diff --git a/lib/common/strings.c b/lib/common/strings.c index acf174d22d..1e5c2b2278 100644 --- a/lib/common/strings.c +++ b/lib/common/strings.c @@ -1,1442 +1,1443 @@ /* * Copyright 2004-2024 the Pacemaker project contributors * * The version control history for this file may have further details. * * This source code is licensed under the GNU Lesser General Public License * version 2.1 or later (LGPLv2.1+) WITHOUT ANY WARRANTY. */ #include "crm/common/results.h" #include #ifndef _GNU_SOURCE # define _GNU_SOURCE #endif #include #include #include #include #include #include // DBL_MIN #include #include #include /*! * \internal * \brief Scan a long long integer from a string * * \param[in] text String to scan * \param[out] result If not NULL, where to store scanned value * \param[in] default_value Value to use if text is NULL or invalid * \param[out] end_text If not NULL, where to store pointer to first * non-integer character * * \return Standard Pacemaker return code (\c pcmk_rc_ok on success, * \c EINVAL on failed string conversion due to invalid input, * or \c EOVERFLOW on arithmetic overflow) * \note Sets \c errno on error */ static int scan_ll(const char *text, long long *result, long long default_value, char **end_text) { long long local_result = default_value; char *local_end_text = NULL; int rc = pcmk_rc_ok; errno = 0; if (text != NULL) { local_result = strtoll(text, &local_end_text, 10); if (errno == ERANGE) { rc = EOVERFLOW; crm_warn("Integer parsed from '%s' was clipped to %lld", text, local_result); } else if (errno != 0) { rc = errno; local_result = default_value; crm_warn("Could not parse integer from '%s' (using %lld instead): " "%s", text, default_value, pcmk_rc_str(rc)); } else if (local_end_text == text) { rc = EINVAL; local_result = default_value; crm_warn("Could not parse integer from '%s' (using %lld instead): " "No digits found", text, default_value); } if ((end_text == NULL) && !pcmk__str_empty(local_end_text)) { crm_warn("Characters left over after parsing '%s': '%s'", text, local_end_text); } errno = rc; } if (end_text != NULL) { *end_text = local_end_text; } if (result != NULL) { *result = local_result; } return rc; } /*! * \internal * \brief Scan a long long integer value from a string * * \param[in] text The string to scan (may be NULL) * \param[out] result Where to store result (or NULL to ignore) * \param[in] default_value Value to use if text is NULL or invalid * * \return Standard Pacemaker return code */ int pcmk__scan_ll(const char *text, long long *result, long long default_value) { long long local_result = default_value; int rc = pcmk_rc_ok; if (text != NULL) { rc = scan_ll(text, &local_result, default_value, NULL); if (rc != pcmk_rc_ok) { local_result = default_value; } } if (result != NULL) { *result = local_result; } return rc; } /*! * \internal * \brief Scan an integer value from a string, constrained to a minimum * * \param[in] text The string to scan (may be NULL) * \param[out] result Where to store result (or NULL to ignore) * \param[in] minimum Value to use as default and minimum * * \return Standard Pacemaker return code * \note If the value is larger than the maximum integer, EOVERFLOW will be * returned and \p result will be set to the maximum integer. */ int pcmk__scan_min_int(const char *text, int *result, int minimum) { int rc; long long result_ll; rc = pcmk__scan_ll(text, &result_ll, (long long) minimum); if (result_ll < (long long) minimum) { crm_warn("Clipped '%s' to minimum acceptable value %d", text, minimum); result_ll = (long long) minimum; } else if (result_ll > INT_MAX) { crm_warn("Clipped '%s' to maximum integer %d", text, INT_MAX); result_ll = (long long) INT_MAX; rc = EOVERFLOW; } if (result != NULL) { *result = (int) result_ll; } return rc; } /*! * \internal * \brief Scan a TCP port number from a string * * \param[in] text The string to scan * \param[out] port Where to store result (or NULL to ignore) * * \return Standard Pacemaker return code * \note \p port will be -1 if \p text is NULL or invalid */ int pcmk__scan_port(const char *text, int *port) { long long port_ll; int rc = pcmk__scan_ll(text, &port_ll, -1LL); if ((text != NULL) && (rc == pcmk_rc_ok) // wasn't default or invalid && ((port_ll < 0LL) || (port_ll > 