/* ==================================================================== * The Apache Software License, Version 1.1 * * Copyright (c) 2000-2002 The Apache Software Foundation. All rights * reserved. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions * are met: * * 1. Redistributions of source code must retain the above copyright * notice, this list of conditions and the following disclaimer. * * 2. Redistributions in binary form must reproduce the above copyright * notice, this list of conditions and the following disclaimer in * the documentation and/or other materials provided with the * distribution. * * 3. The end-user documentation included with the redistribution, * if any, must include the following acknowledgment: * "This product includes software developed by the * Apache Software Foundation (http://www.apache.org/)." * Alternately, this acknowledgment may appear in the software itself, * if and wherever such third-party acknowledgments normally appear. * * 4. The names "Apache" and "Apache Software Foundation" must * not be used to endorse or promote products derived from this * software without prior written permission. For written * permission, please contact apache@apache.org. * * 5. Products derived from this software may not be called "Apache", * nor may "Apache" appear in their name, without prior written * permission of the Apache Software Foundation. * * THIS SOFTWARE IS PROVIDED ``AS IS'' AND ANY EXPRESSED OR IMPLIED * WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES * OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE * DISCLAIMED. IN NO EVENT SHALL THE APACHE SOFTWARE FOUNDATION OR * ITS CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, * SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT * LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF * USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND * ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, * OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT * OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF * SUCH DAMAGE. * ==================================================================== * * This software consists of voluntary contributions made by many * individuals on behalf of the Apache Software Foundation. For more * information on the Apache Software Foundation, please see * . * * Portions of this software are based upon public domain software * originally written at the National Center for Supercomputing Applications, * University of Illinois, Urbana-Champaign. */ /* * http_request.c: functions to get and process requests * * Rob McCool 3/21/93 * * Thoroughly revamped by rst for Apache. NB this file reads * best from the bottom up. * */ #include "apr_strings.h" #include "apr_file_io.h" #include "apr_fnmatch.h" #define APR_WANT_STRFUNC #include "apr_want.h" #define CORE_PRIVATE #include "ap_config.h" #include "httpd.h" #include "http_config.h" #include "http_request.h" #include "http_core.h" #include "http_protocol.h" #include "http_log.h" #include "http_main.h" #include "util_filter.h" #include "util_charset.h" #include "util_script.h" #include "mod_core.h" #if APR_HAVE_STDARG_H #include #endif APR_HOOK_STRUCT( APR_HOOK_LINK(translate_name) APR_HOOK_LINK(map_to_storage) APR_HOOK_LINK(check_user_id) APR_HOOK_LINK(fixups) APR_HOOK_LINK(type_checker) APR_HOOK_LINK(access_checker) APR_HOOK_LINK(auth_checker) APR_HOOK_LINK(insert_filter) APR_HOOK_LINK(create_request) ) AP_IMPLEMENT_HOOK_RUN_FIRST(int,translate_name, (request_rec *r), (r), DECLINED) AP_IMPLEMENT_HOOK_RUN_FIRST(int,map_to_storage, (request_rec *r), (r), DECLINED) AP_IMPLEMENT_HOOK_RUN_FIRST(int,check_user_id, (request_rec *r), (r), DECLINED) AP_IMPLEMENT_HOOK_RUN_ALL(int,fixups, (request_rec *r), (r), OK, DECLINED) AP_IMPLEMENT_HOOK_RUN_FIRST(int,type_checker, (request_rec *r), (r), DECLINED) AP_IMPLEMENT_HOOK_RUN_ALL(int,access_checker, (request_rec *r), (r), OK, DECLINED) AP_IMPLEMENT_HOOK_RUN_FIRST(int,auth_checker, (request_rec *r), (r), DECLINED) AP_IMPLEMENT_HOOK_VOID(insert_filter, (request_rec *r), (r)) AP_IMPLEMENT_HOOK_RUN_ALL(int, create_request, (request_rec *r), (r), OK, DECLINED) static int decl_die(int status, char *phase, request_rec *r) { if (status == DECLINED) { ap_log_rerror(APLOG_MARK, APLOG_CRIT, 0, r, "configuration error: couldn't %s: %s", phase, r->uri); return HTTP_INTERNAL_SERVER_ERROR; } else { return status; } } /* This is the master logic for processing requests. Do NOT duplicate * this logic elsewhere, or the security model will be broken by future * API changes. Each phase must be individually optimized to pick up * redundant/duplicate calls by subrequests, and redirects. */ AP_DECLARE(int) ap_process_request_internal(request_rec *r) { int file_req = (r->main && r->filename); int access_status; /* Ignore embedded %2F's in path for proxy requests */ if (!r->proxyreq && r->parsed_uri.path) { access_status = ap_unescape_url(r->parsed_uri.path); if (access_status) { return access_status; } } ap_getparents(r->uri); /* OK --- shrinking transformations... */ /* All file subrequests are a huge pain... they cannot bubble through the * next several steps. Only file subrequests are allowed an empty uri, * otherwise let translate_name kill the request. */ if (!file_req) { if ((access_status = ap_location_walk(r))) { return access_status; } if ((access_status = ap_run_translate_name(r))) { return decl_die(access_status, "translate", r); } } /* Reset to the server default config prior to running map_to_storage */ r->per_dir_config = r->server->lookup_defaults; if ((access_status = ap_run_map_to_storage(r))) { /* This request wasn't in storage (e.g. TRACE) */ return access_status; } /* Excluding file-specific requests with no 'true' URI... */ if (!file_req) { /* Rerun the location walk, which overrides any map_to_storage config. */ if ((access_status = ap_location_walk(r))) { return access_status; } } /* Only on the main request! */ if (r->main == NULL) { if ((access_status = ap_run_header_parser(r))) { return access_status; } } /* Skip