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freeswitch/src/switch_xml.c

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/*
* FreeSWITCH Modular Media Switching Software Library / Soft-Switch Application
* Copyright (C) 2005/2006, Anthony Minessale II <anthmct@yahoo.com>
*
* 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 <anthmct@yahoo.com>
* Portions created by the Initial Developer are Copyright (C)
* the Initial Developer. All Rights Reserved.
*
* Contributor(s):
*
* Anthony Minessale II <anthmct@yahoo.com>
*
*
* switch_xml.c -- XML PARSER
*
* Derived from ezxml http://ezxml.sourceforge.net
* Original Copyright
*
* Copyright 2004, 2006 Aaron Voisine <aaron@voisine.org>
*
* 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 <switch.h>
#ifndef WIN32
#include <switch_private.h>
#endif
#undef HAVE_MMAP
#ifdef HAVE_MMAP
#include <sys/mman.h>
#ifdef __sun
extern int madvise(caddr_t, size_t, int);
#endif
#endif
#define SWITCH_XML_WS "\t\r\n " // whitespace
#define SWITCH_XML_ERRL 128 // maximum error string length
static int preprocess(const char *file, int 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 for mmap
uint8_t dynamic;
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 <?xml standalone="yes"?>
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;
};
typedef struct switch_xml_binding switch_xml_binding_t;
static switch_xml_binding_t *BINDINGS = NULL;
static switch_xml_t MAIN_XML_ROOT = NULL;
static switch_memory_pool_t *XML_MEMORY_POOL;
static switch_mutex_t *XML_LOCK;
static switch_thread_rwlock_t *RWLOCK;
static uint32_t lock_count = 0;
struct xml_section_t {
const char *name;
switch_xml_section_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},
{"phrases", SWITCH_XML_SECTION_PHRASES},
{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;
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 sections;
}
SWITCH_DECLARE(switch_status_t) switch_xml_bind_search_function(switch_xml_search_function_t function, switch_xml_section_t sections, void *user_data)
{
switch_xml_binding_t *binding = NULL, *ptr = NULL;
assert(function != NULL);
if (!(binding = switch_core_alloc(XML_MEMORY_POOL, sizeof(*binding)))) {
return SWITCH_STATUS_MEMERR;
}
binding->function = function;
binding->sections = sections;
binding->user_data = user_data;
switch_mutex_lock(XML_LOCK);
for (ptr = BINDINGS; ptr && ptr->next; ptr = ptr->next);
if (ptr) {
ptr->next = binding;
} else {
BINDINGS = binding;
}
switch_mutex_unlock(XML_LOCK);
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;
}
// 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] && 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
for (i = 0; root->attr[i] && strcmp(xml->name, root->attr[i][0]); i++);
if (!root->attr[i])
return NULL; // no matching default attributes
while (root->attr[i][j] && 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
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];
for (t = root->s; t && t < s; t++)
if (*t == '\n')
line++;
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((int) (*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
r = (r == m) ? strcpy(malloc(l), r) : realloc(r, l);
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 = 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 = root->cur;
char *m = s;
switch_size_t l;
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
xml->txt = (xml->flags & SWITCH_XML_TXTM) // allocate some space
? realloc(xml->txt, (l = strlen(xml->txt)) + len)
: strcpy(malloc((l = strlen(xml->txt)) + len), xml->txt);
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->cur || !root->cur->name || strcmp(name, root->cur->name))
return switch_xml_err(root, s, "unexpected closing tag </%s>", 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;
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 (!strcmp(target, "xml")) { // <?xml ... ?>
if ((s = strstr(s, "standalone")) && !strncmp(s + strspn(s + 10, SWITCH_XML_WS "='\"") + 10, "yes", 3))
root->standalone = 1;
return;
}
if (!root->pi[0])
*(root->pi = malloc(sizeof(char **))) = NULL; //first pi
while (root->pi[i] && strcmp(target, root->pi[i][0]))
i++; // find target
if (!root->pi[i]) { // new target
root->pi = realloc(root->pi, sizeof(char **) * (i + 2));
root->pi[i] = malloc(sizeof(char *) * 3);
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
root->pi[i] = realloc(root->pi[i], sizeof(char *) * (j + 3));
root->pi[i][j + 2] = realloc(root->pi[i][j + 1], j + 1);
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;
pe = 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, "<!ENTITY", 8)) { // parse entity definitions
c = s += strspn(s + 8, SWITCH_XML_WS) + 8; // skip white space separator
n = s + strspn(s, SWITCH_XML_WS "%"); // find name
*(s = n + strcspn(n, SWITCH_XML_WS)) = ';'; // append ; to name
v = s + strspn(s + 1, SWITCH_XML_WS) + 1; // find value
if ((q = *(v++)) != '"' && q != '\'') { // skip externals
s = strchr(s, '>');
continue;
}
for (i = 0, ent = (*c == '%') ? pe : root->ent; ent[i]; i++);
ent = realloc(ent, (i + 3) * sizeof(char *)); // space for next ent
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, "<!ATTLIST", 9)) { // parse default attributes
t = s + strspn(s + 9, SWITCH_XML_WS) + 9; // skip whitespace separator
if (!*t) {
switch_xml_err(root, t, "unclosed <!ATTLIST");
break;
}
if (*(s = t + strcspn(t, SWITCH_XML_WS ">")) == '>')
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 != '>') {
if (*(s = n + strcspn(n, SWITCH_XML_WS)))
*s = '\0'; // attr name
else {
switch_xml_err(root, t, "malformed <!ATTLIST");
break;
}
s += strspn(s + 1, SWITCH_XML_WS) + 1; // find next token
c = (strncmp(s, "CDATA", 5)) ? "*" : " "; // is it cdata?
