/* * Copyright (C) 2023 Adrien Gesta-Fline * * This file is part of libAAF. * * This program is free software; you can redistribute it and/or modify * it under the terms of the GNU General Public License as published by * the Free Software Foundation; either version 2 of the License, or * (at your option) any later version. * * This program is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the * GNU General Public License for more details. * * You should have received a copy of the GNU General Public License along * with this program; if not, write to the Free Software Foundation, Inc., * 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA. */ #include #include #include #include #include #include #ifdef _MSC_VER #include typedef SSIZE_T ssize_t; #endif #include "aaf/URIParser.h" #define debug(...) \ _dbg (dbg, NULL, DEBUG_SRC_ID_AAF_IFACE, VERB_DEBUG, __VA_ARGS__) #define warning(...) \ _dbg (dbg, NULL, DEBUG_SRC_ID_AAF_IFACE, VERB_WARNING, __VA_ARGS__) #define error(...) \ _dbg (dbg, NULL, DEBUG_SRC_ID_AAF_IFACE, VERB_ERROR, __VA_ARGS__) #define IS_LOWALPHA(c) \ ((c >= 'a') && (c <= 'z')) #define IS_UPALPHA(c) \ ((c >= 'A') && (c <= 'Z')) #define IS_ALPHA(c) \ (IS_LOWALPHA (c) || IS_UPALPHA (c)) #define IS_DIGIT(c) \ (c >= '0' && c <= '9') #define IS_ALPHANUM(c) \ (IS_ALPHA (c) || IS_DIGIT (c)) #define IS_HEX(c) \ (IS_DIGIT (c) || (c >= 'a' && c <= 'f') || (c >= 'A' && c <= 'F')) /* * RFC 2396 * https://datatracker.ietf.org/doc/html/rfc2396#section-2.3 */ #define IS_MARK(c) \ (c == '-' || c == '_' || c == '.' || c == '!' || c == '~' || c == '*' || c == '\'' || c == '(' || c == ')') #define IS_UNRESERVED(c) \ (IS_ALPHANUM (c) || IS_MARK (c)) #define IS_ENCODED(p) \ ((*p == '%') && IS_HEX (*(p + 1)) && IS_HEX (*(p + 2))) #define SCHEME_SAFE_CHAR(c) \ (IS_ALPHANUM (c) || c == '+' || c == '.' || c == '-') #define USERINFO_SAFE_CHAR(p) \ (IS_ALPHANUM (*p) || IS_ENCODED (p) || *p == ';' || *p == ':' || *p == '&' || *p == '=' || *p == '+' || *p == '$' || *p == ',') #define WINDOWS_DRIVE_LETTER(p) \ (IS_ALPHA (*p) && (*(p + 1) == ':' || *(p + 1) == '|') && *(p + 2) == '/') #define SCHEME_ALLOW_QUERY(uri) \ (uri->scheme_t != URI_SCHEME_T_FILE && \ !(uri->opts & URI_OPT_IGNORE_QUERY)) #define SCHEME_ALLOW_FRAGMENT(uri) \ (uri->scheme_t != URI_SCHEME_T_FILE && \ !(uri->opts & URI_OPT_IGNORE_FRAGMENT)) #define URI_SET_STR(str, start, end) \ \ str = malloc (sizeof (char) * ((end - start) + 1)); \ \ if (NULL == str) { \ error ("URI allocation failed"); \ goto err; \ } \ \ snprintf (str, (end - start) + 1, "%s", start); static int _uri_parse_scheme (struct uri* uri, const char** pos, const char* end, struct dbg* dbg); static int _uri_parse_authority (struct uri* uri, const char** pos, const char* end, struct dbg* dbg); static int _uri_parse_userinfo (struct uri* uri, const char** pos, const char* end, struct dbg* dbg); static int _uri_parse_hostname (struct uri* uri, const char** pos, const char* end, struct dbg* dbg); static int _uri_parse_path (struct uri* uri, const char** pos, const char* end, struct dbg* dbg); static int _uri_parse_query (struct uri* uri, const char** pos, const char* end, struct dbg* dbg); static int _uri_parse_fragment (struct uri* uri, const char** pos, const char* end, struct dbg* dbg); static void _uri_scheme2schemeType (struct uri* uri); static int _laaf_util_snprintf_realloc (char** str, size_t* size, size_t offset, const char* format, ...); #ifdef BUILD_URI_TEST // gcc -g -W -Wall ./URIParser.c -D BUILD_URI_TEST static int _uri_cmp (const struct uri* a, const struct uri* b); static void _uri_dump_diff (struct uri* a, struct uri* b, int totalDifferencies); static int _uri_test (const char* uristr, enum uri_option optflags, struct uri expectedRes, int line); #endif // BUILD_URI_TEST char* uriDecodeString (char* src, char* dst) { int inpos = 0; int outpos = 0; if (src == NULL) { return NULL; } if (dst == NULL) { dst = src; } while (src[inpos]) { if (src[inpos] == '%' && IS_HEX (src[inpos + 1]) && IS_HEX (src[inpos + 2])) { int c = 0; char hex1 = src[inpos + 1]; if ((hex1 >= '0') && (hex1 <= '9')) c = (hex1 - '0'); else if ((hex1 >= 'a') && (hex1 <= 'f')) c = (hex1 - 'a') + 10; else if ((hex1 >= 'A') && (hex1 <= 'F')) c = (hex1 - 'A') + 10; char hex2 = src[inpos + 2]; if ((hex2 >= '0') && (hex2 <= '9')) c = c * 16 + (hex2 - '0'); else if ((hex2 >= 'a') && (hex2 <= 'f')) c = c * 16 + (hex2 - 'a') + 10; else if ((hex2 >= 'A') && (hex2 <= 'F')) c = c * 16 + (hex2 - 'A') + 10; dst[outpos] = (char)c; inpos += 3; } else { dst[outpos] = src[inpos]; inpos++; } outpos++; } if (inpos > outpos) { dst[outpos] = 0x00; } return dst; } static int _uri_parse_scheme (struct uri* uri, const char** pos, const char* end, struct dbg* dbg) { const char* p = *pos; while (p < end && *p != ':') { if (!SCHEME_SAFE_CHAR (*p)) { error ("uri scheme contains invalid character : '%c' (0x%02x)", *p, *p); goto err; } p++; } if (*pos == p) { error ("uri is missing scheme"); goto err; } URI_SET_STR (uri->scheme, *pos, p); /* * RFC 3986 - Generic * https://datatracker.ietf.org/doc/html/rfc3986#section-3.1 * * « Although schemes are case- insensitive, the canonical form is lowercase * and documents that specify schemes must do so with lowercase letters. * An implementation