/* * (C) 2011 by Harald Welte * (C) 2011 by Sylvain Munaut * (C) 2014 by Nils O. SelÄsdal * * All Rights Reserved * * SPDX-License-Identifier: GPL-2.0+ * * This program 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 2 of the License, or * (at your option) any later version. * * This program 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. * */ #include #include #include #include #include #if !defined(PRId64) || !defined(PRIu64) /* it gets lost every few years.. https://bugs.debian.org/cgi-bin/bugreport.cgi?bug=953844 https://bugs.debian.org/cgi-bin/bugreport.cgi?bug=1067692 */ #include #endif #include #include #include #include /*! \addtogroup utils * @{ * various utility routines * * \file utils.c */ static __thread char namebuf[255]; /* shared by osmo_str_tolower() and osmo_str_toupper() */ static __thread char capsbuf[128]; /*! get human-readable string for given value * \param[in] vs Array of value_string tuples * \param[in] val Value to be converted * \returns pointer to human-readable string * * If val is found in vs, the array's string entry is returned. Otherwise, an * "unknown" string containing the actual value is composed in a static buffer * that is reused across invocations. */ const char *get_value_string(const struct value_string *vs, uint32_t val) { const char *str = get_value_string_or_null(vs, val); if (str) return str; snprintf(namebuf, sizeof(namebuf), "unknown 0x%"PRIx32, val); namebuf[sizeof(namebuf) - 1] = '\0'; return namebuf; } /*! get human-readable string or NULL for given value * \param[in] vs Array of value_string tuples * \param[in] val Value to be converted * \returns pointer to human-readable string or NULL if val is not found */ const char *get_value_string_or_null(const struct value_string *vs, uint32_t val) { int i; if (!vs) return NULL; for (i = 0;; i++) { if (vs[i].value == 0 && vs[i].str == NULL) break; if (vs[i].value == val) return vs[i].str; } return NULL; } /*! get numeric value for given human-readable string * \param[in] vs Array of value_string tuples * \param[in] str human-readable string * \returns numeric value (>0) or negative numer in case of error */ int get_string_value(const struct value_string *vs, const char *str) { int i; for (i = 0;; i++) { if (vs[i].value == 0 && vs[i].str == NULL) break; if (!strcasecmp(vs[i].str, str)) return vs[i].value; } return -EINVAL; } /*! Convert BCD-encoded digit into printable character * \param[in] bcd A single BCD-encoded digit * \returns single printable character */ char osmo_bcd2char(uint8_t bcd) { if (bcd < 0xa) return '0' + bcd; else return 'A' + (bcd - 0xa); } /*! Convert number in ASCII to BCD value * \param[in] c ASCII character * \returns BCD encoded value of character */ uint8_t osmo_char2bcd(char c) { if (c >= '0' && c <= '9') return c - 0x30; else if (c >= 'A' && c <= 'F') return 0xa + (c - 'A'); else if (c >= 'a' && c <= 'f') return 0xa + (c - 'a'); else return 0; } /*! Convert BCD to string. * The given nibble offsets are interpreted in BCD order, i.e. nibble 0 is bcd[0] & 0xf, nibble 1 is bcd[0] >> 4, nibble * 3 is bcd[1] & 0xf, etc.. * \param[out] dst Output string buffer, is always nul terminated when dst_size > 0. * \param[in] dst_size sizeof() the output string buffer. * \param[in] bcd Binary coded data buffer. * \param[in] start_nibble Offset to start from, in nibbles, typically 1 to skip the first nibble. * \param[in] end_nibble Offset to stop before, in nibbles, e.g. sizeof(bcd)*2 - (bcd[0] & GSM_MI_ODD? 0:1). * \param[in] allow_hex If false, return error if there are digits other than 0-9. If true, return those as [A-F]. * \returns The strlen that would be written if the output buffer is large enough, excluding nul byte (like * snprintf()), or -EINVAL if allow_hex is false and a digit > 9 is encountered. On -EINVAL, the conversion is * still completed as if allow_hex were passed as true. Return -ENOMEM if dst is NULL or dst_size is zero. * If end_nibble <= start_nibble, write an empty string to dst and return 0. */ int osmo_bcd2str(char *dst, size_t dst_size, const uint8_t *bcd, int start_nibble, int end_nibble, bool allow_hex) { char *dst_end; int nibble_i; int rc = 0; if (!dst || dst_size < 1 || start_nibble < 0) return -ENOMEM; dst_end = dst + dst_size - 1; for (nibble_i = start_nibble; nibble_i < end_nibble && dst < dst_end; nibble_i++, dst++) { uint8_t nibble = bcd[nibble_i >> 1]; if ((nibble_i & 1)) nibble >>= 4; nibble &= 0xf; if (!allow_hex && nibble > 9) rc = -EINVAL; *dst = osmo_bcd2char(nibble); } *dst = '\0'; if (rc < 0) return rc; return OSMO_MAX(0, end_nibble - start_nibble); } /*! Convert string to BCD. * The given nibble offsets are interpreted in BCD order, i.e. nibble 0 is bcd[0] & 0x0f, nibble 1 is bcd[0] & 0xf0, nibble * 3 is bcd[1] & 0x0f, etc.. * \param[out] dst Output BCD buffer. * \param[in] dst_size sizeof() the output string buffer. * \param[in] digits String containing decimal or hexadecimal digits in upper or lower case. * \param[in] start_nibble Offset to start from, in nibbles, typically 1 to skip the first (MI type) nibble. * \param[in] end_nibble Negative to write all digits found in str, followed by 0xf nibbles to fill any started octet. * If >= 0, stop before this offset in nibbles, e.g. to get default behavior, pass * start_nibble + strlen(str) + ((start_nibble + strlen(str)) & 1? 1 : 0) + 1. * \param[in] allow_hex If false, return error if there are hexadecimal digits (A-F). If true, write those to * BCD. * \returns The buffer size in octets that is used to place all bcd digits (including the skipped nibbles * from 'start_nibble' and rounded up to full octets); -EINVAL on invalid digits; * -ENOMEM if dst is NULL, if dst_size is too small to contain all nibbles, or if start_nibble is negative. */ int osmo_str2bcd(uint8_t *dst, size_t dst_size, const char *digits, int start_nibble, int end_nibble, bool allow_hex) { const char *digit = digits; int nibble_i; if (!dst || !dst_size || start_nibble < 0) return -ENOMEM; if (end_nibble < 0) { end_nibble = start_nibble + strlen(digits); /* If the last octet is not complete, add another filler nibble */ if (end_nibble & 1) end_nibble++; } if ((unsigned int) (end_nibble / 2) > dst_size) return -ENOMEM; for (nibble_i = start_nibble; nibble_i < end_nibble; nibble_i++) { uint8_t nibble = 0xf; int octet = nibble_i >> 1; if (*digit) { char c = *digit; digit++; if (c >= '0' && c <= '9') nibble = c - '0'; else if (allow_hex && c >= 'A' && c <= 'F') nibble = 0xa + (c - 'A'); else if (allow_hex && c >= 'a' && c <= 'f') nibble = 0xa + (c - 'a'); else return -EINVAL; } nibble &= 0xf; if ((nibble_i & 1)) dst[octet] = (nibble << 4) | (dst[octet] & 0x0f); else dst[octet] = (dst[octet] & 0xf0) | nibble; } /* floor(float(end_nibble) / 2) */ return end_nibble / 2; } /*! Parse a string containing hexadecimal digits * \param[in] str string containing ASCII encoded hexadecimal digits * \param[out] b output buffer * \param[in] max_len maximum space in output buffer * \returns number of parsed octets, or -1 on error */ int osmo_hexparse(const char *str, uint8_t *b, unsigned int max_len) { char c; uint8_t v; const char *strpos; unsigned int nibblepos = 0; memset(b, 0x00, max_len); for (strpos = str; (c = *strpos); strpos++) { /* skip whitespace */ if (c == ' ' || c == '\t' || c == '\n' || c == '\r') continue; /* If the buffer is too small, error out */ if (nibblepos >= (max_len << 1)) return -1; if (c >= '0' && c <= '9') v = c - '0'; else if (c >= 'a' && c <= 'f') v = 10 + (c - 'a'); else if (c >= 'A' && c <= 'F') v = 10 + (c - 'A'); else return -1; b[nibblepos >> 1] |= v << (nibblepos & 1 ? 