if (!strncmp(s, "NOTATION", 8))
s += strspn(s + 8, SWITCH_XML_WS) + 8;
s = (*s == '(') ? strchr(s, ')') : s + strcspn(s, SWITCH_XML_WS);
if (!s) {
switch_xml_err(root, t, "malformed <!ATTLIST");
break;
}
s += strspn(s, SWITCH_XML_WS ")"); // skip white space separator
if (!strncmp(s, "#FIXED", 6))
s += strspn(s + 6, SWITCH_XML_WS) + 6;
if (*s == '#') { // no default value
s += strcspn(s, SWITCH_XML_WS ">") - 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 <!ATTLIST");
break;
}
if (!root->attr[i]) { // new tag name
root->attr = (!i) ? malloc(2 * sizeof(char **))
: realloc(root->attr, (i + 2) * sizeof(char **));
root->attr[i] = 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
root->attr[i] = realloc(root->attr[i], (j + 4) * sizeof(char *));
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, "<!--", 4))
s = strstr(s + 4, "-->"); // comments
else if (!strncmp(s, "<?", 2)) { // processing instructions
if ((s = strstr(c = s + 2, "?>")))
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 = 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)
u = realloc(u, max += SWITCH_XML_BUFSIZE);
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 = 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);
}
// parse the given xml string and return an 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) ? realloc(attr, (l + 4) * sizeof(char *))
: malloc(4 * sizeof(char *)); // allocate space
attr[l + 3] = (l) ? realloc(attr[l + 1], (l / 2) + 2)
: 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] = ""; // 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 <!--");
} else if (!strncmp(s, "![CDATA[", 8)) { // cdata
if ((s = strstr(s, "]]>")))
switch_xml_char_content(root, d + 8, (s += 2) - d - 10, 'c');
else
return switch_xml_err(root, d, "unclosed <![CDATA[");
} else if (!strncmp(s, "!DOCTYPE", 8)) { // dtd
for (l = 0; *s && ((!l && *s != '>') || (l && (*s != ']' || *(s + strspn(s + 1, SWITCH_XML_WS) + 1) != '>'))); l = (*s == '[') ? 1 : l)
s += strcspn(s + 1, "[]>") + 1;
if (!*s && e != '>')
return switch_xml_err(root, d, "unclosed <!DOCTYPE");
d = (l) ? strchr(d, '[') + 1 : d;
if (l && !switch_xml_internal_dtd(root, d, s++ - d))
return &root->xml;
} else if (*s == '?') { // <?...?> processing instructions
do {
s = strchr(s, '?');
} while (s && *(++s) && *s != '>');
if (!s || (!*s && e != '>'))
return switch_xml_err(root, d, "unclosed <?");
else
switch_xml_proc_inst(root, d + 1, s - d - 2);
} else
return switch_xml_err(root, d, "unexpected <");
if (!s || !*s)
break;
*s = '\0';
d = ++s;
if (*s && *s != '<') { // tag character content
while (*s && *s != '<')
s++;
if (*s)
switch_xml_char_content(root, d, s - d, '&');
else
break;
} else if (!*s)
break;
}
if (!root->cur)
return &root->xml;
else if (!root->cur->name)
return switch_xml_err(root, d, "root tag missing");
else
return switch_xml_err(root, d, "unclosed tag <%s>", root->cur->name);
}
// Wrapper for switch_xml_parse_str() that accepts a file stream. Reads the entire
// stream into memory and then parses it. For xml files, use switch_xml_parse_file()
// or switch_xml_parse_fd()
SWITCH_DECLARE(switch_xml_t) switch_xml_parse_fp(FILE * fp)
{
switch_xml_root_t root;
switch_size_t l, len = 0;
char *s;
if (!(s = malloc(SWITCH_XML_BUFSIZE)))
return NULL;
do {
len += (l = fread((s + len), 1, SWITCH_XML_BUFSIZE, fp));
if (l == SWITCH_XML_BUFSIZE)
s = realloc(s, len + SWITCH_XML_BUFSIZE);
} while (s && l == SWITCH_XML_BUFSIZE);
if (!s)
return NULL;
root = (switch_xml_root_t) switch_xml_parse_str(s, len);
root->dynamic = 1; // so we know to free s in switch_xml_free()
return &root->xml;
}
// A wrapper for switch_xml_parse_str() that accepts a file descriptor. First
// attempts to mem map the file. Failing that, reads the file into memory.