should accept uppercase letters as equivalent to lowercase * in scheme names (e.g., allow "HTTP" as well as "http") for the sake of * robustness but should only produce lowercase scheme names for consistency.» */ char* pp = uri->scheme; while (*pp) { *pp = tolower (*pp); pp++; } _uri_scheme2schemeType (uri); *pos = ++p; /* Skips ':' */ return 1; err: return -1; } static int _uri_parse_authority (struct uri* uri, const char** pos, const char* end, struct dbg* dbg) { /* * RFC 3986 - Uniform Resource Identifier (URI): Generic Syntax * https://datatracker.ietf.org/doc/html/rfc3986#section-3.2 * * « Many URI schemes include a hierarchical element for a naming * authority so that governance of the name space defined by the * remainder of the URI is delegated to that authority (which may, in * turn, delegate it further). The generic syntax provides a common * means for distinguishing an authority based on a registered name or * server address, along with optional port and user information. * * The authority component is preceded by a double slash ("//") and is * terminated by the next slash ("/"), question mark ("?"), or number * sign ("#") character, or by the end of the URI. * * authority = [ userinfo "@" ] host [ ":" port ] * * URI producers and normalizers should omit the ":" delimiter that * separates host from port if the port component is empty. Some * schemes do not allow the userinfo and/or port subcomponents. * * If a URI contains an authority component, then the path component * must either be empty or begin with a slash ("/") character. Non- * validating parsers (those that merely separate a URI reference into * its major components) will often ignore the subcomponent structure of * authority, treating it as an opaque string from the double-slash to * the first terminating delimiter, until such time as the URI is * dereferenced.» */ if (*(*pos) != '/' || *((*pos) + 1) != '/') { /* uri has no authority */ if (uri->scheme_t == URI_SCHEME_T_FILE) { uri->flags |= URI_T_LOCALHOST; } // uri->flags |= URI_T_LOCALHOST; // uri->flags |= URI_T_HOST_EMPTY; return 0; } *pos += 2; const char* p = *pos; while (p < end && *p != '/' && (!SCHEME_ALLOW_QUERY (uri) || *p != '?') && (!SCHEME_ALLOW_FRAGMENT (uri) || *p != '#')) { p++; } URI_SET_STR (uri->authority, *pos, p); if (*uri->authority == 0x00) { uri->flags |= URI_T_LOCALHOST; } return 1; err: return -1; } static int _uri_parse_userinfo (struct uri* uri, const char** pos, const char* end, struct dbg* dbg) { int hasUserinfo = 0; int userinfoIllegalCharacters = 0; const char* p = *pos; while (p < end) { if (*p == '@') { hasUserinfo = 1; break; } if (!USERINFO_SAFE_CHAR (p)) { userinfoIllegalCharacters++; } p++; } if (!hasUserinfo) { return 0; } if (userinfoIllegalCharacters > 0) { error ("uri userinfo contains %i invalid char%s", userinfoIllegalCharacters, (userinfoIllegalCharacters > 1) ? "s" : ""); goto err; } /* user / pass */ URI_SET_STR (uri->userinfo, *pos, p); *pos = p + 1; // skips '@' const char* subpos = NULL; p = uri->userinfo; while (1) { if (!*p) { if (subpos) { URI_SET_STR (uri->pass, subpos, p); } else { URI_SET_STR (uri->user, uri->userinfo, p); } break; } else if (*p == ':') { URI_SET_STR (uri->user, uri->userinfo, p); subpos = p + 1; } p++; } if (uri->opts & URI_OPT_DECODE_USERINFO && uri->userinfo) { uriDecodeString (uri->userinfo, NULL); } if (uri->opts & URI_OPT_DECODE_USERPASS) { if (uri->user) uriDecodeString (uri->user, NULL); if (uri->pass) uriDecodeString (uri->pass, NULL); } return 1; err: return -1; } static int _uri_parse_hostname (struct uri* uri, const char** pos, const char* end, struct dbg* dbg) { const char* p = *pos; if (**pos == '[') { /* * IPv6 - RFC 2732 * https://datatracker.ietf.org/doc/html/rfc2732 */ (*pos)++; // skips '[' while (p < end && *p != ']') { p++; } URI_SET_STR (uri->host, *pos, p); char* iperr = NULL; int rc = 0; if ((rc = uriIsIPv6 (uri->host, strlen (uri->host), &iperr))) { uri->flags |= URI_T_HOST_IPV6; if (rc == 2) { uri->flags |= URI_T_LOCALHOST; } } else { error ("URI IPv6 Parser error : %s\n", iperr); free (iperr); goto err; } p++; // skips ']' } else if ((*p == '.' || *p == '?') && (*(p + 1) == '/')) { /* windows "//./" and "//?/" guard */ uri->flags |= URI_T_LOCALHOST; return 0; } else { /* * All other : IPv4, server name, local path */ while (p < end && *p != '/' && // if URI contains a path *p != ':' && // if URI has an explicit port (!SCHEME_ALLOW_QUERY (uri) || *p != '?') && (!SCHEME_ALLOW_FRAGMENT (uri) || *p != '#')) { p++; } // debug( " >>> %.*s", (int)(p-*pos), p ); URI_SET_STR (uri->host, *pos, p); } // if ( !(uri->flags & URI_T_HOST_IPV6 || uri->flags & URI_T_HOST_EMPTY) ) { if (!(uri->flags & URI_T_HOST_IPV6) && uri->host != NULL && *uri->host != 0x00) { if (uriIsIPv4 (uri->host, strlen (uri->host), NULL)) { uri->flags &= ~URI_T_HOST_MASK; uri->flags |= URI_T_HOST_IPV4; if (strcmp (uri->host, "127.0.0.1") == 0) { uri->flags |= URI_T_LOCALHOST; } } else if (strcmp (uri->host, "localhost") == 0) { uri->flags |= URI_T_LOCALHOST; } else { uri->flags |= URI_T_HOST_REGNAME; } if (uri->opts & URI_OPT_DECODE_HOSTNAME) { uriDecodeString (uri->host, NULL); } } // else if ( uri->host == NULL ) { // if ( uri->scheme_t == URI_SCHEME_T_FILE ) { // uri->flags |= URI_T_LOCALHOST; // } // } if (*p == ':') { /* port */ *pos = ++p; while (p < end && *p != '/' && (!SCHEME_ALLOW_QUERY (uri) || *p != '?') && (!SCHEME_ALLOW_FRAGMENT (uri) || *p != '#')) { if (!IS_DIGIT (*p)) { error ("URI port contains non-digit char : %c (0x%02x).