netsurf/utils/url.c
2012-10-06 14:11:29 +01:00

1046 lines
25 KiB
C

/*
* Copyright 2006 Richard Wilson <info@tinct.net>
* Copyright 2005 James Bursa <bursa@users.sourceforge.net>
* Copyright 2005 John M Bell <jmb202@ecs.soton.ac.uk>
*
* This file is part of NetSurf, http://www.netsurf-browser.org/
*
* NetSurf is free software; you can redistribute it and/or modify
* it under the terms of the GNU General Public License as published by
* the Free Software Foundation; version 2 of the License.
*
* NetSurf is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
* GNU General Public License for more details.
*
* You should have received a copy of the GNU General Public License
* along with this program. If not, see <http://www.gnu.org/licenses/>.
*/
/** \file
* URL parsing and joining (implementation).
*/
#include <sys/types.h>
#include <assert.h>
#include <ctype.h>
#include <stdbool.h>
#include <stdlib.h>
#include <string.h>
#include <unistd.h>
#include "curl/curl.h"
#include "utils/config.h"
#include "utils/log.h"
#include "utils/url.h"
#include "utils/utils.h"
struct url_components_internal {
char *buffer; /* buffer used for all the following data */
char *scheme;
char *authority;
char *path;
char *query;
char *fragment;
};
regex_t url_re, url_up_re;
/**
* Initialise URL routines.
*
* Compiles regular expressions required by the url_ functions.
*/
void url_init(void)
{
/* regex from RFC 2396 */
regcomp_wrapper(&url_re, "^[[:space:]]*"
#define URL_RE_SCHEME 2
"(([a-zA-Z][-a-zA-Z0-9+.]*):)?"
#define URL_RE_AUTHORITY 4
"(//([^/?#[:space:]]*))?"
#define URL_RE_PATH 5
"([^?#[:space:]]*)"
#define URL_RE_QUERY 7
"(\\?([^#[:space:]]*))?"
#define URL_RE_FRAGMENT 9
"(#([^[:space:]]*))?"
"[[:space:]]*$", REG_EXTENDED);
regcomp_wrapper(&url_up_re,
"/([^/]?|[.][^./]|[^./][.]|[^./][^./]|[^/][^/][^/]+)"
"/[.][.](/|$)",
REG_EXTENDED);
}
/**
* Check whether a host string is an IP address. It should support and
* detect IPv4 addresses (all of dotted-quad or subsets, decimal or
* hexadecimal notations) and IPv6 addresses (including those containing
* embedded IPv4 addresses.)
*
* \param host a hostname terminated by '\0'
* \return true if the hostname is an IP address, false otherwise
*/
bool url_host_is_ip_address(const char *host)
{
struct in_addr ipv4;
size_t host_len = strlen(host);
const char *sane_host;
const char *slash;
#ifndef NO_IPV6
struct in6_addr ipv6;
char ipv6_addr[64];
#endif
/* FIXME TODO: Some parts of urldb.c (and perhaps other parts of
* NetSurf) make confusions between hosts and "prefixes", we can
* sometimes be erroneously passed more than just a host. Sometimes
* we may be passed trailing slashes, or even whole path segments.
* A specific criminal in this class is urldb_iterate_partial, which
* takes a prefix to search for, but passes that prefix to functions
* that expect only hosts.
*
* For the time being, we will accept such calls; we check if there
* is a / in the host parameter, and if there is, we take a copy and
* replace the / with a \0. This is not a permanent solution; we
* should search through NetSurf and find all the callers that are
* in error and fix them. When doing this task, it might be wise
* to replace the hideousness below with code that doesn't have to do
* this, and add assert(strchr(host, '/') == NULL); somewhere.