// Returns NULL on failure.
SWITCH_DECLARE(switch_xml_t) switch_xml_parse_fd(int fd)
{
switch_xml_root_t root;
struct stat st;
switch_size_t l;
void *m;
if (fd < 0)
return NULL;
fstat(fd, &st);
#ifdef HAVE_MMAP
l = (st.st_size + sysconf(_SC_PAGESIZE) - 1) & ~(sysconf(_SC_PAGESIZE) - 1);
if ((m = mmap(NULL, l, PROT_READ | PROT_WRITE, MAP_PRIVATE, fd, 0)) != MAP_FAILED) {
madvise(m, l, MADV_SEQUENTIAL); // optimize for sequential access
root = (switch_xml_root_t) switch_xml_parse_str(m, st.st_size);
madvise(m, root->len = l, MADV_NORMAL); // put it back to normal
} else { // mmap failed, read file into memory
#endif // HAVE_MMAP
l = read(fd, m = malloc(st.st_size), st.st_size);
root = (switch_xml_root_t) switch_xml_parse_str(m, l);
root->dynamic = 1; // so we know to free s in switch_xml_free()
#ifdef HAVE_MMAP
}
#endif // HAVE_MMAP
return &root->xml;
}
static switch_size_t read_line(int fd, char *buf, switch_size_t len)
{
char c, *p;
int cur;
switch_size_t total = 0;
p = buf;
while (total + sizeof(c) < len && (cur = read(fd, &c, sizeof(c))) > 0) {
total += cur;
*p++ = c;
if (c == '\n') {
break;
}
}
*p++ = '\0';
return total;
}
static char *expand_vars(char *buf, char *ebuf, switch_size_t elen, switch_size_t *newlen)
{
char *var, *val;
char *rp = buf;
char *wp = ebuf;
char *ep = ebuf + elen - 1;
if (!(var = strstr(rp, "$${"))) {
*newlen = strlen(buf);
return buf;
}
while (*rp && wp < ep) {
if (*rp == '$' && *(rp + 1) == '$' && *(rp + 2) == '{') {
char *e = strchr(rp, '}');
if (e) {
rp += 3;
var = rp;
*e++ = '\0';
rp = e;
if ((val = switch_core_get_variable(var))) {
char *p;
for (p = val; p && *p && wp <= ep; p++) {
*wp++ = *p;
}
}
}
}
*wp++ = *rp++;
}
*wp++ = '\0';
*newlen = strlen(ebuf);
return ebuf;
}
/* for apr file and directory handling */
#include <apr_file_io.h>
static int preprocess_glob(const char *pattern, int write_fd, int rlevel)
{
switch_array_header_t *result;
switch_memory_pool_t *pool;
char **list;
int i;
char *p, *dir_path = NULL;
switch_core_new_memory_pool(&pool);
assert(pool != NULL);
if (switch_is_file_path(pattern)) {
dir_path = switch_core_strdup(pool, pattern);
if ((p = strrchr(dir_path, *SWITCH_PATH_SEPARATOR))) {
*p = '\0';
}
} else {
p = switch_core_sprintf(pool, "%s%s%s", SWITCH_GLOBAL_dirs.conf_dir, SWITCH_PATH_SEPARATOR, pattern);
pattern = p;
dir_path = switch_core_strdup(pool, pattern);
if ((p = strrchr(dir_path, *SWITCH_PATH_SEPARATOR))) {
*p = '\0';
}
}
switch_match_glob(pattern, &result, pool);
list = (char **)result->elts;
for (i = 0; i < result->nelts; i++) {
char *path = list[i];
if (strcmp(path, ".") && strcmp(path, "..")) {
p = switch_core_sprintf(pool, "%s%s%s", dir_path, SWITCH_PATH_SEPARATOR, path);
if (preprocess(p, write_fd, rlevel) < 0) {
const char *reason = strerror(errno);
if (rlevel > 100) {
reason = "Maximum recursion limit reached";
}
fprintf(stderr, "Error including %s (%s)\n", p, reason);
}
}
}
switch_core_destroy_memory_pool(&pool);
return write_fd;
}
static int preprocess(const char *file, int write_fd, int rlevel)
{
int read_fd = -1;
switch_size_t cur = 0, ml = 0;
char *q, *cmd, buf[2048], ebuf[8192];
if ((read_fd = open(file, O_RDONLY, 0)) < 0) {
return read_fd;
}
if (rlevel > 100) {
return -1;
}
while ((cur = read_line(read_fd, buf, sizeof(buf))) > 0) {
char *arg, *e;
char *bp = expand_vars(buf, ebuf, sizeof(ebuf), &cur);
/* we ignore <include> or </include> for the sake of validators as well as <?xml version="1.0"?> type stuff */