\n", *p, *p); goto err; } p++; } uri->port = atoi (*pos); } *pos = p; // keeps next char, first path '/' return 1; err: return -1; } static int _uri_parse_path (struct uri* uri, const char** pos, const char* end, struct dbg* dbg) { int winDrive = 0; /* sanitize start of path : ignores all slashes (after already parsed '//' identifying start of authority) */ while (*(*pos + 1) == '/') { (*pos)++; } if (*(*pos) == '/' && WINDOWS_DRIVE_LETTER (((*pos) + 1))) { /* * Windows Drive (c: / c|) - RFC 8089 * https://datatracker.ietf.org/doc/html/rfc8089#appendix-E.2.2 */ (*pos)++; /* moves forward last slash before driver letter, so path starts at the letter with no slash before. */ winDrive = 1; } const char* p = *pos; while (p < end && (!SCHEME_ALLOW_QUERY (uri) || *p != '?') && (!SCHEME_ALLOW_FRAGMENT (uri) || *p != '#')) { p++; } // debug( " >>> (%i) %.*s", (int)(p-*pos), (int)(p-*pos), p ); URI_SET_STR (uri->path, *pos, p); if (winDrive) { if (uri->path[1] == '|') { /* * https://datatracker.ietf.org/doc/html/rfc8089#appendix-E.2.2 * « To update such an old URI, replace the vertical line "|" with a colon ":" » */ uri->path[1] = ':'; } } if (uri->opts & URI_OPT_DECODE_PATH) { uriDecodeString (uri->path, NULL); } *pos = p; return 1; err: return -1; } static int _uri_parse_query (struct uri* uri, const char** pos, const char* end, struct dbg* dbg) { const char* p = *pos; if (!(uri->opts & URI_OPT_IGNORE_QUERY) && **pos == '?') { while (p < end && *p != '#') { p++; } (*pos)++; // skips '?' URI_SET_STR (uri->query, *pos, p); if (uri->opts & URI_OPT_DECODE_QUERY) { uriDecodeString (uri->query, NULL); } *pos = p; } return 1; err: return -1; } static int _uri_parse_fragment (struct uri* uri, const char** pos, const char* end, struct dbg* dbg) { /* * https://datatracker.ietf.org/doc/html/draft-yevstifeyev-ftp-uri-scheme#section-3.2.4.2 * « ... fragment identifier are allowed in any URI. * * The number sign ("#") characters (ASCII character 0x23), if used for * the reason other than to delimit the fragment identifier SHALL be * percent-encoded. » * * However, we've seen filenames in 'file' scheme with non encoded '#'. * Plus, it seems impossible for a client to use fragments in a 'file' * scheme URI. So the SCHEME_ALLOW_FRAGMENT() macro will make the parser * treat '#' chars as a normal character, only for 'file' scheme. */ const char* p = *pos; if (!(uri->opts & URI_OPT_IGNORE_FRAGMENT) && **pos == '#') { while (p < end) { p++; } (*pos)++; // skips '#' URI_SET_STR (uri->fragment, *pos, p); if (uri->opts & URI_OPT_DECODE_FRAGMENT) { uriDecodeString (uri->fragment, NULL); } *pos = ++p; // skips '#' } return 1; err: return -1; } struct uri* uriParse (const char* uristr, enum uri_option optflags, struct dbg* dbg) { if (uristr == NULL) { return NULL; } struct uri* uri = calloc (1, sizeof (struct uri)); if (uri == NULL) { return NULL; } size_t urilen = strlen (uristr); if (urilen >= MAX_URI_LENGTH) { error ("uri is too long"); goto err; } uri->opts = optflags; const char* pos = uristr; const char* end = pos + urilen; _uri_parse_scheme (uri, &pos, end, dbg); if (_uri_parse_authority (uri, &pos, end, dbg)) { _uri_parse_userinfo (uri, &pos, end, dbg); _uri_parse_hostname (uri, &pos, end, dbg); } _uri_parse_path (uri, &pos, end, dbg); if (SCHEME_ALLOW_QUERY (uri)) { _uri_parse_query (uri, &pos, end, dbg); } if (SCHEME_ALLOW_FRAGMENT (uri)) { _uri_parse_fragment (uri, &pos, end, dbg); } goto end; err: uriFree (uri); uri = NULL; end: return uri; } void uriFree (struct uri* uri) { if (uri == NULL) { return; } if (NULL != uri->scheme) { free (uri->scheme); } if (NULL != uri->userinfo) { free (uri->userinfo); } if (NULL != uri->authority) { free (uri->authority); } if (NULL != uri->user) { free (uri->user); } if (NULL != uri->pass) { free (uri->pass); } if (NULL != uri->host) { free (uri->host); } if (NULL != uri->path) { free (uri->path); } if (NULL != uri->query) { free (uri->query); } if (NULL != uri->fragment) { free (uri->fragment); } free (uri); } int uriIsIPv4 (const char* s, int size, char** err) { int octets = 0; const char* currentOctetStart = s; char prev = 0; for (int i = 0; i <= size; i++) { if (prev == 0) { if (IS_DIGIT (*(s + i))) { currentOctetStart = (s + i); prev = 'd'; continue; } if (*(s + i) == '.') { if (err) { _laaf_util_snprintf_realloc (err, NULL, 0, "IPV4 parser error : can't start with a single '.'"); } return 0; } } if (prev == 'p') { if (IS_DIGIT (*(s + i))) { currentOctetStart = (s + i); prev = 'd'; continue; } if (*(s + i) == '.') { if (err) { _laaf_util_snprintf_realloc (err, NULL, 0, "IPV4 parser error : can't have successive '.'"); } return 0; } } if (prev == 'd') { if (IS_DIGIT (*(s + i))) { prev = 'd'; continue; } if (i == size || *(s + i) == '.') { // period int octet = atoi (currentOctetStart); if (octet > 255) { if (err) { _laaf_util_snprintf_realloc (err, NULL, 0, "IPV4 parser error : octet %i is too high : %.