65535LL))) { crm_warn("Ignoring port specification '%s' " "not in valid range (0-65535)", text); rc = (port_ll < 0LL)? pcmk_rc_before_range : pcmk_rc_after_range; port_ll = -1LL; } if (port != NULL) { *port = (int) port_ll; } return rc; } /*! * \internal * \brief Scan a double-precision floating-point value from a string * * \param[in] text The string to parse * \param[out] result Parsed value on success, or * \c PCMK__PARSE_DBL_DEFAULT on error * \param[in] default_text Default string to parse if \p text is * \c NULL * \param[out] end_text If not \c NULL, where to store a pointer * to the position immediately after the * value * * \return Standard Pacemaker return code (\c pcmk_rc_ok on success, * \c EINVAL on failed string conversion due to invalid input, * \c EOVERFLOW on arithmetic overflow, \c pcmk_rc_underflow * on arithmetic underflow, or \c errno from \c strtod() on * other parse errors) */ int pcmk__scan_double(const char *text, double *result, const char *default_text, char **end_text) { int rc = pcmk_rc_ok; char *local_end_text = NULL; CRM_ASSERT(result != NULL); *result = PCMK__PARSE_DBL_DEFAULT; text = (text != NULL) ? text : default_text; if (text == NULL) { rc = EINVAL; crm_debug("No text and no default conversion value supplied"); } else { errno = 0; *result = strtod(text, &local_end_text); if (errno == ERANGE) { /* * Overflow: strtod() returns +/- HUGE_VAL and sets errno to * ERANGE * * Underflow: strtod() returns "a value whose magnitude is * no greater than the smallest normalized * positive" double. Whether ERANGE is set is * implementation-defined. */ const char *over_under; if (QB_ABS(*result) > DBL_MIN) { rc = EOVERFLOW; over_under = "over"; } else { rc = pcmk_rc_underflow; over_under = "under"; } crm_debug("Floating-point value parsed from '%s' would %sflow " "(using %g instead)", text, over_under, *result); } else if (errno != 0) { rc = errno; // strtod() set *result = 0 on parse failure *result = PCMK__PARSE_DBL_DEFAULT; crm_debug("Could not parse floating-point value from '%s' (using " "%.1f instead): %s", text, PCMK__PARSE_DBL_DEFAULT, pcmk_rc_str(rc)); } else if (local_end_text == text) { // errno == 0, but nothing was parsed rc = EINVAL; *result = PCMK__PARSE_DBL_DEFAULT; crm_debug("Could not parse floating-point value from '%s' (using " "%.1f instead): No digits found", text, PCMK__PARSE_DBL_DEFAULT); } else if (QB_ABS(*result) <= DBL_MIN) { /* * errno == 0 and text was parsed, but value might have * underflowed. * * ERANGE might not be set for underflow. Check magnitude * of *result, but also make sure the input number is not * actually zero (0 <= DBL_MIN is not underflow). * * This check must come last. A parse failure in strtod() * also sets *result == 0, so a parse failure would match * this test condition prematurely. */ for (const char *p = text; p != local_end_text; p++) { if (strchr("0.eE", *p) == NULL) { rc = pcmk_rc_underflow; crm_debug("Floating-point value parsed from '%s' would " "underflow (using %g instead)", text, *result); break; } } } else { crm_trace("Floating-point value parsed successfully from " "'%s': %g", text, *result); } if ((end_text == NULL) && !pcmk__str_empty(local_end_text)) { crm_debug("Characters left over after parsing '%s': '%s'", text, local_end_text); } } if (end_text != NULL) { *end_text = local_end_text; } return rc; } /*! * \internal * \brief Parse a guint from a string stored in a hash table * * \param[in] table Hash table to search * \param[in] key Hash table key to use to retrieve string * \param[in] default_val What to use if key has no entry in table * \param[out] result If not NULL, where to store parsed integer * * \return Standard Pacemaker return code */ int pcmk__guint_from_hash(GHashTable *table, const char *key, guint default_val, guint *result) { const char *value; long long value_ll; int rc = pcmk_rc_ok; CRM_CHECK((table != NULL) && (key != NULL), return EINVAL); if (result != NULL) { *result = default_val; } value = g_hash_table_lookup(table, key); if (value == NULL) { return pcmk_rc_ok; } rc = pcmk__scan_ll(value, &value_ll, 0LL); if (rc != pcmk_rc_ok) { return rc; } if ((value_ll < 0) || (value_ll > G_MAXUINT)) { crm_warn("Could not parse non-negative integer from %s", value); return ERANGE; } if (result != NULL) { *result = (guint) value_ll; } return pcmk_rc_ok; } /*! * \brief Parse a time+units string and return milliseconds equivalent * * \param[in] input String with a nonnegative number and optional unit * (optionally with whitespace before and/or after the * number). If missing, the unit defaults to seconds. * * \return Milliseconds corresponding to string expression, or * \c PCMK__PARSE_INT_DEFAULT on error */ long long crm_get_msec(const char *input) { char *units = NULL; // Do not free; will point to part of input long long multiplier = 1000; long long divisor = 1; long long msec = PCMK__PARSE_INT_DEFAULT; if (input == NULL) { return PCMK__PARSE_INT_DEFAULT; } // Skip initial whitespace while (isspace(*input)) { input++; } // Reject negative and unparsable inputs scan_ll(input, &msec, -1, &units); if (msec < 0) { return PCMK__PARSE_INT_DEFAULT; } /* If the number is a decimal, scan_ll() reads only the integer part. Skip * any remaining digits or decimal characters. * * @COMPAT Well-formed and malformed decimals are both accepted inputs. For * example, "3.14 ms" and "3.1.4 ms" are treated the same as "3ms" and * parsed successfully. At a compatibility break, decide if this is still * desired. */ while (isdigit(*units) || (*units == '.')) { units++; } // Skip any additional whitespace after the number while (isspace(*units)) { units++; } /* @COMPAT Use exact comparisons. Currently, we match too liberally, and the * second strncasecmp() in each case is redundant. */ if ((*units == '\0') || (strncasecmp(units, "s", 1) == 0) || (strncasecmp(units, "sec", 3) == 0)) { multiplier = 1000; divisor = 1; } else if ((strncasecmp(units, "ms", 2) == 0) || (strncasecmp(units, "msec", 4) == 0)) { multiplier = 1; divisor = 1; } else if ((strncasecmp(units, "us", 2) == 0) || (strncasecmp(units, "usec", 4) == 0)) { multiplier = 1; divisor = 1000; } else if ((strncasecmp(units, "m", 1) == 0) || (strncasecmp(units, "min", 3) == 0)) { multiplier = 60 * 1000; divisor = 1; } else if ((strncasecmp(units, "h", 1) == 0) || (strncasecmp(units, "hr", 2) == 0)) { multiplier = 60 * 60 * 1000; divisor = 1; } else { // Invalid units return PCMK__PARSE_INT_DEFAULT; } // Apply units, capping at LLONG_MAX if (msec > (LLONG_MAX / multiplier)) { return LLONG_MAX; } return (msec * multiplier) / divisor; } /*! * \brief Parse milliseconds from a Pacemaker interval specification * * \param[in] input Pacemaker time interval specification (a bare number * of seconds; a number with a unit, optionally with * whitespace before and/or after the number; or an ISO * 8601 duration) * \param[out] result_ms Where to store milliseconds equivalent of \p input on * success (limited to the range of an unsigned integer), * or 0 if \p input is \c NULL or invalid * * \return Standard Pacemaker return code (specifically, \c pcmk_rc_ok if * \p input is valid or \c NULL, and \c EINVAL otherwise) */ int pcmk_parse_interval_spec(const char *input, guint *result_ms) { long long msec = PCMK__PARSE_INT_DEFAULT; int rc = pcmk_rc_ok; if (input == NULL) { msec = 0; goto done; } if (input[0] == 'P') { crm_time_t *period_s = crm_time_parse_duration(input); if (period_s != NULL) { - msec = 1000 * crm_time_get_seconds(period_s); + msec = crm_time_get_seconds(period_s); + msec = QB_MIN(msec, G_MAXUINT / 1000) * 1000; crm_time_free(period_s); } } else { msec = crm_get_msec(input); } if (msec == PCMK__PARSE_INT_DEFAULT) { crm_warn("Using 0 instead of invalid interval specification '%s'", input); msec = 0; rc = EINVAL; } done: if (result_ms != NULL) { *result_ms = (msec >= G_MAXUINT)? G_MAXUINT : (guint) msec; } return rc; } gboolean crm_is_true(const char *s) { gboolean ret = FALSE; return (crm_str_to_boolean(s, &ret) < 0)? FALSE : ret; } int crm_str_to_boolean(const char *s, int *ret) { if (s == NULL) { return -1; } if (pcmk__strcase_any_of(s, PCMK_VALUE_TRUE, "on", "yes", "y", "1", NULL)) { if (ret != NULL) { *ret = TRUE; } return 1; } if (pcmk__strcase_any_of(s, PCMK_VALUE_FALSE, "off", "no", "n", "0", NULL)) { if (ret != NULL) { *ret = FALSE; } return 1; } return -1; } /*! * \internal * \brief Replace any trailing newlines in a string with \0's * * \param[in,out] str String to trim * * \return \p str */ char * pcmk__trim(char *str) { int