* -- rjek - 2010-11-04
*/
slash = strchr(host, '/');
if (slash == NULL) {
sane_host = host;
} else {
char *c = strdup(host);
c[slash - host] = '\0';
sane_host = c;
host_len = slash - host - 1;
LOG(("WARNING: called with non-host '%s'", host));
}
if (strspn(sane_host, "0123456789abcdefABCDEF[].:") < host_len)
goto out_false;
if (inet_aton(sane_host, &ipv4) != 0) {
/* This can only be a sane IPv4 address if it contains 3 dots.
* Helpfully, inet_aton is happy to treat "a", "a.b", "a.b.c",
* and "a.b.c.d" as valid IPv4 address strings where we only
* support the full, dotted-quad, form.
*/
int num_dots = 0;
size_t index;
for (index = 0; index < host_len; index++) {
if (sane_host[index] == '.')
num_dots++;
}
if (num_dots == 3)
goto out_true;
else
goto out_false;
}
#ifndef NO_IPV6
if (sane_host[0] != '[' || sane_host[host_len] != ']')
goto out_false;
strncpy(ipv6_addr, sane_host + 1, sizeof(ipv6_addr));
ipv6_addr[sizeof(ipv6_addr) - 1] = '\0';
if (inet_pton(AF_INET6, ipv6_addr, &ipv6) == 1)
goto out_true;
#endif
out_false:
if (slash != NULL) free((void *)sane_host);
return false;
out_true:
if (slash != NULL) free((void *)sane_host);
return true;
}
/**
* Resolve a relative URL to absolute form.
*
* \param rel relative URL
* \param base base URL, must be absolute and cleaned as by nsurl_create()
* \param result pointer to pointer to buffer to hold absolute url
* \return URL_FUNC_OK on success
*/
url_func_result url_join(const char *rel, const char *base, char **result)
{
url_func_result status = URL_FUNC_NOMEM;
struct url_components_internal base_components = {0,0,0,0,0,0};
struct url_components_internal *base_ptr = &base_components;
struct url_components_internal rel_components = {0,0,0,0,0,0};
struct url_components_internal *rel_ptr = &rel_components;
struct url_components_internal merged_components = {0,0,0,0,0,0};
struct url_components_internal *merged_ptr = &merged_components;
char *merge_path = NULL, *split_point;
char *input, *output, *start = NULL;
int len, buf_len;
(*result) = 0;
assert(base);
assert(rel);
/* break down the relative URL (not cached, corruptable) */
status = url_get_components(rel, (struct url_components *) rel_ptr);
if (status != URL_FUNC_OK) {
LOG(("relative url '%s' failed to get components", rel));
return URL_FUNC_FAILED;
}
/* [1] relative URL is absolute, use it entirely */
merged_components = rel_components;
if (rel_components.scheme)
goto url_join_reform_url;
/* break down the base URL (possibly cached, not corruptable) */
status = url_get_components(base, (struct url_components *) base_ptr);
if (status != URL_FUNC_OK) {
url_destroy_components((struct url_components *) rel_ptr);
LOG(("base url '%s' failed to get components", base));
return URL_FUNC_FAILED;
}
/* [2] relative authority takes presidence */
merged_components.scheme = base_components.scheme;
if (rel_components.authority)
goto url_join_reform_url;
/* [3] handle empty paths */
merged_components.authority = base_components.authority;
if (!rel_components.path) {
merged_components.path = base_components.path;
if (!rel_components.query)
merged_components.query = base_components.query;
goto url_join_reform_url;
}
/* [4] handle valid paths */
if (rel_components.path[0] == '/')
merged_components.path = rel_components.path;
else {
/* 5.2.3 */
if ((base_components.authority) && (!base_components.path)) {
merge_path = malloc(strlen(rel_components.path) + 2);
if (!merge_path) {
LOG(("malloc failed"));
goto url_join_no_mem;
}
sprintf(merge_path, "/%s", rel_components.path);
merged_components.path = merge_path;
} else {
split_point = base_components.path ?