*s", (octets), (int)((s + i) - currentOctetStart), currentOctetStart); } return 0; } if (i + 1 == size) { if (err) { _laaf_util_snprintf_realloc (err, NULL, 0, "IPV4 parser error : can't end with a single '.'"); } return 0; } prev = 'p'; octets++; continue; } } if (i == size) { break; } if (err) { _laaf_util_snprintf_realloc (err, NULL, 0, "IPV4 parser error : illegal char '%c' (0x%02x)", *(s + i), *(s + i)); } return 0; } if (octets > 4) { if (err) { _laaf_util_snprintf_realloc (err, NULL, 0, "IPV4 parser error : too many octets"); } return 0; } if (octets < 4) { if (err) { _laaf_util_snprintf_realloc (err, NULL, 0, "IPV4 parser error : not enough octets"); } return 0; } return 1; } int uriIsIPv6 (const char* s, int size, char** err) { int segmentCount = 0; int emptySegmentCount = 0; int curSegmentLength = 0; int ipv4portion = 0; int loopback = 0; const char* curSegmentStart = s; char prev = 0; for (int i = 0; i <= size; i++) { if (prev == 0) { if (IS_HEX (*(s + i))) { segmentCount++; curSegmentStart = s + i; curSegmentLength++; prev = 'h'; // hex if (loopback >= 0) { if (!IS_DIGIT (*(s + i))) { loopback = -1; } else { loopback += (*(s + i) - '0'); //atoi(*(s+i)); } } continue; } if (*(s + i) == ':' && *(s + (i + 1)) == ':') { emptySegmentCount++; prev = 'e', // empty i++; continue; } if (*(s + i) == ':') { if (err) { _laaf_util_snprintf_realloc (err, NULL, 0, "can't start with a single ':'"); } return 0; } } if (prev == 'h') { /* hex */ if (IS_HEX (*(s + i))) { curSegmentLength++; if (loopback >= 0) { if (!IS_DIGIT (*(s + i))) { loopback = -1; } else { loopback += (*(s + i) - '0'); } } continue; } if (*(s + i) == '.') { /* period */ int octet = atoi (curSegmentStart); if (octet > 255) { if (err) { _laaf_util_snprintf_realloc (err, NULL, 0, "ipv4 portion octet %i is too high : %.*s", (ipv4portion), curSegmentLength, curSegmentStart); } return 0; } // debug( "%i", octet ); prev = 'p'; ipv4portion++; continue; } if (i == size || *(s + i) == ':') { if (curSegmentLength > 4) { if (err) { _laaf_util_snprintf_realloc (err, NULL, 0, "segment %i is too long : %.*s", (segmentCount - 1), curSegmentLength, curSegmentStart); } return 0; } /* here we can parse segment */ curSegmentStart = NULL; curSegmentLength = 0; if (i < size && *(s + (i + 1)) == ':') { emptySegmentCount++; prev = 'e', /* empty "::" */ i++; } else if (i + 1 == size) { if (err) { _laaf_util_snprintf_realloc (err, NULL, 0, "can't end with a single ':'"); } return 0; } else { prev = 'c'; /* colon ":" */ } continue; } } if (prev == 'e' || prev == 'c') { /* empty or colon */ if (IS_HEX (*(s + i))) { segmentCount++; curSegmentStart = s + i; curSegmentLength++; prev = 'h'; /* hex */ if (loopback >= 0) { if (!IS_DIGIT (*(s + i))) { loopback = -1; } else { loopback += (*(s + i) - '0'); } } continue; } if (*(s + i) == ':') { if (err) { _laaf_util_snprintf_realloc (err, NULL, 0, "can't have more than two successive ':'"); } return 0; } } if (prev == 'p') { if (IS_DIGIT (*(s + i))) { curSegmentStart = s + i; prev = 'd'; continue; } if (*(s + i) == '.') { if (err) { _laaf_util_snprintf_realloc (err, NULL, 0, "can't have successive '.'"); } return 0; } } if (prev == 'd') { if (IS_DIGIT (*(s + i))) { prev = 'd'; continue; } if (i == size || *(s + i) == '.') { /* period */ int octet = atoi (curSegmentStart); if (octet > 255) { if (err) { _laaf_util_snprintf_realloc (err, NULL, 0, "ipv4 portion octet %i is too high : %.*s", (ipv4portion), curSegmentLength, curSegmentStart); } return 0; } // debug( "%i", octet ); if (i + 1 == size) { if (err) { _laaf_util_snprintf_realloc (err, NULL, 0, "can't end with a single '.'"); } return 0; } prev = 'p'; ipv4portion++; continue; } } if (i == size) { break; } if (err) { _laaf_util_snprintf_realloc (err, NULL, 0, "illegal char '%c' (0x%02x)", *(s + i), *(s + i)); } return 0; } // debug( "segments : %i", segmentCount ); // debug( "empty segments : %i", emptySegmentCount ); // debug( "ipv4portion : %i", ipv4portion ); if (ipv4portion > 4) { if (err) { _laaf_util_snprintf_realloc (err, NULL, 0, "too many octets in ipv4 portion"); } return 0; } if (ipv4portion > 0 && ipv4portion < 4) { if (err) { _laaf_util_snprintf_realloc (err, NULL, 0, "not enough octets in ipv4 portion"); } return 0; } if (emptySegmentCount + (segmentCount / 2) + ipv4portion > 8) { if (err) { _laaf_util_snprintf_realloc (err, NULL, 0, "too many segments"); } return 0; } if (emptySegmentCount == 0 && (((ipv4portion / 2) + segmentCount) < 8)) { if (err) { _laaf_util_snprintf_realloc (err, NULL, 0, "not enough segments"); } return 0; } // debug( "LOCALHOST >>>>>>> %i", loopback ); /* * 1: valid ipv6 address * 2: valid ipv6 address and is loopback */ return (loopback == 1) ? 