/* * wee-utf8.c - UTF-8 string functions * * Copyright (C) 2003-2015 Sébastien Helleu * Copyright (C) 2006 Emmanuel Bouthenot * * This file is part of WeeChat, the extensible chat client. * * WeeChat 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. * * WeeChat 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 WeeChat. If not, see . */ #ifdef HAVE_CONFIG_H #include "config.h" #endif #include #include #include #include "weechat.h" #include "wee-utf8.h" #include "wee-config.h" #include "wee-string.h" int local_utf8 = 0; /* * Initializes UTF-8 in WeeChat. */ void utf8_init () { local_utf8 = (string_strcasecmp (weechat_local_charset, "UTF-8") == 0); } /* * Checks if a string has some 8-bit chars. * * Returns: * 1: string has 8-bit chars * 0: string has only 7-bit chars */ int utf8_has_8bits (const char *string) { while (string && string[0]) { if (string[0] & 0x80) return 1; string++; } return 0; } /* * Checks if a string is UTF-8 valid. * * Returns: * 1: string is UTF-8 valid * 0: string it not UTF-8 valid, and then if error is not NULL, it is set with * first non valid UTF-8 char in string */ int utf8_is_valid (const char *string, char **error) { int code_point; while (string && string[0]) { /* * UTF-8, 2 bytes, should be: 110vvvvv 10vvvvvv * and in range: U+0080 - U+07FF */ if (((unsigned char)(string[0]) & 0xE0) == 0xC0) { if (!string[1] || (((unsigned char)(string[1]) & 0xC0) != 0x80)) goto invalid; code_point = utf8_char_int (string); if ((code_point < 0x0080) || (code_point > 0x07FF)) goto invalid; string += 2; } /* * UTF-8, 3 bytes, should be: 1110vvvv 10vvvvvv 10vvvvvv * and in range: U+0800 - U+FFFF * (note: high and low surrogate halves used by UTF-16 (U+D800 through * U+DFFF) are not legal Unicode values) */ else if (((unsigned char)(string[0]) & 0xF0) == 0xE0) { if (!string[1] || !string[2] || (((unsigned char)(string[1]) & 0xC0) != 0x80) || (((unsigned char)(string[2]) & 0xC0) != 0x80)) { goto invalid; } code_point = utf8_char_int (string); if ((code_point < 0x0800) || (code_point > 0xFFFF) || ((code_point >= 0xD800) && (code_point <= 0xDFFF))) { goto invalid; } string += 3; } /* * UTF-8, 4 bytes, should be: 11110vvv 10vvvvvv 10vvvvvv 10vvvvvv * and in range: U+10000 - U+1FFFFF */ else if (((unsigned char)(string[0]) & 0xF8) == 0xF0) { if (!string[1] || !string[2] || !string[3] || (((unsigned char)(string[1]) & 0xC0) != 0x80) || (((unsigned char)(string[2]) & 0xC0) != 0x80) || (((unsigned char)(string[3]) & 0xC0) != 0x80)) { goto invalid; } code_point = utf8_char_int(string); if ((code_point < 0x10000) || (code_point > 0x1FFFFF)) goto invalid; string += 4; } /* UTF-8, 1 byte, should be: 0vvvvvvv */ else if ((unsigned char)(string[0]) >= 0x80) goto invalid; else string++; } if (error) *error = NULL; return 1; invalid: if (error) *error = (char *)string; return 0; } /* * Normalizes an string: removes non UTF-8 chars and replaces them by a * "replacement" char. */ void utf8_normalize (char *string, char replacement) { char *error; while (string && string[0]) { if (utf8_is_valid (string, &error)) return; error[0] = replacement; string = error + 1; } } /* * Gets pointer to previous UTF-8 char in a string. * * Returns pointer to previous UTF-8 char, NULL if not found (for example * "string_start" was reached). */ char * utf8_prev_char (const char *string_start, const char *string) { if (!string || (string <= string_start)) return NULL; string--; if (((unsigned char)(string[0]) & 0xC0) == 0x80) { /* UTF-8, at least 2 bytes */ string--; if (string < string_start) return (char *)string + 1; if (((unsigned char)(string[0]) & 0xC0) == 0x80) { /* UTF-8, at least 3 bytes */ string--; if (string < string_start) return (char *)string + 