authn/authz if the parent or prior request passed the authn/authz, * and that configuration didn't change (this requires optimized _walk() * functions in map_to_storage that use the same merge results given * identical input.) If the config changes, we must re-auth. */ if (r->main && (r->main->per_dir_config == r->per_dir_config)) { r->user = r->main->user; r->ap_auth_type = r->main->ap_auth_type; } else if (r->prev && (r->prev->per_dir_config == r->per_dir_config)) { r->user = r->prev->user; r->ap_auth_type = r->prev->ap_auth_type; } else { switch (ap_satisfies(r)) { case SATISFY_ALL: case SATISFY_NOSPEC: if ((access_status = ap_run_access_checker(r)) != 0) { return decl_die(access_status, "check access", r); } if (ap_some_auth_required(r)) { if (((access_status = ap_run_check_user_id(r)) != 0) || !ap_auth_type(r)) { return decl_die(access_status, ap_auth_type(r) ? "check user. No user file?" : "perform authentication. AuthType not set!", r); } if (((access_status = ap_run_auth_checker(r)) != 0) || !ap_auth_type(r)) { return decl_die(access_status, ap_auth_type(r) ? "check access. No groups file?" : "perform authentication. AuthType not set!", r); } } break; case SATISFY_ANY: if (((access_status = ap_run_access_checker(r)) != 0) || !ap_auth_type(r)) { if (!ap_some_auth_required(r)) { return decl_die(access_status, ap_auth_type(r) ? "check access" : "perform authentication. AuthType not set!", r); } if (((access_status = ap_run_check_user_id(r)) != 0) || !ap_auth_type(r)) { return decl_die(access_status, ap_auth_type(r) ? "check user. No user file?" : "perform authentication. AuthType not set!", r); } if (((access_status = ap_run_auth_checker(r)) != 0) || !ap_auth_type(r)) { return decl_die(access_status, ap_auth_type(r) ? "check access. No groups file?" : "perform authentication. AuthType not set!", r); } } break; } } /* XXX Must make certain the ap_run_type_checker short circuits mime * in mod-proxy for r->proxyreq && r->parsed_uri.scheme * && !strcmp(r->parsed_uri.scheme, "http") */ if ((access_status = ap_run_type_checker(r)) != 0) { return decl_die(access_status, "find types", r); } if ((access_status = ap_run_fixups(r)) != 0) { return access_status; } return OK; } /* Useful caching structures to repeat _walk/merge sequences as required * when a subrequest or redirect reuses substantially the same config. * * Directive order in the httpd.conf file and its Includes significantly * impact this optimization. Grouping common blocks at the front of the * config that are less likely to change between a request and * its subrequests, or between a request and its redirects reduced * the work of these functions significantly. */ typedef struct walk_walked_t { ap_conf_vector_t *matched; /* A dir_conf sections we matched */ ap_conf_vector_t *merged; /* The dir_conf merged result */ } walk_walked_t; typedef struct walk_cache_t { const char *cached; /* The identifier we matched */ ap_conf_vector_t **dir_conf_tested; /* The sections we matched against */ ap_conf_vector_t *dir_conf_merged; /* Base per_dir_config */ ap_conf_vector_t *per_dir_result; /* per_dir_config += walked result */ apr_array_header_t *walked; /* The list of walk_walked_t results */ } walk_cache_t; static walk_cache_t *prep_walk_cache(apr_size_t t, request_rec *r) { walk_cache_t *cache; void **note; /* Find the most relevant, recent entry to work from. That would be * this request (on the second call), or the parent request of a * subrequest, or the prior request of an internal redirect. Provide * this _walk()er with a copy it is allowed to munge. If there is no * parent or prior cached request, then create a new walk cache. */ note = ap_get_request_note(r, t); if (!note) { return NULL; } if (!(cache = *note)) { void **inherit_note; if ((r->main && ((inherit_note = ap_get_request_note(r->main, t))) && *inherit_note) || (r->prev && ((inherit_note = ap_get_request_note(r->prev, t))) && *inherit_note)) { cache = apr_pmemdup(r->pool, *inherit_note, sizeof(*cache)); cache->walked = apr_array_copy(r->pool, cache->walked); } else { cache = apr_pcalloc(r->pool, sizeof(*cache)); cache->walked = apr_array_make(r->pool, 4, sizeof(walk_walked_t)); } *note = cache; } return cache; } /***************************************************************** * * Getting and checking directory configuration. Also checks the * FollowSymlinks and FollowSymOwner stuff, since this is really the * only place that can happen (barring a new mid_dir_walk callout). * * We can't do it as an access_checker module function which gets * called with the final per_dir_config, since we could have a directory * with FollowSymLinks disabled, which contains a symlink to another * with a .htaccess file which turns FollowSymLinks back on --- and * access in such a case must be denied. So, whatever it is that * checks FollowSymLinks needs to know the state of the options as * they change, all the way down. */ /* * We don't want people able to serve up pipes, or unix sockets, or other * scary things. Note that symlink tests are performed later. */ static int check_safe_file(request_rec *r) { if (r->finfo.filetype == 0 /* doesn't exist */ || r->finfo.filetype == APR_DIR || r->finfo.filetype == APR_REG || r->finfo.filetype == APR_LNK) { return OK; } ap_log_rerror(APLOG_MARK, APLOG_ERR, 0, r, "object is not a file, directory or symlink: %s", r->filename); return HTTP_FORBIDDEN; } /* * resolve_symlink must _always_ be called on an APR_LNK file type! * It will resolve the actual target file type, modification date, etc, * and provide any processing required for symlink evaluation. * Path must already be cleaned, no trailing slash, no multi-slashes, * and don't call this on the root! * * Simply, the number of times we deref a symlink are minimal compared * to the number of times we had an extra lstat() since we 'weren't sure'. * * To optimize, we stat() anything when given (opts & OPT_SYM_LINKS), otherwise * we start off with an lstat(). Every lstat() must be dereferenced in case * it points at a 'nasty' - we must always rerun check_safe_file (or similar.) */ static int resolve_symlink(char *d, apr_finfo_t *lfi, int opts, apr_pool_t *p) { apr_finfo_t fi; int res; const char *savename; if (!