2 : 1; } static void _uri_scheme2schemeType (struct uri* uri) { if (strcmp (uri->scheme, "afp") == 0) { uri->scheme_t = URI_SCHEME_T_AFP; } else if (strcmp (uri->scheme, "cifs") == 0) { uri->scheme_t = URI_SCHEME_T_CIFS; } else if (strcmp (uri->scheme, "data") == 0) { uri->scheme_t = URI_SCHEME_T_DATA; } else if (strcmp (uri->scheme, "dns") == 0) { uri->scheme_t = URI_SCHEME_T_DNS; } else if (strcmp (uri->scheme, "file") == 0) { uri->scheme_t = URI_SCHEME_T_FILE; } else if (strcmp (uri->scheme, "ftp") == 0) { uri->scheme_t = URI_SCHEME_T_FTP; } else if (strcmp (uri->scheme, "http") == 0) { uri->scheme_t = URI_SCHEME_T_HTTP; } else if (strcmp (uri->scheme, "https") == 0) { uri->scheme_t = URI_SCHEME_T_HTTPS; } else if (strcmp (uri->scheme, "imap") == 0) { uri->scheme_t = URI_SCHEME_T_IMAP; } else if (strcmp (uri->scheme, "irc") == 0) { uri->scheme_t = URI_SCHEME_T_IRC; } else if (strcmp (uri->scheme, "mailto") == 0) { uri->scheme_t = URI_SCHEME_T_MAILTO; } else if (strcmp (uri->scheme, "nfs") == 0) { uri->scheme_t = URI_SCHEME_T_NFS; } else if (strcmp (uri->scheme, "pop") == 0) { uri->scheme_t = URI_SCHEME_T_POP; } else if (strcmp (uri->scheme, "rtsp") == 0) { uri->scheme_t = URI_SCHEME_T_RTSP; } else if (strcmp (uri->scheme, "sftp") == 0) { uri->scheme_t = URI_SCHEME_T_SFTP; } else if (strcmp (uri->scheme, "sip") == 0) { uri->scheme_t = URI_SCHEME_T_SIP; } else if (strcmp (uri->scheme, "smb") == 0) { uri->scheme_t = URI_SCHEME_T_SMB; } else if (strcmp (uri->scheme, "ssh") == 0) { uri->scheme_t = URI_SCHEME_T_SSH; } else if (strcmp (uri->scheme, "tel") == 0) { uri->scheme_t = URI_SCHEME_T_TEL; } else if (strcmp (uri->scheme, "telnet") == 0) { uri->scheme_t = URI_SCHEME_T_TELNET; } else { uri->scheme_t = URI_SCHEME_T_UNKNOWN; } } static int _laaf_util_snprintf_realloc (char** str, size_t* size, size_t offset, const char* format, ...) { size_t tmpsize = 0; if (!size) { size = &tmpsize; } int retval, needed; va_list ap; va_start (ap, format); while (0 <= (retval = vsnprintf ((*str) + offset, (*size) - offset, format, ap)) && (int64_t) ((*size) - offset) < (needed = retval + 1)) { va_end (ap); *size *= 2; if ((int64_t) ((*size) - offset) < needed) *size = needed; char* p = realloc (*str, *size); if (p) { *str = p; } else { free (*str); *str = NULL; *size = 0; return -1; } va_start (ap, format); } va_end (ap); return retval; } #ifdef BUILD_URI_TEST static int _uri_cmp (const struct uri* a, const struct uri* b) { int differenciesCount = 0; if (a == NULL || b == NULL) { return -1; } // if ( (strcmp((a->scheme) ? a->scheme : "", (b->scheme) ? b->scheme : "") != 0 ) ) { // differenciesCount++; // } if ((strcmp ((a->userinfo) ? a->userinfo : "", (b->userinfo) ? b->userinfo : "") != 0)) { differenciesCount++; } if ((strcmp ((a->user) ? a->user : "", (b->user) ? b->user : "") != 0)) { differenciesCount++; } if ((strcmp ((a->pass) ? a->pass : "", (b->pass) ? b->pass : "") != 0)) { differenciesCount++; } if ((strcmp ((a->host) ? a->host : "", (b->host) ? b->host : "") != 0)) { differenciesCount++; } if ((strcmp ((a->path) ? a->path : "", (b->path) ? b->path : "") != 0)) { differenciesCount++; } if ((strcmp ((a->query) ? a->query : "", (b->query) ? b->query : "") != 0)) { differenciesCount++; } if ((strcmp ((a->fragment) ? a->fragment : "", (b->fragment) ? b->fragment : "") != 0)) { differenciesCount++; } if (a->port != b->port) { differenciesCount++; } if (a->scheme_t != b->scheme_t) { differenciesCount++; } if (a->flags != b->flags) { differenciesCount++; } return differenciesCount; } static void _uri_dump_diff (struct uri* a, struct uri* b, int totalDifferencies) { int differenciesCount = 0; if (a == NULL || b == NULL) { return; } // if ( (strcmp((a->scheme) ? a->scheme : "", (b->scheme) ? b->scheme : "") != 0 ) ) { // printf(" \x1b[38;5;242m\u2502\x1b[0m \x1b[38;5;124m%s .scheme : \"%s\" (expected: \"%s\")\n", (++differenciesCount < totalDifferencies) ? "\u251c\u2500\u2500\u25fb" : "\u2514\u2500\u2500\u25fb", a->scheme, b->scheme ); // } if ((strcmp ((a->userinfo) ? a->userinfo : "", (b->userinfo) ? b->userinfo : "") != 0)) { printf (" \x1b[38;5;242m\u2502\x1b[0m \x1b[38;5;124m%s .userinfo : \"%s\" (expected: \"%s\")\n", (++differenciesCount < totalDifferencies) ? "\u251c\u2500\u2500\u25fb" : "\u2514\u2500\u2500\u25fb", a->userinfo, b->userinfo); } if ((strcmp ((a->user) ? a->user : "", (b->user) ? b->user : "") != 0)) { printf (" \x1b[38;5;242m\u2502\x1b[0m \x1b[38;5;124m%s .user : \"%s\" (expected: \"%s\")\n", (++differenciesCount < totalDifferencies) ? "\u251c\u2500\u2500\u25fb" : "\u2514\u2500\u2500\u25fb", a->user, b->user); } if ((strcmp ((a->pass) ? a->pass : "", (b->pass) ? b->pass : "") != 0)) { printf (" \x1b[38;5;242m\u2502\x1b[0m \x1b[38;5;124m%s .pass : \"%s\" (expected: \"%s\")\n", (++differenciesCount < totalDifferencies) ? "\u251c\u2500\u2500\u25fb" : "\u2514\u2500\u2500\u25fb", a->pass, b->pass); } if ((strcmp ((a->host) ? a->host : "", (b->host) ? b->host : "") != 0)) { printf (" \x1b[38;5;242m\u2502\x1b[0m \x1b[38;5;124m%s .host : \"%s\" (expected: \"%s\")\n", (++differenciesCount < totalDifferencies) ? "\u251c\u2500\u2500\u25fb" : "\u2514\u2500\u2500\u25fb", a->host, b->host); } if ((strcmp ((a->path) ? a->path : "", (b->path) ? b->path : "") != 0)) { printf (" \x1b[38;5;242m\u2502\x1b[0m \x1b[38;5;124m%s .path : \"%s\" (expected: \"%s\")\n", (++differenciesCount < totalDifferencies) ? "\u251c\u2500\u2500\u25fb" : "\u2514\u2500\u2500\u25fb", a->path, b->path); } if ((strcmp ((a->query) ? a->query : "", (b->query) ? b->query : "") != 0)) { printf (" \x1b[38;5;242m\u2502\x1b[0m \x1b[38;5;124m%s .query : \"%s\" (expected: \"%s\")\n", (++differenciesCount < totalDifferencies) ? "\u251c\u2500\u2500\u25fb" : "\u2514\u2500\u2500\u25fb", a->query, b->query); } if ((strcmp ((a->fragment) ? a->fragment : "", (b->fragment) ? b->fragment : "") != 0)) { printf (" \x1b[38;5;242m\u2502\x1b[0m \x1b[38;5;124m%s .fragment : \"%s\" (expected: \"%s\")\n", (++differenciesCount < totalDifferencies) ? "\u251c\u2500\u2500\u25fb" : "\u2514\u2500\u2500\u25fb", a->fragment, b->fragment); } if (a->port != b->port) { printf (" \x1b[38;5;242m\u2502\x1b[0m \x1b[38;5;124m%s .port : %i (expected: %i)\n", (++differenciesCount < totalDifferencies) ? "\u251c\u2500\u2500\u25fb" : "\u2514\u2500\u2500\u25fb", a->port, b->port); } if (a->scheme_t != b->scheme_t) { printf (" \x1b[38;5;242m\u2502\x1b[0m \x1b[38;5;124m%s .scheme_t : %i (expected: %i)\n", (++differenciesCount < totalDifferencies) ? "\u251c\u2500\u2500\u25fb" : "\u2514\u2500\u2500\u25fb", a->scheme_t, b->scheme_t); } if (a->flags != b->flags) { printf (" \x1b[38;5;242m\u2502\x1b[0m \x1b[38;5;124m%s .flags : %i (expected: %i)\n", (++differenciesCount < totalDifferencies) ? "\u251c\u2500\u2500\u25fb" : "\u2514\u2500\u2500\u25fb", a->flags, b->flags); } } static int _uri_test (const char* uristr, enum uri_option optflags, struct uri expectedRes, int line) { struct uri* uri = uriParse (uristr, optflags); int differenciesCount = 0; if ((differenciesCount = _uri_cmp (uri, &expectedRes)) == 0) { printf ("\x1b[38;5;242m"); // dark gray printf ("%05i", line); printf ("\x1b[0m"); printf ("\x1b[38;5;242m %s \x1b[0m", "\u2502"); printf ("\x1b[38;5;120m"); // green printf ("[ok] "); printf ("\x1b[0m"); printf ("\x1b[38;5;242m"); // dark gray printf ("%s", uristr); printf ("\x1b[0m"); printf ("\n"); } else { printf ("\x1b[38;5;124m"); // red printf ("%05i", line); printf ("\x1b[0m"); printf ("\x1b[38;5;242m %s \x1b[0m", "\u2502"); printf ("\x1b[38;5;124m"); // red printf ("[er] "); printf ("\x1b[0m"); printf ("\x1b[38;5;242m"); // dark gray printf ("%s", uristr); printf ("\x1b[0m"); printf ("\n"); printf ("\x1b[38;5;124m"); // red _uri_dump_diff (uri, &expectedRes, differenciesCount); printf ("\x1b[0m"); printf (" \x1b[38;5;242m\u2502\x1b[0m\n"); } uriFree (uri); return differenciesCount; } int main (void) { int rc = 0; // rc += _uri_test( "", URI_OPT_NONE, (struct uri){ .scheme_t = URI_SCHEME_T_UNKNOWN, .host = NULL, .port = 0, .path = NULL, .query = NULL, .fragment = NULL }, __LINE__ ); rc += _uri_test ("https://www.server.com", URI_OPT_NONE, (struct uri){ .scheme_t = URI_SCHEME_T_HTTPS, .host = "www.server.com", .port = 0, .path = NULL, .query = NULL, .fragment = NULL, .flags = URI_T_HOST_REGNAME }, __LINE__); rc += _uri_test ("https://user:pass@www.server.com", URI_OPT_NONE, (struct uri){ .scheme_t = URI_SCHEME_T_HTTPS, .userinfo = "user:pass", .user = "user", .pass = "pass", .host = "www.server.com", .port = 0, .path = NULL, .query = NULL, .fragment = NULL, .flags = URI_T_HOST_REGNAME }, __LINE__); rc += _uri_test ("HTTPS://www.server.com", URI_OPT_NONE, (struct uri){ .scheme_t = URI_SCHEME_T_HTTPS, .host = "www.server.com", .port = 0, .path = NULL, .query = NULL, .fragment = NULL, .flags = URI_T_HOST_REGNAME }, __LINE__); rc += _uri_test ("hTtPs://www.server.com", URI_OPT_NONE, (struct uri){ .scheme_t = URI_SCHEME_T_HTTPS, .host = "www.server.com", .port = 0, .path = NULL, .query = NULL, .fragment = NULL, .flags = URI_T_HOST_REGNAME }, __LINE__); rc += _uri_test ("https://www.server.com:8080", URI_OPT_NONE, (struct uri){ .scheme_t = URI_SCHEME_T_HTTPS, .host = "www.server.com", .port = 8080, .path = NULL, .query = NULL, .fragment = NULL, .flags = URI_T_HOST_REGNAME }, __LINE__); rc += _uri_test ("https://www.server.com:8080?foo=bar", URI_OPT_NONE, (struct uri){ .scheme_t = URI_SCHEME_T_HTTPS, .host = "www.server.com", .port = 8080, .path = NULL, .query = "foo=bar", .fragment = NULL, .flags = URI_T_HOST_REGNAME }, __LINE__); rc += _uri_test ("https://www.server.com:8080#anchor", URI_OPT_NONE, (struct uri){ .scheme_t = URI_SCHEME_T_HTTPS, .host = "www.server.com", .port = 8080, .path = NULL, .query = NULL, .fragment = "anchor", .flags = URI_T_HOST_REGNAME }, __LINE__); rc += _uri_test ("https://www.server.com/", URI_OPT_NONE, (struct uri){ .scheme_t = URI_SCHEME_T_HTTPS, .host = "www.server.com", .port = 0, .path = "/", .query = NULL, .fragment = NULL, .flags = URI_T_HOST_REGNAME }, __LINE__); rc += _uri_test ("https://www.server.com/?foo=bar", URI_OPT_NONE, (struct uri){ .scheme_t = URI_SCHEME_T_HTTPS, .host = "www.server.com", .port = 0, .path = "/", .query = "foo=bar", .fragment = NULL, .flags = URI_T_HOST_REGNAME }, __LINE__); rc += _uri_test ("https://www.server.com/////?foo=bar", URI_OPT_NONE, (struct uri){ .scheme_t = URI_SCHEME_T_HTTPS, .host = "www.server.com", .port = 0, .path = "/", .query = "foo=bar", .fragment = NULL, .flags = URI_T_HOST_REGNAME }, __LINE__); rc += _uri_test ("https://www.server.com///////", URI_OPT_NONE, (struct uri){ .scheme_t = URI_SCHEME_T_HTTPS, .host = "www.server.com", .port = 0, .path = "/", .query = NULL, .fragment = NULL, .flags = URI_T_HOST_REGNAME }, __LINE__); rc += _uri_test ("https://www.server.com?foo=bar", URI_OPT_NONE, (struct uri){ .scheme_t = URI_SCHEME_T_HTTPS, .host = "www.server.com", .port = 0, .path = NULL, .query = "foo=bar", .fragment = NULL, .flags = URI_T_HOST_REGNAME }, __LINE__); rc += _uri_test ("https://www.server.com#anchor", URI_OPT_NONE, (struct uri){ .scheme_t = URI_SCHEME_T_HTTPS, .host = "www.server.com", .port = 0, .path = NULL, .query = NULL, .fragment = "anchor", .flags = URI_T_HOST_REGNAME }, __LINE__); rc += _uri_test ("https://www.server.com/path/to/file.html?foo=bar&foo2=bar2#anchor", URI_OPT_NONE, (struct uri){ .scheme_t = URI_SCHEME_T_HTTPS, .host = "www.server.com", .port = 0, .path = "/path/to/file.html", .query = "foo=bar&foo2=bar2", .fragment = "anchor", .flags = URI_T_HOST_REGNAME }, __LINE__); rc += _uri_test ("https://www.server.com:80/", URI_OPT_NONE, (struct uri){ .scheme_t = URI_SCHEME_T_HTTPS, .host = "www.server.com", .port = 80, .path = "/", .query = NULL, .fragment = NULL, .flags = URI_T_HOST_REGNAME }, __LINE__); rc += _uri_test ("https://www.server.com:/", URI_OPT_NONE, (struct uri){ .scheme_t = URI_SCHEME_T_HTTPS, .host = "www.server.com", .port = 0, .path = "/", .query = NULL, .fragment = NULL, .flags = URI_T_HOST_REGNAME }, __LINE__); rc += _uri_test ("https://www.server.com:", URI_OPT_NONE, (struct uri){ .scheme_t = URI_SCHEME_T_HTTPS, .host = "www.server.com", .port = 0, .path = "", .query = NULL, .fragment = NULL, .flags = URI_T_HOST_REGNAME }, __LINE__); rc += _uri_test ("https://[8:3:1:2:1234:5678::]:8080/ipv6", URI_OPT_NONE, (struct uri){ .scheme_t = URI_SCHEME_T_HTTPS, .host = "8:3:1:2:1234:5678::", .port = 8080, .path = "/ipv6", .query = NULL, .fragment = NULL, .flags = URI_T_HOST_IPV6 }, __LINE__); rc += _uri_test ("https://[2001:db8:0:85a3::ac1f:8001]:8080/ipv6", URI_OPT_NONE, (struct uri){ .scheme_t = URI_SCHEME_T_HTTPS, .host = "2001:db8:0:85a3::ac1f:8001", .port = 8080, .path = "/ipv6", .query = NULL, .fragment = NULL, .flags = URI_T_HOST_IPV6 }, __LINE__); rc += _uri_test ("https://user:pass@[2001:db8:3333:4444:5555:6666:1.2.3.4]:8080/ipv6", URI_OPT_NONE, (struct uri){ .scheme_t = URI_SCHEME_T_HTTPS, .userinfo = "user:pass", .user = "user", .pass = "pass", .host = "2001:db8:3333:4444:5555:6666:1.2.3.4", .port = 8080, .path = "/ipv6", .query = NULL, .fragment = NULL, .flags = URI_T_HOST_IPV6 }, __LINE__); rc += _uri_test ("https://192.168.0.1:8080/ipv4", URI_OPT_NONE, (struct uri){ .scheme_t = URI_SCHEME_T_HTTPS, .host = "192.168.0.1", .port = 8080, .path = "/ipv4", .query = NULL, .fragment = NULL, .flags = URI_T_HOST_IPV4 }, __LINE__); rc += _uri_test ("https://127.0.0.1:8080/ipv4loopback", URI_OPT_NONE, (struct uri){ .scheme_t = URI_SCHEME_T_HTTPS, .host = "127.0.0.1", .port = 8080, .path = "/ipv4loopback", .query = NULL, .fragment = NULL, .flags = URI_T_HOST_IPV4 | URI_T_LOCALHOST }, __LINE__); rc += _uri_test ("https://localhost:8080/loopback", URI_OPT_NONE, (struct uri){ .scheme_t = URI_SCHEME_T_HTTPS, .host = "localhost", .port = 8080, .path = "/loopback", .query = NULL, .fragment = NULL, .flags = URI_T_LOCALHOST }, __LINE__); rc += _uri_test ("https://[0:0:0:0:0:0:0:1]:8080/ipv6loopback", URI_OPT_NONE, (struct uri){ .scheme_t = URI_SCHEME_T_HTTPS, .host = "0:0:0:0:0:0:0:1", .port = 8080, .path = "/ipv6loopback", .query = NULL, .fragment = NULL, .flags = URI_T_HOST_IPV6 | URI_T_LOCALHOST }, __LINE__); rc += _uri_test ("https://[::0:0:0:1]:8080/ipv6loopback", URI_OPT_NONE, (struct uri){ .scheme_t = URI_SCHEME_T_HTTPS, .host = "::0:0:0:1", .port = 8080, .path = "/ipv6loopback", .query = NULL, .fragment = NULL, .flags = URI_T_HOST_IPV6 | URI_T_LOCALHOST }, __LINE__); rc += _uri_test ("https://[::0:0000:0:001]:8080/ipv6loopback", URI_OPT_NONE, (struct uri){ .scheme_t = URI_SCHEME_T_HTTPS, .host = "::0:0000:0:001", .port = 8080, .path = "/ipv6loopback", .query = NULL, .fragment = NULL, .flags = URI_T_HOST_IPV6 | URI_T_LOCALHOST }, __LINE__); rc += _uri_test ("https://[::1]:8080/ipv6loopback", URI_OPT_NONE, (struct uri){ .scheme_t = URI_SCHEME_T_HTTPS, .host = "::1", .port = 8080, .path = "/ipv6loopback", .query = NULL, .fragment = NULL, .flags = URI_T_HOST_IPV6 | URI_T_LOCALHOST }, __LINE__); rc += _uri_test ("https://user:pass@192.168.0.1:8080/ipv4", URI_OPT_NONE, (struct uri){ .scheme_t = URI_SCHEME_T_HTTPS, .userinfo = "user:pass", .user = "user", .pass = "pass", .host = "192.168.0.1", .port = 8080, .path = "/ipv4", .query = NULL, .fragment = NULL, .flags = URI_T_HOST_IPV4 }, __LINE__); rc += _uri_test ("file://///C:/windows/path", URI_OPT_NONE, (struct uri){ .scheme_t = URI_SCHEME_T_FILE, .host = NULL, .port = 0, .path = "C:/windows/path", .query = NULL, .fragment = NULL, .flags = URI_T_LOCALHOST }, __LINE__); rc += _uri_test ("file:C:/windows/path", URI_OPT_NONE, (struct uri){ .scheme_t = URI_SCHEME_T_FILE, .host = NULL, .port = 0, .path = "C:/windows/path", .query = NULL, .fragment = NULL, .flags = URI_T_LOCALHOST }, __LINE__); rc += _uri_test ("file:/C:/windows/path", URI_OPT_NONE, (struct uri){ .scheme_t = URI_SCHEME_T_FILE, .host = NULL, .port = 0, .path = "C:/windows/path", .query = NULL, .fragment = NULL, .flags = URI_T_LOCALHOST }, __LINE__); rc += _uri_test ("file:///C:/windows/path", URI_OPT_NONE, (struct uri){ .scheme_t = URI_SCHEME_T_FILE, .host = NULL, .port = 0, .path = "C:/windows/path", .query = NULL, .fragment = NULL, .flags = URI_T_LOCALHOST }, __LINE__); rc += _uri_test ("file://?