0 : 4); nibblepos ++; } /* In case of uneven amount of digits, the last byte is not complete * and that's an error. */ if (nibblepos & 1) return -1; return nibblepos >> 1; } static __thread char hexd_buff[4096]; static const char hex_chars[] = "0123456789abcdef"; /*! Convert binary sequence to hexadecimal ASCII string. * \param[out] out_buf Output buffer to write the resulting string to. * \param[in] out_buf_size sizeof(out_buf). * \param[in] buf Input buffer, pointer to sequence of bytes. * \param[in] len Length of input buf in number of bytes. * \param[in] delim String to separate each byte; NULL or "" for no delim. * \param[in] delim_after_last If true, end the string in delim (true: "1a:ef:d9:", false: "1a:ef:d9"); * if out_buf has insufficient space, the string will always end in a delim. * \returns out_buf, containing a zero-terminated string, or "" (empty string) if out_buf == NULL or out_buf_size < 1. * * This function will print a sequence of bytes as hexadecimal numbers, adding one delim between each byte (e.g. for * delim passed as ":", return a string like "1a:ef:d9"). * * The delim_after_last argument exists to be able to exactly show the original osmo_hexdump() behavior, which always * ends the string with a delimiter. */ const char *osmo_hexdump_buf(char *out_buf, size_t out_buf_size, const unsigned char *buf, int len, const char *delim, bool delim_after_last) { int i; char *cur = out_buf; size_t delim_len; if (!out_buf || !out_buf_size) return ""; delim = delim ? : ""; delim_len = strlen(delim); for (i = 0; i < len; i++) { const char *delimp = delim; int len_remain = out_buf_size - (cur - out_buf) - 1; if (len_remain < (int) (2 + delim_len) && !(!delim_after_last && i == (len - 1) && len_remain >= 2)) break; *cur++ = hex_chars[buf[i] >> 4]; *cur++ = hex_chars[buf[i] & 0xf]; if (i == (len - 1) && !delim_after_last) break; while (len_remain > 1 && *delimp) { *cur++ = *delimp++; len_remain--; } } *cur = '\0'; return out_buf; } /*! Convert a sequence of unpacked bits to ASCII string, in user-supplied buffer. * \param[out] buf caller-provided output string buffer * \param[out] buf_len size of buf in bytes * \param[in] bits A sequence of unpacked bits * \param[in] len Length of bits * \return The output buffer (buf). */ char *osmo_ubit_dump_buf(char *buf, size_t buf_len, const uint8_t *bits, unsigned int len) { unsigned int i; if (len > buf_len-1) len = buf_len-1; memset(buf, 0, buf_len); for (i = 0; i < len; i++) { char outch; switch (bits[i]) { case 0: outch = '0'; break; case 0xff: outch = '?'; break; case 1: outch = '1'; break; default: outch = 'E'; break; } buf[i] = outch; } buf[buf_len-1] = 0; return buf; } /*! Convert a sequence of unpacked bits to ASCII string, in static buffer. * \param[in] bits A sequence of unpacked bits * \param[in] len Length of bits * \returns string representation in static buffer. */ char *osmo_ubit_dump(const uint8_t *bits, unsigned int len) { return osmo_ubit_dump_buf(hexd_buff, sizeof(hexd_buff), bits, len); } /*! Convert binary sequence to hexadecimal ASCII string * \param[in] buf pointer to sequence of bytes * \param[in] len length of buf in number of bytes * \returns pointer to zero-terminated string * * This function will print a sequence of bytes as hexadecimal numbers, * adding one space character between each byte (e.g. "1a ef d9") * * The maximum size of the output buffer is 4096 bytes, i.e. the maximum * number of input bytes that can be printed in one call is 1365! */ char *osmo_hexdump(const unsigned char *buf, int len) { osmo_hexdump_buf(hexd_buff, sizeof(hexd_buff), buf, len, " ", true); return hexd_buff; } /*! Convert binary sequence to hexadecimal ASCII string * \param[in] ctx talloc context from where to allocate the output string * \param[in] buf pointer to sequence of bytes * \param[in] len length of buf in number of bytes * \returns pointer to zero-terminated string * * This function will print a sequence of bytes as hexadecimal numbers, * adding one space character between each byte (e.g. "1a ef d9") */ char *osmo_hexdump_c(const void *ctx, const unsigned char *buf, int len) { size_t hexd_buff_len = len * 3 + 1; char *hexd_buff = talloc_size(ctx, hexd_buff_len); if (!hexd_buff) return NULL; osmo_hexdump_buf(hexd_buff, hexd_buff_len, buf, len, " ", true); return hexd_buff; } /*! Convert binary sequence to hexadecimal ASCII string * \param[in] buf pointer to sequence of bytes * \param[in] len length of buf in number of bytes * \returns pointer to zero-terminated string * * This function will print a sequence of bytes as hexadecimal numbers, * without any space character between each byte (e.g. "1aefd9") * * The maximum size of the output buffer is 4096 bytes, i.e. the maximum * number of input bytes that can be printed in one call is 2048! */ char *osmo_hexdump_nospc(const unsigned char *buf, int len) { osmo_hexdump_buf(hexd_buff, sizeof(hexd_buff), buf, len, "", true); return hexd_buff; } /*! Convert binary sequence to hexadecimal ASCII string * \param[in] ctx talloc context from where to allocate the output string * \param[in] buf pointer to sequence of bytes * \param[in] len length of buf in number of bytes * \returns pointer to zero-terminated string * * This function will print a sequence of bytes as hexadecimal numbers, * without any space character between each byte (e.g. "1aefd9") */ char *osmo_hexdump_nospc_c(const void *ctx, const unsigned char *buf, int len) { size_t hexd_buff_len = len * 2 + 1; char *hexd_buff = talloc_size(ctx, hexd_buff_len); if (!hexd_buff) return NULL; osmo_hexdump_buf(hexd_buff, hexd_buff_len, buf, len, "", true); return hexd_buff; } /* Compat with previous typo to preserve abi */ char *osmo_osmo_hexdump_nospc(const unsigned char *buf, int len) #if defined(__MACH__) && defined(__APPLE__) ; #else __attribute__((weak, alias("osmo_hexdump_nospc"))); #endif #include "config.h" #ifdef HAVE_CTYPE_H #include /*! Convert an entire string to lower case * \param[out] out output string, caller-allocated * \param[in] in input string */ void osmo_str2lower(char *out, const char *in) { unsigned int i; for (i = 0; i < strlen(in); i++) out[i] = tolower((const unsigned char)in[i]); out[strlen(in)] = '\0'; } /*! Convert an entire string to upper case * \param[out] out output string, caller-allocated * \param[in] in input string */ void osmo_str2upper(char *out, const char *in) { unsigned int i; for (i = 0; i < strlen(in); i++) out[i] = toupper((const unsigned char)in[i]); out[strlen(in)] = '\0'; } #endif /* HAVE_CTYPE_H */ /*! Wishful thinking to generate a constant time compare * \param[in] exp Expected data * \param[in] rel Comparison value * \param[in] count Number of bytes to compare * \returns 1 in case \a exp equals \a rel; zero otherwise * * Compare count bytes of exp to rel. Return 0 if they are identical, 1 * otherwise. Do not return a mismatch on the first mismatching byte, * but always compare all bytes, regardless. The idea is that the amount of * matching bytes cannot be inferred from the time the comparison took. */ int osmo_constant_time_cmp(const uint8_t *exp, const uint8_t *rel, const int count) { int x = 0, i; for (i = 0; i < count; ++i) x |= exp[i] ^ rel[i]; /* if x is zero, all data was identical */ return x? 1 : 0; } /*! Generic retrieval of 1..8 bytes as big-endian uint64_t * \param[in] data Input data as byte-array * \param[in] data_len Length of \a data in octets * \returns uint64_t of \a data interpreted as big-endian * * This is like osmo_load64be_ext, except that if data_len is less than * sizeof(uint64_t), the data is interpreted as the least significant bytes * (osmo_load64be_ext loads them as the most significant bytes into the * returned uint64_t). In this way, any integer size up to 64 bits can be * decoded conveniently by using sizeof(), without the need to call specific * numbered functions (osmo_load16, 32, ...). */ uint64_t osmo_decode_big_endian(const uint8_t *data, size_t data_len) { uint64_t value = 0; while (data_len > 0) { value = (value << 8) + *data; data += 1; data_len -= 1; } return value; } /*! Generic big-endian encoding of big endian number up to 64bit * \param[in] value unsigned integer value to be stored * \param[in] data_len number of octets * \returns static buffer containing big-endian stored value * * This is like osmo_store64be_ext, except that this returns a static buffer of * the result (for convenience, but not threadsafe). If data_len is less than * sizeof(uint64_t), only the least significant bytes of value are encoded. */ uint8_t *osmo_encode_big_endian(uint64_t value, size_t data_len) { static __thread uint8_t buf[sizeof(uint64_t)]; OSMO_ASSERT(data_len <= ARRAY_SIZE(buf)); osmo_store64be_ext(value, buf, data_len); return buf; } /*! Copy a C-string into a sized buffer * \param[in] src source string * \param[out] dst destination string * \param[in] siz size of the \a dst buffer * \returns length of \a src * * Copy at most \a siz bytes from \a src to \a dst, ensuring that the result is * NUL terminated. The NUL character is included in \a siz, i.e. passing the * actual sizeof(*dst) is correct. * * Note, a similar function that also limits the input buffer size is osmo_print_n(). */ size_t osmo_strlcpy(char *dst, const char *src, size_t siz) { size_t ret = src ? strlen(src) : 0; if (siz) { size_t len = OSMO_MIN(siz - 1, ret); if (len) memcpy(dst, src, len); dst[len] = '\0'; } return ret; } /*! Find first occurence of a char in a size limited string. * Like strchr() but with a buffer size limit. * \param[in] str String buffer to examine. * \param[in] str_size sizeof(str). * \param[in] c Character to look for. * \return Pointer to the matched char, or NULL if not found. */ const char *osmo_strnchr(const char *str, size_t str_size, char c) { const char *end = str + str_size; const char *pos; if (!str) return NULL; for (pos = str; pos < end; pos++) { if (c == *pos) return pos; if (!*pos) return NULL; } return NULL; } /*! Validate that a given string is a hex string within given size limits. * Note that each hex digit amounts to a nibble, so if checking for a hex * string to result in N bytes, pass amount of digits as 2*N. * \param str A nul-terminated string to validate, or NULL. * \param min_digits least permitted amount of digits. * \param max_digits most permitted amount of digits. * \param require_even if true, require an even amount of digits. * \returns true when the hex_str contains only hexadecimal digits (no * whitespace) and matches the requested length; also true * when min_digits <= 0 and str is NULL. */ bool osmo_is_hexstr(const char *str, int min_digits, int max_digits, bool require_even) { int len; /* Use unsigned char * to avoid a compiler warning of * "error: array subscript has type 'char' [-Werror=char-subscripts]" */ const unsigned char *pos = (const unsigned char*)str; if (!pos) return min_digits < 1; for (len = 0; *pos && len < max_digits; len++, pos++) if (!isxdigit(*pos)) return false; if (len < min_digits) return false; /* With not too many digits, we should have reached *str == nul */ if (*pos) return false; if (require_even && (len & 1)) return false; return true; } static const char osmo_identifier_illegal_chars[] = "., {}[]()<>|~\\^`'\"?=;/+*&%$#!"; /*! Determine if a given identifier is valid, i.e. doesn't contain illegal chars * \param[in] str String to validate * \param[in] sep_chars Permitted separation characters between identifiers. * \returns true in case \a str contains only valid identifiers and sep_chars, false otherwise */ bool osmo_separated_identifiers_valid(const char *str, const char *sep_chars) { /* characters that are illegal in names */ unsigned int i; size_t len; /* an empty string is not a valid identifier */ if (!str || (len = strlen(str)) == 0) return false; for (i = 0; i < len; i++) { if (sep_chars && strchr(sep_chars, str[i])) continue; /* check for 7-bit ASCII */ if (str[i] & 0x80) return false; if (!isprint((int)str[i])) return false; /* check for some explicit reserved control characters */ if (strchr(osmo_identifier_illegal_chars, str[i])) return false; } return true; } /*! Determine if a given identifier is valid, i.e. doesn't contain illegal chars * \param[in] str String to validate * \returns true in case \a str contains valid identifier, false otherwise */ bool osmo_identifier_valid(const char *str) { return osmo_separated_identifiers_valid(str, NULL); } /*! Replace characters in the given string buffer so that it is guaranteed to pass osmo_separated_identifiers_valid(). * To guarantee passing osmo_separated_identifiers_valid(), replace_with must not itself be an illegal character. If in * doubt, use '-'. * \param[inout] str Identifier to sanitize, must be nul terminated and in a writable buffer. * \param[in] sep_chars Additional characters that are to be replaced besides osmo_identifier_illegal_chars. * \param[in] replace_with Replace any illegal characters with