1; if (((unsigned char)(string[0]) & 0xC0) == 0x80) { /* UTF-8, 4 bytes */ string--; if (string < string_start) return (char *)string + 1; return (char *)string; } else return (char *)string; } else return (char *)string; } return (char *)string; } /* * Gets pointer to next UTF-8 char in a string. * * Returns pointer to next UTF-8 char, NULL if string was NULL. */ char * utf8_next_char (const char *string) { if (!string) return NULL; /* UTF-8, 2 bytes: 110vvvvv 10vvvvvv */ if (((unsigned char)(string[0]) & 0xE0) == 0xC0) { if (!string[1]) return (char *)string + 1; return (char *)string + 2; } /* UTF-8, 3 bytes: 1110vvvv 10vvvvvv 10vvvvvv */ else if (((unsigned char)(string[0]) & 0xF0) == 0xE0) { if (!string[1]) return (char *)string + 1; if (!string[2]) return (char *)string + 2; return (char *)string + 3; } /* UTF-8, 4 bytes: 11110vvv 10vvvvvv 10vvvvvv 10vvvvvv */ else if (((unsigned char)(string[0]) & 0xF8) == 0xF0) { if (!string[1]) return (char *)string + 1; if (!string[2]) return (char *)string + 2; if (!string[3]) return (char *)string + 3; return (char *)string + 4; } /* UTF-8, 1 byte: 0vvvvvvv */ return (char *)string + 1; } /* * Gets UTF-8 char as an integer. * * Returns the UTF-8 char as integer number. */ int utf8_char_int (const char *string) { const unsigned char *ptr_string; if (!string) return 0; ptr_string = (unsigned char *)string; /* UTF-8, 2 bytes: 110vvvvv 10vvvvvv */ if ((ptr_string[0] & 0xE0) == 0xC0) { if (!ptr_string[1]) return (int)(ptr_string[0] & 0x1F); return ((int)(ptr_string[0] & 0x1F) << 6) + ((int)(ptr_string[1] & 0x3F)); } /* UTF-8, 3 bytes: 1110vvvv 10vvvvvv 10vvvvvv */ else if ((ptr_string[0] & 0xF0) == 0xE0) { if (!ptr_string[1]) return (int)(ptr_string[0] & 0x0F); if (!ptr_string[2]) return (((int)(ptr_string[0] & 0x0F)) << 6) + ((int)(ptr_string[1] & 0x3F)); return (((int)(ptr_string[0] & 0x0F)) << 12) + (((int)(ptr_string[1] & 0x3F)) << 6) + ((int)(ptr_string[2] & 0x3F)); } /* UTF-8, 4 bytes: 11110vvv 10vvvvvv 10vvvvvv 10vvvvvv */ else if ((ptr_string[0] & 0xF8) == 0xF0) { if (!ptr_string[1]) return (int)(ptr_string[0] & 0x07); if (!ptr_string[2]) return (((int)(ptr_string[0] & 0x07)) << 6) + ((int)(ptr_string[1] & 0x3F)); if (!ptr_string[3]) return (((int)(ptr_string[0] & 0x07)) << 12) + (((int)(ptr_string[1] & 0x3F)) << 6) + ((int)(ptr_string[2] & 0x3F)); return (((int)(ptr_string[0] & 0x07)) << 18) + (((int)(ptr_string[1] & 0x3F)) << 12) + (((int)(ptr_string[2] & 0x3F)) << 6) + ((int)(ptr_string[3] & 0x3F)); } /* UTF-8, 1 byte: 0vvvvvvv */ return (int)ptr_string[0]; } /* * Converts a unicode char (as unsigned integer) to a string. * * The string must have a size >= 5 * (4 bytes for the UTF-8 char + the final '\0'). * * In case of error (if unicode value is > 0x1FFFFF), the string is set to an * empty string (string[0] == '\0'). */ void utf8_int_string (unsigned int unicode_value, char *string) { if (!string) return; string[0] = '\0'; if (unicode_value <= 0x007F) { /* UTF-8, 1 byte: 0vvvvvvv */ string[0] = unicode_value; string[1] = '\0'; } else if (unicode_value <= 0x07FF) { /* UTF-8, 2 bytes: 110vvvvv 10vvvvvv */ string[0] = 0xC0 | ((unicode_value >> 6) & 0x1F); string[1] = 0x80 | (unicode_value & 0x3F); string[2] = '\0'; } else if (unicode_value <= 0xFFFF) { /* UTF-8, 3 bytes: 1110vvvv 10vvvvvv 10vvvvvv */ string[0] = 0xE0 | ((unicode_value >> 12) & 0x0F); string[1] = 0x80 | ((unicode_value >> 6) & 0x3F); string[2] = 0x80 | (unicode_value & 0x3F); string[3] = '\0'; } else if (unicode_value <= 0x1FFFFF) { /* UTF-8, 4 bytes: 11110vvv 10vvvvvv 10vvvvvv 10vvvvvv */ string[0] = 0xF0 | ((unicode_value >> 18) & 0x07); string[1] = 0x80 | ((unicode_value >> 12) & 0x3F); string[2] = 0x80 | ((unicode_value >> 6) & 0x3F); string[3] = 0x80 | (unicode_value & 0x3F); string[4] = '\0'; } } /* * Gets wide char from string (first char). * * Returns the char as "wint_t", WEOF is string was NULL/empty or in case of * error. */ wint_t utf8_wide_char (const char *string) { int char_size; wint_t result; if (!string || !string[0]) return WEOF; char_size = utf8_char_size (string); switch (char_size) { case 1: result = (wint_t)string[0]; break; case 2: result = ((wint_t)((unsigned char)string[0])) << 8 | ((wint_t)((unsigned char)string[1])); break; case 3: result = ((wint_t)((unsigned char)string[0])) << 16 | ((wint_t)((unsigned char)string[1])) << 8 | ((wint_t)((unsigned char)string[2])); break; case 4: result = ((wint_t)((unsigned char)string[0])) << 24 | ((wint_t)((unsigned char)string[1])) << 16 | ((wint_t)((unsigned char)string[2])) << 8 | ((wint_t)((unsigned char)string[3])); break; default: result = WEOF; } return result; } /* * Gets size of UTF-8 char (in bytes). * * Returns an integer between 0 and 4. */ int utf8_char_size (const char *string) { if (!string) return 0; return utf8_next_char (string) - string; } /* * Gets length of an UTF-8 string in number of chars (not bytes). * Result is <= strlen(string). * * Returns length of string (>= 0). */ int utf8_strlen (const char *string) { int length; if (!string) return 0; length = 0; while (string && string[0]) { string = utf8_next_char (string); length++; } return length; } /* * Gets length of an UTF-8 string for N bytes max in string. * * Returns length of string (>= 0). */ int utf8_strnlen (const char *string, int bytes) { char *start; int length; if (!string) return 0; start = (char *)string; length = 0; while (string && string[0] && (string - start < bytes)) { string = utf8_next_char (string); length++; } return length; } /* * Gets number of chars needed on screen to display the UTF-8 string. * * Returns the number of chars (>= 0). */ int utf8_strlen_screen (const char *string) { int length, num_char, add_for_tab; wchar_t *alloc_wstring, *ptr_wstring, wstring[4+2]; const char *ptr_string; if (!string || !string[0]) return 0; if (!local_utf8) return utf8_strlen (string); alloc_wstring = NULL; if (!string[1] || !string[2] || !string[3] || !string[4]) { /* optimization for max 4 chars: no malloc */ num_char = 4 + 1; ptr_wstring = wstring; } else { num_char = mbstowcs (NULL, string, 0) + 1; alloc_wstring = malloc ((num_char + 1) * sizeof (alloc_wstring[0])); if (!alloc_wstring) return utf8_strlen (string); ptr_wstring = alloc_wstring; } if (mbstowcs (ptr_wstring, string, num_char) != (size_t)(-1)) { length = wcswidth (ptr_wstring, num_char); /* * if the char is non-printable, wcswidth returns -1 * (for example the length of the snowman without snow (U+26C4) == -1) * => in this case, consider the length is 1, to prevent any display bug */ if (length < 0) length = 1; } else length = utf8_strlen (string); if (alloc_wstring) free (alloc_wstring); add_for_tab = CONFIG_INTEGER(config_look_tab_width) - 1; if (add_for_tab > 0) { for (ptr_string = string; ptr_string[0]; ptr_string++) { if (ptr_string[0] == '\t') length += add_for_tab; } } return length; } /* * Compares two UTF-8 chars (case sensitive). * * Returns: * -1: string1 < string2 * 0: string1 == string2 * 1: string1 > string2 */ int utf8_charcmp (const char *string1, const char *string2) { int length1, length2, i, diff; if (!string1 || !string2) return (string1) ? 