/C:/windows/path", URI_OPT_NONE, (struct uri){ .scheme_t = URI_SCHEME_T_FILE, .host = NULL, .port = 0, .path = "C:/windows/path", .query = NULL, .fragment = NULL, .flags = URI_T_LOCALHOST }, __LINE__); rc += _uri_test ("file://./C:/windows/path", URI_OPT_NONE, (struct uri){ .scheme_t = URI_SCHEME_T_FILE, .host = NULL, .port = 0, .path = "C:/windows/path", .query = NULL, .fragment = NULL, .flags = URI_T_LOCALHOST }, __LINE__); // Examples from AAF files external essences rc += _uri_test ("file:///C:/Users/username/Downloads/441-16b.wav", URI_OPT_NONE, (struct uri){ .scheme_t = URI_SCHEME_T_FILE, .host = NULL, .port = 0, .path = "C:/Users/username/Downloads/441-16b.wav", .query = NULL, .fragment = NULL, .flags = URI_T_LOCALHOST }, __LINE__); rc += _uri_test ("file://?/E:/ADPAAF/Sequence A Rendu.mxf", URI_OPT_NONE, (struct uri){ .scheme_t = URI_SCHEME_T_FILE, .host = NULL, .port = 0, .path = "E:/ADPAAF/Sequence A Rendu.mxf", .query = NULL, .fragment = NULL, .flags = URI_T_LOCALHOST }, __LINE__); rc += _uri_test ("file:////C:/Users/username/Desktop/TEST2977052.aaf", URI_OPT_NONE, (struct uri){ .scheme_t = URI_SCHEME_T_FILE, .host = NULL, .port = 0, .path = "C:/Users/username/Desktop/TEST2977052.aaf", .query = NULL, .fragment = NULL, .flags = URI_T_LOCALHOST }, __LINE__); rc += _uri_test ("file://localhost/Users/username/Music/fonk_2_3#04.wav", URI_OPT_NONE, (struct uri){ .scheme_t = URI_SCHEME_T_FILE, .host = "localhost", .port = 0, .path = "/Users/username/Music/fonk_2_3#04.wav", .query = NULL, .fragment = NULL, .flags = URI_T_LOCALHOST }, __LINE__); rc += _uri_test ("file://10.87.230.71/mixage/DR2/Avid MediaFiles/MXF/1/3572607.mxf", URI_OPT_NONE, (struct uri){ .scheme_t = URI_SCHEME_T_FILE, .host = "10.87.230.71", .port = 0, .path = "/mixage/DR2/Avid MediaFiles/MXF/1/3572607.mxf", .query = NULL, .fragment = NULL, .flags = URI_T_HOST_IPV4 }, __LINE__); rc += _uri_test ("file:///_system/Users/username/pt2MCCzmhsFRHQgdgsTMQX.mxf", URI_OPT_NONE, (struct uri){ .scheme_t = URI_SCHEME_T_FILE, .host = NULL, .port = 0, .path = "/_system/Users/username/pt2MCCzmhsFRHQgdgsTMQX.mxf", .query = NULL, .fragment = NULL, .flags = URI_T_LOCALHOST }, __LINE__); // URL Percent Decoding rc += _uri_test ("https://www.server.com/NON_DECODING/%C2%B0%2B%29%3D%C5%93%21%3A%3B%2C%3F.%2F%C2%A7%C3%B9%2A%24%C2%B5%C2%A3%7D%5D%E2%80%9C%23%7B%5B%7C%5E%40%5D%3C%3E", URI_OPT_NONE, (struct uri){ .scheme_t = URI_SCHEME_T_HTTPS, .host = "www.server.com", .port = 0, .path = "/NON_DECODING/%C2%B0%2B%29%3D%C5%93%21%3A%3B%2C%3F.%2F%C2%A7%C3%B9%2A%24%C2%B5%C2%A3%7D%5D%E2%80%9C%23%7B%5B%7C%5E%40%5D%3C%3E", .query = NULL, .fragment = NULL, .flags = URI_T_HOST_REGNAME }, __LINE__); rc += _uri_test ("https://www.server.com/DECODING/%C2%B0%2B%29%3D%C5%93%21%3A%3B%2C%3F.%2F%C2%A7%C3%B9%2A%24%C2%B5%C2%A3%7D%5D%E2%80%9C%23%7B%5B%7C%5E%40%5D%3C%3E", URI_OPT_DECODE_ALL, (struct uri){ .scheme_t = URI_SCHEME_T_HTTPS, .host = "www.server.com", .port = 0, .path = "/DECODING/°+)=œ!:;,?./§ù*$µ£}]“#{[|^@]<>", .query = NULL, .fragment = NULL, .flags = URI_T_HOST_REGNAME }, __LINE__); rc += _uri_test ("https://www.server.com/DECODING_UTF8/%E3%82%B5%E3%83%B3%E3%83%97%E3%83%AB%E7%B2%BE%E5%BA%A6%E7%B7%A8%E9%9B%86", URI_OPT_DECODE_ALL, (struct uri){ .scheme_t = URI_SCHEME_T_HTTPS, .userinfo = NULL, .user = NULL, .pass = NULL, .host = "www.server.com", .port = 0, .path = "/DECODING_UTF8/サンプル精度編集", .query = NULL, .fragment = NULL, .flags = URI_T_HOST_REGNAME }, __LINE__); // Examples from https://en.wikipedia.org/wiki/Uniform_Resource_Identifier rc += _uri_test ("tel:+1-816-555-1212", URI_OPT_NONE, (struct uri){ .scheme_t = URI_SCHEME_T_TEL, .userinfo = NULL, .user = NULL, .pass = NULL, .host = NULL, .port = 0, .path = "+1-816-555-1212", .query = NULL, .fragment = NULL, .flags = 0 }, __LINE__); rc += _uri_test ("mailto:John.Doe@example.com", URI_OPT_NONE, (struct uri){ .scheme_t = URI_SCHEME_T_MAILTO, .userinfo = NULL, .user = NULL, .pass = NULL, .host = NULL, .port = 0, .path = "John.Doe@example.com", .query = NULL, .fragment = NULL, .flags = 0 }, __LINE__); rc += _uri_test ("urn:oasis:names:specification:docbook:dtd:xml:4.1.2", URI_OPT_NONE, (struct uri){ .scheme_t = URI_SCHEME_T_UNKNOWN, .userinfo = NULL, .user = NULL, .pass = NULL, .host = NULL, .port = 0, .path = "oasis:names:specification:docbook:dtd:xml:4.1.2", .query = NULL, .fragment = NULL, .flags = 0 }, __LINE__); rc += _uri_test ("ldap://[2001:db8::7]/c=GB?objectClass?one", URI_OPT_NONE, (struct uri){ .scheme_t = URI_SCHEME_T_UNKNOWN, .userinfo = NULL, .user = NULL, .pass = NULL, .host = "2001:db8::7", .port = 0, .path = "/c=GB", .query = "objectClass?one", .fragment = NULL, .flags = URI_T_HOST_IPV6 }, __LINE__); rc += _uri_test ("news:comp.infosystems.www.servers.unix", URI_OPT_NONE, (struct uri){ .scheme_t = URI_SCHEME_T_UNKNOWN, .userinfo = NULL, .user = NULL, .pass = NULL, .host = NULL, .port = 0, .path = "comp.infosystems.www.servers.unix", .query = NULL, .fragment = NULL, .flags = 0 }, __LINE__); // rc += _uri_test( "xxxxxxxx", URI_OPT_NONE, (struct uri){ .scheme_t = URI_SCHEME_T_UNKNOWN, .userinfo = NULL, .user = NULL, .pass = NULL, .host = NULL, .port = 0, .path = NULL, .query = NULL, .fragment = NULL, .flags = 0 }, __LINE__ ); // rc += _uri_test( "xxxxxxxx", URI_OPT_NONE, (struct uri){ .scheme_t = URI_SCHEME_T_UNKNOWN, .userinfo = NULL, .user = NULL, .pass = NULL, .host = NULL, .port = 0, .path = NULL, .query = NULL, .fragment = NULL, .flags = 0 }, __LINE__ ); return rc; } #endif // BUILD_URI_TEST