(opts & (OPT_SYM_OWNER | OPT_SYM_LINKS))) { return HTTP_FORBIDDEN; } /* Save the name from the valid bits. */ savename = (lfi->valid & APR_FINFO_NAME) ? lfi->name : NULL; if (opts & OPT_SYM_LINKS) { if ((res = apr_stat(&fi, d, lfi->valid & ~(APR_FINFO_NAME | APR_FINFO_LINK), p)) != APR_SUCCESS) { return HTTP_FORBIDDEN; } /* Give back the target */ memcpy(lfi, &fi, sizeof(fi)); if (savename) { lfi->name = savename; lfi->valid |= APR_FINFO_NAME; } return OK; } /* OPT_SYM_OWNER only works if we can get the owner of * both the file and symlink. First fill in a missing * owner of the symlink, then get the info of the target. */ if (!(lfi->valid & APR_FINFO_OWNER)) { if ((res = apr_lstat(&fi, d, lfi->valid | APR_FINFO_OWNER, p)) != APR_SUCCESS) { return HTTP_FORBIDDEN; } } if ((res = apr_stat(&fi, d, lfi->valid & ~(APR_FINFO_NAME), p)) != APR_SUCCESS) { return HTTP_FORBIDDEN; } if (apr_compare_users(fi.user, lfi->user) != APR_SUCCESS) { return HTTP_FORBIDDEN; } /* Give back the target */ memcpy(lfi, &fi, sizeof(fi)); if (savename) { lfi->name = savename; lfi->valid |= APR_FINFO_NAME; } return OK; } /***************************************************************** * * Getting and checking directory configuration. Also checks the * FollowSymlinks and FollowSymOwner stuff, since this is really the * only place that can happen (barring a new mid_dir_walk callout). * * We can't do it as an access_checker module function which gets * called with the final per_dir_config, since we could have a directory * with FollowSymLinks disabled, which contains a symlink to another * with a .htaccess file which turns FollowSymLinks back on --- and * access in such a case must be denied. So, whatever it is that * checks FollowSymLinks needs to know the state of the options as * they change, all the way down. */ AP_DECLARE(int) ap_directory_walk(request_rec *r) { ap_conf_vector_t *now_merged = NULL; core_server_config *sconf = ap_get_module_config(r->server->module_config, &core_module); ap_conf_vector_t **sec_ent = (ap_conf_vector_t **) sconf->sec_dir->elts; int num_sec = sconf->sec_dir->nelts; walk_cache_t *cache; char *entry_dir; apr_status_t rv; /* XXX: Better (faster) tests needed!!! * * "OK" as a response to a real problem is not _OK_, but to allow broken * modules to proceed, we will permit the not-a-path filename to pass the * following two tests. This behavior may be revoked in future versions * of Apache. We still must catch it later if it's heading for the core * handler. Leave INFO notes here for module debugging. */ if (r->filename == NULL) { ap_log_rerror(APLOG_MARK, APLOG_INFO, 0, r, "Module bug? Request filename is missing for URI %s", r->uri); return OK; } /* Canonicalize the file path without resolving filename case or aliases * so we can begin by checking the cache for a recent directory walk. * This call will ensure we have an absolute path in the same pass. */ if ((rv = apr_filepath_merge(&entry_dir, NULL, r->filename, APR_FILEPATH_NOTRELATIVE, r->pool)) != APR_SUCCESS) { ap_log_rerror(APLOG_MARK, APLOG_INFO, 0, r, "Module bug? Request filename path %s is invalid or " "or not absolute for uri %s", r->filename, r->uri); return OK; } /* XXX Notice that this forces path_info to be canonical. That might * not be desired by all apps. However, some of those same apps likely * have significant security holes. */ r->filename = entry_dir; cache = prep_walk_cache(AP_NOTE_DIRECTORY_WALK, r); /* If this is not a dirent subrequest with a preconstructed * r->finfo value, then we can simply stat the filename to * save burning mega-cycles with unneeded stats - if this is * an exact file match. We don't care about failure... we * will stat by component failing this meager attempt. * * It would be nice to distinguish APR_ENOENT from other * types of failure, such as APR_ENOTDIR. We can do something * with APR_ENOENT, knowing that the path is good. */ if (!r->finfo.filetype || r->finfo.filetype == APR_LNK) { apr_stat(&r->finfo, r->filename, APR_FINFO_MIN, r->pool); /* some OSs will return APR_SUCCESS/APR_REG if we stat * a regular file but we have '/' at the end of the name; * * other OSs will return APR_ENOTDIR for that situation; * * handle it the same everywhere by simulating a failure * if it looks like a directory but really isn't */ if (r->finfo.filetype && r->finfo.filetype != APR_DIR && r->filename[strlen(r->filename) - 1] == '/') { r->finfo.filetype = 0; /* forget what we learned */ } } if (r->finfo.filetype == APR_REG) { entry_dir = ap_make_dirstr_parent(r->pool, entry_dir); } else if (r->filename[strlen(r->filename) - 1] != '/') { entry_dir = apr_pstrcat(r->pool, r->filename, "/", NULL); } /* If we have a file already matches the path of r->filename, * and the vhost's list of directory sections hasn't changed, * we can skip rewalking the directory_walk entries. */ if (cache->cached && ((r->finfo.filetype == APR_REG) || ((r->finfo.filetype == APR_DIR) && (!r->path_info || !*r->path_info))) && (cache->dir_conf_tested == sec_ent) && (strcmp(entry_dir, cache->cached) == 0)) { /* Well this looks really familiar! If our end-result (per_dir_result) * didn't change, we have absolutely nothing to do :) * Otherwise (as is the case with most dir_merged/file_merged requests) * we must merge our dir_conf_merged onto this new r->per_dir_config. */ if (r->per_dir_config == cache->per_dir_result) { return OK; } if (r->per_dir_config == cache->dir_conf_merged) { r->per_dir_config = cache->per_dir_result; return OK; } if (cache->walked->nelts) { now_merged = ((walk_walked_t*)cache->walked->elts) [cache->walked->nelts - 1].merged; } } else { /* We start now_merged from NULL since we want to build * a locations list that can be merged to any vhost. */ int sec_idx; int matches = cache->walked->nelts; walk_walked_t *last_walk = (walk_walked_t*)cache->walked->elts; core_dir_config *this_dir; allow_options_t