/* * This file is part of mpv. * * mpv is free software; you can redistribute it and/or * modify it under the terms of the GNU Lesser General Public * License as published by the Free Software Foundation; either * version 2.1 of the License, or (at your option) any later version. * * mpv 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 Lesser General Public License for more details. * * You should have received a copy of the GNU Lesser General Public * License along with mpv. If not, see . */ #ifndef MPLAYER_BSTR_H #define MPLAYER_BSTR_H #include #include #include #include #include #include "mpv_talloc.h" #include "osdep/compiler.h" /* NOTE: 'len' is size_t, but most string-handling functions below assume * that input size has been sanity checked and len fits in an int. */ typedef struct bstr { unsigned char *start; size_t len; } bstr; // If str.start is NULL, return NULL. static inline char *bstrdup0(void *talloc_ctx, struct bstr str) { return talloc_strndup(talloc_ctx, (char *)str.start, str.len); } // Like bstrdup0(), but always return a valid C-string. static inline char *bstrto0(void *talloc_ctx, struct bstr str) { return str.start ? bstrdup0(talloc_ctx, str) : talloc_strdup(talloc_ctx, ""); } // Return start = NULL iff that is true for the original. static inline struct bstr bstrdup(void *talloc_ctx, struct bstr str) { struct bstr r = { NULL, str.len }; if (str.start) r.start = (unsigned char *)talloc_memdup(talloc_ctx, str.start, str.len); return r; } #define bstr0_lit(s) {(unsigned char *)(s), sizeof("" s) - 1} static inline struct bstr bstr0(const char *s) { return (struct bstr){(unsigned char *)s, s ? strlen(s) : 0}; } int bstrcmp(struct bstr str1, struct bstr str2); int bstrcasecmp(struct bstr str1, struct bstr str2); int bstrchr(struct bstr str, int c); int bstrrchr(struct bstr str, int c); int bstrspn(struct bstr str, const char *accept); int bstrcspn(struct bstr str, const char *reject); int bstr_find(struct bstr haystack, struct bstr needle); struct bstr bstr_lstrip(struct bstr str); struct bstr bstr_strip(struct bstr str); struct bstr bstr_split(struct bstr str, const char *sep, struct bstr *rest); bool bstr_split_tok(bstr str, const char *tok, bstr *out_left, bstr *out_right); struct bstr bstr_splice(struct bstr str, int start, int end); long long bstrtoll(struct bstr str, struct bstr *rest, int base); double bstrtod(struct bstr str, struct bstr *rest); void bstr_lower(struct bstr str); int bstr_sscanf(struct bstr str, const char *format, ...) SCANF_ATTRIBUTE(2, 3); // Decode a string containing hexadecimal data. All whitespace will be silently // ignored. When successful, this allocates a new array to store the output. bool bstr_decode_hex(void *talloc_ctx, struct bstr hex, struct bstr *out); // Decode the UTF-8 code point at the start of the string, and return the // character. // After calling this function, *out_next will point to the next character. // out_next can be NULL. // On error, -1 is returned, and *out_next is not modified. int bstr_decode_utf8(struct bstr str, struct bstr *out_next); // Return the UTF-8 code point at the start of the string. // After calling this function, *out_next will point to the next character. // out_next can be NULL. // On error, an empty string is returned, and *out_next is not modified. struct bstr bstr_split_utf8(struct bstr str, struct bstr *out_next); // Return the length of the UTF-8 sequence that starts with the given byte. // Given a string char *s, the next UTF-8 code point is to be expected at // s + bstr_parse_utf8_code_length(s[0]) // On error, -1 is returned. On success, it returns a value in the range [1, 4]. int bstr_parse_utf8_code_length(unsigned char b); // Return >= 0 if the string is valid UTF-8, otherwise negative error code. // Embedded \0 bytes are considered valid. // This returns -N if the UTF-8 string was likely just cut-off in the middle of // an UTF-8 sequence: -1 means 1 byte was missing, -5 5 bytes missing. // If the string was likely not cut off, -8 is returned. // Use (return_value > -8) to check whether the string is valid UTF-8 or valid // but cut-off UTF-8. int bstr_validate_utf8(struct bstr s); // Force the input string to valid UTF-8. If invalid UTF-8 encoding is // encountered, the invalid bytes are interpreted as Latin-1. // Embedded \0 bytes are considered valid. // If replacement happens, a newly allocated string is returned (with a \0 // byte added past its end for convenience). The string is allocated via // talloc, with talloc_ctx as parent. struct bstr bstr_sanitize_utf8_latin1(void *talloc_ctx, struct bstr s); // Return the text before the occurrence of a character, and return it. Change // *rest to point to the text following this character. (rest can be NULL.) struct bstr