strrchr(base_components.path, '/') :
NULL;
if (!split_point) {
merged_components.path = rel_components.path;
} else {
len = ++split_point - base_components.path;
buf_len = len + 1 + strlen(rel_components.path);
merge_path = malloc(buf_len);
if (!merge_path) {
LOG(("malloc failed"));
goto url_join_no_mem;
}
memcpy(merge_path, base_components.path, len);
memcpy(merge_path + len, rel_components.path,
strlen(rel_components.path));
merge_path[buf_len - 1] = '\0';
merged_components.path = merge_path;
}
}
}
url_join_reform_url:
/* 5.2.4 */
input = merged_components.path;
if ((input) && (strchr(input, '.'))) {
/* [1] remove all dot references */
output = start = malloc(strlen(input) + 1);
if (!output) {
LOG(("malloc failed"));
goto url_join_no_mem;
}
merged_components.path = output;
*output = '\0';
while (*input != '\0') {
/* [2A] */
if (input[0] == '.') {
if (input[1] == '/') {
input = input + 2;
continue;
} else if ((input[1] == '.') &&
(input[2] == '/')) {
input = input + 3;
continue;
}
}
/* [2B] */
if ((input[0] == '/') && (input[1] == '.')) {
if (input[2] == '/') {
input = input + 2;
continue;
} else if (input[2] == '\0') {
input = input + 1;
*input = '/';
continue;
}
/* [2C] */
if ((input[2] == '.') && ((input[3] == '/') ||
(input[3] == '\0'))) {
if (input[3] == '/') {
input = input + 3;
} else {
input = input + 2;
*input = '/';
}
if ((output > start) &&
(output[-1] == '/'))
*--output = '\0';
split_point = strrchr(start, '/');
if (!split_point)
output = start;
else
output = split_point;
*output = '\0';
continue;
}
}
/* [2D] */
if (input[0] == '.') {
if (input[1] == '\0') {
input = input + 1;
continue;
} else if ((input[1] == '.') &&
(input[2] == '\0')) {
input = input + 2;
continue;
}
}
/* [2E] */
if (*input == '/')
*output++ = *input++;
while ((*input != '/') && (*input != '\0'))
*output++ = *input++;
*output = '\0';
}
/* [3] */
merged_components.path = start;
}
/* 5.3 */
*result = url_reform_components((struct url_components *) merged_ptr);
if (!(*result))
goto url_join_no_mem;
/* return success */
status = URL_FUNC_OK;
url_join_no_mem:
free(start);
free(merge_path);
url_destroy_components((struct url_components *) base_ptr);
url_destroy_components((struct url_components *) rel_ptr);
return status;
}
/**
* Return the host name from an URL.
*
* \param url an absolute URL
* \param result pointer to pointer to buffer to hold host name
* \return URL_FUNC_OK on success
*/
url_func_result url_host(const char *url, char **result)
{
url_func_result status;
struct url_components components;
const char *host_start, *host_end;
assert(url);
status = url_get_components(url, &components);
if (status == URL_FUNC_OK) {
if (!components.authority) {
url_destroy_components(&components);
return URL_FUNC_FAILED;
}
host_start = strchr(components.authority, '@');
host_start = host_start ? host_start + 1 : components.authority;
/* skip over an IPv6 address if there is one */
if (host_start[0] == '[') {
host_end = strchr(host_start, ']') + 1;
} else {
host_end = strchr(host_start, ':');
}
if (!host_end)
host_end = components.authority +
strlen(components.authority);
*result = malloc(host_end - host_start + 1);
if (!(*result)) {
url_destroy_components(&components);
return URL_FUNC_FAILED;
}
memcpy((*result), host_start, host_end - host_start);
(*result)[host_end - host_start] = '\0';
}
url_destroy_components(&components);
return status;
}
/**
* Return the scheme name from an URL.
*
* See RFC 3986, 3.1 for reference.