len; if (str == NULL) { return str; } for (len = strlen(str) - 1; len >= 0 && str[len] == '\n'; len--) { str[len] = '\0'; } return str; } /*! * \brief Check whether a string starts with a certain sequence * * \param[in] str String to check * \param[in] prefix Sequence to match against beginning of \p str * * \return \c true if \p str begins with match, \c false otherwise * \note This is equivalent to !strncmp(s, prefix, strlen(prefix)) * but is likely less efficient when prefix is a string literal * if the compiler optimizes away the strlen() at compile time, * and more efficient otherwise. */ bool pcmk__starts_with(const char *str, const char *prefix) { const char *s = str; const char *p = prefix; if (!s || !p) { return false; } while (*s && *p) { if (*s++ != *p++) { return false; } } return (*p == 0); } static inline bool ends_with(const char *s, const char *match, bool as_extension) { if (pcmk__str_empty(match)) { return true; } else if (s == NULL) { return false; } else { size_t slen, mlen; /* Besides as_extension, we could also check !strchr(&match[1], match[0]) but that would be inefficient. */ if (as_extension) { s = strrchr(s, match[0]); return (s == NULL)? false : !strcmp(s, match); } mlen = strlen(match); slen = strlen(s); return ((slen >= mlen) && !strcmp(s + slen - mlen, match)); } } /*! * \internal * \brief Check whether a string ends with a certain sequence * * \param[in] s String to check * \param[in] match Sequence to match against end of \p s * * \return \c true if \p s ends case-sensitively with match, \c false otherwise * \note pcmk__ends_with_ext() can be used if the first character of match * does not recur in match. */ bool pcmk__ends_with(const char *s, const char *match) { return ends_with(s, match, false); } /*! * \internal * \brief Check whether a string ends with a certain "extension" * * \param[in] s String to check * \param[in] match Extension to match against end of \p s, that is, * its first character must not occur anywhere * in the rest of that very sequence (example: file * extension where the last dot is its delimiter, * e.g., ".html"); incorrect results may be * returned otherwise. * * \return \c true if \p s ends (verbatim, i.e., case sensitively) * with "extension" designated as \p match (including empty * string), \c false otherwise * * \note Main incentive to prefer this function over \c pcmk__ends_with() * where possible is the efficiency (at the cost of added * restriction on \p match as stated; the complexity class * remains the same, though: BigO(M+N) vs. BigO(M+2N)). */ bool pcmk__ends_with_ext(const char *s, const char *match) { return ends_with(s, match, true); } /*! * \internal * \brief Create a hash of a string suitable for use with GHashTable * * \param[in] v String to hash * * \return A hash of \p v compatible with g_str_hash() before glib 2.28 * \note glib changed their hash implementation: * * https://gitlab.gnome.org/GNOME/glib/commit/354d655ba8a54b754cb5a3efb42767327775696c * * Note that the new g_str_hash is presumably a *better* hash (it's actually * a correct implementation of DJB's hash), but we need to preserve existing * behaviour, because the hash key ultimately determines the "sort" order * when iterating through GHashTables, which affects allocation of scores to * clone instances when iterating through rsc->allowed_nodes. It (somehow) * also appears to have some minor impact on the ordering of a few * pseudo_event IDs in the transition graph. */ static guint pcmk__str_hash(gconstpointer v) { const signed char *p; guint32 h = 0; for (p = v; *p != '\0'; p++) h = (h << 5) - h + *p; return h; } /*! * \internal * \brief Create a hash table with case-sensitive strings as keys * * \param[in] key_destroy_func Function to free a key * \param[in] value_destroy_func Function to free a value * * \return Newly allocated hash table * \note It is the caller's responsibility to free the result, using * g_hash_table_destroy(). */ GHashTable * pcmk__strkey_table(GDestroyNotify key_destroy_func, GDestroyNotify value_destroy_func) { return g_hash_table_new_full(pcmk__str_hash, g_str_equal, key_destroy_func, value_destroy_func); } /*! * \internal * \brief Insert string copies into a hash table as key and value * * \param[in,out] table Hash table