb_char; } #endif /* ENABLE_UTF8 */ /* Return the length (in bytes) of the character located at *pointer. */ int char_length(const char *pointer) { #ifdef ENABLE_UTF8 /* If possibly a multibyte character, get its length; otherwise, it's 1. */ if ((signed char)*pointer < 0) { int length = mblen(pointer, MAXCHARLEN); return (length < 0 ? 1 : length); } else #endif return 1; } /* Return the number of (multibyte) characters in the given string. */ size_t mbstrlen(const char *pointer) { size_t count = 0; while (*pointer != '\0') { #ifdef ENABLE_UTF8 if ((signed char)*pointer < 0) { int length = mblen(pointer, MAXCHARLEN); pointer += (length < 0 ? 1 : length); } else #endif pointer++; count++; } return count; } /* Return the length (in bytes) of the character at the start of the * given string, and return a copy of this character in *thechar. */ int collect_char(const char *string, char *thechar) { int charlen; #ifdef ENABLE_UTF8 /* If this is a UTF-8 starter byte, get the number of bytes of the character. */ if ((signed char)*string < 0) { charlen = mblen(string, MAXCHARLEN); /* When the multibyte sequence is invalid, only take the first byte. */ if (charlen <= 0) charlen = 1; } else #endif charlen = 1; for (int i = 0; i < charlen; i++) thechar[i] = string[i]; return charlen; } /* Return the length (in bytes) of the character at the start of * the given string, and add this character's width to *column. */ int advance_over(const char *string, size_t *column) { #ifdef ENABLE_UTF8 if ((signed char)*string < 0) { int charlen = mblen(string, MAXCHARLEN); if (charlen > 0) { if (is_cntrl_char(string)) *column += 2; else *column += mbwidth(string); } else { charlen = 1; *column += 1; } return charlen; } #endif if ((unsigned char)*string < 0x20) { if (*string == '\t') *column += tabsize - *column % tabsize; else *column += 2; } else if (*string == 0x7F) *column += 2; #ifndef ENABLE_UTF8 else if (0x7F < (unsigned char)*string && (unsigned char)*string < 0xA0) *column += 2; #endif else *column += 1; return 1; } /* Return the index in buf of the beginning of the multibyte character * before the one at pos. */ size_t step_left(const char *buf, size_t pos) { #ifdef ENABLE_UTF8 if (use_utf8) { size_t before, charlen = 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) { charlen = char_length(buf + before); before += charlen; } return before - charlen; } 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 step_right(const char *buf, size_t pos) { return pos + char_length(buf + pos); } /* 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) { if ((signed char)*s1 >= 0 && (signed char)*s2 >= 0) { if ('A' <= (*s1 & 0x5F) && (*s1 & 0x5F) <= 'Z') { if ('A' <= (*s2 & 0x5F) && (*s2 & 0x5F) <= 'Z') { if ((*s1 & 0x5F) != (*s2 & 0x5F)) return ((*s1 & 0x5F) - (*s2 & 0x5F)); } else return ((*s1 | 0x20) - *s2); } else if ('A' <= (*s2 & 0x5F) && (*s2 & 0x5F) <= 'Z') return (*s1 - (*s2 | 0x20)); else if (*s1 != *s2) return (*s1 - *s2); s1++; s2++; n--; continue; } 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 += char_length(s1); s2 += char_length(s2); 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 += char_length(haystack); } 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 + step_left(haystack, pointer - haystack); } } else #endif return revstrcasestr(haystack, needle, pointer); } #if !defined(NANO_TINY) || defined(ENABLE_JUSTIFY) /* This function is equivalent to strchr() for multibyte strings. */ char *mbstrchr(const char *string, const char *chr) { #ifdef ENABLE_UTF8 if (use_utf8) { bool bad_s = FALSE, bad_c = FALSE; wchar_t ws, wc; if (mbtowc(&wc, chr, MAXCHARLEN) < 0) { wc = (unsigned char)*chr; bad_c = TRUE; } while (*string != '\0') { int symlen = mbtowc(&ws, string, MAXCHARLEN); if (symlen < 0) { ws = (unsigned char)*string; bad_s = TRUE; } if (ws == wc && bad_s == bad_c) break; string += symlen; } if (*string == '\0') return NULL; return (char *)string; } else #endif return strchr(string, *chr); } #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 += char_length(string); } 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 + step_left(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 + step_left(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 += collect_char(string, symbol); if (is_blank_char(symbol)) return TRUE; } return FALSE; } #endif /* ENABLE_NANORC && (!NANO_TINY || ENABLE_JUSTIFY) */ /* Return TRUE when the given string is empty or consists of only blanks. */ bool white_string(const char *string) { while (*string != '\0' && (is_blank_char(string) || *string == '\r')) string += char_length(string); return !*string; } #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