*
* \param url an absolute URL
* \param result pointer to pointer to buffer to hold scheme name
* \return URL_FUNC_OK on success
*/
url_func_result url_scheme(const char *url, char **result)
{
url_func_result status;
struct url_components components;
assert(url);
status = url_get_components(url, &components);
if (status == URL_FUNC_OK) {
if (!components.scheme) {
status = URL_FUNC_FAILED;
} else {
*result = strdup(components.scheme);
if (!(*result))
status = URL_FUNC_NOMEM;
}
}
url_destroy_components(&components);
return status;
}
/**
* Return the canonical root of an URL
*
* \param url an absolute URL
* \param result pointer to pointer to buffer to hold canonical rool URL
* \return URL_FUNC_OK on success
*/
url_func_result url_canonical_root(const char *url, char **result)
{
url_func_result status;
struct url_components components;
assert(url);
status = url_get_components(url, &components);
if (status == URL_FUNC_OK) {
if ((!components.scheme) || (!components.authority)) {
status = URL_FUNC_FAILED;
} else {
*result = malloc(strlen(components.scheme) +
strlen(components.authority) + 4);
if (!(*result))
status = URL_FUNC_NOMEM;
else
sprintf((*result), "%s://%s", components.scheme,
components.authority);
}
}
url_destroy_components(&components);
return status;
}
/**
* Extract path segment from an URL
*
* \param url an absolute URL
* \param result pointer to pointer to buffer to hold result
* \return URL_FUNC_OK on success
*/
url_func_result url_path(const char *url, char **result)
{
url_func_result status;
struct url_components components;
assert(url);
status = url_get_components(url, &components);
if (status == URL_FUNC_OK) {
if (!components.path) {
status = URL_FUNC_FAILED;
} else {
*result = strdup(components.path);
if (!(*result))
status = URL_FUNC_NOMEM;
}
}
url_destroy_components(&components);
return status;
}
/**
* Attempt to find a nice filename for a URL.
*
* \param url an absolute URL
* \param result pointer to pointer to buffer to hold filename
* \param remove_extensions remove any extensions from the filename
* \return URL_FUNC_OK on success
*/
url_func_result url_nice(const char *url, char **result,
bool remove_extensions)
{
int m;
regmatch_t match[10];
regoff_t start, end;
size_t i;
char *dot;
*result = 0;
m = regexec(&url_re, url, 10, match, 0);
if (m) {
LOG(("url '%s' failed to match regex", url));
return URL_FUNC_FAILED;
}
/* extract the last component of the path, if possible */
if (match[URL_RE_PATH].rm_so == -1 || match[URL_RE_PATH].rm_so ==
match[URL_RE_PATH].rm_eo)
goto no_path; /* no path, or empty */
for (end = match[URL_RE_PATH].rm_eo - 1;
end != match[URL_RE_PATH].rm_so && url[end] == '/';
end--)
;
if (end == match[URL_RE_PATH].rm_so)
goto no_path; /* path is a string of '/' */
end++;
for (start = end - 1;
start != match[URL_RE_PATH].rm_so && url[start] != '/';
start--)
;
if (url[start] == '/')
start++;
if (!strncasecmp(url + start, "index.", 6) ||
!strncasecmp(url + start, "default.", 8)) {
/* try again */
if (start == match[URL_RE_PATH].rm_so)
goto no_path;
for (end = start - 1;
end != match[URL_RE_PATH].rm_so &&
url[end] == '/';
end--)
;
if (end == match[URL_RE_PATH].rm_so)
goto no_path;
end++;
for (start = end - 1;
start != match[URL_RE_PATH].rm_so &&
url[start] != '/';
start--)
;
if (url[start] == '/')
start++;
}
*result = malloc(end - start + 1);
if (!*result) {
LOG(("malloc failed"));
return URL_FUNC_NOMEM;
}
strncpy(*result, url + start, end - start);
(*result)[end - start] = 0;
if (remove_extensions) {
dot = strchr(*result, '.');
if (dot && dot != *result)
*dot = 0;
}
return URL_FUNC_OK;
no_path:
/* otherwise, use the host name, with '.' replaced by '_' */
if (match[URL_RE_AUTHORITY].rm_so != -1 &&
match[URL_RE_AUTHORITY].rm_so !=
match[URL_RE_AUTHORITY].rm_eo) {
*result = malloc(match[URL_RE_AUTHORITY].rm_eo -
match[URL_RE_AUTHORITY].rm_so + 1);
if (!*result) {
LOG(("malloc failed"));
return URL_FUNC_NOMEM;
}
strncpy(*result, url + match[URL_RE_AUTHORITY].rm_so,
match[URL_RE_AUTHORITY].rm_eo -
match[URL_RE_AUTHORITY].rm_so);
(*result)[match[URL_RE_AUTHORITY].rm_eo -
match[URL_RE_AUTHORITY].rm_so] = 0;
for (i = 0; (*result)[i]; i++)
if ((*result)[i] == '.')