opts; allow_options_t opts_add; allow_options_t opts_remove; overrides_t override; apr_finfo_t thisinfo; char *save_path_info; apr_size_t buflen; char *buf; unsigned int seg, startseg; /* Invariant: from the first time filename_len is set until * it goes out of scope, filename_len==strlen(r->filename) */ apr_size_t filename_len; #ifdef CASE_BLIND_FILESYSTEM apr_size_t canonical_len; #endif /* * We must play our own mimi-merge game here, for the few * running dir_config values we care about within dir_walk. * We didn't start the merge from r->per_dir_config, so we * accumulate opts and override as we merge, from the globals. */ this_dir = ap_get_module_config(r->per_dir_config, &core_module); opts = this_dir->opts; opts_add = this_dir->opts_add; opts_remove = this_dir->opts_remove; override = this_dir->override; /* Set aside path_info to merge back onto path_info later. * If r->filename is a directory, we must remerge the path_info, * before we continue! [Directories cannot, by defintion, have * path info. Either the next segment is not-found, or a file.] * * r->path_info tracks the unconsumed source path. * r->filename tracks the path as we process it */ if ((r->finfo.filetype == APR_DIR) && r->path_info && *r->path_info) { if ((rv = apr_filepath_merge(&r->path_info, r->filename, r->path_info, APR_FILEPATH_NOTABOVEROOT, r->pool)) != APR_SUCCESS) { ap_log_rerror(APLOG_MARK, APLOG_ERR, rv, r, "dir_walk error, path_info %s is not relative " "to the filename path %s for uri %s", r->path_info, r->filename, r->uri); return HTTP_INTERNAL_SERVER_ERROR; } save_path_info = NULL; } else { save_path_info = r->path_info; r->path_info = r->filename; } #ifdef CASE_BLIND_FILESYSTEM canonical_len = 0; while (r->canonical_filename && r->canonical_filename[canonical_len] && (r->canonical_filename[canonical_len] == r->path_info[canonical_len])) { ++canonical_len; } while (canonical_len && ((r->canonical_filename[canonical_len - 1] != '/' && r->canonical_filename[canonical_len - 1]) || (r->path_info[canonical_len - 1] != '/' && r->path_info[canonical_len - 1]))) { --canonical_len; } /* * Now build r->filename component by component, starting * with the root (on Unix, simply "/"). We will make a huge * assumption here for efficiency, that any canonical path * already given included a canonical root. */ rv = apr_filepath_root((const char **)&r->filename, (const char **)&r->path_info, canonical_len ? 0 : APR_FILEPATH_TRUENAME, r->pool); filename_len = strlen(r->filename); /* * Bad assumption above? If the root's length is longer * than the canonical length, then it cannot be trusted as * a truename. So try again, this time more seriously. */ if ((rv == APR_SUCCESS) && canonical_len && (filename_len > canonical_len)) { rv = apr_filepath_root((const char **)&r->filename, (const char **)&r->path_info, APR_FILEPATH_TRUENAME, r->pool); filename_len = strlen(r->filename); canonical_len = 0; } #else /* ndef CASE_BLIND_FILESYSTEM, really this simple for Unix today; */ rv = apr_filepath_root((const char **)&r->filename, (const char **)&r->path_info, 0, r->pool); filename_len = strlen(r->filename); #endif if (rv != APR_SUCCESS) { ap_log_rerror(APLOG_MARK, APLOG_ERR, rv, r, "dir_walk error, could not determine the root " "path of filename %s%s for uri %s", r->filename, r->path_info, r->uri); return HTTP_INTERNAL_SERVER_ERROR; } /* Working space for terminating null and an extra / is required. */ buflen = filename_len + strlen(r->path_info) + 2; buf = apr_palloc(r->pool, buflen); memcpy(buf, r->filename, filename_len + 1); r->filename = buf; thisinfo.valid = APR_FINFO_TYPE; thisinfo.filetype = APR_DIR; /* It's the root, of course it's a dir */ /* * seg keeps track of which segment we've copied. * sec_idx keeps track of which section we're on, since sections are * ordered by number of segments. See core_reorder_directories */ startseg = seg = ap_count_dirs(r->filename); sec_idx = 0; /* * Go down the directory hierarchy. Where we have to check for * symlinks, do so. Where a .htaccess file has permission to * override anything, try to find one. */ do { int res; char *seg_name; char *delim; int temp_slash=0; /* We have no trailing slash, but we sure would appreciate one. * However, we don't want to append a / our first time through. */ if ((seg > startseg) && r->filename[filename_len-1] != '/') { r->filename[filename_len++] = '/'; r->filename[filename_len] = 0; temp_slash=1; } /* Begin *this* level by looking for matching sections * from the server config. */ for (; sec_idx < num_sec; ++sec_idx) { ap_conf_vector_t *entry_config = sec_ent[sec_idx]; core_dir_config *entry_core; entry_core = ap_get_module_config(entry_config, &core_module); /* No more possible matches for this many segments? * We are done when we find relative/regex/longer components. */ if (entry_core->r || entry_core->d_components > seg) { break; } /* We will never skip '0' element components, e.g. plain old * , and are classified as zero * so that Win32/Netware/OS2 etc all pick them up. * Otherwise, skip over the mismatches. */ if (entry_core->d_components && ((entry_core->d_components < seg) || (entry_core->d_is_fnmatch ? (apr_fnmatch(entry_core->d, r->filename, FNM_PATHNAME) != APR_SUCCESS) : (strcmp(r->filename, entry_core->d) != 0)))) { continue; } /* If we merged this same section last time, reuse it */ if (matches) { if (last_walk->matched == sec_ent[sec_idx]) { now_merged = last_walk->merged; ++last_walk; --matches; goto minimerge; } /* We fell out of sync. This is our own copy of walked, * so truncate the remaining matches and reset remaining. */ cache->walked->nelts -= matches; matches = 0; } if (now_merged) { now_merged = ap_merge_per_dir_configs(r->pool, now_merged, sec_ent[sec_idx]); } else { now_merged = sec_ent[sec_idx]; } last_walk = (walk_walked_t*)apr_array_push(cache->walked); last_walk->matched = sec_ent[sec_idx]; last_walk->merged = now_merged; /* Do a mini-merge to our globally-based running calculations of * core_dir->override and core_dir->opts, since now_merged * never considered the global config. Of course, if there is * no core config at this level, continue without a thought. * See core.c::merge_core_dir_configs() for explanation. */ minimerge: this_dir = ap_get_module_config(sec_ent[sec_idx], &core_module); if (!this_dir) { continue; } if (this_dir->opts & OPT_UNSET) { opts_add = (opts_add & ~this_dir->opts_remove) | this_dir->opts_add; opts_remove = (opts_remove & ~this_dir->opts_add) | this_dir->opts_remove; opts = (opts & ~opts_remove) | opts_add; } else { opts = this_dir->opts; opts_add = this_dir->opts_add; opts_remove = this_dir->opts_remove; } if (!