/* * FreeSWITCH Modular Media Switching Software Library / Soft-Switch Application * Copyright (C) 2005-2012, Anthony Minessale II * * Version: MPL 1.1 * * The contents of this file are subject to the Mozilla Public License Version * 1.1 (the "License"); you may not use this file except in compliance with * the License. You may obtain a copy of the License at * http://www.mozilla.org/MPL/ * * Software distributed under the License is distributed on an "AS IS" basis, * WITHOUT WARRANTY OF ANY KIND, either express or implied. See the License * for the specific language governing rights and limitations under the * License. * * The Original Code is FreeSWITCH Modular Media Switching Software Library / Soft-Switch Application * * The Initial Developer of the Original Code is * Anthony Minessale II * Portions created by the Initial Developer are Copyright (C) * the Initial Developer. All Rights Reserved. * * Contributor(s): * * Anthony Minessale II * Simon Capper * Marc Olivier Chouinard * Raymond Chandler * * switch_xml.c -- XML PARSER * * Derived from ezxml http://ezxml.sourceforge.net * Original Copyright * * Copyright 2004, 2006 Aaron Voisine * * Permission is hereby granted, free of charge, to any person obtaining * a copy of this software and associated documentation files (the * "Software"), to deal in the Software without restriction, including * without limitation the rights to use, copy, modify, merge, publish, * distribute, sublicense, and/or sell copies of the Software, and to * permit persons to whom the Software is furnished to do so, subject to * the following conditions: * * The above copyright notice and this permission notice shall be included * in all copies or substantial portions of the Software. * * THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, * EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF * MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. * IN NO EVENT SHALL THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY * CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER IN AN ACTION OF CONTRACT, * TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN CONNECTION WITH THE * SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE. */ #include #ifndef WIN32 #include #include #include #else /* we're on windoze :( */ /* glob functions at end of this file */ #include typedef struct { size_t gl_pathc; /* Count of total paths so far. */ size_t gl_matchc; /* Count of paths matching pattern. */ size_t gl_offs; /* Reserved at beginning of gl_pathv. */ int gl_flags; /* Copy of flags parameter to glob. */ char **gl_pathv; /* List of paths matching pattern. */ /* Copy of errfunc parameter to glob. */ int (*gl_errfunc) (const char *, int); } glob_t; /* Believed to have been introduced in 1003.2-1992 */ #define GLOB_APPEND 0x0001 /* Append to output from previous call. */ #define GLOB_DOOFFS 0x0002 /* Use gl_offs. */ #define GLOB_ERR 0x0004 /* Return on error. */ #define GLOB_MARK 0x0008 /* Append / to matching directories. */ #define GLOB_NOCHECK 0x0010 /* Return pattern itself if nothing matches. */ #define GLOB_NOSORT 0x0020 /* Don't sort. */ /* Error values returned by glob(3) */ #define GLOB_NOSPACE (-1) /* Malloc call failed. */ #define GLOB_ABORTED (-2) /* Unignored error. */ #define GLOB_NOMATCH (-3) /* No match and GLOB_NOCHECK was not set. */ #define GLOB_NOSYS (-4) /* Obsolete: source comptability only. */ #define GLOB_ALTDIRFUNC 0x0040 /* Use alternately specified directory funcs. */ #define GLOB_MAGCHAR 0x0100 /* Pattern had globbing characters. */ #define GLOB_NOMAGIC 0x0200 /* GLOB_NOCHECK without magic chars (csh). */ #define GLOB_QUOTE 0x0400 /* Quote special chars with \. */ #define GLOB_LIMIT 0x1000 /* limit number of returned paths */ int glob(const char *, int, int (*)(const char *, int), glob_t *); void globfree(glob_t *); #endif #define SWITCH_XML_WS "\t\r\n " /* whitespace */ #define SWITCH_XML_ERRL 128 /* maximum error string length */ /* Use UTF-8 as the general encoding */ static switch_bool_t USE_UTF_8_ENCODING = SWITCH_TRUE; static void preprocess_exec_set(char *keyval) { char *key = keyval; char *val = strchr(key, '='); if (val) { char *ve = val++; while (*val && *val == ' ') { val++; } *ve-- = '\0'; while (*ve && *ve == ' ') { *ve-- = '\0'; } } if (key && val) { switch_stream_handle_t exec_result = { 0 }; SWITCH_STANDARD_STREAM(exec_result); if (switch_stream_system_fork(val, &exec_result) == 0) { if (!zstr(exec_result.data)) { char *tmp = (char *) exec_result.data; tmp = &tmp[strlen(tmp)-1]; while (tmp >= (char *) exec_result.data && ( tmp[0] == ' ' || tmp[0] == '\n') ) { tmp[0] = '\0'; /* remove trailing spaces and newlines */ tmp--; } switch_core_set_variable(key, exec_result.data); } } else { switch_log_printf(SWITCH_CHANNEL_LOG, SWITCH_LOG_ERROR, "Error while executing command: %s\n", val); } switch_safe_free(exec_result.data); } } static int preprocess(const char *cwd, const char *file, FILE *write_fd, int rlevel); typedef struct switch_xml_root *switch_xml_root_t; struct switch_xml_root { /* additional data for the root tag */ struct switch_xml xml; /* is a super-struct built on top of switch_xml struct */ switch_xml_t cur; /* current xml tree insertion point */ char *m; /* original xml string */ switch_size_t len; /* length of allocated memory */ uint8_t dynamic; /* Free the original string when calling switch_xml_free */ char *u; /* UTF-8 conversion of string if original was UTF-16 */ char *s; /* start of work area */ char *e; /* end of work area */ char **ent; /* general entities (ampersand sequences) */ char ***attr; /* default attributes */ char ***pi; /* processing instructions */ short standalone; /* non-zero if */ char err[SWITCH_XML_ERRL]; /* error string */ }; char *SWITCH_XML_NIL[] = { NULL }; /* empty, null terminated array of strings */ struct switch_xml_binding { switch_xml_search_function_t function; switch_xml_section_t sections; void *user_data; struct switch_xml_binding *next; }; static switch_xml_binding_t *BINDINGS = NULL; static switch_xml_t MAIN_XML_ROOT = NULL; static switch_memory_pool_t *XML_MEMORY_POOL = NULL; static switch_thread_rwlock_t *B_RWLOCK = NULL; static switch_mutex_t *XML_LOCK = NULL; static switch_mutex_t *CACHE_MUTEX = NULL; static switch_mutex_t *REFLOCK = NULL; static switch_mutex_t *FILE_LOCK = NULL; static switch_mutex_t *XML_GEN_LOCK = NULL; SWITCH_DECLARE_NONSTD(switch_xml_t) __switch_xml_open_root(uint8_t reload, const char **err, void *user_data); static switch_xml_open_root_function_t XML_OPEN_ROOT_FUNCTION = (switch_xml_open_root_function_t)__switch_xml_open_root; static void *XML_OPEN_ROOT_FUNCTION_USER_DATA = NULL; static switch_hash_t *CACHE_HASH = NULL; static switch_hash_t *CACHE_EXPIRES_HASH = NULL; struct xml_section_t { const char *name; /* switch_xml_section_t section; */ uint32_t section; }; static struct xml_section_t SECTIONS[] = { {"result", SWITCH_XML_SECTION_RESULT}, {"config", SWITCH_XML_SECTION_CONFIG}, {"directory", SWITCH_XML_SECTION_DIRECTORY}, {"dialplan", SWITCH_XML_SECTION_DIALPLAN}, {"languages", SWITCH_XML_SECTION_LANGUAGES}, {"chatplan", SWITCH_XML_SECTION_CHATPLAN}, {NULL, 0} }; SWITCH_DECLARE(switch_xml_section_t) switch_xml_parse_section_string(const char *str) { size_t x; char buf[1024] = ""; /*switch_xml_section_t sections = SWITCH_XML_SECTION_RESULT; */ uint32_t sections = SWITCH_XML_SECTION_RESULT; if (str) { for (x = 0; x < strlen(str); x++) { buf[x] = (char) tolower((int) str[x]); } for (x = 0;; x++) { if (!SECTIONS[x].name) { break; } if (strstr(buf, SECTIONS[x].name)) { sections |= SECTIONS[x].section; } } } return (switch_xml_section_t) sections; } SWITCH_DECLARE(switch_status_t) switch_xml_unbind_search_function(switch_xml_binding_t **binding) { switch_xml_binding_t *ptr, *last = NULL; switch_status_t status = SWITCH_STATUS_FALSE; switch_thread_rwlock_wrlock(B_RWLOCK); for (ptr = BINDINGS; ptr; ptr = ptr->next) { if (ptr == *binding) { if (last) { last->next = (*binding)->next; } else { BINDINGS = (*binding)->next; } status = SWITCH_STATUS_SUCCESS; break; } last = ptr; } switch_thread_rwlock_unlock(B_RWLOCK); return status; } SWITCH_DECLARE(switch_status_t) switch_xml_unbind_search_function_ptr(switch_xml_search_function_t function) { switch_xml_binding_t *ptr, *last = NULL; switch_status_t status = SWITCH_STATUS_FALSE; switch_thread_rwlock_wrlock(B_RWLOCK); for (ptr = BINDINGS; ptr; ptr = ptr->next) { if (ptr->function == function) { status = SWITCH_STATUS_SUCCESS; if (last) { last->next = ptr->next; } else { BINDINGS = ptr->next; last = NULL; continue; } } last = ptr; } switch_thread_rwlock_unlock(B_RWLOCK); return status; } SWITCH_DECLARE(void) switch_xml_set_binding_sections(switch_xml_binding_t *binding, switch_xml_section_t sections) { switch_assert(binding); binding->sections = sections; } SWITCH_DECLARE(void) switch_xml_set_binding_user_data(switch_xml_binding_t *binding, void *user_data) { switch_assert(binding); binding->user_data = user_data; } SWITCH_DECLARE(switch_xml_section_t) switch_xml_get_binding_sections(switch_xml_binding_t *binding) { return binding->sections; } SWITCH_DECLARE(void *) switch_xml_get_binding_user_data(switch_xml_binding_t *binding) { return binding->user_data; } SWITCH_DECLARE(switch_status_t) switch_xml_bind_search_function_ret(switch_xml_search_function_t function, switch_xml_section_t sections, void *user_data, switch_xml_binding_t **ret_binding) { switch_xml_binding_t *binding = NULL, *ptr = NULL; assert(function != NULL); if (!(binding = (switch_xml_binding_t *) switch_core_alloc(XML_MEMORY_POOL, sizeof(*binding)))) { return SWITCH_STATUS_MEMERR; } binding->function = function; binding->sections = sections; binding->user_data = user_data; switch_thread_rwlock_wrlock(B_RWLOCK); for (ptr = BINDINGS; ptr && ptr->next; ptr = ptr->next); if (ptr) { ptr->next = binding; } else { BINDINGS = binding; } if (ret_binding) { *ret_binding = binding; } switch_thread_rwlock_unlock(B_RWLOCK); return SWITCH_STATUS_SUCCESS; } SWITCH_DECLARE(switch_xml_t) switch_xml_find_child(switch_xml_t node, const char *childname, const char *attrname, const char *value) { switch_xml_t p = NULL; if (!(childname && attrname && value)) { return node; } for (p = switch_xml_child(node, childname); p; p = p->next) { const char *aname = switch_xml_attr(p, attrname); if (aname && value && !strcasecmp(aname, value)) { break; } } return p; } SWITCH_DECLARE(switch_xml_t) switch_xml_find_child_multi(switch_xml_t node, const char *childname,...) { switch_xml_t p = NULL; const char *names[256] = { 0 }; const char *vals[256] = { 0 }; int x, i = 0; va_list ap; const char *attrname, *value = NULL; va_start(ap, childname); while (i < 255) { if ((attrname = va_arg(ap, const char *))) { value = va_arg(ap, const char *); } if (attrname && value) { names[i] = attrname; vals[i] = value; } else { break; } i++; } va_end(ap); if (!