to add to * \param[in] name String to add a copy of as key * \param[in] value String to add a copy of as value * * \note This asserts on invalid arguments or memory allocation failure. */ void pcmk__insert_dup(GHashTable *table, const char *name, const char *value) { CRM_ASSERT((table != NULL) && (name != NULL)); g_hash_table_insert(table, pcmk__str_copy(name), pcmk__str_copy(value)); } /* used with hash tables where case does not matter */ static gboolean pcmk__strcase_equal(gconstpointer a, gconstpointer b) { return pcmk__str_eq((const char *)a, (const char *)b, pcmk__str_casei); } static guint pcmk__strcase_hash(gconstpointer v) { const signed char *p; guint32 h = 0; for (p = v; *p != '\0'; p++) h = (h << 5) - h + g_ascii_tolower(*p); return h; } /*! * \internal * \brief Create a hash table with case-insensitive strings as keys * * \param[in] key_destroy_func Function to free a key * \param[in] value_destroy_func Function to free a value * * \return Newly allocated hash table * \note It is the caller's responsibility to free the result, using * g_hash_table_destroy(). */ GHashTable * pcmk__strikey_table(GDestroyNotify key_destroy_func, GDestroyNotify value_destroy_func) { return g_hash_table_new_full(pcmk__strcase_hash, pcmk__strcase_equal, key_destroy_func, value_destroy_func); } static void copy_str_table_entry(gpointer key, gpointer value, gpointer user_data) { if (key && value && user_data) { pcmk__insert_dup((GHashTable *) user_data, (const char *) key, (const char *) value); } } /*! * \internal * \brief Copy a hash table that uses dynamically allocated strings * * \param[in,out] old_table Hash table to duplicate * * \return New hash table with copies of everything in \p old_table * \note This assumes the hash table uses dynamically allocated strings -- that * is, both the key and value free functions are free(). */ GHashTable * pcmk__str_table_dup(GHashTable *old_table) { GHashTable *new_table = NULL; if (old_table) { new_table = pcmk__strkey_table(free, free); g_hash_table_foreach(old_table, copy_str_table_entry, new_table); } return new_table; } /*! * \internal * \brief Add a word to a string list of words * * \param[in,out] list Pointer to current string list (may not be \p NULL) * \param[in] init_size \p list will be initialized to at least this size, * if it needs initialization (if 0, use GLib's default * initial string size) * \param[in] word String to add to \p list (\p list will be * unchanged if this is \p NULL or the empty string) * \param[in] separator String to separate words in \p list * (a space will be used if this is NULL) * * \note \p word may contain \p separator, though that would be a bad idea if * the string needs to be parsed later. */ void pcmk__add_separated_word(GString **list, size_t init_size, const char *word, const char *separator) { CRM_ASSERT(list != NULL); if (pcmk__str_empty(word)) { return; } if (*list == NULL) { if (init_size > 0) { *list = g_string_sized_new(init_size); } else { *list = g_string_new(NULL); } } if ((*list)->len == 0) { // Don't add a separator before the first word in the list separator = ""; } else if (separator == NULL) { // Default to space-separated separator = " "; } g_string_append(*list, separator); g_string_append(*list, word); } /*! * \internal * \brief Compress data * * \param[in] data Data to compress * \param[in] length Number of characters of data to compress * \param[in] max Maximum size of compressed data (or 0 to estimate) * \param[out] result Where to store newly allocated compressed result * \param[out] result_len Where to store actual compressed length of result * * \return Standard Pacemaker return code */ int pcmk__compress(const char *data, unsigned int length, unsigned int max, char **result, unsigned int *result_len) { int rc; char *compressed = NULL; char *uncompressed = strdup(data); #ifdef CLOCK_MONOTONIC struct timespec after_t; struct timespec before_t; #endif if (max == 0) { max = (length * 1.01) + 601; // Size guaranteed to hold result } #ifdef CLOCK_MONOTONIC clock_gettime(CLOCK_MONOTONIC, &before_t); #endif compressed = pcmk__assert_alloc((size_t) max, sizeof(char)); *result_len = max; rc = BZ2_bzBuffToBuffCompress(compressed, result_len, uncompressed, length, CRM_BZ2_BLOCKS, 0, CRM_BZ2_WORK); rc = pcmk__bzlib2rc(rc); free(uncompressed); if (rc != pcmk_rc_ok) { crm_err("Compression of %d bytes failed: %s " CRM_XS " rc=%d", length, pcmk_rc_str(rc), rc); free(compressed); return rc; } #ifdef CLOCK_MONOTONIC clock_gettime(CLOCK_MONOTONIC, &after_t); crm_trace("Compressed %d bytes into %d (ratio %d:1) in %.0fms", length, *result_len, length / (*result_len), (after_t.tv_sec - before_t.tv_sec) * 1000 + (after_t.tv_nsec - before_t.tv_nsec) / 1e6); #else crm_trace("Compressed %d bytes into %d (ratio %d:1)", length, *result_len, length / (*result_len)); #endif *result = compressed; return pcmk_rc_ok; } char * crm_strdup_printf(char const *format, ...) { va_list ap; int len = 0; char *string = NULL; va_start(ap, format); len = vasprintf (&string, format, ap); CRM_ASSERT(len > 0); va_end(ap); return string; } int pcmk__parse_ll_range(const char *srcstring, long long *start, long long *end) { char *remainder = NULL; int rc = pcmk_rc_ok; CRM_ASSERT(start != NULL && end != NULL); *start = PCMK__PARSE_INT_DEFAULT; *end = PCMK__PARSE_INT_DEFAULT; crm_trace("Attempting to decode: [%s]", srcstring); if (pcmk__str_eq(srcstring, "", pcmk__str_null_matches)) { return ENODATA; } else if (pcmk__str_eq(srcstring, "-", pcmk__str_none)) { return pcmk_rc_bad_input; } /* String starts with a dash, so this is either a range with * no beginning or garbage. * */ if (*srcstring == '-') { int rc = scan_ll(srcstring+1, end, PCMK__PARSE_INT_DEFAULT, &remainder); if (rc != pcmk_rc_ok || *remainder != '\0') { return pcmk_rc_bad_input; } else { return pcmk_rc_ok; } } rc = scan_ll(srcstring, start, PCMK__PARSE_INT_DEFAULT, &remainder); if (rc != pcmk_rc_ok) { return rc; } if (*remainder && *remainder == '-') { if (*(remainder+1)) { char *more_remainder = NULL; int rc = scan_ll(remainder+1, end, PCMK__PARSE_INT_DEFAULT, &more_remainder); if (rc != pcmk_rc_ok) { return rc; } else if (*more_remainder != '\0') { return pcmk_rc_bad_input; } } } else if (*remainder && *remainder != '-') { *start = PCMK__PARSE_INT_DEFAULT; return pcmk_rc_bad_input; } else { /* The input string contained only one number. Set start and end * to the same value and return pcmk_rc_ok. This gives the caller * a way to tell this condition apart from a range with no end. */ *end = *start; } return pcmk_rc_ok; } /*! * \internal * \brief Find a string in a list of strings * * \note This function takes the same flags and has the same behavior as * pcmk__str_eq(). * * \note No matter what input string or flags are provided, an empty * list will always return FALSE. * * \param[in] s String to search for * \param[in] lst List to search * \param[in] flags A bitfield of pcmk__str_flags to modify operation * * \return \c TRUE if \p s is in \p lst, or \c FALSE otherwise */ gboolean pcmk__str_in_list(const gchar *s, const GList *lst, uint32_t flags) { for (const GList *ele = lst; ele != NULL; ele = ele->next) { if (pcmk__str_eq(s, ele->data, flags)) { return TRUE; } } return FALSE; } static bool str_any_of(const char *s, va_list args, uint32_t flags) { if (s == NULL) { return pcmk_is_set(flags, pcmk__str_null_matches); } while (1) { const char *ele = va_arg(args, const char *); if (ele == NULL) { break; } else if (pcmk__str_eq(s, ele, flags)) { return true; } } return false; } /*! * \internal * \brief Is a string a member of a list of strings? * * \param[in] s String to search for in \p ... * \param[in] ... Strings to compare \p s against. The final string * must be NULL. * * \note The comparison is done case-insensitively. The function name is * meant to be reminiscent of strcasecmp. * * \return \c true if \p s is in \p ..., or \c false otherwise */ bool pcmk__strcase_any_of(const char *s, ...) { va_list ap; bool rc; va_start(ap, s); rc = str_any_of(s, ap, pcmk__str_casei); va_end(ap); return rc; } /*! * \internal * \brief Is a string a member of a list of strings? * * \param[in] s String to search for in \p ... * \param[in] ... Strings to compare \p s against. The final string * must be NULL. * * \note The comparison is done taking case into account. * * \return \c true if \p s is in \p ..., or \c false otherwise */ bool pcmk__str_any_of(const char *s, ...) { va_list ap; bool rc; va_start(ap, s); rc = str_any_of(s, ap, pcmk__str_none); va_end(ap); return