(this_dir->override & OR_UNSET)) { override = this_dir->override; } } /* If .htaccess files are enabled, check for one, provided we * have reached a real path. */ if (seg >= startseg && override) { ap_conf_vector_t *htaccess_conf = NULL; res = ap_parse_htaccess(&htaccess_conf, r, override, apr_pstrdup(r->pool, r->filename), sconf->access_name); if (res) { return res; } if (htaccess_conf) { /* If we merged this same htaccess last time, reuse it... * this wouldn't work except that we cache the htaccess * sections for the lifetime of the request, so we match * the same conf. Good planning (no, pure luck ;) */ if (matches) { if (last_walk->matched == htaccess_conf) { now_merged = last_walk->merged; ++last_walk; --matches; goto minimerge2; } /* We fell out of sync. This is our own copy of walked, * so truncate the remaining matches and reset * remaining. */ cache->walked->nelts -= matches; matches = 0; } if (now_merged) { now_merged = ap_merge_per_dir_configs(r->pool, now_merged, htaccess_conf); } else { now_merged = htaccess_conf; } last_walk = (walk_walked_t*)apr_array_push(cache->walked); last_walk->matched = htaccess_conf; last_walk->merged = now_merged; /* Do a mini-merge to our globally-based running * calculations of core_dir->override and core_dir->opts, * since now_merged never considered the global config. * Of course, if there is no core config at this level, * continue without a thought. * See core.c::merge_core_dir_configs() for explanation. */ minimerge2: this_dir = ap_get_module_config(htaccess_conf, &core_module); if (this_dir) { if (this_dir->opts & OPT_UNSET) { opts_add = (opts_add & ~this_dir->opts_remove) | this_dir->opts_add; opts_remove = (opts_remove & ~this_dir->opts_add) | this_dir->opts_remove; opts = (opts & ~opts_remove) | opts_add; } else { opts = this_dir->opts; opts_add = this_dir->opts_add; opts_remove = this_dir->opts_remove; } if (!(this_dir->override & OR_UNSET)) { override = this_dir->override; } } } } /* That temporary trailing slash was useful, now drop it. */ if (temp_slash) { r->filename[--filename_len] = '\0'; } /* Time for all good things to come to an end? */ if (!r->path_info || !*r->path_info) { break; } /* Now it's time for the next segment... * We will assume the next element is an end node, and fix it up * below as necessary... */ seg_name = r->filename + filename_len; delim = strchr(r->path_info + (*r->path_info == '/' ? 1 : 0), '/'); if (delim) { size_t path_info_len = delim - r->path_info; *delim = '\0'; memcpy(seg_name, r->path_info, path_info_len + 1); filename_len += path_info_len; r->path_info = delim; *delim = '/'; } else { size_t path_info_len = strlen(r->path_info); memcpy(seg_name, r->path_info, path_info_len + 1); filename_len += path_info_len; r->path_info += path_info_len; } if (*seg_name == '/') ++seg_name; /* If nothing remained but a '/' string, we are finished */ if (!*seg_name) { break; } /* First optimization; * If...we knew r->filename was a file, and * if...we have strict (case-sensitive) filenames, or * we know the canonical_filename matches to _this_ name, and * if...we have allowed symlinks * skip the lstat and dummy up an APR_DIR value for thisinfo. */ if (r->finfo.filetype #ifdef CASE_BLIND_FILESYSTEM && (filename_len <= canonical_len) #endif && ((opts & (OPT_SYM_OWNER | OPT_SYM_LINKS)) == OPT_SYM_LINKS)) { thisinfo.filetype = APR_DIR; ++seg; continue; } /* We choose apr_lstat here, rather that apr_stat, so that we * capture this path object rather than its target. We will * replace the info with our target's info below. We especially * want the name of this 'link' object, not the name of its * target, if we are fixing the filename case/resolving aliases. */ rv = apr_lstat(&thisinfo, r->filename, APR_FINFO_MIN | APR_FINFO_NAME, r->pool); if (APR_STATUS_IS_ENOENT(rv)) { /* Nothing? That could be nice. But our directory * walk is done. */ thisinfo.filetype = APR_NOFILE; break; } else if (APR_STATUS_IS_EACCES(rv)) { ap_log_rerror(APLOG_MARK, APLOG_ERR, rv, r, "access to %s denied", r->uri); return r->status = HTTP_FORBIDDEN; } else if ((rv != APR_SUCCESS && rv != APR_INCOMPLETE) || !(thisinfo.valid & APR_FINFO_TYPE)) { /* If we hit ENOTDIR, we must have over-optimized, deny * rather than assume not found. */ ap_log_rerror(APLOG_MARK, APLOG_ERR, rv, r, "access to %s failed", r->uri); return r->status = HTTP_FORBIDDEN; } if ((res = check_safe_file(r))) { r->status = res; return res; } /* Fix up the path now if we have a name, and they don't agree */ if ((thisinfo.valid & APR_FINFO_NAME) && strcmp(seg_name, thisinfo.name)) { /* TODO: provide users an option that an internal/external * redirect is required here? We need to walk the URI and * filename in tandem to properly correlate these. */ strcpy(seg_name, thisinfo.name); filename_len = strlen(r->filename); } if (thisinfo.filetype == APR_LNK) { /* Is this a possibly acceptable symlink? */ if ((res = resolve_symlink(r->filename, &thisinfo, opts, r->pool)) != OK) { ap_log_rerror(APLOG_MARK, APLOG_ERR, 0, r, "Symbolic link not allowed: %s", r->filename); return r->status = res; } /* Ok, we are done with the link's info, test the real target */ if (thisinfo.filetype == APR_REG) { /* That was fun, nothing left for us here */ break; } else if (thisinfo.filetype != APR_DIR) { ap_log_rerror(APLOG_MARK, APLOG_ERR, 0, r, "symlink doesn't point to a file or " "directory: %s", r->filename); return r->status = HTTP_FORBIDDEN; } } ++seg; } while (thisinfo.filetype == APR_DIR); /* If we have _not_ optimized, this is the time to recover * the final stat result. */ if (!r->finfo.filetype || r->finfo.filetype == APR_LNK) { r->finfo = thisinfo; } /* Now splice the saved path_info back onto any new path_info */ if (save_path_info) { if (r->path_info && *r->path_info) { r->path_info = ap_make_full_path(r->pool, r->path_info, save_path_info); } else { r->path_info = save_path_info; } } /* * Now we'll deal with the regexes, note we pick up sec_idx * where we left off (we gave up after we hit entry_core->r) */ for (; sec_idx < num_sec; ++sec_idx) { core_dir_config *entry_core; entry_core = ap_get_module_config(sec_ent[sec_idx], &core_module); if (!entry_core->r) { continue; } if (ap_regexec(entry_core->r, r->filename, 0, NULL, REG_NOTEOL)) { continue; } /* If we merged this same section last time, reuse it */ if (matches) { if (last_walk->matched == sec_ent[sec_idx]) { now_merged = last_walk->merged; ++last_walk; --matches; goto minimerge; } /* We fell out of sync. This is our own copy of walked, * so truncate the remaining matches and reset remaining. */ cache->walked->nelts -= matches; matches = 0; } if (now_merged) { now_merged = ap_merge_per_dir_configs(r->pool, now_merged, sec_ent[sec_idx]); } else { now_merged = sec_ent[sec_idx]; } last_walk = (walk_walked_t*)apr_array_push(cache->walked); last_walk->matched = sec_ent[sec_idx]; last_walk->merged = now_merged; } /* Whoops - everything matched in sequence, but the original walk * found some additional matches. Truncate them. */ if (matches) { cache->walked->nelts -= matches; } } /* It seems this shouldn't be needed anymore. We translated the x symlink above into a real resource, and should have died up there. x Even if we keep this, it needs more thought (maybe an r->file_is_symlink) x perhaps it should actually happen in file_walk, so we catch more x obscure cases in autoindex sub requests, etc. x x * Symlink permissions are determined by the parent. If the request is x * for a directory then applying the symlink test here would use the x * permissions of the directory as opposed to its parent. Consider a x * symlink pointing to a dir with a .htaccess disallowing symlinks. If x * you access /symlink (or /symlink/) you would get a 403 without this x * APR_DIR test. But if you accessed /symlink/index.html, for example, x * you would *not* get the 403. x x if (r->finfo.filetype != APR_DIR x && (res = resolve_symlink(r->filename, r->info, ap_allow_options(r), x r->pool))) { x ap_log_rerror(APLOG_MARK, APLOG_ERR, 0, r, x "Symbolic link not allowed: %s", r->filename); x return res; x } */ /* Save future sub-requestors much angst in processing * this subrequest. If dir_walk couldn't canonicalize * the file path, nothing can. */ r->canonical_filename = r->filename; if (r->finfo.filetype == APR_DIR) { cache->cached = r->filename; } else { cache->cached = ap_make_dirstr_parent(r->pool, r->filename); } cache->dir_conf_tested = sec_ent; cache->dir_conf_merged = r->per_dir_config; /* Merge our cache->dir_conf_merged construct with the r->per_dir_configs, * and note the end result to (potentially) skip this step next time. */ if (now_merged) { r->per_dir_config = ap_merge_per_dir_configs(r->pool, r->per_dir_config, now_merged); } cache->per_dir_result = r->per_dir_config; return OK; } AP_DECLARE(int) ap_location_walk(request_rec *r) { ap_conf_vector_t *now_merged = NULL; core_server_config *sconf = ap_get_module_config(r->server->module_config, &core_module); ap_conf_vector_t **sec_ent = (ap_conf_vector_t **)sconf->sec_url->elts; int num_sec = sconf->sec_url->nelts; walk_cache_t *cache; const char *entry_uri; /* No tricks here, there are no to parse in this vhost. * We won't destroy the cache, just in case _this_ redirect is later * redirected again to a vhost with blocks to optimize. */ if (!num_sec) { return OK; } cache = prep_walk_cache(AP_NOTE_LOCATION_WALK, r); /* Location and LocationMatch differ on their behaviour w.r.t. multiple * slashes. Location matches multiple slashes with a single slash, * LocationMatch doesn't. An exception, for backwards brokenness is * absoluteURIs... in which case neither match multiple slashes. */ if (r->uri[0] != '/') { entry_uri = r->uri; } else { char *uri = apr_pstrdup(r->pool, r->uri); ap_no2slash(uri); entry_uri = uri; } /* If we have an cache->cached location that matches r->uri, * and the vhost's list of locations hasn't changed, we can skip * rewalking the location_walk entries. */ if (cache->cached && (cache->dir_conf_tested == sec_ent) && (strcmp(entry_uri, cache->cached) == 0)) { /* Well this looks really familiar! If our end-result (per_dir_result) * didn't change, we have absolutely nothing to do :) * Otherwise (as is the case with most dir_merged/file_merged requests) * we must merge our dir_conf_merged onto this new r->per_dir_config. */ if (r->per_dir_config == cache->per_dir_result) { return OK; } if (r->per_dir_config == cache->dir_conf_merged) { r->per_dir_config = cache->per_dir_result; return OK; } if (cache->walked->nelts) { now_merged = ((walk_walked_t*)cache->walked->elts) [cache->walked->nelts - 1].merged; } } else { /* We start now_merged from NULL since we want to build * a locations list that can be merged to any vhost. */ int len, sec_idx; int matches = cache->walked->nelts; walk_walked_t *last_walk = (walk_walked_t*)cache->walked->elts; cache->cached = entry_uri; /* Go through the location entries, and check for matches. * We apply the directive sections in given order, we should * really try them with the most general first. */ for (sec_idx = 0; sec_idx < num_sec; ++sec_idx) { core_dir_config *entry_core; entry_core = ap_get_module_config(sec_ent[sec_idx], &core_module); /* ### const strlen can be optimized in location config parsing */ len = strlen(entry_core->d); /* Test the regex, fnmatch or string as appropriate. * If it's a strcmp, and the pattern was * not slash terminated, then this uri must be slash * terminated (or at the end of the string) to match. */ if (entry_core->r ? ap_regexec(entry_core->r, r->uri, 