(childname && i)) { return node; } for (p = switch_xml_child(node, childname); p; p = p->next) { for (x = 0; x < i; x++) { if (names[x] && vals[x]) { const char *aname = switch_xml_attr(p, names[x]); if (aname) { if (*vals[x] == '!') { const char *sval = vals[x] + 1; if (sval && strcasecmp(aname, sval)) { goto done; } } else { if (!strcasecmp(aname, vals[x])) { goto done; } } } } } } done: return p; } /* returns the first child tag with the given name or NULL if not found */ SWITCH_DECLARE(switch_xml_t) switch_xml_child(switch_xml_t xml, const char *name) { xml = (xml) ? xml->child : NULL; while (xml && strcmp(name, xml->name)) xml = xml->sibling; return xml; } /* returns the Nth tag with the same name in the same subsection or NULL if not found */ switch_xml_t switch_xml_idx(switch_xml_t xml, int idx) { for (; xml && idx; idx--) xml = xml->next; return xml; } /* returns the value of the requested tag attribute or "" if not found */ SWITCH_DECLARE(const char *) switch_xml_attr_soft(switch_xml_t xml, const char *attr) { const char *ret = switch_xml_attr(xml, attr); return ret ? ret : ""; } /* returns the value of the requested tag attribute or NULL if not found */ SWITCH_DECLARE(const char *) switch_xml_attr(switch_xml_t xml, const char *attr) { int i = 0, j = 1; switch_xml_root_t root = (switch_xml_root_t) xml; if (!xml || !xml->attr) return NULL; while (xml->attr[i] && attr && strcmp(attr, xml->attr[i])) i += 2; if (xml->attr[i]) return xml->attr[i + 1]; /* found attribute */ while (root->xml.parent) root = (switch_xml_root_t) root->xml.parent; /* root tag */ /* Make sure root is really a switch_xml_root_t (Issues with switch_xml_toxml) */ if (!root->xml.is_switch_xml_root_t) { return NULL; } if (!root->attr) { return NULL; } for (i = 0; root->attr[i] && xml->name && strcmp(xml->name, root->attr[i][0]); i++); if (!root->attr[i]) return NULL; /* no matching default attributes */ while (root->attr[i][j] && attr && strcmp(attr, root->attr[i][j])) j += 3; return (root->attr[i][j]) ? root->attr[i][j + 1] : NULL; /* found default */ } /* same as switch_xml_get but takes an already initialized va_list */ static switch_xml_t switch_xml_vget(switch_xml_t xml, va_list ap) { char *name = va_arg(ap, char *); int idx = -1; if (name && *name) { idx = va_arg(ap, int); xml = switch_xml_child(xml, name); } return (idx < 0) ? xml : switch_xml_vget(switch_xml_idx(xml, idx), ap); } /* Traverses the xml tree to retrieve a specific subtag. Takes a variable length list of tag names and indexes. The argument list must be terminated by either an index of -1 or an empty string tag name. Example: title = switch_xml_get(library, "shelf", 0, "book", 2, "title", -1); This retrieves the title of the 3rd book on the 1st shelf of library. Returns NULL if not found. */ SWITCH_DECLARE(switch_xml_t) switch_xml_get(switch_xml_t xml,...) { va_list ap; switch_xml_t r; va_start(ap, xml); r = switch_xml_vget(xml, ap); va_end(ap); return r; } /* returns a null terminated array of processing instructions for the given target */ SWITCH_DECLARE(const char **) switch_xml_pi(switch_xml_t xml, const char *target) { switch_xml_root_t root = (switch_xml_root_t) xml; int i = 0; if (!root) return (const char **) SWITCH_XML_NIL; while (root->xml.parent) root = (switch_xml_root_t) root->xml.parent; /* root tag */ if (!root || !root->pi) { return (const char **) SWITCH_XML_NIL; } while (root->pi[i] && strcmp(target, root->pi[i][0])) i++; /* find target */ return (const char **) ((root->pi[i]) ? root->pi[i] + 1 : SWITCH_XML_NIL); } /* set an error string and return root */ static switch_xml_t switch_xml_err(switch_xml_root_t root, char *s, const char *err, ...) { va_list ap; int line = 1; char *t, fmt[SWITCH_XML_ERRL]; if (!root || !root->s) { return NULL; } for (t = root->s; t && t < s; t++) if (*t == '\n') line++; switch_snprintf(fmt, SWITCH_XML_ERRL, "[error near line %d]: %s", line, err); va_start(ap, err); vsnprintf(root->err, SWITCH_XML_ERRL, fmt, ap); va_end(ap); return &root->xml; } /* Recursively decodes entity and character references and normalizes new lines ent is a null terminated array of alternating entity names and values. set t to '&' for general entity decoding, '%' for parameter entity decoding, 'c' for cdata sections, ' ' for attribute normalization, or '*' for non-cdata attribute normalization. Returns s, or if the decoded string is longer than s, returns a malloced string that must be freed. */ static char *switch_xml_decode(char *s, char **ent, char t) { char *e, *r = s, *m = s; long b, c, d, l; for (; *s; s++) { /* normalize line endings */ while (*s == '\r') { *(s++) = '\n'; if (*s == '\n') memmove(s, (s + 1), strlen(s)); } } for (s = r;;) { while (*s && *s != '&' && (*s != '%' || t != '%') && !isspace((unsigned char) (*s))) s++; if (!*s) break; else if (t != 'c' && !strncmp(s, "&#", 2)) { /* character reference */ if (s[2] == 'x') c = strtol(s + 3, &e, 16); /* base 16 */ else c = strtol(s + 2, &e, 10); /* base 10 */ if (!c || *e != ';') { s++; continue; } /* not a character ref */ if (c < 0x80) *(s++) = (char) c; /* US-ASCII subset */ else { /* multi-byte UTF-8 sequence */ for (b = 0, d = c; d; d /= 2) b++; /* number of bits in c */ b = (b - 2) / 5; /* number of bytes in payload */ *(s++) = (char) ((0xFF << (7 - b)) | (c >> (6 * b))); /* head */ while (b) *(s++) = (char) (0x80 | ((c >> (6 * --b)) & 0x3F)); /* payload */ } memmove(s, strchr(s, ';') + 1, strlen(strchr(s, ';'))); } else if ((*s == '&' && (t == '&' || t == ' ' || t == '*')) || (*s == '%' && t == '%')) { /* entity reference */ for (b = 0; ent[b] && strncmp(s + 1, ent[b], strlen(ent[b])); b += 2); /* find entity in entity list */ if (ent[b++]) { /* found a match */ if ((c = (long) strlen(ent[b])) - 1 > (e = strchr(s, ';')) - s) { l = (d = (long) (s - r)) + c + (long) strlen(e); /* new length */ if (l) { if (r == m) { char *tmp = (char *) malloc(l); if (tmp) { r = strcpy(tmp, r); } else { if (r) free(r); return NULL; } } else { char *tmp = (char *) realloc(r, l); if (tmp) { r = tmp; } else { if (r) free(r); return NULL; } } } e = strchr((s = r + d), ';'); /* fix up pointers */ } memmove(s + c, e + 1, strlen(e)); /* shift rest of string */ strncpy(s, ent[b], c); /* copy in replacement text */ } else s++; /* not a known entity */ } else if ((t == ' ' || t == '*') && isspace((int) (*s))) *(s++) = ' '; else s++; /* no decoding needed */ } if (t == '*') { /* normalize spaces for non-cdata attributes */ for (s = r; *s; s++) { if ((l = (long) strspn(s, " "))) memmove(s, s + l, strlen(s + l) + 1); while (*s && *s != ' ') s++; } if (--s >= r && *s == ' ') *s = '\0'; /* trim any trailing space */ } return r; } /* called when parser finds start of new tag */ static void switch_xml_open_tag(switch_xml_root_t root, char *name, char **attr) { switch_xml_t xml; if (!root || !root->cur) { return; } xml = root->cur; if (xml->name) xml = switch_xml_add_child(xml, name, strlen(xml->txt)); else xml->name = name; /* first open tag */ xml->attr = attr; root->cur = xml; /* update tag insertion point */ } /* called when parser finds character content between open and closing tag */ static void switch_xml_char_content(switch_xml_root_t root, char *s, switch_size_t len, char t) { switch_xml_t xml; char *m = s; switch_size_t l; if (!root || !root->cur) { return; } xml = root->cur; if (!xml || !xml->name || !len) return; /* sanity check */ s[len] = '\0'; /* null terminate text (calling functions anticipate this) */ len = strlen(s = switch_xml_decode(s, root->ent, t)) + 1; if (!*(xml->txt)) xml->txt = s; /* initial character content */ else { /* allocate our own memory and make a copy */ if ((xml->flags & SWITCH_XML_TXTM)) { /* allocate some space */ char *tmp = (char *) realloc(xml->txt, (l = strlen(xml->txt)) + len); if (tmp) { xml->txt = tmp; } else { return; } } else { char *tmp = (char *) malloc((l = strlen(xml->txt)) + len); if (tmp) { xml->txt = strcpy(tmp, xml->txt); } else { return; } } strcpy(xml->txt + l, s); /* add new char content */ if (s != m) free(s); /* free s if it was malloced by switch_xml_decode() */ } if (xml->txt != m) switch_xml_set_flag(xml, SWITCH_XML_TXTM); } /* called when parser finds closing tag */ static switch_xml_t switch_xml_close_tag(switch_xml_root_t root, char *name, char *s) { if (!root || !root->cur || !root->cur->name || strcmp(name, root->cur->name)) return switch_xml_err(root, s, "unexpected closing tag ", name); root->cur = root->cur->parent; return NULL; } /* checks for circular entity references, returns non-zero if no circular references are found, zero otherwise */ static int switch_xml_ent_ok(char *name, char *s, char **ent) { int i; for (;; s++) { while (*s && *s != '&') s++; /* find next entity reference */ if (!*s) return 1; if (!strncmp(s + 1, name, strlen(name))) return 0; /* circular ref. */ for (i = 0; ent[i] && strncmp(ent[i], s + 1, strlen(ent[i])); i += 2); if (ent[i] && !switch_xml_ent_ok(name, ent[i + 1], ent)) return 0; } } /* called when the parser finds a processing instruction */ static void switch_xml_proc_inst(switch_xml_root_t root, char *s, switch_size_t len) { int i = 0, j = 1; char *target = s; char **sstmp; char *stmp; s[len] = '\0'; /* null terminate instruction */ if (*(s += strcspn(s, SWITCH_XML_WS))) { *s = '\0'; /* null terminate target */ s += strspn(s + 1, SWITCH_XML_WS) + 1; /* skip whitespace after target */ } if (!root) return; if (!strcmp(target, "xml")) { /* */ if ((s = strstr(s, "standalone")) && !strncmp(s + strspn(s + 10, SWITCH_XML_WS "='\"") + 10, "yes", 3)) root->standalone = 1; return; } if (!root->pi || !root->pi[0]) { root->pi = (char ***) malloc(sizeof(char **)); if (!root->pi) return; *(root->pi) = NULL; /* first pi */ } while (root->pi[i] && strcmp(target, root->pi[i][0])) i++; /* find target */ if (!root->pi[i]) { /* new target */ char ***ssstmp = (char ***) realloc(root->pi, sizeof(char **) * (i + 2)); if (!ssstmp) return; root->pi = ssstmp; if (!root->pi) return; root->pi[i] = (char **) malloc(sizeof(char *) * 3); if (!root->pi[i]) return; root->pi[i][0] = target; root->pi[i][1] = (char *) (root->pi[i + 1] = NULL); /* terminate pi list */ root->pi[i][2] = strdup(""); /* empty document position list */ } while (root->pi[i][j]) j++; /* find end of instruction list for this target */ sstmp = (char **) realloc(root->pi[i], sizeof(char *) * (j + 3)); if (!sstmp) return; root->pi[i] = sstmp; stmp = (char *) realloc(root->pi[i][j + 1], j + 1); if (!stmp) return; root->pi[i][j + 2] = stmp; strcpy(root->pi[i][j + 2] + j - 1, (root->xml.name) ? ">" : "<"); root->pi[i][j + 1] = NULL; /* null terminate pi list for this target */ root->pi[i][j] = s; /* set instruction */ } /* called when the parser finds an internal doctype subset */ static short switch_xml_internal_dtd(switch_xml_root_t root, char *s, switch_size_t len) { char q, *c, *t, *n = NULL, *v, **ent, **pe; int i, j; char **sstmp; pe = (char **) memcpy(malloc(sizeof(SWITCH_XML_NIL)), SWITCH_XML_NIL, sizeof(SWITCH_XML_NIL)); for (s[len] = '\0'; s;) { while (*s && *s != '<' && *s != '%') s++; /* find next declaration */ if (!*s) break; else if (!strncmp(s, "'); continue; } for (i = 0, ent = (*c == '%') ? pe : root->ent; ent[i]; i++); sstmp = (char **) realloc(ent, (i + 3) * sizeof(char *)); /* space for next ent */ if (!sstmp) { switch_xml_err(root, v, "Allocation Error!"); break; } ent = sstmp; if (*c == '%') pe = ent; else root->ent = ent; *(++s) = '\0'; /* null terminate name */ if ((s = strchr(v, q))) *(s++) = '\0'; /* null terminate value */ ent[i + 1] = switch_xml_decode(v, pe, '%'); /* set value */ ent[i + 2] = NULL; /* null terminate entity list */ if (!switch_xml_ent_ok(n, ent[i + 1], ent)) { /* circular reference */ if (ent[i + 1] != v) free(ent[i + 1]); switch_xml_err(root, v, "circular entity declaration &%s", n); break; } else ent[i] = n; /* set entity name */ } else if (!strncmp(s, "")) == '>') continue; else *s = '\0'; /* null terminate tag name */ for (i = 0; root->attr[i] && strcmp(n, root->attr[i][0]); i++); //while (*(n = ++s + strspn(s, SWITCH_XML_WS)) && *n != '>') { // gcc 4.4 you are a creep for (;;) { s++; if (!