if (strstr(buf, "<include>") || strstr(buf, "</include>") || strstr(buf, "<?")) {
continue;
}
if (ml) {
if ((e = strstr(buf, "-->"))) {
ml = 0;
bp = e + 3;
cur = strlen(bp);
} else {
continue;
}
}
if ((cmd = strstr(bp, "<!--#"))) {
if(write(write_fd, bp, (unsigned) (cmd - bp)) != (cmd - bp)) {
switch_log_printf(SWITCH_CHANNEL_LOG, SWITCH_LOG_ERROR, "Short write!\n");
}
if ((e = strstr(cmd, "-->"))) {
*e = '\0';
e += 3;
if(write(write_fd, e, (unsigned) strlen(e)) != (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, "include")) {
preprocess_glob(arg, write_fd, rlevel + 1);
}
}
continue;
}
if(write(write_fd, bp, (unsigned) cur) != (int) cur) {
switch_log_printf(SWITCH_CHANNEL_LOG, SWITCH_LOG_ERROR, "Short write!\n");
}
}
close(read_fd);
return write_fd;
}
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);
l = read(fd, m = malloc(st.st_size), st.st_size);
root = (switch_xml_root_t) switch_xml_parse_str(m, l);
root->dynamic = 1;
close(fd);
return &root->xml;
}
return NULL;
}
SWITCH_DECLARE(switch_xml_t) switch_xml_parse_file(const char *file)
{
int fd = -1, write_fd = -1;
switch_xml_t xml = NULL;
char *new_file = NULL;
const char *abs;
if ((abs = strrchr(file, '/')) || (abs = strrchr(file, '\\'))) {
abs++;
} else {
abs = file;
}
if (!(new_file = switch_mprintf("%s%s%s.fsxml", SWITCH_GLOBAL_dirs.log_dir, SWITCH_PATH_SEPARATOR, abs))) {
return NULL;
}
if ((write_fd = open(new_file, O_WRONLY | O_CREAT | O_TRUNC, S_IRUSR | S_IWUSR)) < 0) {
goto done;
}
if (preprocess(file, write_fd, 0) > -1) {
close(write_fd);
write_fd = -1;
if ((fd = open(new_file, O_RDONLY, 0)) > -1) {
if ((xml = switch_xml_parse_fd(fd))) {
xml->free_path = new_file;
new_file = NULL;
}
close(fd);
fd = -1;
}
}
done:
if (write_fd > -1) {
close(write_fd);
}
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,
const char *params)
{
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_mutex_lock(XML_LOCK);
for (binding = BINDINGS; binding; binding = binding->next) {
switch_xml_section_t sections = switch_xml_parse_section_string(section);
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 (switch_strlen_zero(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_mutex_unlock(XML_LOCK);
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))) {
*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, char *params, switch_xml_t *root, switch_xml_t *domain)
{
char my_params[512];
*domain = NULL;
if (!params) {
snprintf(my_params, sizeof(my_params), "domain=%s", domain_name);
params = my_params;
}
return switch_xml_locate("directory", "domain", "name", domain_name, root, domain, params);
}
SWITCH_DECLARE(switch_status_t) switch_xml_locate_user(const char *user_name,
const char *domain_name,
const char *ip,
switch_xml_t *root,
switch_xml_t *domain,
switch_xml_t *user,
const char *xtra_params)
{
char params[1024] = "";
switch_status_t status;
*root = NULL;
*user = NULL;
*domain = NULL;
if (!switch_strlen_zero(xtra_params)) {
snprintf(params, sizeof(params), "user=%s&domain=%s&ip=%s&%s",
switch_str_nil(user_name), switch_str_nil(domain_name), switch_str_nil(ip), xtra_params);
} else {
snprintf(params, sizeof(params), "user=%s&domain=%s&ip=%s",
switch_str_nil(user_name), switch_str_nil(domain_name), switch_str_nil(ip));
}
if ((status = switch_xml_locate_domain(domain_name, params, root, domain)) != SWITCH_STATUS_SUCCESS) {
return status;