1 : ((string2) ? -1 : 0); length1 = utf8_char_size (string1); length2 = utf8_char_size (string2); i = 0; while ((i < length1) && (i < length2)) { diff = (int)((unsigned char) string1[i]) - (int)((unsigned char) string2[i]); if (diff != 0) return (diff < 0) ? -1 : 1; i++; } /* string1 == string2 ? */ if ((i == length1) && (i == length2)) return 0; /* string1 < string2 ? */ if (i == length1) return 1; /* string1 > string2 */ return -1; } /* * Compares two UTF-8 chars (case is ignored). * * Returns: * -1: string1 < string2 * 0: string1 == string2 * 1: string1 > string2 */ int utf8_charcasecmp (const char *string1, const char *string2) { wint_t wchar1, wchar2; if (!string1 || !string2) return (string1) ? 1 : ((string2) ? -1 : 0); wchar1 = utf8_wide_char (string1); if ((wchar1 >= 'A') && (wchar1 <= 'Z')) wchar1 += ('a' - 'A'); wchar2 = utf8_wide_char (string2); if ((wchar2 >= 'A') && (wchar2 <= 'Z')) wchar2 += ('a' - 'A'); return (wchar1 < wchar2) ? -1 : ((wchar1 == wchar2) ? 0 : 1); } /* * Compares two UTF-8 chars (case is ignored) using a range. * * The range is the number of chars which can be converted from upper to lower * case. For example 26 = all letters of alphabet, 29 = all letters + 3 chars. * * Examples: * - range = 26: A-Z ==> a-z * - range = 29: A-Z [ \ ] ==> a-z { | } * - range = 30: A-Z [ \ ] ^ ==> a-z { | } ~ * (ranges 29 and 30 are used by some protocols like IRC) * * Returns: * < 0: char1 < char2 * 0: char1 == char2 * > 0: char1 > char2 */ int utf8_charcasecmp_range (const char *string1, const char *string2, int range) { wint_t wchar1, wchar2; if (!string1 || !string2) return (string1) ? 1 : ((string2) ? -1 : 0); wchar1 = utf8_wide_char (string1); if ((wchar1 >= (wint_t)'A') && (wchar1 < (wint_t)('A' + range))) wchar1 += ('a' - 'A'); wchar2 = utf8_wide_char (string2); if ((wchar2 >= (wint_t)'A') && (wchar2 < (wint_t)('A' + range))) wchar2 += ('a' - 'A'); return (wchar1 < wchar2) ? -1 : ((wchar1 == wchar2) ? 0 : 1); } /* * Gets number of chars needed on screen to display the UTF-8 char. * * Returns the number of chars (>= 0). */ int utf8_char_size_screen (const char *string) { int char_size; char utf_char[16]; if (!string) return 0; char_size = utf8_char_size (string); if (char_size == 0) return 0; memcpy (utf_char, string, char_size); utf_char[char_size] = '\0'; return utf8_strlen_screen (utf_char); } /* * Moves forward N chars in an UTF-8 string. * * Returns pointer to the new position in string. */ char * utf8_add_offset (const char *string, int offset) { if (!string) return NULL; while (string && string[0] && (offset > 0)) { string = utf8_next_char (string); offset--; } return (char *)string; } /* * Gets real position in UTF-8 string, in bytes. * * Argument "pos" is a number of chars (not bytes). * * Example: ("déca", 2) returns 3. * * Returns the real position (>= 0). */ int utf8_real_pos (const char *string, int pos) { int count, real_pos; char *next_char; if (!string) return pos; count = 0; real_pos = 0; while (string && string[0] && (count < pos)) { next_char = utf8_next_char (string); real_pos += (next_char - string); string = next_char; count++; } return real_pos; } /* * Gets position in UTF-8 string, in chars. * * Argument "real_pos" is a number of bytes (not chars). * * Example: ("déca", 3) returns 2. * * Returns the position in string. */ int utf8_pos (const char *string, int real_pos) { int count; char *limit; if (!string || !weechat_local_charset) return real_pos; count = 0; limit = (char *)string + real_pos; while (string && string[0] && (string < limit)) { string = utf8_next_char (string); count++; } return count; } /* * Duplicates an UTF-8 string, with max N chars. * * Note: result must be freed after use. */ char * utf8_strndup (const char *string, int length) { const char *end; if (!string || (length < 0)) return NULL; if (length == 0) return strdup (""); end = utf8_add_offset (string, length); if (!end || (end == string)) return strdup (string); return string_strndup (string, end - string); }