(*(n = s + strspn(s, SWITCH_XML_WS)) && *n != '>')) { break; } if (*(s = n + strcspn(n, SWITCH_XML_WS))) *s = '\0'; /* attr name */ else { switch_xml_err(root, t, "malformed ") - 1; if (*c == ' ') continue; /* cdata is default, nothing to do */ v = NULL; } else if ((*s == '"' || *s == '\'') && /* default value */ (s = strchr(v = s + 1, *s))) *s = '\0'; else { switch_xml_err(root, t, "malformed attr[i]) { /* new tag name */ root->attr = (!i) ? (char ***) malloc(2 * sizeof(char **)) : (char ***) realloc(root->attr, (i + 2) * sizeof(char **)); root->attr[i] = (char **) malloc(2 * sizeof(char *)); root->attr[i][0] = t; /* set tag name */ root->attr[i][1] = (char *) (root->attr[i + 1] = NULL); } for (j = 1; root->attr[i][j]; j += 3); /* find end of list */ sstmp = (char **) realloc(root->attr[i], (j + 4) * sizeof(char *)); if (!sstmp) { switch_xml_err(root, t, "Allocation Error!"); break; } root->attr[i] = sstmp; root->attr[i][j + 3] = NULL; /* null terminate list */ root->attr[i][j + 2] = c; /* is it cdata? */ root->attr[i][j + 1] = (v) ? switch_xml_decode(v, root->ent, *c) : NULL; root->attr[i][j] = n; /* attribute name */ } } else if (!strncmp(s, ""); /* comments */ else if (!strncmp(s, ""))) switch_xml_proc_inst(root, c, s++ - c); } else if (*s == '<') s = strchr(s, '>'); /* skip other declarations */ else if (*(s++) == '%' && !root->standalone) break; } free(pe); return !*root->err; } /* Converts a UTF-16 string to UTF-8. Returns a new string that must be freed or NULL if no conversion was needed. */ static char *switch_xml_str2utf8(char **s, switch_size_t *len) { char *u; switch_size_t l = 0, sl, max = *len; long c, d; int b, be = (**s == '\xFE') ? 1 : (**s == '\xFF') ? 0 : -1; if (be == -1) return NULL; /* not UTF-16 */ u = (char *) malloc(max); for (sl = 2; sl < *len - 1; sl += 2) { c = (be) ? (((*s)[sl] & 0xFF) << 8) | ((*s)[sl + 1] & 0xFF) /* UTF-16BE */ : (((*s)[sl + 1] & 0xFF) << 8) | ((*s)[sl] & 0xFF); /* UTF-16LE */ if (c >= 0xD800 && c <= 0xDFFF && (sl += 2) < *len - 1) { /* high-half */ d = (be) ? (((*s)[sl] & 0xFF) << 8) | ((*s)[sl + 1] & 0xFF) : (((*s)[sl + 1] & 0xFF) << 8) | ((*s)[sl] & 0xFF); c = (((c & 0x3FF) << 10) | (d & 0x3FF)) + 0x10000; } while (l + 6 > max) { char *tmp; tmp = (char *) realloc(u, max += SWITCH_XML_BUFSIZE); if (!tmp) return NULL; u = tmp; } if (c < 0x80) u[l++] = (char) c; /* US-ASCII subset */ else { /* multi-byte UTF-8 sequence */ for (b = 0, d = c; d; d /= 2) b++; /* bits in c */ b = (b - 2) / 5; /* bytes in payload */ u[l++] = (char) ((0xFF << (7 - b)) | (c >> (6 * b))); /* head */ while (b) u[l++] = (char) (0x80 | ((c >> (6 * --b)) & 0x3F)); /* payload */ } } return *s = (char *) realloc(u, *len = l); } /* frees a tag attribute list */ static void switch_xml_free_attr(char **attr) { int i = 0; char *m; if (!attr || attr == SWITCH_XML_NIL) return; /* nothing to free */ while (attr[i]) i += 2; /* find end of attribute list */ m = attr[i + 1]; /* list of which names and values are malloced */ for (i = 0; m[i]; i++) { if (m[i] & SWITCH_XML_NAMEM) free(attr[i * 2]); if (m[i] & SWITCH_XML_TXTM) free(attr[(i * 2) + 1]); } free(m); free(attr); } SWITCH_DECLARE(switch_xml_t) switch_xml_parse_str_dynamic(char *s, switch_bool_t dup) { switch_xml_root_t root; char *data; switch_assert(s); data = dup ? strdup(s) : s; if ((root = (switch_xml_root_t) switch_xml_parse_str(data, strlen(data)))) { root->dynamic = 1; /* Make sure we free the memory is switch_xml_free() */ return &root->xml; } else { if (dup) { free(data); } return NULL; } } /* parse the given xml string and return a switch_xml structure */ SWITCH_DECLARE(switch_xml_t) switch_xml_parse_str(char *s, switch_size_t len) { switch_xml_root_t root = (switch_xml_root_t) switch_xml_new(NULL); char q, e, *d, **attr, **a = NULL; /* initialize a to avoid compile warning */ int l, i, j; root->m = s; if (!len) return switch_xml_err(root, s, "root tag missing"); root->u = switch_xml_str2utf8(&s, &len); /* convert utf-16 to utf-8 */ root->e = (root->s = s) + len; /* record start and end of work area */ e = s[len - 1]; /* save end char */ s[len - 1] = '\0'; /* turn end char into null terminator */ while (*s && *s != '<') s++; /* find first tag */ if (!*s) return switch_xml_err(root, s, "root tag missing"); for (;;) { attr = (char **) SWITCH_XML_NIL; d = ++s; if (isalpha((int) (*s)) || *s == '_' || *s == ':' || (int8_t) * s < '\0') { /* new tag */ if (!root->cur) return switch_xml_err(root, d, "markup outside of root element"); s += strcspn(s, SWITCH_XML_WS "/>"); while (isspace((int) (*s))) *(s++) = '\0'; /* null terminate tag name */ if (*s && *s != '/' && *s != '>') /* find tag in default attr list */ for (i = 0; (a = root->attr[i]) && strcmp(a[0], d); i++); for (l = 0; *s && *s != '/' && *s != '>'; l += 2) { /* new attrib */ attr = (l) ? (char **) realloc(attr, (l + 4) * sizeof(char *)) : (char **) malloc(4 * sizeof(char *)); /* allocate space */ attr[l + 3] = (l) ? (char *) realloc(attr[l + 1], (l / 2) + 2) : (char *) malloc(2); /* mem for list of maloced vals */ strcpy(attr[l + 3] + (l / 2), " "); /* value is not malloced */ attr[l + 2] = NULL; /* null terminate list */ attr[l + 1] = (char *) ""; /* temporary attribute value */ attr[l] = s; /* set attribute name */ s += strcspn(s, SWITCH_XML_WS "=/>"); if (*s == '=' || isspace((int) (*s))) { *(s++) = '\0'; /* null terminate tag attribute name */ q = *(s += strspn(s, SWITCH_XML_WS "=")); if (q == '"' || q == '\'') { /* attribute value */ attr[l + 1] = ++s; while (*s && *s != q) s++; if (*s) *(s++) = '\0'; /* null terminate attribute val */ else { switch_xml_free_attr(attr); return switch_xml_err(root, d, "missing %c", q); } for (j = 1; a && a[j] && strcmp(a[j], attr[l]); j += 3); attr[l + 1] = switch_xml_decode(attr[l + 1], root->ent, (a && a[j]) ? *a[j + 2] : ' '); if (attr[l + 1] < d || attr[l + 1] > s) attr[l + 3][l / 2] = SWITCH_XML_TXTM; /* value malloced */ } } while (isspace((int) (*s))) s++; } if (*s == '/') { /* self closing tag */ *(s++) = '\0'; if ((*s && *s != '>') || (!*s && e != '>')) { if (l) switch_xml_free_attr(attr); return switch_xml_err(root, d, "missing >"); } switch_xml_open_tag(root, d, attr); switch_xml_close_tag(root, d, s); } else if ((q = *s) == '>' || (!*s && e == '>')) { /* open tag */ *s = '\0'; /* temporarily null terminate tag name */ switch_xml_open_tag(root, d, attr); *s = q; } else { if (l) switch_xml_free_attr(attr); return switch_xml_err(root, d, "missing >"); } } else if (*s == '/') { /* close tag */ s += strcspn(d = s + 1, SWITCH_XML_WS ">") + 1; if (!(q = *s) && e != '>') return switch_xml_err(root, d, "missing >"); *s = '\0'; /* temporarily null terminate tag name */ if (switch_xml_close_tag(root, d, s)) return &root->xml; if (isspace((int) (*s = q))) s += strspn(s, SWITCH_XML_WS); } else if (!strncmp(s, "!--", 3)) { /* xml comment */ if (!(s = strstr(s + 3, "--")) || (*(s += 2) != '>' && *s) || (!*s && e != '>')) return switch_xml_err(root, d, "unclosed ", command); fwrite( buffer, 1, strlen(buffer), write_fd); } #else int fds[2], pid = 0; if (pipe(fds)) { goto end; } else { /* good to go */ pid = switch_fork(); if (pid < 0) { /* ok maybe not */ close(fds[0]); close(fds[1]); goto end; } else if (pid) { /* parent */ char buf[1024] = ""; int bytes; close(fds[1]); while ((bytes = read(fds[0], buf, sizeof(buf))) > 0) { if (fwrite(buf, 1, bytes, write_fd) <= 0) { break; } } close(fds[0]); waitpid(pid, NULL, 0); } else { /* child */ switch_close_extra_files(fds, 2); close(fds[0]); dup2(fds[1], STDOUT_FILENO); switch_system(command, SWITCH_TRUE); close(fds[1]); exit(0); } } #endif end: return write_fd; } static FILE *preprocess_glob(const char *cwd, const char *pattern, FILE *write_fd, int rlevel) { char *full_path = NULL; char *dir_path = NULL, *e = NULL; glob_t glob_data; size_t n; if (!switch_is_file_path(pattern)) { full_path = switch_mprintf("%s%s%s", cwd, SWITCH_PATH_SEPARATOR, pattern); pattern = full_path; } if (glob(pattern, GLOB_NOCHECK, NULL, &glob_data) != 0) { switch_log_printf(SWITCH_CHANNEL_LOG, SWITCH_LOG_ERROR, "Error including %s\n", pattern); goto end; } for (n = 0; n < glob_data.gl_pathc; ++n) { dir_path = strdup(glob_data.gl_pathv[n]); switch_assert(dir_path); if ((e = strrchr(dir_path, *SWITCH_PATH_SEPARATOR))) { *e = '\0'; } if (preprocess(dir_path, glob_data.gl_pathv[n], write_fd, rlevel) < 0) { if (rlevel > 100) { switch_log_printf(SWITCH_CHANNEL_LOG, SWITCH_LOG_ERROR, "Error including %s (Maximum recursion limit reached)\n", pattern); } } free(dir_path); } globfree(&glob_data); end: switch_safe_free(full_path); return write_fd; } static int preprocess(const char *cwd, const char *file, FILE *write_fd, int rlevel) { FILE *read_fd = NULL; switch_size_t cur = 0, ml = 0; char *q, *cmd, *buf = NULL, *ebuf = NULL; char *tcmd, *targ; int line = 0; switch_size_t len = 0, eblen = 0; if (rlevel > 100) { return -1; } if (!(read_fd = fopen(file, "r"))) { const char *reason = strerror(errno); switch_log_printf(SWITCH_CHANNEL_LOG, SWITCH_LOG_ERROR, "Couldnt open %s (%s)\n", file, reason); return -1; } setvbuf(read_fd, (char *) NULL, _IOFBF, 65536); for(;;) { char *arg, *e; const char *err = NULL; char *bp; switch_safe_free(ebuf); if ((cur = switch_fp_read_dline(read_fd, &buf, &len)) <= 0) { break; } eblen = len *2; ebuf = malloc(eblen); memset(ebuf, 0, eblen); bp = expand_vars(buf, ebuf, eblen, &cur, &err); line++; if (err) { switch_log_printf(SWITCH_CHANNEL_LOG, SWITCH_LOG_ERROR, "Error [%s] in file %s line %d\n", err, file, line); } /* we ignore or for the sake of validators as well as type stuff */ if (strstr(buf, "") || strstr(buf, "") || strstr(buf, ""))) { ml = 0; bp = e + 3; cur = strlen(bp); } else { continue; } } if ((tcmd = (char *) switch_stristr("X-pre-process", bp))) { if (*(tcmd - 1) != '<') { continue; } if ((e = strstr(tcmd, "/>"))) { *e += 2; *e = '\0'; if (fwrite(e, 1, (unsigned) strlen(e), write_fd) != (int) strlen(e)) { switch_log_printf(SWITCH_CHANNEL_LOG, SWITCH_LOG_ERROR, "Short write!\n"); } } if (!(tcmd = (char *) switch_stristr("cmd", tcmd))) { continue; } if (!(tcmd = (char *) switch_stristr("=", tcmd))) { continue; } if (!(tcmd = (char *) switch_stristr("\"", tcmd))) { continue; } tcmd++; if ((e = strchr(tcmd, '"'))) { *e++ = '\0'; } if (!(targ = (char *) switch_stristr("data", e))) { continue; } if (!(targ = (char *) switch_stristr("=", targ))) { continue; } if (!(targ = (char *) switch_stristr("\"", targ))) { continue; } targ++; if ((e = strchr(targ, '"'))) { *e++ = '\0'; } if (!strcasecmp(tcmd, "set")) { char *name = (char *) targ; char *val = strchr(name, '='); if (val) { char *ve = val++; while (*val && *val == ' ') { val++; } *ve-- = '\0'; while (*ve && *ve == ' ') { *ve-- = '\0'; } } if (name && val) { switch_core_set_variable(name, val); } } else if (!strcasecmp(tcmd, "exec-set")) { preprocess_exec_set(targ); } else if (!strcasecmp(tcmd, "include")) { preprocess_glob(cwd, targ, write_fd, rlevel + 1); } else if (!strcasecmp(tcmd, "exec")) { preprocess_exec(cwd, targ, write_fd, rlevel + 1); } continue; } if ((cmd = strstr(bp, ""))) { *e = '\0'; e += 3; if (fwrite(e, 1, (unsigned) strlen(e), write_fd) != (int) strlen(e)) { switch_log_printf(SWITCH_CHANNEL_LOG, SWITCH_LOG_ERROR, "Short write!