(*result)[i] = '_';
return URL_FUNC_OK;
}
return URL_FUNC_FAILED;
}
/**
* Convert an escaped string to plain.
* \param result unescaped string owned by caller must be freed with free()
* \return URL_FUNC_OK on success
*/
url_func_result url_unescape(const char *str, char **result)
{
char *curlstr;
char *retstr;
curlstr = curl_unescape(str, 0);
if (curlstr == NULL) {
return URL_FUNC_NOMEM;
}
retstr = strdup(curlstr);
curl_free(curlstr);
if (retstr == NULL) {
return URL_FUNC_NOMEM;
}
*result = retstr;
return URL_FUNC_OK;
}
/**
* Escape a string suitable for inclusion in an URL.
*
* \param unescaped the unescaped string
* \param toskip number of bytes to skip in unescaped string
* \param sptoplus true iff spaces should be converted to +
* \param escexceptions NULL or a string of characters excluded to be escaped
* \param result pointer to pointer to buffer to hold escaped string
* \return URL_FUNC_OK on success
*/
url_func_result url_escape(const char *unescaped, size_t toskip,
bool sptoplus, const char *escexceptions, char **result)
{
size_t len;
char *escaped, *d, *tmpres;
const char *c;
if (!unescaped || !result)
return URL_FUNC_FAILED;
*result = NULL;
len = strlen(unescaped);
if (len < toskip)
return URL_FUNC_FAILED;
len -= toskip;
escaped = malloc(len * 3 + 1);
if (!escaped)
return URL_FUNC_NOMEM;
for (c = unescaped + toskip, d = escaped; *c; c++) {
/* Check if we should escape this byte.
* '~' is unreserved and should not be percent encoded, if
* you believe the spec; however, leaving it unescaped
* breaks a bunch of websites, so we escape it anyway. */
if (!isascii(*c)
|| (strchr(":/?#[]@" /* gen-delims */
"!$&'()*+,;=" /* sub-delims */
"<>%\"{}|\\^`~" /* others */, *c)
&& (!escexceptions || !strchr(escexceptions, *c)))
|| *c <= 0x20 || *c == 0x7f) {
if (*c == 0x20 && sptoplus) {
*d++ = '+';
} else {
*d++ = '%';
*d++ = "0123456789ABCDEF"[((*c >> 4) & 0xf)];
*d++ = "0123456789ABCDEF"[(*c & 0xf)];
}
} else {
/* unreserved characters: [a-zA-Z0-9-._] */
*d++ = *c;
}
}
*d++ = '\0';
tmpres = malloc(d - escaped + toskip);
if (!tmpres) {
free(escaped);
return URL_FUNC_NOMEM;
}
memcpy(tmpres, unescaped, toskip);
memcpy(tmpres + toskip, escaped, d - escaped);
*result = tmpres;
free(escaped);
return URL_FUNC_OK;
}
/**
* Compare two absolute, normalized URLs
*
* \param url1 URL 1
* \param url2 URL 2
* \param nofrag Ignore fragment part in comparison
* \param result Pointer to location to store result (true if URLs match)
* \return URL_FUNC_OK on success
*/
url_func_result url_compare(const char *url1, const char *url2,
bool nofrag, bool *result)
{
url_func_result status;
struct url_components c1, c2;
bool res = true;
assert(url1 && url2 && result);
/* Decompose URLs */
status = url_get_components(url1, &c1);
if (status != URL_FUNC_OK) {
url_destroy_components(&c1);
return status;
}
status = url_get_components(url2, &c2);
if (status != URL_FUNC_OK) {
url_destroy_components(&c2);
url_destroy_components(&c1);
return status;
}
if (((c1.scheme && c2.scheme) || (!c1.scheme && !c2.scheme )) &&
((c1.authority && c2.authority) ||
(!c1.authority && !c2.authority)) &&
((c1.path && c2.path) || (!c1.path && !c2.path)) &&
((c1.query && c2.query) ||
(!c1.query && !c2.query)) &&
(nofrag || (c1.fragment && c2.fragment) ||
(!c1.fragment && !c2.fragment))) {
if (c1.scheme)