this character. */ void osmo_identifier_sanitize_buf(char *str, const char *sep_chars, char replace_with) { char *pos; if (!str) return; for (pos = str; *pos; pos++) { if (strchr(osmo_identifier_illegal_chars, *pos) || (sep_chars && strchr(sep_chars, *pos))) *pos = replace_with; } } /*! Like osmo_escape_str_buf2, but with unusual ordering of arguments, and may sometimes return string constants instead * of writing to buf for error cases or empty input. * Most *_buf() functions have the buffer and size as first arguments, here the arguments are last. * In particular, this function signature doesn't work with OSMO_STRBUF_APPEND_NOLEN(). * \param[in] str A string that may contain any characters. * \param[in] len Pass -1 to print until nul char, or >= 0 to force a length. * \param[inout] buf string buffer to write escaped characters to. * \param[in] bufsize size of \a buf. * \returns buf containing an escaped representation, possibly truncated, * or "(null)" if str == NULL, or "(error)" in case of errors. */ const char *osmo_escape_str_buf(const char *str, int in_len, char *buf, size_t bufsize) { if (!str) return "(null)"; if (!buf || !bufsize) return "(error)"; return osmo_escape_str_buf2(buf, bufsize, str, in_len); } /*! Copy N characters to a buffer with a function signature useful for OSMO_STRBUF_APPEND(). * Similarly to snprintf(), the result is always nul terminated (except if buf is NULL or bufsize is 0). * \param[out] buf Target buffer. * \param[in] bufsize sizeof(buf). * \param[in] str String to copy. * \param[in] n Maximum number of non-nul characters to copy. * \return Number of characters that would be written if bufsize were large enough excluding '\0' (like snprintf()). */ int osmo_print_n(char *buf, size_t bufsize, const char *str, size_t n) { size_t write_n; if (!str) str = ""; n = strnlen(str, n); if (!buf || !bufsize) return n; write_n = n; if (write_n >= bufsize) write_n = bufsize - 1; if (write_n) strncpy(buf, str, write_n); buf[write_n] = '\0'; return n; } /*! Return the string with all non-printable characters escaped. * This internal function is the implementation for all osmo_escape_str* and osmo_quote_str* API versions. * It provides both the legacy (non C compatible) escaping, as well as C compatible string constant syntax, * and it provides a return value of characters-needed, to allow producing un-truncated strings in all cases. * \param[out] buf string buffer to write escaped characters to. * \param[in] bufsize sizeof(buf). * \param[in] str A string that may contain any characters. * \param[in] in_len Pass -1 to print until nul char, or >= 0 to force a length (also past nul chars). * \param[in] legacy_format If false, return C compatible string constants ("\x0f"), if true the legacy * escaping format ("\15"). The legacy format also escapes as "\a\b\f\v", while * the non-legacy format also escapes those as "\xNN" sequences. * \return Number of characters that would be written if bufsize were large enough excluding '\0' (like snprintf()). */ static int _osmo_escape_str_buf(char *buf, size_t bufsize, const char *str, int in_len, bool legacy_format) { struct osmo_strbuf sb = { .buf = buf, .len = bufsize }; int in_pos = 0; int next_unprintable = 0; if (!str) in_len = 0; if (in_len < 0) in_len = strlen(str); /* Make sure of '\0' termination */ if (!in_len) OSMO_STRBUF_PRINTF(sb, "%s", ""); while (in_pos < in_len) { for (next_unprintable = in_pos; next_unprintable < in_len && isprint((int)str[next_unprintable]) && str[next_unprintable] != '"' && str[next_unprintable] != '\\'; next_unprintable++); OSMO_STRBUF_APPEND(sb, osmo_print_n, &str[in_pos], next_unprintable - in_pos); in_pos = next_unprintable; if (in_pos == in_len) goto done; switch (str[next_unprintable]) { #define BACKSLASH_CASE(c, repr) \ case c: \ OSMO_STRBUF_PRINTF(sb, "\\%c", repr); \ break BACKSLASH_CASE('\n', 'n'); BACKSLASH_CASE('\r', 'r'); BACKSLASH_CASE('\t', 't'); BACKSLASH_CASE('\0', '0'); BACKSLASH_CASE('\\', '\\'); BACKSLASH_CASE('"', '"'); default: if (legacy_format) { switch (str[next_unprintable]) { BACKSLASH_CASE('\a', 'a'); BACKSLASH_CASE('\b', 'b'); BACKSLASH_CASE('\v', 'v'); BACKSLASH_CASE('\f', 'f'); default: OSMO_STRBUF_PRINTF(sb, "\\%u", (unsigned char)str[in_pos]); break; } break; } OSMO_STRBUF_PRINTF(sb, "\\x%02x", (unsigned char)str[in_pos]); break; } in_pos ++; #undef BACKSLASH_CASE } done: return sb.chars_needed; } /*! Return the string with all non-printable characters escaped. * \param[out] buf string buffer to write escaped characters to. * \param[in] bufsize sizeof(buf). * \param[in] str A string that may contain any characters. * \param[in] in_len Pass -1 to print until nul char, or >= 0 to force a length (also past nul chars). * \return Number of characters that would be written if bufsize were large enough excluding '\0' (like snprintf()). */ int osmo_escape_str_buf3(char *buf, size_t bufsize, const char *str, int in_len) { return _osmo_escape_str_buf(buf, bufsize, str, in_len, false); } /*! Return the string with all non-printable characters escaped. * \param[out] buf string buffer to write escaped characters to. * \param[in] bufsize sizeof(buf). * \param[in] str A string that may contain any characters. * \param[in] in_len Pass -1 to print until nul char, or >= 0 to force a length (also past nul chars). * \return The output buffer (buf). */ char *osmo_escape_str_buf2(char *buf, size_t bufsize, const char *str, int in_len) { _osmo_escape_str_buf(buf, bufsize, str, in_len, true); return buf; } /*! Return the string with all non-printable characters escaped. * Call osmo_escape_str_buf() with a static buffer. * \param[in] str A string that may contain any characters. * \param[in] len Pass -1 to print until nul char, or >= 0 to force a length. * \returns buf containing an escaped representation, possibly truncated, or str itself. */ const char *osmo_escape_str(const char *str, int in_len) { return osmo_escape_str_buf(str, in_len, namebuf, sizeof(namebuf)); } /*! Return the string with all non-printable characters escaped, in dynamically-allocated buffer. * \param[in] str A string that may contain any characters. * \param[in] len Pass -1 to print until nul char, or >= 0 to force a length. * \returns dynamically-allocated output buffer, containing an escaped representation */ char *osmo_escape_str_c(const void *ctx, const char *str, int in_len) { /* The string will be at least as long as in_len, but some characters might need escaping. * These extra bytes should catch most usual escaping situations, avoiding a second run in OSMO_NAME_C_IMPL. */ OSMO_NAME_C_IMPL(ctx, in_len + 16, "ERROR", _osmo_escape_str_buf, str, in_len, true); } /*! Return a quoted and escaped representation of the string. * This internal function is the implementation for all osmo_quote_str* API versions. * It provides both the