\n"); } } else { ml++; } cmd += 5; if ((e = strchr(cmd, '\r')) || (e = strchr(cmd, '\n'))) { *e = '\0'; } if ((arg = strchr(cmd, ' '))) { *arg++ = '\0'; if ((q = strchr(arg, '"'))) { char *qq = q + 1; if ((qq = strchr(qq, '"'))) { *qq = '\0'; arg = q + 1; } } if (!strcasecmp(cmd, "set")) { char *name = arg; char *val = strchr(name, '='); if (val) { char *ve = val++; while (*val && *val == ' ') { val++; } *ve-- = '\0'; while (*ve && *ve == ' ') { *ve-- = '\0'; } } if (name && val) { switch_core_set_variable(name, val); } } else if (!strcasecmp(cmd, "exec-set")) { preprocess_exec_set(arg); } else if (!strcasecmp(cmd, "include")) { preprocess_glob(cwd, arg, write_fd, rlevel + 1); } else if (!strcasecmp(cmd, "exec")) { preprocess_exec(cwd, arg, write_fd, rlevel + 1); } } continue; } if (fwrite(bp, 1, (unsigned) cur, write_fd) != (int) cur) { switch_log_printf(SWITCH_CHANNEL_LOG, SWITCH_LOG_ERROR, "Short write!\n"); } } switch_safe_free(buf); switch_safe_free(ebuf); fclose(read_fd); return 0; } SWITCH_DECLARE(switch_xml_t) switch_xml_parse_file_simple(const char *file) { int fd = -1; struct stat st; switch_size_t l; void *m; switch_xml_root_t root; if ((fd = open(file, O_RDONLY, 0)) > -1) { fstat(fd, &st); if (!st.st_size) goto error; m = malloc(st.st_size); switch_assert(m); if (!(l = read(fd, m, st.st_size))) goto error; if (!(root = (switch_xml_root_t) switch_xml_parse_str((char *) m, l))) goto error; root->dynamic = 1; close(fd); return &root->xml; } error: switch_log_printf(SWITCH_CHANNEL_LOG, SWITCH_LOG_ERROR, "Error Parsing File [%s]\n", file); return NULL; } SWITCH_DECLARE(switch_xml_t) switch_xml_parse_file(const char *file) { int fd = -1; FILE *write_fd = NULL; switch_xml_t xml = NULL; char *new_file = NULL; const char *abs, *absw; abs = strrchr(file, '/'); absw = strrchr(file, '\\'); if (abs || absw) { abs > absw ? abs++ : (abs = ++absw); } else { abs = file; } switch_mutex_lock(FILE_LOCK); if (!(new_file = switch_mprintf("%s%s%s.fsxml", SWITCH_GLOBAL_dirs.log_dir, SWITCH_PATH_SEPARATOR, abs))) { goto done; } if ((write_fd = fopen(new_file, "w+")) == NULL) { goto done; } setvbuf(write_fd, (char *) NULL, _IOFBF, 65536); if (preprocess(SWITCH_GLOBAL_dirs.conf_dir, file, write_fd, 0) > -1) { fclose(write_fd); write_fd = NULL; if ((fd = open(new_file, O_RDONLY, 0)) > -1) { if ((xml = switch_xml_parse_fd(fd))) { if (strcmp(abs, SWITCH_GLOBAL_filenames.conf_name)) { xml->free_path = new_file; new_file = NULL; } } close(fd); fd = -1; } } done: switch_mutex_unlock(FILE_LOCK); if (write_fd) { fclose(write_fd); write_fd = NULL; } if (fd > -1) { close(fd); } switch_safe_free(new_file); return xml; } SWITCH_DECLARE(switch_status_t) switch_xml_locate(const char *section, const char *tag_name, const char *key_name, const char *key_value, switch_xml_t *root, switch_xml_t *node, switch_event_t *params, switch_bool_t clone) { switch_xml_t conf = NULL; switch_xml_t tag = NULL; switch_xml_t xml = NULL; switch_xml_binding_t *binding; uint8_t loops = 0; switch_xml_section_t sections = BINDINGS ? switch_xml_parse_section_string(section) : 0; switch_thread_rwlock_rdlock(B_RWLOCK); for (binding = BINDINGS; binding; binding = binding->next) { if (binding->sections && !(sections & binding->sections)) { continue; } if ((xml = binding->function(section, tag_name, key_name, key_value, params, binding->user_data))) { const char *err = NULL; err = switch_xml_error(xml); if (zstr(err)) { if ((conf = switch_xml_find_child(xml, "section", "name", "result"))) { switch_xml_t p; const char *aname; if ((p = switch_xml_child(conf, "result"))) { aname = switch_xml_attr(p, "status"); if (aname && !strcasecmp(aname, "not found")) { switch_xml_free(xml); xml = NULL; continue; } } } break; } else { switch_log_printf(SWITCH_CHANNEL_LOG, SWITCH_LOG_ERROR, "Error[%s]\n", err); switch_xml_free(xml); xml = NULL; } } } switch_thread_rwlock_unlock(B_RWLOCK); for (;;) { if (!xml) { if (!(xml = switch_xml_root())) { *node = NULL; *root = NULL; return SWITCH_STATUS_FALSE; } } if ((conf = switch_xml_find_child(xml, "section", "name", section)) && (tag = switch_xml_find_child(conf, tag_name, key_name, key_value))) { if (clone) { char *x = switch_xml_toxml(tag, SWITCH_FALSE); switch_assert(x); *node = *root = switch_xml_parse_str_dynamic(x, SWITCH_FALSE); /* x will be free()'d in switch_xml_free() */ switch_xml_free(xml); } else { *node = tag; *root = xml; } return SWITCH_STATUS_SUCCESS; } else { switch_xml_free(xml); xml = NULL; *node = NULL; *root = NULL; if (loops++ > 1) { break; } } } return SWITCH_STATUS_FALSE; } SWITCH_DECLARE(switch_status_t) switch_xml_locate_domain(const char *domain_name, switch_event_t *params, switch_xml_t *root, switch_xml_t *domain) { switch_event_t *my_params = NULL; switch_status_t status; *domain = NULL; if (!params) { switch_event_create(&my_params, SWITCH_EVENT_REQUEST_PARAMS); switch_assert(my_params); switch_event_add_header_string(my_params, SWITCH_STACK_BOTTOM, "domain", domain_name); params = my_params; } status = switch_xml_locate("directory", "domain", "name", domain_name, root, domain, params, SWITCH_FALSE); if (my_params) { switch_event_destroy(&my_params); } return status; } SWITCH_DECLARE(switch_status_t) switch_xml_locate_group(const char *group_name, const char *domain_name, switch_xml_t *root, switch_xml_t *domain, switch_xml_t *group, switch_event_t *params) { switch_status_t status = SWITCH_STATUS_FALSE; switch_event_t *my_params = NULL; switch_xml_t groups = NULL; *root = NULL; *group = NULL; *domain = NULL; if (!params) { switch_event_create(&my_params, SWITCH_EVENT_REQUEST_PARAMS); switch_assert(my_params); params = my_params; } if (group_name) { switch_event_add_header_string(params, SWITCH_STACK_BOTTOM, "group_name", group_name); } if (domain_name) { switch_event_add_header_string(params, SWITCH_STACK_BOTTOM, "domain", domain_name); } if ((status = switch_xml_locate_domain(domain_name, params, root, domain)) != SWITCH_STATUS_SUCCESS) { goto end; } status = SWITCH_STATUS_FALSE; if ((groups = switch_xml_child(*domain, "groups"))) { if ((*group = switch_xml_find_child(groups, "group", "name", group_name))) { status = SWITCH_STATUS_SUCCESS; } } end: if (my_params) { switch_event_destroy(&my_params); } return status; } static switch_status_t find_user_in_tag(switch_xml_t tag, const char *ip, const char *user_name, const char *key, switch_event_t *params, switch_xml_t *user) { const char *type = "!pointer"; const char *val; if (params && (val = switch_event_get_header(params, "user_type"))) { if (!strcasecmp(val, "any")) { type = NULL; } else { type = val; } } if (ip) { if ((*user = switch_xml_find_child_multi(tag, "user", "ip", ip, "type", type, NULL))) { return SWITCH_STATUS_SUCCESS; } } if (user_name) { if (!strcasecmp(key, "id")) { if ((*user = switch_xml_find_child_multi(tag, "user", key, user_name, "number-alias", user_name, "type", type, NULL))) { return SWITCH_STATUS_SUCCESS; } } else { if ((*user = switch_xml_find_child_multi(tag, "user", key, user_name, "type", type, NULL))) { return SWITCH_STATUS_SUCCESS; } } } return SWITCH_STATUS_FALSE; } SWITCH_DECLARE(switch_status_t) switch_xml_locate_user_in_domain(const char *user_name, switch_xml_t domain, switch_xml_t *user, switch_xml_t *ingroup) { switch_xml_t group = NULL, groups = NULL, users = NULL; switch_status_t status = SWITCH_STATUS_FALSE; if ((groups = switch_xml_child(domain, "groups"))) { for (group = switch_xml_child(groups, "group"); group; group = group->next) { if ((users = switch_xml_child(group, "users"))) { if ((status = find_user_in_tag(users, NULL, user_name, "id", NULL, user)) == SWITCH_STATUS_SUCCESS) { if (ingroup) { *ingroup = group; } break; } } } } return status; } SWITCH_DECLARE(switch_xml_t) switch_xml_dup(switch_xml_t xml) { char *x = switch_xml_toxml(xml, SWITCH_FALSE); return switch_xml_parse_str_dynamic(x, SWITCH_FALSE); } static void do_merge(switch_xml_t in, switch_xml_t src, const char *container, const char *tag_name) { switch_xml_t itag, tag, param, iparam, iitag; if (!(itag = switch_xml_child(in, container))) { itag = switch_xml_add_child_d(in, container, 0); } if ((tag = switch_xml_child(src, container))) { for (param = switch_xml_child(tag, tag_name); param; param = param->next) { const char *var = switch_xml_attr(param, "name"); const char *val = switch_xml_attr(param, "value"); int go = 1; for (iparam = switch_xml_child(itag, tag_name); iparam; iparam = iparam->next) { const char *ivar = switch_xml_attr(iparam, "name"); if (var && ivar && !strcasecmp(var, ivar)) { go = 0; break; } } if (go) { iitag = switch_xml_add_child_d(itag, tag_name, 0); switch_xml_set_attr_d(iitag, "name", var); switch_xml_set_attr_d(iitag, "value", val); } } } } SWITCH_DECLARE(void) switch_xml_merge_user(switch_xml_t user, switch_xml_t domain, switch_xml_t group) { const char *domain_name = switch_xml_attr(domain, "name"); do_merge(user, group, "params", "param"); do_merge(user, group, "variables", "variable"); do_merge(user, group, "profile-variables", "variable"); do_merge(user, domain, "params", "param"); do_merge(user, domain, "variables", "variable"); do_merge(user, domain, "profile-variables", "variable"); if (!zstr(domain_name)) { switch_xml_set_attr_d(user, "domain-name", domain_name); } } SWITCH_DECLARE(uint32_t) switch_xml_clear_user_cache(const char *key, const char *user_name, const char *domain_name) { switch_hash_index_t *hi; void *val; const void *var; char mega_key[1024]; int r = 0; switch_xml_t lookup; switch_mutex_lock(CACHE_MUTEX); if (key && user_name && domain_name) { switch_snprintf(mega_key, sizeof(mega_key), "%s%s%s", key, user_name, domain_name); if ((lookup = switch_core_hash_find(CACHE_HASH, mega_key))) { switch_core_hash_delete(CACHE_HASH, mega_key); if ((lookup = switch_core_hash_find(CACHE_EXPIRES_HASH, mega_key))) { switch_core_hash_delete(CACHE_EXPIRES_HASH, mega_key); } switch_xml_free(lookup); r++; } } else { while ((hi = switch_hash_first(NULL, CACHE_HASH))) { switch_hash_this(hi, &var, NULL, &val); switch_xml_free(val); switch_core_hash_delete(CACHE_HASH, var); r++; } while ((hi = switch_hash_first(NULL, CACHE_EXPIRES_HASH))) { switch_hash_this(hi, &var, NULL, &val); switch_safe_free(val); switch_core_hash_delete(CACHE_EXPIRES_HASH, var); } } switch_mutex_unlock(CACHE_MUTEX); return r; } static switch_status_t switch_xml_locate_user_cache(const char *key, const char *user_name, const char *domain_name, switch_xml_t *user) { char mega_key[1024]; switch_status_t status = SWITCH_STATUS_FALSE; switch_xml_t lookup; switch_snprintf(mega_key, sizeof(mega_key), "%s%s%s", key, user_name, domain_name); switch_mutex_lock(CACHE_MUTEX); if ((lookup = switch_core_hash_find(CACHE_HASH, mega_key))) { char *expires_lookup = NULL; if ((expires_lookup = switch_core_hash_find(CACHE_EXPIRES_HASH, mega_key))) { switch_time_t time_expires = 0; switch_time_t time_now = 0; time_now = switch_micro_time_now(); time_expires = atol(expires_lookup); switch_log_printf(SWITCH_CHANNEL_LOG, SWITCH_LOG_DEBUG, "Cache Info\nTime Now:\t%ld\nExpires:\t%ld\n", (long)time_now, (long)time_expires); if (time_expires < time_now) { switch_log_printf(SWITCH_CHANNEL_LOG, SWITCH_LOG_DEBUG, "Cache expired for %s@%s, doing fresh lookup\n", user_name, domain_name); } else { *user = switch_xml_dup(lookup); status = SWITCH_STATUS_SUCCESS; } } else { *user = switch_xml_dup(lookup); status = SWITCH_STATUS_SUCCESS; } } switch_mutex_unlock(CACHE_MUTEX); return status; } static void switch_xml_user_cache(const char *key, const char *user_name, const char *domain_name, switch_xml_t user, switch_time_t expires) { char mega_key[1024]; switch_xml_t lookup; char *expires_lookup; switch_snprintf(mega_key, sizeof(mega_key), "%s%s%s", key, user_name, domain_name); switch_mutex_lock(CACHE_MUTEX); if ((lookup = switch_core_hash_find(CACHE_HASH, mega_key))) { switch_core_hash_delete(CACHE_HASH, mega_key); switch_xml_free(lookup); } if ((expires_lookup = switch_core_hash_find(CACHE_EXPIRES_HASH, mega_key))) { switch_core_hash_delete(CACHE_EXPIRES_HASH, mega_key); switch_safe_free(expires_lookup); } if (expires) { char *expires_val = malloc(1024); if (sprintf(expires_val, "%ld", (long)expires)) { switch_core_hash_insert(CACHE_EXPIRES_HASH, mega_key, expires_val); } } switch_core_hash_insert(CACHE_HASH, mega_key, switch_xml_dup(user)); switch_mutex_unlock(CACHE_MUTEX); } SWITCH_DECLARE(switch_status_t) switch_xml_locate_user_merged(const char *key, const char *user_name, const char *domain_name, const char *ip, switch_xml_t *user, switch_event_t *params) { switch_xml_t xml, domain, group, x_user, x_user_dup; switch_status_t status = SWITCH_STATUS_FALSE; char *kdup = NULL; char *keys[10] = {0}; int i, nkeys; if (strchr(key, ':')) { kdup = strdup(key); nkeys = switch_split(kdup, ':', keys); } else { keys[0] = (char *)key; nkeys = 1; } for(i = 0; i < nkeys; i++) { if ((status = switch_xml_locate_user_cache(keys[i], user_name, domain_name, &x_user)) == SWITCH_STATUS_SUCCESS) { *user = x_user; break; } else if ((status = switch_xml_locate_user(keys[i], user_name, domain_name, ip, &xml, &domain, &x_user, &group, params)) == SWITCH_STATUS_SUCCESS) { const char *cacheable = NULL; x_user_dup = switch_xml_dup(x_user); switch_xml_merge_user(x_user_dup, domain, group); cacheable = switch_xml_attr(x_user_dup, "cacheable"); if (!zstr(cacheable)) { switch_time_t expires = 0; switch_time_t time_now = 0; if (switch_is_number(cacheable)) { int cache_ms = atol(cacheable); switch_log_printf(SWITCH_CHANNEL_LOG, SWITCH_LOG_DEBUG, "caching lookup for user %s@%s for %d milliseconds\n", user_name, domain_name, cache_ms); time_now = switch_micro_time_now(); expires = time_now + (cache_ms * 1000); } else { switch_log_printf(SWITCH_CHANNEL_LOG, SWITCH_LOG_DEBUG, "caching lookup for user %s@%s indefinitely\n", user_name, domain_name); } switch_xml_user_cache(keys[i], user_name, domain_name, x_user_dup, expires); } *user = x_user_dup; switch_xml_free(xml); break; } } switch_safe_free(kdup); return status; } SWITCH_DECLARE(switch_status_t) switch_xml_locate_user(const char *key, const char *user_name, const char *domain_name, const char *ip, switch_xml_t *root, switch_xml_t *domain, switch_xml_t *user, switch_xml_t *ingroup, switch_event_t *params) { switch_status_t status = SWITCH_STATUS_FALSE; switch_event_t *my_params = NULL; switch_xml_t group = NULL, groups = NULL, users = NULL; *root = NULL; *user = NULL; *domain = NULL; if (ingroup) { *ingroup = NULL; } if (!params) { switch_event_create(&my_params, SWITCH_EVENT_REQUEST_PARAMS); switch_assert(my_params); params = my_params; } switch_event_add_header_string(params, SWITCH_STACK_BOTTOM, "key", key); if (user_name) { switch_event_add_header_string(params, SWITCH_STACK_BOTTOM, "user", user_name); } if (domain_name) { switch_event_add_header_string(params, SWITCH_STACK_BOTTOM, "domain", domain_name); } if (ip) { switch_event_add_header_string(params, SWITCH_STACK_BOTTOM, "ip", ip); } if ((status = switch_xml_locate_domain(domain_name, params, root, domain)) != SWITCH_STATUS_SUCCESS) { goto end; } status = SWITCH_STATUS_FALSE; if ((groups = switch_xml_child(*domain, "groups"))) { for (group = switch_xml_child(groups, "group"); group; group = group->next) { if ((users = switch_xml_child(group, "users"))) { if ((status = find_user_in_tag(users, ip, user_name, key, params, user)) == SWITCH_STATUS_SUCCESS) { if (ingroup) { *ingroup = group; } break; } } } } if (status != SWITCH_STATUS_SUCCESS) { status = find_user_in_tag(*domain, ip, user_name, key, params, user); } end: if (my_params) { switch_event_destroy(&my_params); } if (status != SWITCH_STATUS_SUCCESS && root && *root) { switch_xml_free(*root); *root = NULL; *domain = NULL; } return status; } SWITCH_DECLARE(switch_xml_t) switch_xml_root(void) { switch_xml_t xml; switch_mutex_lock(REFLOCK); xml = MAIN_XML_ROOT; xml->refs++; switch_mutex_unlock(REFLOCK); return xml; } struct destroy_xml { switch_xml_t xml; switch_memory_pool_t *pool; }; static void *SWITCH_THREAD_FUNC destroy_thread(switch_thread_t *thread, void *obj) { struct destroy_xml *dx = (struct destroy_xml *) obj; switch_memory_pool_t *pool = dx->pool; switch_xml_free(dx->xml); switch_core_destroy_memory_pool(&pool); return NULL; } SWITCH_DECLARE(void) switch_xml_free_in_thread(switch_xml_t xml, int stacksize) { switch_thread_t *thread; switch_threadattr_t *thd_attr; switch_memory_pool_t *pool = NULL; struct destroy_xml *dx; switch_core_new_memory_pool(&pool); switch_threadattr_create(&thd_attr, pool); switch_threadattr_detach_set(thd_attr, 1); /* TBD figure out how much space we need by looking at the xml_t when stacksize == 0 */ switch_threadattr_stacksize_set(thd_attr, stacksize); dx = switch_core_alloc(pool, sizeof(*dx)); dx->pool = pool; dx->xml = xml; switch_thread_create(&thread, thd_attr, destroy_thread, dx, pool); } static char not_so_threadsafe_error_buffer[256] = ""; SWITCH_DECLARE(switch_status_t) switch_xml_set_root(switch_xml_t new_main) { switch_xml_t old_root = NULL; switch_mutex_lock(REFLOCK); old_root = MAIN_XML_ROOT; MAIN_XML_ROOT = new_main; switch_set_flag(MAIN_XML_ROOT, SWITCH_XML_ROOT); MAIN_XML_ROOT->refs++; if (old_root) { if (old_root->refs) { old_root->refs--; } if (!old_root->refs) { switch_xml_free(old_root); } } switch_mutex_unlock(REFLOCK); return SWITCH_STATUS_SUCCESS; } SWITCH_DECLARE(switch_status_t) switch_xml_set_open_root_function(switch_xml_open_root_function_t func, void *user_data) { if (XML_LOCK) { switch_mutex_lock(XML_LOCK); } XML_OPEN_ROOT_FUNCTION = func; XML_OPEN_ROOT_FUNCTION_USER_DATA = user_data; if (XML_LOCK) { switch_mutex_unlock(XML_LOCK); } return SWITCH_STATUS_SUCCESS; } SWITCH_DECLARE(switch_xml_t) switch_xml_open_root(uint8_t reload, const char **err) { switch_xml_t root = NULL; switch_event_t *event; switch_mutex_lock(XML_LOCK); if (XML_OPEN_ROOT_FUNCTION) { root = XML_OPEN_ROOT_FUNCTION(reload, err, XML_OPEN_ROOT_FUNCTION_USER_DATA); } switch_mutex_unlock(XML_LOCK); if (root) { if (switch_event_create(&event, SWITCH_EVENT_RELOADXML) == SWITCH_STATUS_SUCCESS) { if (switch_event_fire(&event) != SWITCH_STATUS_SUCCESS) { switch_event_destroy(&event); } } } return root; } SWITCH_DECLARE_NONSTD(switch_xml_t) __switch_xml_open_root(uint8_t reload, const char **err, void *user_data) { char path_buf[1024]; uint8_t errcnt = 0; switch_xml_t new_main, r = NULL; if (MAIN_XML_ROOT) { if (!reload) { r = switch_xml_root(); goto done; } } switch_snprintf(path_buf, sizeof(path_buf), "%s%s%s", SWITCH_GLOBAL_dirs.conf_dir, SWITCH_PATH_SEPARATOR, SWITCH_GLOBAL_filenames.conf_name); if ((new_main = switch_xml_parse_file(path_buf))) { *err = switch_xml_error(new_main); switch_copy_string(not_so_threadsafe_error_buffer, *err, sizeof(not_so_threadsafe_error_buffer)); *err = not_so_threadsafe_error_buffer; if (!zstr(*err)) { switch_xml_free(new_main); new_main = NULL; errcnt++; } else { *err = "Success"; switch_xml_set_root(new_main); } } else { *err = "Cannot Open log directory or XML Root!"; errcnt++; } if (errcnt == 0) { r = switch_xml_root(); } done: return r; } SWITCH_DECLARE(switch_status_t) switch_xml_reload(const char **err) { switch_xml_t xml_root; if ((xml_root = switch_xml_open_root(1, err))) { switch_xml_free(xml_root); return SWITCH_STATUS_SUCCESS; } return SWITCH_STATUS_GENERR; } SWITCH_DECLARE(switch_status_t) switch_xml_init(switch_memory_pool_t *pool, const char **err) { switch_xml_t xml; XML_MEMORY_POOL = pool; *err = "Success"; switch_mutex_init(&CACHE_MUTEX, SWITCH_MUTEX_NESTED, XML_MEMORY_POOL); switch_mutex_init(&XML_LOCK, SWITCH_MUTEX_NESTED, XML_MEMORY_POOL); switch_mutex_init(&REFLOCK, SWITCH_MUTEX_NESTED, XML_MEMORY_POOL); switch_mutex_init(&FILE_LOCK, SWITCH_MUTEX_NESTED, XML_MEMORY_POOL); switch_mutex_init(&XML_GEN_LOCK, SWITCH_MUTEX_NESTED, XML_MEMORY_POOL); switch_core_hash_init(&CACHE_HASH, XML_MEMORY_POOL); switch_core_hash_init(&CACHE_EXPIRES_HASH, XML_MEMORY_POOL); switch_thread_rwlock_create(&B_RWLOCK, XML_MEMORY_POOL); assert(pool != NULL); if ((xml = switch_xml_open_root(FALSE, err))) { switch_xml_free(xml); return SWITCH_STATUS_SUCCESS; } else { return SWITCH_STATUS_FALSE; } } SWITCH_DECLARE(switch_status_t) switch_xml_destroy(void) { switch_status_t status = SWITCH_STATUS_FALSE; switch_mutex_lock(XML_LOCK); switch_mutex_lock(REFLOCK); if (MAIN_XML_ROOT) { switch_xml_t xml = MAIN_XML_ROOT; MAIN_XML_ROOT = NULL; switch_xml_free(xml); status = SWITCH_STATUS_SUCCESS; } switch_mutex_unlock(XML_LOCK); switch_mutex_unlock(REFLOCK); switch_xml_clear_user_cache(NULL, NULL, NULL); switch_core_hash_destroy(&CACHE_HASH); return status; } SWITCH_DECLARE(switch_xml_t) switch_xml_open_cfg(const char *file_path, switch_xml_t *node, switch_event_t *params) { switch_xml_t xml = NULL, cfg = NULL; *node = NULL; assert(MAIN_XML_ROOT != NULL); if (switch_xml_locate("configuration", "configuration", "name", file_path, &xml, &cfg, params, SWITCH_FALSE) == SWITCH_STATUS_SUCCESS) { *node = cfg; } return xml; } /* Encodes ampersand sequences appending the results to *dst, reallocating *dst if length exceeds max. a is non-zero for attribute encoding. Returns *dst */ static char *switch_xml_ampencode(const char *s, switch_size_t len, char **dst, switch_size_t *dlen, switch_size_t *max, short a) { const char *e = NULL; int immune = 0; int expecting_x_utf_8_char = 0; int unicode_char = 0x000000; if (!