}
if (ip) {
if ((*user = switch_xml_find_child(*domain, "user", "ip", ip))) {
return SWITCH_STATUS_SUCCESS;
}
}
if (user_name) {
if (!(*user = switch_xml_find_child(*domain, "user", "id", user_name)) && strstr(xtra_params, "mailbox") &&
!(*user = switch_xml_find_child(*domain, "user", "mailbox", user_name))) {
return SWITCH_STATUS_FALSE;
}
return SWITCH_STATUS_SUCCESS;
}
return SWITCH_STATUS_FALSE;
}
SWITCH_DECLARE(switch_xml_t) switch_xml_root(void)
{
lock_count++;
switch_thread_rwlock_rdlock(RWLOCK);
return MAIN_XML_ROOT;
}
static char not_so_threadsafe_error_buffer[256] = "";
SWITCH_DECLARE(switch_xml_t) switch_xml_open_root(uint8_t reload, const char **err)
{
char path_buf[1024];
uint8_t hasmain = 0, errcnt = 0;
switch_xml_t new_main;
switch_mutex_lock(XML_LOCK);
if (MAIN_XML_ROOT) {
hasmain++;
if (!reload) {
switch_mutex_unlock(XML_LOCK);
return switch_xml_root();
}
switch_thread_rwlock_wrlock(RWLOCK);
}
snprintf(path_buf, sizeof(path_buf), "%s%s%s", SWITCH_GLOBAL_dirs.conf_dir, SWITCH_PATH_SEPARATOR, "freeswitch.xml");
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 (!switch_strlen_zero(*err)) {
switch_xml_free(new_main);
new_main = NULL;
errcnt++;
} else {
switch_xml_t old_root;
*err = "Success";
old_root = MAIN_XML_ROOT;
MAIN_XML_ROOT = new_main;
switch_set_flag(MAIN_XML_ROOT, SWITCH_XML_ROOT);
switch_xml_free(old_root);
}
} else {
*err = "Cannot Open log directory or XML Root!";
errcnt++;
}
if (hasmain) {
switch_thread_rwlock_unlock(RWLOCK);
}
switch_mutex_unlock(XML_LOCK);
return errcnt == 0 ? switch_xml_root() : NULL;
}
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(&XML_LOCK, SWITCH_MUTEX_NESTED, XML_MEMORY_POOL);
switch_thread_rwlock_create(&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)
{
if (MAIN_XML_ROOT) {
switch_xml_t xml = MAIN_XML_ROOT;
MAIN_XML_ROOT = NULL;
switch_xml_free(xml);
return SWITCH_STATUS_SUCCESS;
}
return SWITCH_STATUS_FALSE;
}
SWITCH_DECLARE(switch_xml_t) switch_xml_open_cfg(const char *file_path, switch_xml_t * node, const char *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_STATUS_SUCCESS) {
*node = cfg;
}
return xml;
}
// Encodes ampersand sequences appending the results to *dst, reallocating *dst
// if length excedes 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;
if (len) {
e = s + len;
}
while (s != e) {
while (*dlen + 10 > *max)
*dst = realloc(*dst, *max += SWITCH_XML_BUFSIZE);
switch (*s) {
case '\0':
return *dst;
case '&':
*dlen += sprintf(*dst + *dlen, "&amp;");
break;
case '<':
*dlen += sprintf(*dst + *dlen, "&lt;");
break;
case '>':
*dlen += sprintf(*dst + *dlen, "&gt;");
break;
case '"':
*dlen += sprintf(*dst + *dlen, (a) ? "&quot;" : "\"");
break;
case '\n':
*dlen += sprintf(*dst + *dlen, (a) ? "&#xA;" : "\n");
break;
case '\t':
*dlen += sprintf(*dst + *dlen, (a) ? "&#x9;" : "\t");
break;
case '\r':
*dlen += sprintf(*dst + *dlen, "&#xD;");
break;
default:
(*dst)[(*dlen)++] = *s;
}
s++;
}
return *dst;
}
#define XML_INDENT " "
// Recursively converts each tag to xml appending it to *s. Reallocates *s if
// its length excedes 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 = (xml->parent) ? xml->parent->txt : "";
switch_size_t off = 0;
uint32_t lcount = 0;
// 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
*s = realloc(*s, *max += SWITCH_XML_BUFSIZE);
if (*(*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
*s = realloc(*s, *max += SWITCH_XML_BUFSIZE);