rc; } /*! * \internal * \brief Sort strings, with numeric portions sorted numerically * * Sort two strings case-insensitively like strcasecmp(), but with any numeric * portions of the string sorted numerically. This is particularly useful for * node names (for example, "node10" will sort higher than "node9" but lower * than "remotenode9"). * * \param[in] s1 First string to compare (must not be NULL) * \param[in] s2 Second string to compare (must not be NULL) * * \retval -1 \p s1 comes before \p s2 * \retval 0 \p s1 and \p s2 are equal * \retval 1 \p s1 comes after \p s2 */ int pcmk__numeric_strcasecmp(const char *s1, const char *s2) { CRM_ASSERT((s1 != NULL) && (s2 != NULL)); while (*s1 && *s2) { if (isdigit(*s1) && isdigit(*s2)) { // If node names contain a number, sort numerically char *end1 = NULL; char *end2 = NULL; long num1 = strtol(s1, &end1, 10); long num2 = strtol(s2, &end2, 10); // allow ordering e.g. 007 > 7 size_t len1 = end1 - s1; size_t len2 = end2 - s2; if (num1 < num2) { return -1; } else if (num1 > num2) { return 1; } else if (len1 < len2) { return -1; } else if (len1 > len2) { return 1; } s1 = end1; s2 = end2; } else { // Compare non-digits case-insensitively int lower1 = tolower(*s1); int lower2 = tolower(*s2); if (lower1 < lower2) { return -1; } else if (lower1 > lower2) { return 1; } ++s1; ++s2; } } if (!*s1 && *s2) { return -1; } else if (*s1 && !*s2) { return 1; } return 0; } /*! * \internal * \brief Sort strings. * * This is your one-stop function for string comparison. By default, this * function works like \p g_strcmp0. That is, like \p strcmp but a \p NULL * string sorts before a non-NULL string. * * The \p pcmk__str_none flag produces the default behavior. Behavior can be * changed with various flags: * * - \p pcmk__str_regex - The second string is a regular expression that the * first string will be matched against. * - \p pcmk__str_casei - By default, comparisons are done taking case into * account. This flag makes comparisons case- * insensitive. This can be combined with * \p pcmk__str_regex. * - \p pcmk__str_null_matches - If one string is \p NULL and the other is not, * still return \p 0. * - \p pcmk__str_star_matches - If one string is \p "*" and the other is not, * still return \p 0. * * \param[in] s1 First string to compare * \param[in] s2 Second string to compare, or a regular expression to * match if \p pcmk__str_regex is set * \param[in] flags A bitfield of \p pcmk__str_flags to modify operation * * \retval negative \p s1 is \p NULL or comes before \p s2 * \retval 0 \p s1 and \p s2 are equal, or \p s1 is found in \p s2 if * \c pcmk__str_regex is set * \retval positive \p s2 is \p NULL or \p s1 comes after \p s2, or \p s2 * is an invalid regular expression, or \p s1 was not found * in \p s2 if \p pcmk__str_regex is set. */ int pcmk__strcmp(const char *s1, const char *s2, uint32_t flags) { /* If this flag is set, the second string is a regex. */ if (pcmk_is_set(flags, pcmk__str_regex)) { regex_t r_patt; int reg_flags = REG_EXTENDED | REG_NOSUB; int regcomp_rc = 0; int rc = 0; if (s1 == NULL || s2 == NULL) { return 1; } if (pcmk_is_set(flags, pcmk__str_casei)) { reg_flags |= REG_ICASE; } regcomp_rc = regcomp(&r_patt, s2, reg_flags); if (regcomp_rc != 0) { rc = 1; crm_err("Bad regex '%s' for update: %s", s2, strerror(regcomp_rc)); } else { rc = regexec(&r_patt, s1, 0, NULL, 0); regfree(&r_patt); if (rc != 0) { rc = 1; } } return rc; } /* If the strings are the same pointer, return 0 immediately. */ if (s1 == s2) { return 0; } /* If this flag is set, return 0 if either (or both) of the input strings * are NULL. If neither one is NULL, we need to continue and compare * them normally. */ if (pcmk_is_set(flags, pcmk__str_null_matches)) { if (s1 == NULL || s2 == NULL) { return 0; } } /* Handle the cases where one is NULL and the str_null_matches flag is not set. * A NULL string always sorts to the beginning. */ if (s1 == NULL) { return -1; } else if (s2 == NULL) { return 1; } /* If this flag is set, return 0 if either (or both) of the input strings * are "*". If neither one is, we need to continue and compare them * normally. */ if (pcmk_is_set(flags, pcmk__str_star_matches)) { if (strcmp(s1, "*") == 0 || strcmp(s2, "*") == 0) { return 