bstr_splitchar(struct bstr str, struct bstr *rest, const char c); // Like bstr_splitchar. Trailing newlines are not stripped. static inline struct bstr bstr_getline(struct bstr str, struct bstr *rest) { return bstr_splitchar(str, rest, '\n'); } // Strip one trailing line break. This is intended for use with bstr_getline, // and will remove the trailing \n or \r\n sequence. struct bstr bstr_strip_linebreaks(struct bstr str); /** * @brief Append a string to the existing bstr. * * This function appends the content of the `append` bstr to the `s` bstr. * `s->start` is expected to be a talloc allocation (which can be resized) or NULL. * A null terminator ('\0') is always appended for convenience. If `s->start` * is NULL, the `talloc_ctx` will be used as the parent context to allocate * memory. * * @param talloc_ctx The parent talloc context. * @param s The destination bstr to which the `append` string is appended. * @param append The string to append to `s`. */ void bstr_xappend(void *talloc_ctx, bstr *s, bstr append); /** * @brief Append a formatted string to the existing bstr. * * This function works like bstr_xappend() but appends a formatted string using * a format string and additional arguments. The formatted string is created * using vsnprintf. The function takes care of resizing the destination * buffer if necessary. * * @param talloc_ctx The parent talloc context. * @param s The destination bstr to which the formatted string is appended. * @param fmt The format string (same as in vsnprintf). * @param ... Additional arguments for the format string. * @return The number of characters added (excluding the null terminator) * or a negative value on error. */ int bstr_xappend_asprintf(void *talloc_ctx, bstr *s, const char *fmt, ...) PRINTF_ATTRIBUTE(3, 4); /** * @brief Append a formatted string to the existing bstr using a va_list. * * This function is identical to bstr_xappend_asprintf() but takes a `va_list` * instead of a variable number of arguments. * * @param talloc_ctx The parent talloc context. * @param s The destination bstr to which the formatted string is appended. * @param fmt The format string (same as in printf). * @param ap The `va_list` containing the arguments for the format string. * @return The number of characters added (excluding the null terminator) * or a negative value on error. */ int bstr_xappend_vasprintf(void *talloc_ctx, bstr *s, const char *fmt, va_list va) PRINTF_ATTRIBUTE(3, 0); // If s starts/ends with prefix, return true and return the rest of the string // in s. bool bstr_eatstart(struct bstr *s, struct bstr prefix); bool bstr_eatend(struct bstr *s, struct bstr prefix); bool bstr_case_startswith(struct bstr s, struct bstr prefix); bool bstr_case_endswith(struct bstr s, struct bstr suffix); struct bstr bstr_strip_ext(struct bstr str); struct bstr bstr_get_ext(struct bstr s); static inline struct bstr bstr_cut(struct bstr str, int n) { if (n < 0) { n += str.len; if (n < 0) n = 0; } if (((size_t)n) > str.len) n = str.len; return (struct bstr){str.start + n, str.len - n}; } static inline bool bstr_startswith(struct bstr str, struct bstr prefix) { if (str.len < prefix.len) return false; return !memcmp(str.start, prefix.start, prefix.len); } static inline bool bstr_startswith0(struct bstr str, const char *prefix) { return bstr_startswith(str, bstr0(prefix)); } static inline bool bstr_endswith(struct bstr str, struct bstr suffix) { if (str.len < suffix.len) return false; return !memcmp(str.start + str.len - suffix.len, suffix.start, suffix.len); } static inline bool bstr_endswith0(struct bstr str, const char *suffix) { return bstr_endswith(str, bstr0(suffix)); } static inline int bstrcmp0(struct bstr str1, const char *str2) { return bstrcmp(str1, bstr0(str2)); } static inline bool bstr_equals(struct bstr str1, struct bstr str2) { if (str1.len != str2.len) return false; return str1.start == str2.start || bstrcmp(str1, str2) == 0; } static inline bool bstr_equals0(struct bstr str1, const char *str2) { return bstr_equals(str1, bstr0(str2)); } static inline int bstrcasecmp0(struct bstr str1, const char *str2) { return bstrcasecmp(str1, bstr0(str2)); } static inline int bstr_find0(struct bstr haystack, const char *needle) { return bstr_find(haystack, bstr0(needle)); } static inline bool bstr_eatstart0(struct bstr *s, const char *prefix) { return bstr_eatstart(s, bstr0(prefix)); } static inline bool bstr_eatend0(struct bstr *s, const char *prefix) { return bstr_eatend(s, bstr0(prefix)); } #ifdef _WIN32 int bstr_to_wchar(void *talloc_ctx, struct bstr s, wchar_t **ret); #endif // create a pair (not single value!) for "%.*s" printf syntax #define BSTR_P(bstr) (int)((bstr).len), ((bstr).start ? (char*)(bstr).start : "") #define WHITESPACE " \f\n\r\t\v" #endif /* MPLAYER_BSTR_H */