legacy (non C compatible) escaping, as well as C compatible string constant syntax, * and it provides a return value of characters-needed, to allow producing un-truncated strings in all cases. * \param[out] buf string buffer to write escaped characters to. * \param[in] bufsize sizeof(buf). * \param[in] str A string that may contain any characters. * \param[in] in_len Pass -1 to print until nul char, or >= 0 to force a length (also past nul chars). * \param[in] legacy_format If false, return C compatible string constants ("\x0f"), if true the legacy * escaping format ("\15"). The legacy format also escapes as "\a\b\f\v", while * the non-legacy format also escapes those as "\xNN" sequences. * \return Number of characters that would be written if bufsize were large enough excluding '\0' (like snprintf()). */ static size_t _osmo_quote_str_buf(char *buf, size_t bufsize, const char *str, int in_len, bool legacy_format) { struct osmo_strbuf sb = { .buf = buf, .len = bufsize }; if (!str) OSMO_STRBUF_PRINTF(sb, "NULL"); else { OSMO_STRBUF_PRINTF(sb, "\""); OSMO_STRBUF_APPEND(sb, _osmo_escape_str_buf, str, in_len, legacy_format); OSMO_STRBUF_PRINTF(sb, "\""); } return sb.chars_needed; } /*! Like osmo_escape_str_buf3(), but returns double-quotes around a string, or "NULL" for a NULL string. * This allows passing any char* value and get its C representation as string. * The function signature is suitable for OSMO_STRBUF_APPEND_NOLEN(). * \param[out] buf string buffer to write escaped characters to. * \param[in] bufsize sizeof(buf). * \param[in] str A string that may contain any characters. * \param[in] in_len Pass -1 to print until nul char, or >= 0 to force a length. * \return Number of characters that would be written if bufsize were large enough excluding '\0' (like snprintf()). */ int osmo_quote_str_buf3(char *buf, size_t bufsize, const char *str, int in_len) { return _osmo_quote_str_buf(buf, bufsize, str, in_len, false); } /*! Like osmo_escape_str_buf2(), but returns double-quotes around a string, or "NULL" for a NULL string. * This allows passing any char* value and get its C representation as string. * The function signature is suitable for OSMO_STRBUF_APPEND_NOLEN(). * \param[out] buf string buffer to write escaped characters to. * \param[in] bufsize sizeof(buf). * \param[in] str A string that may contain any characters. * \param[in] in_len Pass -1 to print until nul char, or >= 0 to force a length. * \return The output buffer (buf). */ char *osmo_quote_str_buf2(char *buf, size_t bufsize, const char *str, int in_len) { _osmo_quote_str_buf(buf, bufsize, str, in_len, true); return buf; } /*! Like osmo_quote_str_buf2, but with unusual ordering of arguments, and may sometimes return string constants instead * of writing to buf for error cases or empty input. * Most *_buf() functions have the buffer and size as first arguments, here the arguments are last. * In particular, this function signature doesn't work with OSMO_STRBUF_APPEND_NOLEN(). * \param[in] str A string that may contain any characters. * \param[in] in_len Pass -1 to print until nul char, or >= 0 to force a length. * \returns buf containing a quoted and escaped representation, possibly truncated. */ const char *osmo_quote_str_buf(const char *str, int in_len, char *buf, size_t bufsize) { if (!str) return "NULL"; if (!buf || !bufsize) return "(error)"; _osmo_quote_str_buf(buf, bufsize, str, in_len, true); return buf; } /*! Like osmo_quote_str_buf() but returns the result in a static buffer. * The static buffer is shared with get_value_string() and osmo_escape_str(). * \param[in] str A string that may contain any characters. * \param[in] in_len Pass -1 to print until nul char, or >= 0 to force a length. * \returns static buffer containing a quoted and escaped representation, possibly truncated. */ const char *osmo_quote_str(const char *str, int in_len) { _osmo_quote_str_buf(namebuf, sizeof(namebuf), str, in_len, true); return namebuf; } /*! Like osmo_quote_str_buf() but returns the result in a dynamically-allocated buffer. * \param[in] str A string that may contain any characters. * \param[in] in_len Pass -1 to print until nul char, or >= 0 to force a length. * \returns dynamically-allocated buffer containing a quoted and escaped representation. */ char *osmo_quote_str_c(const void *ctx, const char *str, int in_len) { /* The string will be at least as long as in_len, but some characters might need escaping. * These extra bytes should catch most usual escaping situations, avoiding a second run in OSMO_NAME_C_IMPL. */ OSMO_NAME_C_IMPL(ctx, in_len + 16, "ERROR", _osmo_quote_str_buf, str, in_len, true); } /*! Return the string with all non-printable characters escaped. * In contrast to osmo_escape_str_buf2(), this returns the needed buffer size suitable for OSMO_STRBUF_APPEND(), and * this escapes characters in a way compatible with C string constant syntax. * \param[out] buf string buffer to write escaped characters to. * \param[in] bufsize sizeof(buf). * \param[in] str A string that may contain any characters. * \param[in] in_len Pass -1 to print until nul char, or >= 0 to force a length (also past nul chars). * \return Number of characters that would be written if bufsize were large enough excluding '\0' (like snprintf()). */ size_t osmo_escape_cstr_buf(char *buf, size_t bufsize, const char *str, int in_len) { return _osmo_escape_str_buf(buf, bufsize, str, in_len, false); } /*! Return the string with all non-printable characters escaped, in dynamically-allocated buffer. * In contrast to osmo_escape_str_c(), this escapes characters in a way compatible with C string constant syntax, and * allocates sufficient memory in all cases. * \param[in] str A string that may contain any characters. * \param[in] len Pass -1 to print until nul char, or >= 0 to force a length. * \returns dynamically-allocated buffer, containing an escaped representation. */ char *osmo_escape_cstr_c(void *ctx, const char *str, int in_len) { /* The string will be at least as long as in_len, but some characters might need escaping. * These extra bytes should catch most usual escaping situations, avoiding a second run in OSMO_NAME_C_IMPL. */ OSMO_NAME_C_IMPL(ctx, in_len + 16, "ERROR", _osmo_escape_str_buf, str, in_len, false); } /*! Like osmo_escape_str_buf2(), but returns double-quotes around a string, or "NULL" for a NULL string. * This allows passing any char* value and get its C representation as string. * The function signature is suitable for OSMO_STRBUF_APPEND_NOLEN(). * In contrast to osmo_escape_str_buf2(), this returns the needed buffer size suitable for OSMO_STRBUF_APPEND(), and * this escapes characters in a way compatible with C string constant syntax. * \param[out] buf string buffer to write escaped characters to. * \param[in] bufsize sizeof(buf). * \param[in] str A string that may