0; } } if (pcmk_is_set(flags, pcmk__str_casei)) { return strcasecmp(s1, s2); } else { return strcmp(s1, s2); } } /*! * \internal * \brief Copy a string, asserting on failure * * \param[in] file File where \p function is located * \param[in] function Calling function * \param[in] line Line within \p file * \param[in] str String to copy (can be \c NULL) * * \return Newly allocated copy of \p str, or \c NULL if \p str is \c NULL * * \note The caller is responsible for freeing the return value using \c free(). */ char * pcmk__str_copy_as(const char *file, const char *function, uint32_t line, const char *str) { if (str != NULL) { char *result = strdup(str); if (result == NULL) { crm_abort(file, function, line, "Out of memory", FALSE, TRUE); crm_exit(CRM_EX_OSERR); } return result; } return NULL; } /*! * \internal * \brief Update a dynamically allocated string with a new value * * Given a dynamically allocated string and a new value for it, if the string * is different from the new value, free the string and replace it with either a * newly allocated duplicate of the value or NULL as appropriate. * * \param[in,out] str Pointer to dynamically allocated string * \param[in] value New value to duplicate (or NULL) * * \note The caller remains responsibile for freeing \p *str. */ void pcmk__str_update(char **str, const char *value) { if ((str != NULL) && !pcmk__str_eq(*str, value, pcmk__str_none)) { free(*str); *str = pcmk__str_copy(value); } } /*! * \internal * \brief Append a list of strings to a destination \p GString * * \param[in,out] buffer Where to append the strings (must not be \p NULL) * \param[in] ... A NULL-terminated list of strings * * \note This tends to be more efficient than a single call to * \p g_string_append_printf(). */ void pcmk__g_strcat(GString *buffer, ...) { va_list ap; CRM_ASSERT(buffer != NULL); va_start(ap, buffer); while (true) { const char *ele = va_arg(ap, const char *); if (ele == NULL) { break; } g_string_append(buffer, ele); } va_end(ap); } // Deprecated functions kept only for backward API compatibility // LCOV_EXCL_START #include gboolean safe_str_neq(const char *a, const char *b) { if (a == b) { return FALSE; } else if (a == NULL || b == NULL) { return TRUE; } else if (strcasecmp(a, b) == 0) { return FALSE; } return TRUE; } gboolean crm_str_eq(const char *a, const char *b, gboolean use_case) { if (use_case) { return g_strcmp0(a, b) == 0; /* TODO - Figure out which calls, if any, really need to be case independent */ } else if (a == b) { return TRUE; } else if (a == NULL || b == NULL) { /* shouldn't be comparing NULLs */ return FALSE; } else if (strcasecmp(a, b) == 0) { return TRUE; } return FALSE; } char * crm_itoa_stack(int an_int, char *buffer, size_t len) { if (buffer != NULL) { snprintf(buffer, len, "%d", an_int); } return buffer; } guint g_str_hash_traditional(gconstpointer v) { return pcmk__str_hash(v); } gboolean crm_strcase_equal(gconstpointer a, gconstpointer b) { return pcmk__strcase_equal(a, b); } guint crm_strcase_hash(gconstpointer v) { return pcmk__strcase_hash(v); } GHashTable * crm_str_table_dup(GHashTable *old_table) { return pcmk__str_table_dup(old_table); } long long crm_parse_ll(const char *text, const char *default_text) { long long result; if (text == NULL) { text = default_text; if (text == NULL) { crm_err("No default conversion value supplied"); errno = EINVAL; return PCMK__PARSE_INT_DEFAULT; } } scan_ll(text, &result, PCMK__PARSE_INT_DEFAULT, NULL); return result; } int crm_parse_int(const char *text, const char *default_text) { long long result = crm_parse_ll(text, default_text); if (result < INT_MIN) { // If errno is ERANGE, crm_parse_ll() has already logged a message if (errno != ERANGE) { crm_err("Conversion of %s was clipped: %lld", text, result); errno = ERANGE; } return INT_MIN; } else if (result > INT_MAX) { // If errno is ERANGE, crm_parse_ll() has already logged a message if (errno != ERANGE) { crm_err("Conversion of %s was clipped: %lld", text, result); errno = ERANGE; } return INT_MAX; } return (int) result; } char * crm_strip_trailing_newline(char *str) { return pcmk__trim(str); } int pcmk_numeric_strcasecmp(const char *s1, const char *s2) { return pcmk__numeric_strcasecmp(s1, s2); } // LCOV_EXCL_STOP // End deprecated API