res &= strcasecmp(c1.scheme, c2.scheme) == 0;
/** \todo consider each part of the authority separately */
if (c1.authority)
res &= strcasecmp(c1.authority, c2.authority) == 0;
if (c1.path)
res &= strcmp(c1.path, c2.path) == 0;
if (c1.query)
res &= strcmp(c1.query, c2.query) == 0;
if (!nofrag && c1.fragment)
res &= strcmp(c1.fragment, c2.fragment) == 0;
} else {
/* Can't match */
res = false;
}
*result = res;
url_destroy_components(&c2);
url_destroy_components(&c1);
return URL_FUNC_OK;
}
/**
* Split a URL into separate components
*
* URLs passed to this function are assumed to be valid and no error checking
* or recovery is attempted.
*
* See RFC 3986 for reference.
*
* \param url a valid absolute or relative URL
* \param result pointer to buffer to hold components
* \return URL_FUNC_OK on success
*/
url_func_result url_get_components(const char *url,
struct url_components *result)
{
int storage_length;
char *storage_end;
const char *scheme;
const char *authority;
const char *path;
const char *query;
const char *fragment;
struct url_components_internal *internal;
assert(url);
/* clear our return value */
internal = (struct url_components_internal *)result;
memset(result, 0x00, sizeof(struct url_components));
/* get enough storage space for a URL with termination at each node */
storage_length = strlen(url) + 8;
internal->buffer = malloc(storage_length);
if (!internal->buffer)
return URL_FUNC_NOMEM;
storage_end = internal->buffer;
/* look for a valid scheme */
scheme = url;
if (isalpha(*scheme)) {
for (scheme = url + 1;
((*scheme != ':') && (*scheme != '\0'));
scheme++) {
if (!isalnum(*scheme) && (*scheme != '+') &&
(*scheme != '-') && (*scheme != '.'))
break;
}
if (*scheme == ':') {
memcpy(storage_end, url, scheme - url);
storage_end[scheme - url] = '\0';
result->scheme = storage_end;
storage_end += scheme - url + 1;
scheme++;
} else {
scheme = url;
}
}
/* look for an authority */
authority = scheme;
if ((authority[0] == '/') && (authority[1] == '/')) {
authority = strpbrk(scheme + 2, "/?#");
if (!authority)
authority = scheme + strlen(scheme);
memcpy(storage_end, scheme + 2, authority - scheme - 2);
storage_end[authority - scheme - 2] = '\0';
result->authority = storage_end;
storage_end += authority - scheme - 1;
}
/* look for a path */
path = authority;
if ((*path != '?') && (*path != '#') && (*path != '\0')) {
path = strpbrk(path, "?#");
if (!path)
path = authority + strlen(authority);
memcpy(storage_end, authority, path - authority);
storage_end[path - authority] = '\0';
result->path = storage_end;
storage_end += path - authority + 1;
}
/* look for a query */
query = path;
if (*query == '?') {
query = strchr(query, '#');
if (!query)
query = path + strlen(path);
memcpy(storage_end, path + 1, query - path - 1);
storage_end[query - path - 1] = '\0';
result->query = storage_end;
storage_end += query - path;
}
/* look for a fragment */
fragment = query;
if (*fragment == '#') {
fragment = query + strlen(query);
/* make a copy of the result for the caller */
memcpy(storage_end, query + 1, fragment - query - 1);
storage_end[fragment - query - 1] = '\0';
result->fragment = storage_end;
storage_end += fragment - query;
}
assert((result->buffer + storage_length) >= storage_end);
return URL_FUNC_OK;
}
/**
* Reform a URL from separate components
*
* See RFC 3986 for reference.