contain any characters. * \param[in] in_len Pass -1 to print until nul char, or >= 0 to force a length. * \return Number of characters that would be written if bufsize were large enough excluding '\0' (like snprintf()). */ size_t osmo_quote_cstr_buf(char *buf, size_t bufsize, const char *str, int in_len) { return _osmo_quote_str_buf(buf, bufsize, str, in_len, false); } /*! Return the string quoted and with all non-printable characters escaped, in dynamically-allocated buffer. * In contrast to osmo_quote_str_c(), this escapes characters in a way compatible with C string constant syntax, and * allocates sufficient memory in all cases. * \param[in] str A string that may contain any characters. * \param[in] len Pass -1 to print until nul char, or >= 0 to force a length. * \returns dynamically-allocated buffer, containing a quoted and escaped representation. */ char *osmo_quote_cstr_c(void *ctx, const char *str, int in_len) { /* The string will be at least as long as in_len plus two quotes, but some characters might need escaping. * These extra bytes should catch most usual escaping situations, avoiding a second run in OSMO_NAME_C_IMPL. */ OSMO_NAME_C_IMPL(ctx, in_len + 16, "ERROR", _osmo_quote_str_buf, str, in_len, false); } /*! perform an integer square root operation on unsigned 32bit integer. * This implementation is taken from "Hacker's Delight" Figure 11-1 "Integer square root, Newton's * method", which can also be found at http://www.hackersdelight.org/hdcodetxt/isqrt.c.txt */ uint32_t osmo_isqrt32(uint32_t x) { uint32_t x1; int s, g0, g1; if (x <= 1) return x; s = 1; x1 = x - 1; if (x1 > 0xffff) { s = s + 8; x1 = x1 >> 16; } if (x1 > 0xff) { s = s + 4; x1 = x1 >> 8; } if (x1 > 0xf) { s = s + 2; x1 = x1 >> 4; } if (x1 > 0x3) { s = s + 1; } g0 = 1 << s; /* g0 = 2**s */ g1 = (g0 + (x >> s)) >> 1; /* g1 = (g0 + x/g0)/2 */ /* converges after four to five divisions for arguments up to 16,785,407 */ while (g1 < g0) { g0 = g1; g1 = (g0 + (x/g0)) >> 1; } return g0; } /*! Convert a string to lowercase, while checking buffer size boundaries. * The result written to \a dest is guaranteed to be nul terminated if \a dest_len > 0. * If dest == src, the string is converted in-place, if necessary truncated at dest_len - 1 characters * length as well as nul terminated. * Note: similar osmo_str2lower(), but safe to use for src strings of arbitrary length. * \param[out] dest Target buffer to write lowercase string. * \param[in] dest_len Maximum buffer size of dest (e.g. sizeof(dest)). * \param[in] src String to convert to lowercase. * \returns Length of \a src, like osmo_strlcpy(), but if \a dest == \a src at most \a dest_len - 1. */ size_t osmo_str_tolower_buf(char *dest, size_t dest_len, const char *src) { size_t rc; if (dest == src) { if (dest_len < 1) return 0; dest[dest_len - 1] = '\0'; rc = strlen(dest); } else { if (dest_len < 1) return strlen(src); rc = osmo_strlcpy(dest, src, dest_len); } for (; *dest; dest++) *dest = tolower(*dest); return rc; } /*! Convert a string to lowercase, using a static buffer. * The resulting string may be truncated if the internally used static buffer is shorter than src. * The internal buffer is at least 128 bytes long, i.e. guaranteed to hold at least 127 characters and a * terminating nul. The static buffer returned is shared with osmo_str_toupper(). * See also osmo_str_tolower_buf(). * \param[in] src String to convert to lowercase. * \returns Resulting lowercase string in a static buffer, always nul terminated. */ const char *osmo_str_tolower(const char *src) { osmo_str_tolower_buf(capsbuf, sizeof(capsbuf), src); return capsbuf; } /*! Convert a string to lowercase, dynamically allocating the output from given talloc context * See also osmo_str_tolower_buf(). * \param[in] ctx talloc context from where to allocate the output string * \param[in] src String to convert to lowercase. * \returns Resulting lowercase string in a dynamically allocated buffer, always nul terminated. */ char *osmo_str_tolower_c(const void *ctx, const char *src) { size_t buf_len = strlen(src) + 1; char *buf = talloc_size(ctx, buf_len); if (!buf) return NULL; osmo_str_tolower_buf(buf, buf_len, src); return buf; } /*! Convert a string to uppercase, while checking buffer size boundaries. * The result written to \a dest is guaranteed to be nul terminated if \a dest_len > 0. * If dest == src, the string is converted in-place, if necessary truncated at dest_len - 1 characters * length as well as nul terminated. * Note: similar osmo_str2upper(), but safe to use for src strings of arbitrary length. * \param[out] dest Target buffer to write uppercase string. * \param[in] dest_len Maximum buffer size of dest (e.g. sizeof(dest)). * \param[in] src String to convert to uppercase. * \returns Length of \a src, like osmo_strlcpy(), but if \a dest == \a src at most \a dest_len - 1. */ size_t osmo_str_toupper_buf(char *dest, size_t dest_len, const char *src) { size_t rc; if (dest == src) { if (dest_len < 1) return 0; dest[dest_len - 1] = '\0'; rc = strlen(dest); } else { if (dest_len < 1) return strlen(src); rc = osmo_strlcpy(dest, src, dest_len); } for (; *dest; dest++) *dest = toupper(*dest); return rc; } /*! Convert a string to uppercase, using a static buffer. * The resulting string may be truncated if the internally used static buffer is shorter than src. * The internal buffer is at least 128 bytes long, i.e. guaranteed to hold at least 127 characters and a * terminating nul. The static buffer returned is shared with osmo_str_tolower(). * See also osmo_str_toupper_buf(). * \param[in] src String to convert to uppercase. * \returns Resulting uppercase string in a static buffer, always nul terminated. */ const char *osmo_str_toupper(const char *src) { osmo_str_toupper_buf(capsbuf, sizeof(capsbuf), src); return capsbuf; } /*! Convert a string to uppercase, dynamically allocating the output from given talloc context * See also osmo_str_tolower_buf(). * \param[in] ctx talloc context from where to allocate the output string * \param[in] src String to convert to uppercase. * \returns Resulting uppercase string in a dynamically allocated buffer, always nul terminated. */ char *osmo_str_toupper_c(const void *ctx, const char *src) { size_t buf_len = strlen(src) + 1; char *buf = talloc_size(ctx, buf_len); if (!buf) return NULL; osmo_str_toupper_buf(buf, buf_len, src); return buf; } /*! Calculate the Luhn checksum (as used for IMEIs). * \param[in] in Input digits in ASCII string representation. * \param[in] in_len Count of digits to use for the input (14 for IMEI). * \returns checksum char (e.g. '3'); negative on error */ char osmo_luhn(const char* in, int in_len) { int i, sum = 0; /* All input must be numbers */ for (i = 0; i < in_len; i++) { if (!isdigit((unsigned char)in[i])) return -EINVAL; } /* Double every second digit and add it to