(s && *s)) return *dst; if (len) { e = s + len; } while (s != e) { while (*dlen + 10 > *max) { char *tmp = (char *) realloc(*dst, *max += SWITCH_XML_BUFSIZE); if (!tmp) return *dst; *dst = tmp; } if (immune) { if (*s == '\0') { return *dst; } (*dst)[(*dlen)++] = *s; } else switch (*s) { case '\0': return *dst; case '&': *dlen += sprintf(*dst + *dlen, "&"); break; case '<': if (*(s + 1) == '!') { (*dst)[(*dlen)++] = *s; immune++; break; } *dlen += sprintf(*dst + *dlen, "<"); break; case '>': *dlen += sprintf(*dst + *dlen, ">"); break; case '"': *dlen += sprintf(*dst + *dlen, (a) ? """ : "\""); break; case '\n': *dlen += sprintf(*dst + *dlen, (a) ? " " : "\n"); break; case '\t': *dlen += sprintf(*dst + *dlen, (a) ? " " : "\t"); break; case '\r': *dlen += sprintf(*dst + *dlen, " "); break; default: if (USE_UTF_8_ENCODING && expecting_x_utf_8_char == 0 && ((*s >> 8) & 0x01)) { int num = 1; for (;num<4;num++) { if (! ((*s >> (7-num)) & 0x01)) { break; } } switch (num) { case 2: unicode_char = *s & 0x1f; break; case 3: unicode_char = *s & 0x0f; break; case 4: unicode_char = *s & 0x07; break; default: switch_log_printf(SWITCH_CHANNEL_LOG, SWITCH_LOG_WARNING, "Invalid UTF-8 Initial charactere, skip it\n"); /* ERROR HERE */ break; } expecting_x_utf_8_char = num - 1; } else if (USE_UTF_8_ENCODING && expecting_x_utf_8_char > 0) { if (((*s >> 6) & 0x03) == 0x2) { unicode_char = unicode_char << 6; unicode_char = unicode_char | (*s & 0x3f); } else { switch_log_printf(SWITCH_CHANNEL_LOG, SWITCH_LOG_WARNING, "Invalid UTF-8 character to ampersand, skip it\n"); expecting_x_utf_8_char = 0; break; } expecting_x_utf_8_char--; if (expecting_x_utf_8_char == 0) { *dlen += sprintf(*dst + *dlen, "&#x%X;", unicode_char); } } else { (*dst)[(*dlen)++] = *s; } } s++; } return *dst; } #define XML_INDENT " " /* Recursively converts each tag to xml appending it to *s. Reallocates *s if its length exceeds max. start is the location of the previous tag in the parent tag's character content. Returns *s. */ static char *switch_xml_toxml_r(switch_xml_t xml, char **s, switch_size_t *len, switch_size_t *max, switch_size_t start, char ***attr, uint32_t *count) { int i, j; char *txt; switch_size_t off; uint32_t lcount; tailrecurse: off = 0; lcount = 0; txt = (char *) (xml->parent) ? xml->parent->txt : (char *) ""; /* parent character content up to this tag */ *s = switch_xml_ampencode(txt + start, xml->off - start, s, len, max, 0); while (*len + strlen(xml->name) + 5 + (strlen(XML_INDENT) * (*count)) + 1 > *max) { /* reallocate s */ char *tmp = *s; *s = (char *) realloc(*s, *max += SWITCH_XML_BUFSIZE); if (!*s) return tmp; } if (*len && *(*s + (*len) - 1) == '>') { *len += sprintf(*s + *len, "\n"); /* indent */ } for (lcount = 0; lcount < *count; lcount++) { *len += sprintf(*s + *len, "%s", XML_INDENT); /* indent */ } *len += sprintf(*s + *len, "<%s", xml->name); /* open tag */ for (i = 0; xml->attr[i]; i += 2) { /* tag attributes */ if (switch_xml_attr(xml, xml->attr[i]) != xml->attr[i + 1]) continue; while (*len + strlen(xml->attr[i]) + 7 + (strlen(XML_INDENT) * (*count)) > *max) { /* reallocate s */ char *tmp = (char *) realloc(*s, *max += SWITCH_XML_BUFSIZE); if (!tmp) return *s; *s = tmp; } *len += sprintf(*s + *len, " %s=\"", xml->attr[i]); switch_xml_ampencode(xml->attr[i + 1], 0, s, len, max, 1); *len += sprintf(*s + *len, "\""); } for (i = 0; attr[i] && strcmp(attr[i][0], xml->name); i++); for (j = 1; attr[i] && attr[i][j]; j += 3) { /* default attributes */ if (!attr[i][j + 1] || switch_xml_attr(xml, attr[i][j]) != attr[i][j + 1]) continue; /* skip duplicates and non-values */ while (*len + strlen(attr[i][j]) + 8 + (strlen(XML_INDENT) * (*count)) > *max) { /* reallocate s */ char *tmp = (char *) realloc(*s, *max += SWITCH_XML_BUFSIZE); if (!tmp) return *s; *s = tmp; } *len += sprintf(*s + *len, " %s=\"", attr[i][j]); switch_xml_ampencode(attr[i][j + 1], 0, s, len, max, 1); *len += sprintf(*s + *len, "\""); } *len += sprintf(*s + *len, (xml->child || xml->txt) ? ">" : "/>\n"); if (xml->child) { (*count)++; *s = switch_xml_toxml_r(xml->child, s, len, max, 0, attr, count); } else { *s = switch_xml_ampencode(xml->txt, 0, s, len, max, 0); /* data */ } while (*len + strlen(xml->name) + 5 + (strlen(XML_INDENT) * (*count)) > *max) { /* reallocate s */ char *tmp = *s; *s = (char *) realloc(*s, *max += SWITCH_XML_BUFSIZE); if (!*s) return tmp; } if (xml->child || xml->txt) { if (*(*s + (*len) - 1) == '\n') { for (lcount = 0; lcount < *count; lcount++) { *len += sprintf(*s + *len, "%s", XML_INDENT); /* indent */ } } *len += sprintf(*s + (*len), "\n", xml->name); /* close tag */ } while (txt[off] && off < xml->off) off++; /* make sure off is within bounds */ if (xml->ordered) { xml = xml->ordered; start = off; goto tailrecurse; /* return switch_xml_toxml_r(xml->ordered, s, len, max, off, attr, count); */ } else { if (*count > 0) (*count)--; return switch_xml_ampencode(txt + off, 0, s, len, max, 0); } } SWITCH_DECLARE(char *) switch_xml_toxml_nolock(switch_xml_t xml, switch_bool_t prn_header) { char *s = (char *) malloc(SWITCH_XML_BUFSIZE); switch_assert(s); return switch_xml_toxml_buf(xml, s, SWITCH_XML_BUFSIZE, 0, prn_header); } SWITCH_DECLARE(char *) switch_xml_toxml(switch_xml_t xml, switch_bool_t prn_header) { char *r, *s; s = (char *) malloc(SWITCH_XML_BUFSIZE); switch_assert(s); switch_mutex_lock(XML_GEN_LOCK); r = switch_xml_toxml_buf(xml, s, SWITCH_XML_BUFSIZE, 0, prn_header); switch_mutex_unlock(XML_GEN_LOCK); return r; } SWITCH_DECLARE(char *) switch_xml_tohtml(switch_xml_t xml, switch_bool_t prn_header) { char *r, *s, *h; switch_size_t rlen = 0; switch_size_t len = SWITCH_XML_BUFSIZE; switch_mutex_lock(XML_GEN_LOCK); s = (char *) malloc(SWITCH_XML_BUFSIZE); switch_assert(s); h = (char *) malloc(SWITCH_XML_BUFSIZE); switch_assert(h); r = switch_xml_toxml_buf(xml, s, SWITCH_XML_BUFSIZE, 0, prn_header); h = switch_xml_ampencode(r, 0, &h, &rlen, &len, 1); switch_safe_free(r); switch_mutex_unlock(XML_GEN_LOCK); return h; } /* converts a switch_xml structure back to xml, returning a string of xml data that must be freed */ SWITCH_DECLARE(char *) switch_xml_toxml_buf(switch_xml_t xml, char *buf, switch_size_t buflen, switch_size_t offset, switch_bool_t prn_header) { switch_xml_t p = (xml) ? xml->parent : NULL, o = (xml) ? xml->ordered : NULL; switch_xml_root_t root = (switch_xml_root_t) xml; switch_size_t len = 0, max = buflen; char *s, *t, *n, *r; int i, j, k; uint32_t count = 0; s = buf; assert(s != NULL); memset(s, 0, max); len += offset; if (prn_header) { len += sprintf(s + len, "\n"); } if (!xml || !xml->name) { if (!(r = (char *) realloc(s, len + 1))) { abort(); } return r; } while (root->xml.parent) { root = (switch_xml_root_t) root->xml.parent; /* root tag */ } for (i = 0; !p && root->pi[i]; i++) { /* pre-root processing instructions */ for (k = 2; root->pi[i][k - 1]; k++); for (j = 1; (n = root->pi[i][j]); j++) { if (root->pi[i][k][j - 1] == '>') { continue; /* not pre-root */ } while (len + strlen(t = root->pi[i][0]) + strlen(n) + 7 > max) { if (!(r = (char *) realloc(s, max += SWITCH_XML_BUFSIZE))) { abort(); } s = r; } len += sprintf(s + len, "", t, *n ? " " : "", n); } } xml->parent = xml->ordered = NULL; s = switch_xml_toxml_r(xml, &s, &len, &max, 0, root->attr, &count); xml->parent = p; xml->ordered = o; for (i = 0; !p && root->pi[i]; i++) { /* post-root processing instructions */ for (k = 2; root->pi[i][k - 1]; k++); for (j = 1; (n = root->pi[i][j]); j++) { if (root->pi[i][k][j - 1] == '<') { continue; /* not post-root */ } while (len + strlen(t = root->pi[i][0]) + strlen(n) + 7 > max) { if (!(r = (char *) realloc(s, max += SWITCH_XML_BUFSIZE))) { abort(); } s = r; } len += sprintf(s + len, "\n", t, *n ? " " : "", n); } } if (!(r = (char *) realloc(s, len + 1))) { abort(); } return r; } /* free the memory allocated for the switch_xml structure */ SWITCH_DECLARE(void) switch_xml_free(switch_xml_t xml) { switch_xml_root_t root; int i, j; char **a, *s; switch_xml_t orig_xml; int refs = 0; tailrecurse: root = (switch_xml_root_t) xml; if (!xml) { return; } if (switch_test_flag(xml, SWITCH_XML_ROOT)) { switch_mutex_lock(REFLOCK); if (xml->refs) { xml->refs--; refs = xml->refs; } switch_mutex_unlock(REFLOCK); } if (refs) { return; } if (xml->free_path) { if (unlink(xml->free_path) != 0) { switch_log_printf(SWITCH_CHANNEL_LOG, SWITCH_LOG_WARNING, "Failed to delete file [%s]\n", xml->free_path); } switch_safe_free(xml->free_path); } switch_xml_free(xml->child); /*switch_xml_free(xml->ordered); */ if (!xml->parent) { /* free root tag allocations */ #if (_MSC_VER >= 1400) // VC8+ __analysis_assume(sizeof(root->ent) > 44); /* tail recursion confuses code analysis */ #endif for (i = 10; root->ent[i]; i += 2) /* 0 - 9 are default entities (<>&"') */ if ((s = root->ent[i + 1]) < root->s || s > root->e) free(s); free(root->ent); /* free list of general entities */ for (i = 0; (a = root->attr[i]); i++) { for (j = 1; a[j++]; j += 2) /* free malloced attribute values */ if (a[j] && (a[j] < root->s || a[j] > root->e)) free(a[j]); free(a); } if (root->attr[0]) free(root->attr); /* free default attribute list */ for (i = 0; root->pi[i]; i++) { for (j = 1; root->pi[i][j]; j++); free(root->pi[i][j + 1]); free(root->pi[i]); } if (root->pi[0]) free(root->pi); /* free processing instructions */ if (root->dynamic == 1) free(root->m); /* malloced xml data */ if (root->u) free(root->u); /* utf8 conversion */ } switch_xml_free_attr(xml->attr); /* tag attributes */ if ((xml->flags & SWITCH_XML_TXTM)) free(xml->txt); /* character content */ if ((xml->flags & SWITCH_XML_NAMEM)) free(xml->name); /* tag name */ if (xml->ordered) { orig_xml = xml; xml = xml->ordered; free(orig_xml); goto tailrecurse; } free(xml); } /* return parser error message or empty string if none */ SWITCH_DECLARE(const char *) switch_xml_error(switch_xml_t xml) { while (xml && xml->parent) xml = xml->parent; /* find root tag */ return (xml) ? ((switch_xml_root_t) xml)->err : ""; } /* returns a new empty switch_xml structure with the given root tag name */ SWITCH_DECLARE(switch_xml_t) switch_xml_new(const char *name) { static const char *ent[] = { "lt;", "<", "gt;", ">", "quot;", """, "apos;", "'", "amp;", "&", NULL }; switch_xml_root_t root = (switch_xml_root_t) malloc(sizeof(struct switch_xml_root)); if (!root) return NULL; memset(root, '\0', sizeof(struct switch_xml_root)); root->xml.name = (char *) name; root->cur = &root->xml; strcpy(root->err, root->xml.txt = (char *) ""); root->ent = (char **) memcpy(malloc(sizeof(ent)), ent, sizeof(ent)); root->attr = root->pi = (char ***) (root->xml.attr = SWITCH_XML_NIL); root->xml.is_switch_xml_root_t = SWITCH_TRUE; return &root->xml; } /* inserts an existing tag into a switch_xml structure */ SWITCH_DECLARE(switch_xml_t) switch_xml_insert(switch_xml_t xml, switch_xml_t dest, switch_size_t off) { switch_xml_t cur, prev, head; xml->next = xml->sibling = xml->ordered = NULL; xml->off = off; xml->parent = dest; if ((head = dest->child)) { /* already have sub tags */ if (head->off <= off) { /* not first subtag */ for (cur = head; cur->ordered && cur->ordered->off <= off; cur = cur->ordered); xml->ordered = cur->ordered; cur->ordered = xml; } else { /* first subtag */ xml->ordered = head; dest->child = xml; } for (cur = head, prev = NULL; cur && strcmp(cur->name, xml->name); prev = cur, cur = cur->sibling); /* find tag type */ if (cur && cur->off <= off) { /* not first of type */ while (cur->next && cur->next->off <= off) cur = cur->next; xml->next = cur->next; cur->next = xml; } else { /* first tag of this type */ if (prev && cur) prev->sibling = cur->sibling; /* remove old first */ xml->next = cur; /* old first tag is now next */ for (cur = head, prev = NULL; cur && cur->off <= off; prev = cur, cur = cur->sibling); /* new sibling insert point */ xml->sibling = cur; if (prev) prev->sibling = xml; } } else dest->child = xml; /* only sub tag */ return xml; } /* Adds a child tag. off is the offset of the child tag relative to the start of the parent tag's character content. Returns the child tag */ SWITCH_DECLARE(switch_xml_t) switch_xml_add_child(switch_xml_t xml, const char *name, switch_size_t off) { switch_xml_t child; if (!xml) return NULL; if (!