*
* \param components the components to reform into a URL
* \return a new URL allocated on the heap, or NULL on failure
*/
char *url_reform_components(const struct url_components *components)
{
int scheme_len = 0, authority_len = 0, path_len = 0, query_len = 0,
fragment_len = 0;
char *result, *url;
/* 5.3 */
if (components->scheme)
scheme_len = strlen(components->scheme) + 1;
if (components->authority)
authority_len = strlen(components->authority) + 2;
if (components->path)
path_len = strlen(components->path);
if (components->query)
query_len = strlen(components->query) + 1;
if (components->fragment)
fragment_len = strlen(components->fragment) + 1;
/* claim memory */
url = result = malloc(scheme_len + authority_len + path_len +
query_len + fragment_len + 1);
if (!url) {
LOG(("malloc failed"));
return NULL;
}
/* rebuild URL */
if (components->scheme) {
sprintf(url, "%s:", components->scheme);
url += scheme_len;
}
if (components->authority) {
sprintf(url, "//%s", components->authority);
url += authority_len;
}
if (components->path) {
sprintf(url, "%s", components->path);
url += path_len;
}
if (components->query) {
sprintf(url, "?%s", components->query);
url += query_len;
}
if (components->fragment)
sprintf(url, "#%s", components->fragment);
return result;
}
/**
* Release some url components from memory
*
* \param result pointer to buffer containing components
*/
void url_destroy_components(const struct url_components *components)
{
const struct url_components_internal *internal;
assert(components);
internal = (const struct url_components_internal *)components;
if (internal->buffer)
free(internal->buffer);
}
#ifdef TEST
int main(int argc, char *argv[])
{
int i;
url_func_result res;
char *s;
url_init();
for (i = 1; i != argc; i++) {
/* printf("==> '%s'\n", argv[i]);
res = url_normalize(argv[i], &s);
if (res == URL_FUNC_OK) {
printf("<== '%s'\n", s);
free(s);
}*/
/* printf("==> '%s'\n", argv[i]);
res = url_host(argv[i], &s);
if (res == URL_FUNC_OK) {
printf("<== '%s'\n", s);
free(s);
}*/
if (1 != i) {
res = url_join(argv[i], argv[1], &s);
if (res == URL_FUNC_OK) {
printf("'%s' + '%s' \t= '%s'\n", argv[1],
argv[i], s);
free(s);
}
}
/* printf("'%s' => ", argv[i]);
res = url_nice(argv[i], &s, true);
if (res == URL_FUNC_OK) {
printf("'%s', ", s);
free(s);
} else {
printf("failed %u, ", res);
}
res = url_nice(argv[i], &s, false);
if (res == URL_FUNC_OK) {
printf("'%s', ", s);
free(s);
} else {
printf("failed %u, ", res);
}
printf("\n");*/
}
return 0;
}
void regcomp_wrapper(regex_t *preg, const char *regex, int cflags)
{
char errbuf[200];
int r;
r = regcomp(preg, regex, cflags);
if (r) {
regerror(r, preg, errbuf, sizeof errbuf);
fprintf(stderr, "Failed to compile regexp '%s'\n", regex);
fprintf(stderr, "error: %s\n", errbuf);
exit(1);
}
}
#endif