sum */ for (i = in_len - 1; i >= 0; i -= 2) { int dbl = (in[i] - '0') * 2; if (dbl > 9) dbl -= 9; sum += dbl; } /* Add other digits to sum */ for (i = in_len - 2; i >= 0; i -= 2) sum += in[i] - '0'; /* Final checksum */ return (sum * 9) % 10 + '0'; } /*! Remove up to N chars from the end of an osmo_strbuf. * |--char-count---| - - chars_needed - - | * |<---------drop----------| */ void osmo_strbuf_drop_tail(struct osmo_strbuf *sb, size_t n_chars) { size_t drop_n; if (sb->pos <= sb->buf) return; drop_n = OSMO_MIN(sb->chars_needed, n_chars); sb->chars_needed -= drop_n; /* chars_needed was reduced by n_chars, which may have been entirely behind the end of a full buffer, within the * hypothetical chars_needed. Modify the buffer tail pos only if the buffer is not or longer full now. */ if (sb->chars_needed >= OSMO_STRBUF_CHAR_COUNT(*sb)) return; sb->pos = sb->buf + sb->chars_needed; *sb->pos = '\0'; } /*! Let osmo_strbuf know that n_chars characters (excluding nul) were written to the end of the buffer. * If sb is nonempty, the n_chars are assumed to have been written to sb->pos. If sb is still empty and pos == NULL, the * n_chars are assumed to have been written to the start of the buffer. * Advance sb->pos and sb->chars_needed by at most n_chars, or up to sb->len - 1. * Ensure nul termination. */ void osmo_strbuf_added_tail(struct osmo_strbuf *sb, size_t n_chars) { /* On init of an osmo_strbuf, sb->pos == NULL, which is defined as semantically identical to pointing at the * start of the buffer. A caller may just write to the buffer and call osmo_strbuf_added_tail(), in which case * still pos == NULL. pos != NULL happens as soon as the first OSMO_STRBUF_*() API has acted on the strbuf. */ if (!sb->pos) sb->pos = sb->buf; sb->chars_needed += n_chars; /* first get remaining space, not counting trailing nul; but safeguard against empty buffer */ size_t n_added = OSMO_STRBUF_REMAIN(*sb); if (n_added) n_added--; /* do not add more than fit in sb->len, still ensuring nul termination */ n_added = OSMO_MIN(n_added, n_chars); if (n_added) sb->pos += n_added; /* when a strbuf is full, sb->pos may point after the final nul, so nul terminate only when pos is valid. */ if (sb->pos < sb->buf + sb->len) *sb->pos = '\0'; } /*! Compare start of a string. * This is an optimisation of 'strstr(str, startswith_str) == str' because it doesn't search through the entire string. * \param str (Longer) string to compare. * \param startswith_str (Shorter) string to compare with the start of str. * \return true iff the first characters of str fully match startswith_str or startswith_str is empty. */ bool osmo_str_startswith(const char *str, const char *startswith_str) { if (!startswith_str || !*startswith_str) return true; if (!str) return false; return strncmp(str, startswith_str, strlen(startswith_str)) == 0; } /*! Convert a string of a floating point number to a signed int, with a decimal factor (fixed-point precision). * For example, with precision=3, convert "-1.23" to -1230. In other words, the float value is multiplied by * 10 to-the-power-of precision to obtain the returned integer. * The usable range of digits is -INT64_MAX .. INT64_MAX -- note, not INT64_MIN! The value of INT64_MIN is excluded to * reduce implementation complexity. See also utils_test.c. * The advantage over using sscanf("%f") is guaranteed precision: float or double types may apply rounding in the * conversion result. osmo_float_str_to_int() and osmo_int_to_float_str_buf() guarantee true results when converting * back and forth between string and int. * \param[out] val Returned integer value. * \param[in] str String of a float, like '-12.345'. * \param[in] precision Fixed-point precision, or * \returns 0 on success, negative on error. */ int osmo_float_str_to_int(int64_t *val, const char *str, unsigned int precision) { const char *point; char *endptr; const char *p; int64_t sign = 1; int64_t integer = 0; int64_t decimal = 0; int64_t precision_factor; int64_t integer_max; int64_t decimal_max; unsigned int i; OSMO_ASSERT(val); *val = 0; if (!str) return -EINVAL; if (str[0] == '-') { str = str + 1; sign = -1; } else if (str[0] == '+') { str = str + 1; } if (!str[0]) return -EINVAL; /* Validate entire string as purely digits and at most one decimal dot. If not doing this here in advance, * parsing digits might stop early because of precision cut-off and miss validation of input data. */ point = NULL; for (p = str; *p; p++) { if (*p == '.') { if (point) return -EINVAL; point = p; } else if (!isdigit((unsigned char)*p)) return -EINVAL; } /* Parse integer part if there is one. If the string starts with a point, there's nothing to parse for the * integer part. */ if (!point || point > str) { errno = 0; integer = strtoll(str, &endptr, 10); if ((errno == ERANGE && (integer == LLONG_MAX || integer == LLONG_MIN)) || (errno != 0 && integer == 0)) return -ERANGE; if ((point && endptr != point) || (!point && *endptr)) return -EINVAL; } /* Parse the fractional part if there is any, and if the precision is nonzero (if we even care about fractional * digits) */ if (precision && point && point[1] != '\0') { /* limit the number of digits parsed to 'precision'. * If 'precision' is larger than the 19 digits representable in int64_t, skip some, to pick up lower * magnitude digits. */ unsigned int skip_digits = (precision < 20) ? 0 : precision - 20; char decimal_str[precision + 1]; osmo_strlcpy(decimal_str, point+1, precision+1); /* fill with zeros to make exactly 'precision' digits */ for (i = strlen(decimal_str); i < precision; i++) decimal_str[i] = '0'; decimal_str[precision] = '\0'; for (i = 0; i < skip_digits; i++) { /* When skipping digits because precision > nr-of-digits-in-int64_t, they must be zero; * if there is a nonzero digit above the precision, it's -ERANGE. */ if (decimal_str[i] != '0') return -ERANGE; } errno = 0; decimal = strtoll(decimal_str + skip_digits, &endptr, 10); if ((errno == ERANGE && (decimal == LLONG_MAX || decimal == LLONG_MIN)) || (errno != 0 && decimal == 0)) return -ERANGE; if (*endptr) return -EINVAL; } if (precision > 18) { /* Special case of returning more digits than fit in int64_t range, e.g. * osmo_float_str_to_int("0.0000000012345678901234567", precision=25) -> 12345678901234567. */ precision_factor = 0; integer_max = 0; decimal_max = INT64_MAX; } else { /* Do not surpass the resulting int64_t range. Depending on the amount of precision, the integer part * and decimal part have specific ranges they must comply to. */ precision_factor = 1; for (i = 0; i < precision; i++) precision_factor *= 10; integer_max = INT64_MAX / precision_factor; if (integer == integer_max) decimal_max = INT64_MAX % precision_factor; else decimal_max = INT64_MAX; } if (integer > integer_max) return -ERANGE; if (decimal > decimal_max) return -ERANGE; *val = sign * (integer * precision_factor + decimal); return 0; } /*! Convert an integer to a floating point string using a decimal quotient (fixed-point precision). * For example, with precision = 3, convert -1230 to "-1.23". * The usable range of digits is -INT64_MAX .. INT64_MAX -- note, not INT64_MIN! The value of INT64_MIN is excluded to * reduce implementation complexity. See also utils_test.c. * The advantage over using printf("%.6g") is guaranteed precision: float or double types may apply rounding in the * conversion result. osmo_float_str_to_int() and osmo_int_to_float_str_buf() guarantee true results when converting * back and forth between string and int. * The resulting string omits trailing zeros in the fractional part (like "%g" would) but never applies rounding. * \param[out] buf Buffer to write string to. * \param[in] buflen sizeof(buf). * \param[in] val Value to convert to float. * \returns number of chars that would be written, like snprintf(). */ int osmo_int_to_float_str_buf(char *buf, size_t buflen, int64_t val, unsigned int precision) { struct osmo_strbuf sb = { .buf = buf, .len = buflen }; unsigned int i; unsigned int w; int64_t precision_factor; if (val < 0) { OSMO_STRBUF_PRINTF(sb, "-"); if (val == INT64_MIN) { OSMO_STRBUF_PRINTF(sb, "ERR"); return sb.chars_needed; } val = -val; } if (precision > 18) { /* Special case of returning more digits than fit in int64_t range, e.g. * osmo_int_to_float_str(12345678901234567, precision=25) -> "0.0000000012345678901234567". */ if (!val) { OSMO_STRBUF_PRINTF(sb, "0"); return sb.chars_needed; } OSMO_STRBUF_PRINTF(sb, "0."); for (i = 19; i < precision; i++) OSMO_STRBUF_PRINTF(sb, "0"); precision = 19; } else { precision_factor = 1; for (i = 0; i < precision; i++) precision_factor *= 10; OSMO_STRBUF_PRINTF(sb, "%" PRId64, val / precision_factor); val %= precision_factor; if (!val) return sb.chars_needed; OSMO_STRBUF_PRINTF(sb, "."); } /* print fractional part, skip trailing zeros */ w = precision; while (!(val % 10)) { val /= 10; w--; } OSMO_STRBUF_PRINTF(sb, "%0*" PRId64, w, val); return sb.chars_needed; } /*! Convert an integer with a factor of a million to a floating point string. * For example, convert -1230000 to "-1.23". * \param[in] ctx Talloc ctx to allocate string buffer from. * \param[in] val Value to convert to float. * \returns resulting string, dynamically allocated. */ char *osmo_int_to_float_str_c(void *ctx, int64_t val, unsigned int precision) { OSMO_NAME_C_IMPL(ctx, 16, "ERROR", osmo_int_to_float_str_buf, val, precision) } /*! Convert a string of a number to int64_t, including all common strtoll() validity checks. * It's not so trivial to call strtoll() and properly verify that the input string was indeed a valid number string. * \param[out] result Buffer for the resulting integer number, or NULL if the caller is only interested in the * validation result (returned rc). * \param[in] str The string to convert. * \param[in] base The integer base, i.e. 10 for decimal numbers or 16 for hexadecimal, as in strtoll(). * \param[in] min_val The smallest valid number expected in the string. * \param[in] max_val The largest valid number expected in the string. * \return 0 on success, -EOVERFLOW if the number in the string exceeds int64_t, -ENOTSUPP if the base is not supported, * -ERANGE if the converted number exceeds the range [min_val..max_val] but is still within int64_t range, -E2BIG if * surplus characters follow after the number, -EINVAL if the string does not contain a number. In case of -ERANGE and * -E2BIG, the converted number is still accurately returned in result. In case of -EOVERFLOW, the returned value is * clamped to INT64_MIN..INT64_MAX. */ int osmo_str_to_int64(int64_t *result, const char *str, int base, int64_t min_val, int64_t max_val) { long long int val; char *endptr; if (result) *result = 0; if (!str || !*str) return -EINVAL; errno = 0; val = strtoll(str, &endptr, base); /* In case the number string exceeds long long int range, strtoll() clamps the returned value to LLONG_MIN or * LLONG_MAX. Make sure of the same here with respect to int64_t. */ if (val < INT64_MIN) { if (result) *result = INT64_MIN; return -ERANGE; } if (val > INT64_MAX) { if (result) *result = INT64_MAX; return -ERANGE; } if (result) *result = (int64_t)val; switch (errno) { case 0: break; case ERANGE: return -EOVERFLOW; default: case EINVAL: return -ENOTSUP; } if (!endptr || *endptr) { /* No chars were converted */ if (endptr == str) return -EINVAL; /* Or there are surplus chars after the converted number */ return -E2BIG; } if (val < min_val || val > max_val) return -ERANGE; return 0; } /*! Convert a string of a number to int, including all common strtoll() validity checks. * Same as osmo_str_to_int64() but using the plain int data type. * \param[out] result Buffer for the resulting integer number, or NULL if the caller is only interested in the * validation result (returned rc). * \param[in] str The string to convert. * \param[in] base The integer base, i.e. 10 for decimal numbers or 16 for hexadecimal, as in strtoll(). * \param[in] min_val The smallest valid number expected in the string. * \param[in] max_val The largest valid number expected in the string. * \return 0 on success, -EOVERFLOW if the number in the string exceeds int range, -ENOTSUPP if the base is not supported, * -ERANGE if the converted number exceeds the range [min_val..max_val] but is still within int range, -E2BIG if * surplus characters follow after the number, -EINVAL if the string does not contain a number. In case of -ERANGE and * -E2BIG, the converted number is still accurately returned in result. In case of -EOVERFLOW, the returned value is * clamped to INT_MIN..INT_MAX. */ int osmo_str_to_int(int *result, const char *str, int base, int min_val, int max_val) { int64_t val; int rc = osmo_str_to_int64(&val, str, base, min_val, max_val); /* In case the number string exceeds long long int range, strtoll() clamps the returned value to LLONG_MIN or * LLONG_MAX. Make sure of the same here with respect to int. */ if (val < INT_MIN) { if (result) *result = INT_MIN; return -EOVERFLOW; } if (val > INT_MAX) { if (result) *result = INT_MAX; return -EOVERFLOW; } if (result) *result = (int)val; return rc; } /*! Replace a string using talloc and release its prior content (if any). * This is a format string capable equivalent of osmo_talloc_replace_string(). * \param[in] ctx Talloc context to use for allocation. * \param[out] dst Pointer to string, will be updated with ptr to new string. * \param[in] fmt Format string that will be copied to newly allocated string. */ void osmo_talloc_replace_string_fmt(void *ctx, char **dst, const char *fmt, ...) { char *name = NULL; if (fmt != NULL) { va_list ap; va_start(ap, fmt); name = talloc_vasprintf(ctx, fmt, ap); va_end(ap); } talloc_free(*dst); *dst = name; } /*! @} */