(child = (switch_xml_t) malloc(sizeof(struct switch_xml)))) return NULL; memset(child, '\0', sizeof(struct switch_xml)); child->name = (char *) name; child->attr = SWITCH_XML_NIL; child->off = off; child->parent = xml; child->txt = (char *) ""; return switch_xml_insert(child, xml, off); } /* sets the character content for the given tag and returns the tag */ SWITCH_DECLARE(switch_xml_t) switch_xml_set_txt(switch_xml_t xml, const char *txt) { if (!xml) return NULL; if (xml->flags & SWITCH_XML_TXTM) free(xml->txt); /* existing txt was malloced */ xml->flags &= ~SWITCH_XML_TXTM; xml->txt = (char *) txt; return xml; } /* Sets the given tag attribute or adds a new attribute if not found. A value of NULL will remove the specified attribute. Returns the tag given */ SWITCH_DECLARE(switch_xml_t) switch_xml_set_attr(switch_xml_t xml, const char *name, const char *value) { int l = 0, c; if (!xml) return NULL; while (xml->attr[l] && strcmp(xml->attr[l], name)) l += 2; if (!xml->attr[l]) { /* not found, add as new attribute */ if (!value) return xml; /* nothing to do */ if (xml->attr == SWITCH_XML_NIL) { /* first attribute */ xml->attr = (char **) malloc(4 * sizeof(char *)); if (!xml->attr) return NULL; xml->attr[1] = strdup(""); /* empty list of malloced names/vals */ } else { char **tmp = (char **) realloc(xml->attr, (l + 4) * sizeof(char *)); if (!tmp) return xml; xml->attr = tmp; } xml->attr[l] = (char *) name; /* set attribute name */ xml->attr[l + 2] = NULL; /* null terminate attribute list */ xml->attr[l + 3] = (char *) realloc(xml->attr[l + 1], (c = (int) strlen(xml->attr[l + 1])) + 2); strcpy(xml->attr[l + 3] + c, " "); /* set name/value as not malloced */ if (xml->flags & SWITCH_XML_DUP) xml->attr[l + 3][c] = SWITCH_XML_NAMEM; } else if (xml->flags & SWITCH_XML_DUP) free((char *) name); /* name was strduped */ for (c = l; xml->attr[c]; c += 2); /* find end of attribute list */ if (xml->attr[c + 1][l / 2] & SWITCH_XML_TXTM) free(xml->attr[l + 1]); /* old val */ if (xml->flags & SWITCH_XML_DUP) xml->attr[c + 1][l / 2] |= SWITCH_XML_TXTM; else xml->attr[c + 1][l / 2] &= ~SWITCH_XML_TXTM; if (value) xml->attr[l + 1] = (char *) value; /* set attribute value */ else { /* remove attribute */ char **tmp; if (xml->attr[c + 1][l / 2] & SWITCH_XML_NAMEM) free(xml->attr[l]); memmove(xml->attr + l, xml->attr + l + 2, (c - l + 2) * sizeof(char *)); tmp = (char **) realloc(xml->attr, (c + 2) * sizeof(char *)); if (!tmp) return xml; xml->attr = tmp; memmove(xml->attr[c + 1] + (l / 2), xml->attr[c + 1] + (l / 2) + 1, (c / 2) - (l / 2)); /* fix list of which name/vals are malloced */ } xml->flags &= ~SWITCH_XML_DUP; /* clear strdup() flag */ return xml; } /* sets a flag for the given tag and returns the tag */ SWITCH_DECLARE(switch_xml_t) switch_xml_set_flag(switch_xml_t xml, switch_xml_flag_t flag) { if (xml) xml->flags |= flag; return xml; } /* removes a tag along with its subtags without freeing its memory */ SWITCH_DECLARE(switch_xml_t) switch_xml_cut(switch_xml_t xml) { switch_xml_t cur; if (!xml) return NULL; /* nothing to do */ if (xml->next) xml->next->sibling = xml->sibling; /* patch sibling list */ if (xml->parent) { /* not root tag */ cur = xml->parent->child; /* find head of subtag list */ if (cur == xml) xml->parent->child = xml->ordered; /* first subtag */ else { /* not first subtag */ while (cur->ordered != xml) cur = cur->ordered; cur->ordered = cur->ordered->ordered; /* patch ordered list */ cur = xml->parent->child; /* go back to head of subtag list */ if (strcmp(cur->name, xml->name)) { /* not in first sibling list */ while (strcmp(cur->sibling->name, xml->name)) cur = cur->sibling; if (cur->sibling == xml) { /* first of a sibling list */ cur->sibling = (xml->next) ? xml->next : cur->sibling->sibling; } else cur = cur->sibling; /* not first of a sibling list */ } while (cur->next && cur->next != xml) cur = cur->next; if (cur->next) cur->next = cur->next->next; /* patch next list */ } } xml->ordered = xml->sibling = xml->next = NULL; /* prevent switch_xml_free() from clobbering ordered list */ return xml; } SWITCH_DECLARE(int) switch_xml_std_datetime_check(switch_xml_t xcond, int *offset, const char *tzname) { const char *xdt = switch_xml_attr(xcond, "date-time"); const char *xyear = switch_xml_attr(xcond, "year"); const char *xyday = switch_xml_attr(xcond, "yday"); const char *xmon = switch_xml_attr(xcond, "mon"); const char *xmday = switch_xml_attr(xcond, "mday"); const char *xweek = switch_xml_attr(xcond, "week"); const char *xmweek = switch_xml_attr(xcond, "mweek"); const char *xwday = switch_xml_attr(xcond, "wday"); const char *xhour = switch_xml_attr(xcond, "hour"); const char *xminute = switch_xml_attr(xcond, "minute"); const char *xminday = switch_xml_attr(xcond, "minute-of-day"); const char *xtod = switch_xml_attr(xcond, "time-of-day"); const char *tzoff = switch_xml_attr(xcond, "tz-offset"); const char *isdst = switch_xml_attr(xcond, "dst"); int loffset = -1000; int eoffset = -1000; int dst = -1000; switch_time_t ts = switch_micro_time_now(); int time_match = -1; switch_time_exp_t tm, tm2; if (!zstr(isdst)) { dst = switch_true(isdst); } if (!zstr(tzoff) && switch_is_number(tzoff)) { loffset = atoi(tzoff); } switch_time_exp_lt(&tm2, ts); if (offset) { eoffset = *offset; switch_time_exp_tz(&tm, ts, *offset * 3600); } else if (!zstr(tzname)) { switch_time_exp_tz_name(tzname, &tm, ts); } else { tm = tm2; } if (eoffset == -1000) { eoffset = tm.tm_gmtoff / 3600; } if (loffset == -1000) { loffset = eoffset; } if (time_match && tzoff) { time_match = loffset == eoffset; switch_log_printf(SWITCH_CHANNEL_LOG, SWITCH_LOG_DEBUG9, "XML DateTime Check: TZOFFSET[%d] == %d (%s)\n", eoffset, loffset, time_match ? "PASS" : "FAIL"); } if (time_match && dst > -1) { time_match = (tm2.tm_isdst > 0 && dst > 0); switch_log_printf(SWITCH_CHANNEL_LOG, SWITCH_LOG_DEBUG9, "XML DateTime Check: DST[%s] == %s (%s)\n", tm2.tm_isdst > 0 ? "true" : "false", dst > 0 ? "true" : "false", time_match ? "PASS" : "FAIL"); } if (time_match && xdt) { char tmpdate[80]; switch_size_t retsize; switch_strftime(tmpdate, &retsize, sizeof(tmpdate), "%Y-%m-%d %H:%M:%S", &tm); time_match = switch_fulldate_cmp(xdt, &ts); switch_log_printf(SWITCH_CHANNEL_LOG, SWITCH_LOG_DEBUG, "XML DateTime Check: date time[%s] =~ %s (%s)\n", tmpdate, xdt, time_match ? "PASS" : "FAIL"); } if (time_match && xyear) { int test = tm.tm_year + 1900; time_match = switch_number_cmp(xyear, test); switch_log_printf(SWITCH_CHANNEL_LOG, SWITCH_LOG_DEBUG9, "XML DateTime Check: year[%d] =~ %s (%s)\n", test, xyear, time_match ? "PASS" : "FAIL"); } if (time_match && xyday) { int test = tm.tm_yday + 1; time_match = switch_number_cmp(xyday, test); switch_log_printf(SWITCH_CHANNEL_LOG, SWITCH_LOG_DEBUG9, "XML DateTime Check: day of year[%d] =~ %s (%s)\n", test, xyday, time_match ? "PASS" : "FAIL"); } if (time_match && xmon) { int test = tm.tm_mon + 1; time_match = switch_number_cmp(xmon, test); switch_log_printf(SWITCH_CHANNEL_LOG, SWITCH_LOG_DEBUG9, "XML DateTime Check: month[%d] =~ %s (%s)\n", test, xmon, time_match ? "PASS" : "FAIL"); } if (time_match && xmday) { int test = tm.tm_mday; time_match = switch_number_cmp(xmday, test); switch_log_printf(SWITCH_CHANNEL_LOG, SWITCH_LOG_DEBUG9, "XML DateTime Check: day of month[%d] =~ %s (%s)\n", test, xmday, time_match ? "PASS" : "FAIL"); } if (time_match && xweek) { int test = (int) (tm.tm_yday / 7 + 1); time_match = switch_number_cmp(xweek, test); switch_log_printf(SWITCH_CHANNEL_LOG, SWITCH_LOG_DEBUG9, "XML DateTime Check: week of year[%d] =~ %s (%s)\n", test, xweek, time_match ? "PASS" : "FAIL"); } if (time_match && xweek) { int test = (int) (tm.tm_yday / 7 + 1); time_match = switch_number_cmp(xweek, test); switch_log_printf(SWITCH_CHANNEL_LOG, SWITCH_LOG_DEBUG9, "XML DateTime Check: week of year[%d] =~ %s (%s)\n", test, xweek, time_match ? "PASS" : "FAIL"); } if (time_match && xmweek) { /* calculate the day of the week of the first of the month (0-6) */ int firstdow = (int) (7 - (tm.tm_mday - (tm.tm_wday + 1)) % 7) % 7; /* calculate the week of the month (1-6)*/ int test = (int) ceil((tm.tm_mday + firstdow) / 7.0); time_match = switch_number_cmp(xmweek, test); switch_log_printf(SWITCH_CHANNEL_LOG, SWITCH_LOG_DEBUG9, "XML DateTime: week of month[%d] =~ %s (%s)\n", test, xmweek, time_match ? "PASS" : "FAIL"); } if (time_match && xwday) { int test = tm.tm_wday + 1; time_match = switch_dow_cmp(xwday, test); switch_log_printf(SWITCH_CHANNEL_LOG, SWITCH_LOG_DEBUG9, "XML DateTime Check: day of week[%s] =~ %s (%s)\n", switch_dow_int2str(test), xwday, time_match ? "PASS" : "FAIL"); } if (time_match && xhour) { int test = tm.tm_hour; time_match = switch_number_cmp(xhour, test); switch_log_printf(SWITCH_CHANNEL_LOG, SWITCH_LOG_DEBUG9, "XML DateTime Check: hour[%d] =~ %s (%s)\n", test, xhour, time_match ? "PASS" : "FAIL"); } if (time_match && xminute) { int test = tm.tm_min; time_match = switch_number_cmp(xminute, test); switch_log_printf(SWITCH_CHANNEL_LOG, SWITCH_LOG_DEBUG9, "XML DateTime Check: minute[%d] =~ %s (%s)\n", test, xminute, time_match ? "PASS" : "FAIL"); } if (time_match && xminday) { int test = (tm.tm_hour * 60) + (tm.tm_min + 1); time_match = switch_number_cmp(xminday, test); switch_log_printf(SWITCH_CHANNEL_LOG, SWITCH_LOG_DEBUG9, "XML DateTime Check: minute of day[%d] =~ %s (%s)\n", test, xminday, time_match ? "PASS" : "FAIL"); } if (time_match && xtod) { int test = (tm.tm_hour * 60 * 60) + (tm.tm_min * 60) + tm.tm_sec; char tmpdate[10]; switch_snprintf(tmpdate, 10, "%d:%d:%d", tm.tm_hour, tm.tm_min, tm.tm_sec); time_match = switch_tod_cmp(xtod, test); switch_log_printf(SWITCH_CHANNEL_LOG, SWITCH_LOG_DEBUG9, "XML DateTime Check: time of day[%s] =~ %s (%s)\n", tmpdate, xtod, time_match ? "PASS" : "FAIL"); } return time_match; } SWITCH_DECLARE(switch_status_t) switch_xml_locate_language(switch_xml_t *root, switch_xml_t *node, switch_event_t *params, switch_xml_t *language, switch_xml_t *phrases, switch_xml_t *macros, const char *str_language) { switch_status_t status = SWITCH_STATUS_FALSE; if (switch_xml_locate("languages", NULL, NULL, NULL, root, node, params, SWITCH_TRUE) != SWITCH_STATUS_SUCCESS) { switch_xml_t sub_macros; if (switch_xml_locate("phrases", NULL, NULL, NULL, root, node, params, SWITCH_TRUE) != SWITCH_STATUS_SUCCESS) { switch_log_printf(SWITCH_CHANNEL_LOG, SWITCH_LOG_ERROR, "Open of languages and phrases failed.\n"); goto done; } if (!(sub_macros = switch_xml_child(*node, "macros"))) { switch_log_printf(SWITCH_CHANNEL_LOG, SWITCH_LOG_ERROR, "Can't find macros tag.\n"); switch_xml_free(*root); *root = NULL; *node = NULL; goto done; } if (!(*language = switch_xml_find_child(sub_macros, "language", "name", str_language))) { switch_log_printf(SWITCH_CHANNEL_LOG, SWITCH_LOG_ERROR, "Can't find language %s.\n", str_language); switch_xml_free(*root); *root = NULL; *node = NULL; goto done; } *macros = *language; } else { if (!(*language = switch_xml_find_child(*node, "language", "name", str_language))) { switch_log_printf(SWITCH_CHANNEL_LOG, SWITCH_LOG_ERROR, "Can't find language %s.\n", str_language); switch_xml_free(*root); *root = NULL; goto done; } if (!(*phrases = switch_xml_child(*language, "phrases"))) { switch_log_printf(SWITCH_CHANNEL_LOG, SWITCH_LOG_ERROR, "Can't find phrases tag.\n"); switch_xml_free(*root); *root = NULL; *node = NULL; *language = NULL; goto done; } if (!(*macros = switch_xml_child(*phrases, "macros"))) { switch_log_printf(SWITCH_CHANNEL_LOG, SWITCH_LOG_ERROR, "Can't find macros tag.\n"); switch_xml_free(*root); *root = NULL; *node = NULL; *language = NULL; *phrases = NULL; goto done; } } status = SWITCH_STATUS_SUCCESS; done: return status; } #ifdef WIN32 /* * globbing functions for windows, part of libc on unix, this code was cut and paste from * freebsd lib and distilled a bit to work with windows */ /* * Copyright (c) 1989, 1993 * The Regents of the University of California. All rights reserved. * * This code is derived from software contributed to Berkeley by * Guido van Rossum. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions * are met: * 1. Redistributions of source code must retain the above copyright * notice, this list of conditions and the following disclaimer. * 2. Redistributions in binary form must reproduce the above copyright * notice, this list of conditions and the following disclaimer in the * documentation and/or other materials provided with the distribution. * 4. Neither the name of the University nor the names of its contributors * may be used to endorse or promote products derived from this software * without specific prior written permission. * * THIS SOFTWARE IS PROVIDED BY THE REGENTS AND CONTRIBUTORS ``AS IS'' AND * ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE * ARE DISCLAIMED. IN NO EVENT SHALL THE REGENTS OR CONTRIBUTORS BE LIABLE * FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL * DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS * OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) * HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT * LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY * OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF * SUCH DAMAGE. */ #define DOLLAR '$' #define DOT '.' #define EOS '\0' #define LBRACKET '[' #define NOT '!' #define QUESTION '?' #define RANGE '-' #define RBRACKET ']' #define SEP '/' #define WIN_SEP '/' #define STAR '*' #define TILDE '~' #define UNDERSCORE '_' #define LBRACE '{' #define RBRACE '}' #define SLASH '/' #define COMMA ',' #define M_QUOTE (char)0x80 #define M_PROTECT (char)0x40 #define M_MASK (char)0xff #define M_ASCII (char)0x7f #define CHAR(c) ((char)((c)&M_ASCII)) #define META(c) ((char)((c)|M_QUOTE)) #define M_ALL META('*') #define M_END META(']') #define M_NOT META('!') #define M_ONE META('?') #define M_RNG META('-') #define M_SET META('[') #define ismeta(c) (((c)&M_QUOTE) != 0) #ifndef MAXPATHLEN #define MAXPATHLEN 256 #endif static int compare(const void *, const void *); static int glob0(const char *, glob_t *, size_t *); static int glob1(char *, glob_t *, size_t *); static int glob2(char *, char *, char *, char *, glob_t *, size_t *); static int glob3(char *, char *, char *, char *, char *, glob_t *, size_t *); static int globextend(const char *, glob_t *, size_t *); static int match(char *, char *, char *); #pragma warning(push) #pragma warning(disable:4310) int glob(const char *pattern, int flags, int (*errfunc) (const char *, int), glob_t *pglob) { const unsigned char *patnext; size_t limit; char c; char *bufnext, *bufend, patbuf[MAXPATHLEN]; patnext = (unsigned char *) pattern; if (!(flags & GLOB_APPEND)) { pglob->gl_pathc = 0; pglob->gl_pathv = NULL; if (!(flags & GLOB_DOOFFS)) pglob->gl_offs = 0; } if (flags & GLOB_LIMIT) { limit = pglob->gl_matchc; if (limit == 0) limit = 9999999; } else limit = 0; pglob->gl_flags = flags & ~GLOB_MAGCHAR; pglob->gl_errfunc = errfunc; pglob->gl_matchc = 0; bufnext = patbuf; bufend = bufnext + MAXPATHLEN - 1; while (bufnext < bufend && (c = *patnext++) != EOS) *bufnext++ = c; *bufnext = EOS; return glob0(patbuf, pglob, &limit); } /* * The main glob() routine: compiles the pattern (optionally processing * quotes), calls glob1() to do the real pattern matching, and finally * sorts the list (unless unsorted operation is requested). Returns 0 * if things went well, nonzero if errors occurred. */ static int glob0(const char *pattern, glob_t *pglob, size_t *limit) { const char *qpatnext; int c, err; size_t oldpathc; char *bufnext, patbuf[MAXPATHLEN]; qpatnext = pattern; oldpathc = pglob->gl_pathc; bufnext = patbuf; /* We don't need to check for buffer overflow any more. */ while ((c = *qpatnext++) != EOS) { switch (c) { case SEP: *bufnext++ = WIN_SEP; break; case LBRACKET: c = *qpatnext; if (c == NOT) ++qpatnext; if (*qpatnext == EOS || strchr((char *) qpatnext + 1, RBRACKET) == NULL) { *bufnext++ = LBRACKET; if (c == NOT) --qpatnext; break; } *bufnext++ = M_SET; if (c == NOT) *bufnext++ = M_NOT; c = *qpatnext++; do { *bufnext++ = CHAR(c); if (*qpatnext == RANGE && (c = qpatnext[1]) != RBRACKET) { *bufnext++ = M_RNG; *bufnext++ = CHAR(c); qpatnext += 2; } } while ((c = *qpatnext++) != RBRACKET); pglob->gl_flags |= GLOB_MAGCHAR; *bufnext++ = M_END; break; case QUESTION: pglob->gl_flags |= GLOB_MAGCHAR; *bufnext++ = M_ONE; break; case STAR: pglob->gl_flags |= GLOB_MAGCHAR; /* collapse adjacent stars to one, * to avoid exponential behavior */ if (bufnext == patbuf || bufnext[-1] != M_ALL) *bufnext++ = M_ALL; break; default: *bufnext++ = CHAR(c); break; } } *bufnext = EOS; if ((err = glob1(patbuf, pglob, limit)) != 0) return (err); /* * If there was no match we are going to append the pattern * if GLOB_NOCHECK was specified or if GLOB_NOMAGIC was specified * and the pattern did not contain any magic characters * GLOB_NOMAGIC is there just for compatibility with csh. */ if (pglob->gl_pathc == oldpathc) { if (((pglob->gl_flags & GLOB_NOCHECK) || ((pglob->gl_flags & GLOB_NOMAGIC) && !(pglob->gl_flags & GLOB_MAGCHAR)))) return (globextend(pattern, pglob, limit)); else return (GLOB_NOMATCH); } if (!(pglob->gl_flags & GLOB_NOSORT)) qsort(pglob->gl_pathv + pglob->gl_offs + oldpathc, pglob->gl_pathc - oldpathc, sizeof(char *), compare); return (0); } static int compare(const void *p, const void *q) { return (strcmp(*(char **) p, *(char **) q)); } static int glob1(char *pattern, glob_t *pglob, size_t *limit) { char pathbuf[MAXPATHLEN]; /* A null pathname is invalid -- POSIX 1003.1 sect. 2.4. */ if (*pattern == EOS) return (0); return (glob2(pathbuf, pathbuf, pathbuf + MAXPATHLEN - 1, pattern, pglob, limit)); } /* * The functions glob2 and glob3 are mutually recursive; there is one level * of recursion for each segment in the pattern that contains one or more * meta characters. */ static int glob2(char *pathbuf, char *pathend, char *pathend_last, char *pattern, glob_t *pglob, size_t *limit) { struct stat sb; char *p, *q; int anymeta; /* * Loop over pattern segments until end of pattern or until * segment with meta character found. */ for (anymeta = 0;;) { if (*pattern == EOS) { /* End of pattern? */ *pathend = EOS; if (stat(pathbuf, &sb)) return (0); if (((pglob->gl_flags & GLOB_MARK) && pathend[-1] != SEP && pathend[-1] != WIN_SEP) && (_S_IFDIR & sb.st_mode)) { if (pathend + 1 > pathend_last) return (GLOB_ABORTED); *pathend++ = WIN_SEP; *pathend = EOS; } ++pglob->gl_matchc; return (globextend(pathbuf, pglob, limit)); } /* Find end of next segment, copy tentatively to pathend. */ q = pathend; p = pattern; while (*p != EOS && *p != SEP && *p != WIN_SEP) { if (ismeta(*p)) anymeta = 1; if (q + 1 > pathend_last) return (GLOB_ABORTED); *q++ = *p++; } if (!anymeta) { /* No expansion, do next segment. */ pathend = q; pattern = p; while (*pattern == SEP || *pattern == WIN_SEP) { if (pathend + 1 > pathend_last) return (GLOB_ABORTED); *pathend++ = *pattern++; } } else /* Need expansion, recurse. */ return (glob3(pathbuf, pathend, pathend_last, pattern, p, pglob, limit)); } /* NOTREACHED */ } static int glob3(char *pathbuf, char *pathend, char *pathend_last, char *pattern, char *restpattern, glob_t *pglob, size_t *limit) { int err; apr_dir_t *dirp; apr_pool_t *pool; apr_pool_create(&pool, NULL); if (pathend > pathend_last) return (GLOB_ABORTED); *pathend = EOS; errno = 0; if (apr_dir_open(&dirp, pathbuf, pool) != APR_SUCCESS) { /* TODO: don't call for ENOENT or ENOTDIR? */ apr_pool_destroy(pool); if (pglob->gl_errfunc) { if (pglob->gl_errfunc(pathbuf, errno) || pglob->gl_flags & GLOB_ERR) return (GLOB_ABORTED); } return (0); } err = 0; /* Search directory for matching names. */ while (dirp) { apr_finfo_t dp; unsigned char *sc; char *dc; if (apr_dir_read(&dp, APR_FINFO_NAME, dirp) != APR_SUCCESS) break; if (!(dp.valid & APR_FINFO_NAME) || !(dp.name) || !strlen(dp.name)) break; /* Initial DOT must be matched literally. */ if (dp.name[0] == DOT && *pattern != DOT) continue; dc = pathend; sc = (unsigned char *) dp.name; while (dc < pathend_last && (*dc++ = *sc++) != EOS); if (!match(pathend, pattern, restpattern)) { *pathend = EOS; continue; } err = glob2(pathbuf, --dc, pathend_last, restpattern, pglob, limit); if (err) break; } if (dirp) apr_dir_close(dirp); apr_pool_destroy(pool); return (err); } /* * Extend the gl_pathv member of a glob_t structure to accommodate a new item, * add the new item, and update gl_pathc. * * This assumes the BSD realloc, which only copies the block when its size * crosses a power-of-two boundary; for v7 realloc, this would cause quadratic * behavior. * * Return 0 if new item added, error code if memory couldn't be allocated. * * Invariant of the glob_t structure: * Either gl_pathc is zero and gl_pathv is NULL; or gl_pathc > 0 and * gl_pathv points to (gl_offs + gl_pathc + 1) items. */ static int globextend(const char *path, glob_t *pglob, size_t *limit) { char **pathv; char *copy; size_t i; size_t newsize, len; const char *p; if (*limit && pglob->gl_pathc > *limit) { errno = 0; return (GLOB_NOSPACE); } newsize = sizeof(*pathv) * (2 + pglob->gl_pathc + pglob->gl_offs); pathv = pglob->gl_pathv ? realloc((char *) pglob->gl_pathv, newsize) : malloc(newsize); if (pathv == NULL) { if (pglob->gl_pathv) { free(pglob->gl_pathv); pglob->gl_pathv = NULL; } return (GLOB_NOSPACE); } if (pglob->gl_pathv == NULL && pglob->gl_offs > 0) { /* first time around -- clear initial gl_offs items */ pathv += pglob->gl_offs; for (i = pglob->gl_offs; i-- > 0;) *--pathv = NULL; } pglob->gl_pathv = pathv; for (p = path; *p++;) continue; len = (size_t) (p - path); if ((copy = malloc(len)) != NULL) { memcpy(copy, path, len); pathv[pglob->gl_offs + pglob->gl_pathc++] = copy; } pathv[pglob->gl_offs + pglob->gl_pathc] = NULL; return (copy == NULL ? GLOB_NOSPACE : 0); } /* * pattern matching function for filenames. Each occurrence of the * * pattern causes a recursion level. */ static int match(char *name, char *pat, char *patend) { int ok, negate_range; char c, k; char s1[6]; while (pat < patend) { c = *pat++; switch (c & M_MASK) { case M_ALL: if (pat == patend) return (1); do if (match(name, pat, patend)) return (1); while (*name++ != EOS); return (0); case M_ONE: if (*name++ == EOS) return (0); break; case M_SET: ok = 0; if ((k = *name++) == EOS) return (0); if ((negate_range = ((*pat & M_MASK) == M_NOT)) != EOS) ++pat; while (((c = *pat++) & M_MASK) != M_END) if ((*pat & M_MASK) == M_RNG) { memset(s1, 0, sizeof(s1)); s1[0] = c; s1[2] = k; s1[4] = pat[1]; if (strcoll(&s1[0], &s1[2]) <= 0 && strcoll(&s1[2], &s1[4]) <= 0) ok = 1; pat += 2; } else if (c == k) ok = 1; if (ok == negate_range) return (0); break; default: if (*name++ != c) return (0); break; } } return (*name == EOS); } /* Free allocated data belonging to a glob_t structure. */ void globfree(glob_t *pglob) { size_t i; char **pp; if (pglob->gl_pathv != NULL) { pp = pglob->gl_pathv + pglob->gl_offs; for (i = pglob->gl_pathc; i--; ++pp) if (*pp) free(*pp); free(pglob->gl_pathv); pglob->gl_pathv = NULL; } } #pragma warning(pop) #endif /* For Emacs: * Local Variables: * mode:c * indent-tabs-mode:t * tab-width:4 * c-basic-offset:4 * End: * For VIM: * vim:set softtabstop=4 shiftwidth=4 tabstop=4 noet: */