*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
*s = realloc(*s, *max += SWITCH_XML_BUFSIZE);
*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
*s = realloc(*s, *max += SWITCH_XML_BUFSIZE);
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), "</%s>\n", xml->name); // close tag
}
while (txt[off] && off < xml->off)
off++; // make sure off is within bounds
if (xml->ordered) {
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(switch_xml_t xml)
{
char *s;
s = malloc(SWITCH_XML_BUFSIZE);
return switch_xml_toxml_buf(xml, s, SWITCH_XML_BUFSIZE, 0);
}
// converts an switch_xml structure back to xml, returning a string of xml date 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_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;
len += sprintf(s + len, "<?xml version=\"1.0\"?>\n");
if (!xml || !xml->name) {
if (!(r = 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 = realloc(s, max += SWITCH_XML_BUFSIZE))) {
abort();
}
s = r;
}
len += sprintf(s + len, "<?%s%s%s?>", 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 = realloc(s, max += SWITCH_XML_BUFSIZE))) {
abort();
}
s = r;
}
len += sprintf(s + len, "\n<?%s%s%s?>", t, *n ? " " : "", n);
}
}
if (!(r = 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 = (switch_xml_root_t) xml;
int i, j;
char **a, *s;
if (!xml)
return;
if (switch_test_flag(xml, SWITCH_XML_ROOT)) {
if (lock_count > 0) {
switch_thread_rwlock_unlock(RWLOCK);
lock_count--;
}
}
if (xml == MAIN_XML_ROOT) {
return;
}
if (xml->free_path) {
unlink(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
for (i = 10; root->ent[i]; i += 2) // 0 - 9 are default entites (<>&"')
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
#ifdef HAVE_MMAP
else if (root->len)
munmap(root->m, root->len); // mem mapped xml data
#endif // HAVE_MMAP
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
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 char *ent[] = { "lt;", "&#60;", "gt;", "&#62;", "quot;", "&#34;",
"apos;", "&#39;", "amp;", "&#38;", NULL
};
switch_xml_root_t root = (switch_xml_root_t) memset(malloc(sizeof(struct switch_xml_root)),
'\0', sizeof(struct switch_xml_root));
root->xml.name = (char *) name;
root->cur = &root->xml;
strcpy(root->err, root->xml.txt = "");
root->ent = memcpy(malloc(sizeof(ent)), ent, sizeof(ent));
root->attr = root->pi = (char ***) (root->xml.attr = SWITCH_XML_NIL);
return &root->xml;
}
// inserts an existing tag into an 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;
child = (switch_xml_t) memset(malloc(sizeof(struct switch_xml)), '\0', sizeof(struct switch_xml));
child->name = (char *) name;
child->attr = SWITCH_XML_NIL;
child->off = off;
child->parent = xml;
child->txt = "";
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 = malloc(4 * sizeof(char *));
xml->attr[1] = strdup(""); // empty list of malloced names/vals
} else
xml->attr = realloc(xml->attr, (l + 4) * sizeof(char *));
xml->attr[l] = (char *) name; // set attribute name
xml->attr[l + 2] = NULL; // null terminate attribute list
xml->attr[l + 3] = 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
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 *));
xml->attr = realloc(xml->attr, (c + 2) * sizeof(char *));
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;
}
/* 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 expandtab:
*/
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