0, NULL, 0) : (entry_core->d_is_fnmatch ? apr_fnmatch(entry_core->d, cache->cached, FNM_PATHNAME) : (strncmp(entry_core->d, cache->cached, len) || (entry_core->d[len - 1] != '/' && cache->cached[len] != '/' && cache->cached[len] != '\0')))) { continue; } /* If we merged this same section last time, reuse it */ if (matches) { if (last_walk->matched == sec_ent[sec_idx]) { now_merged = last_walk->merged; ++last_walk; --matches; continue; } /* We fell out of sync. This is our own copy of walked, * so truncate the remaining matches and reset remaining. */ cache->walked->nelts -= matches; matches = 0; } if (now_merged) { now_merged = ap_merge_per_dir_configs(r->pool, now_merged, sec_ent[sec_idx]); } else { now_merged = sec_ent[sec_idx]; } last_walk = (walk_walked_t*)apr_array_push(cache->walked); last_walk->matched = sec_ent[sec_idx]; last_walk->merged = now_merged; } /* Whoops - everything matched in sequence, but the original walk * found some additional matches. Truncate them. */ if (matches) { cache->walked->nelts -= matches; } } cache->dir_conf_tested = sec_ent; cache->dir_conf_merged = r->per_dir_config; /* Merge our cache->dir_conf_merged construct with the r->per_dir_configs, * and note the end result to (potentially) skip this step next time. */ if (now_merged) { r->per_dir_config = ap_merge_per_dir_configs(r->pool, r->per_dir_config, now_merged); } cache->per_dir_result = r->per_dir_config; return OK; } AP_DECLARE(int) ap_file_walk(request_rec *r) { ap_conf_vector_t *now_merged = NULL; core_dir_config *dconf = ap_get_module_config(r->per_dir_config, &core_module); ap_conf_vector_t **sec_ent = (ap_conf_vector_t **)dconf->sec_file->elts; int num_sec = dconf->sec_file->nelts; walk_cache_t *cache; const char *test_file; /* To allow broken modules to proceed, we allow missing filenames to pass. * We will catch it later if it's heading for the core handler. * directory_walk already posted an INFO note for module debugging. */ if (r->filename == NULL) { return OK; } cache = prep_walk_cache(AP_NOTE_FILE_WALK, r); /* No tricks here, there are just no to parse in this context. * We won't destroy the cache, just in case _this_ redirect is later * redirected again to a context containing the same or similar . */ if (!num_sec) { return OK; } /* Get the basename .. and copy for the cache just * in case r->filename is munged by another module */ test_file = strrchr(r->filename, '/'); if (test_file == NULL) { test_file = apr_pstrdup(r->pool, r->filename); } else { test_file = apr_pstrdup(r->pool, ++test_file); } /* If we have an cache->cached file name that matches test_file, * and the directory's list of file sections hasn't changed, we * can skip rewalking the file_walk entries. */ if (cache->cached && (cache->dir_conf_tested == sec_ent) && (strcmp(test_file, cache->cached) == 0)) { /* Well this looks really familiar! If our end-result (per_dir_result) * didn't change, we have absolutely nothing to do :) * Otherwise (as is the case with most dir_merged requests) * we must merge our dir_conf_merged onto this new r->per_dir_config. */ if (r->per_dir_config == cache->per_dir_result) { return OK; } if (r->per_dir_config == cache->dir_conf_merged) { r->per_dir_config = cache->per_dir_result; return OK; } if (cache->walked->nelts) { now_merged = ((walk_walked_t*)cache->walked->elts) [cache->walked->nelts - 1].merged; } } else { /* We start now_merged from NULL since we want to build * a file section list that can be merged to any dir_walk. */ int sec_idx; int matches = cache->walked->nelts; walk_walked_t *last_walk = (walk_walked_t*)cache->walked->elts; cache->cached = test_file; /* Go through the location entries, and check for matches. * We apply the directive sections in given order, we should * really try them with the most general first. */ for (sec_idx = 0; sec_idx < num_sec; ++sec_idx) { core_dir_config *entry_core; entry_core = ap_get_module_config(sec_ent[sec_idx], &core_module); if (entry_core->r ? ap_regexec(entry_core->r, cache->cached , 0, NULL, 0) : (entry_core->d_is_fnmatch ? apr_fnmatch(entry_core->d, cache->cached, FNM_PATHNAME) : strcmp(entry_core->d, cache->cached))) { continue; } /* If we merged this same section last time, reuse it */ if (matches) { if (last_walk->matched == sec_ent[sec_idx]) { now_merged = last_walk->merged; ++last_walk; --matches; continue; } /* We fell out of sync. This is our own copy of walked, * so truncate the remaining matches and reset remaining. */ cache->walked->nelts -= matches; matches = 0; } if (now_merged) { now_merged = ap_merge_per_dir_configs(r->pool, now_merged, sec_ent[sec_idx]); } else { now_merged = sec_ent[sec_idx]; } last_walk = (walk_walked_t*)apr_array_push(cache->walked); last_walk->matched = sec_ent[sec_idx]; last_walk->merged = now_merged; } /* Whoops - everything matched in sequence, but the original walk * found some additional matches. Truncate them. */ if (matches) { cache->walked->nelts -= matches; } } cache->dir_conf_tested = sec_ent; cache->dir_conf_merged = r->per_dir_config; /* Merge our cache->dir_conf_merged construct with the r->per_dir_configs, * and note the end result to (potentially) skip this step next time. */ if (now_merged) { r->per_dir_config = ap_merge_per_dir_configs(r->pool, r->per_dir_config, now_merged); } cache->per_dir_result = r->per_dir_config; return OK; } /***************************************************************** * * The sub_request mechanism. * * Fns to look up a relative URI from, e.g., a map file or SSI document. * These do all access checks, etc., but don't actually run the transaction * ... use run_sub_req below for that. Also, be sure to use destroy_sub_req * as appropriate if you're likely to be creating more than a few of these. * (An early Apache version didn't destroy the sub_reqs used in directory * indexing. The result, when indexing a directory with 800-odd files in * it, was massively excessive storage allocation). * * Note more manipulation of protocol-specific vars in the request * structure... */ static request_rec *make_sub_request(const request_rec *r, ap_filter_t *next_filter) { apr_pool_t *rrp; request_rec *rnew; apr_pool_create(&rrp, r->pool); rnew = apr_pcalloc(rrp, sizeof(request_rec)); rnew->pool = rrp; rnew->hostname = r->hostname; rnew->request_time = r->request_time; rnew->connection = r->connection; rnew->server = r->server; rnew->request_config = ap_create_request_config(rnew->pool); /* Start a clean config from this subrequest's vhost. Optimization in * Location/File/Dir walks from the parent request assure that if the * config blocks of the subrequest match the parent request, no merges * will actually occur (and generally a minimal number of merges are * required, even if the parent and subrequest aren't quite identical.) */ rnew->per_dir_config = r->server->lookup_defaults; rnew->htaccess = r->htaccess; rnew->allowed_methods = ap_make_method_list(rnew->pool, 2); /* make a copy of the allowed-methods list */ ap_copy_method_list(rnew->allowed_methods, r->allowed_methods); /* start with the same set of output filters */ if (next_filter) { /* while there are no input filters for a subrequest, we will * try to insert some, so if we don't have valid data, the code * will seg fault. */ rnew->input_filters = r->input_filters; rnew->proto_input_filters = r->proto_input_filters; rnew->output_filters = next_filter; rnew->proto_output_filters = r->proto_output_filters; ap_add_output_filter_handle(ap_subreq_core_filter_handle, NULL, rnew, rnew->connection); } else { /* If NULL - we are expecting to be internal_fast_redirect'ed * to this subrequest - or this request will never be invoked. * Ignore the original request filter stack entirely, and * drill the input and output stacks back to the connection. */ rnew->proto_input_filters = r->proto_input_filters; rnew->proto_output_filters = r->proto_output_filters; rnew->input_filters = r->proto_input_filters; rnew->output_filters = r->proto_output_filters; } /* no input filters for a subrequest */ ap_set_sub_req_protocol(rnew, r); /* We have to run this after we fill in sub req vars, * or the r->main pointer won't be setup */ ap_run_create_request(rnew); return rnew; } AP_CORE_DECLARE_NONSTD(apr_status_t) ap_sub_req_output_filter(ap_filter_t *f, apr_bucket_brigade *bb) { apr_bucket *e = APR_BRIGADE_LAST(bb); if (APR_BUCKET_IS_EOS(e)) { apr_bucket_delete(e); } if (!APR_BRIGADE_EMPTY(bb)) { return ap_pass_brigade(f->next, bb); } return APR_SUCCESS; } AP_DECLARE(int) ap_some_auth_required(request_rec *r) { /* Is there a require line configured for the type of *this* req? */ const apr_array_header_t *reqs_arr = ap_requires(r); require_line *reqs; int i; if (!reqs_arr) { return 0; } reqs = (require_line *) reqs_arr->elts; for (i = 0; i < reqs_arr->nelts; ++i) { if (reqs[i].method_mask & (AP_METHOD_BIT << r->method_number)) { return 1; } } return 0; } AP_DECLARE(request_rec *) ap_sub_req_method_uri(const char *method, const char *new_file, const request_rec *r, ap_filter_t *next_filter) { request_rec *rnew; int res; char *udir; rnew = make_sub_request(r, next_filter); /* would be nicer to pass "method" to ap_set_sub_req_protocol */ rnew->method = method; rnew->method_number = ap_method_number_of(method); if (new_file[0] == '/') { ap_parse_uri(rnew, new_file); } else { udir = ap_make_dirstr_parent(rnew->pool, r->uri); udir = ap_escape_uri(rnew->pool, udir); /* re-escape it */ ap_parse_uri(rnew, ap_make_full_path(rnew->pool, udir, new_file)); } /* lookup_uri * If the content can be served by the quick_handler, we can * safely bypass request_internal processing. */ res = ap_run_quick_handler(rnew, 1); if (res != OK) { if ((res = ap_process_request_internal(rnew))) { rnew->status = res; } } return rnew; } AP_DECLARE(request_rec *) ap_sub_req_lookup_uri(const char *new_file, const request_rec *r, ap_filter_t *next_filter) { return ap_sub_req_method_uri("GET", new_file, r, next_filter); } AP_DECLARE(request_rec *) ap_sub_req_lookup_dirent(const apr_finfo_t *dirent, const request_rec *r, int subtype, ap_filter_t *next_filter) { request_rec *rnew; int res; char *fdir; char *udir; rnew = make_sub_request(r, next_filter); /* Special case: we are looking at a relative lookup in the same directory. * This is 100% safe, since dirent->name just came from the filesystem. */ if (r->path_info && *r->path_info) { /* strip path_info off the end of the uri to keep it in sync * with r->filename, which has already been stripped by directory_walk, * merge the dirent->name, and then, if the caller wants us to remerge * the original path info, do so. Note we never fix the path_info back * to r->filename, since dir_walk would do so (but we don't expect it * to happen in the usual cases) */ udir = apr_pstrdup(rnew->pool, r->uri); udir[ap_find_path_info(udir, r->path_info)] = '\0'; udir = ap_make_dirstr_parent(rnew->pool, udir); rnew->uri = ap_make_full_path(rnew->pool, udir, dirent->name); if (subtype == AP_SUBREQ_MERGE_ARGS) { rnew->uri = ap_make_full_path(rnew->pool, rnew->uri, r->path_info + 1); rnew->path_info = apr_pstrdup(rnew->pool, r->path_info); } } else { udir = ap_make_dirstr_parent(rnew->pool, r->uri); rnew->uri = ap_make_full_path(rnew->pool, udir, dirent->name); } fdir = ap_make_dirstr_parent(rnew->pool, r->filename); rnew->filename = ap_make_full_path(rnew->pool, fdir, dirent->name); if (r->canonical_filename == r->filename) { rnew->canonical_filename = rnew->filename; } /* XXX This is now less relevant; we will do a full location walk * these days for this case. Preserve the apr_stat results, and * perhaps we also tag that symlinks were tested and/or found for * r->filename. */ rnew->per_dir_config = r->server->lookup_defaults; if ((dirent->valid & APR_FINFO_MIN) != APR_FINFO_MIN) { /* * apr_dir_read isn't very complete on this platform, so * we need another apr_lstat (or simply apr_stat if we allow * all symlinks here.) If this is an APR_LNK that resolves * to an APR_DIR, then we will rerun everything anyways... * this should be safe. */ apr_status_t rv; if (ap_allow_options(rnew) & OPT_SYM_LINKS) { if (((rv = apr_stat(&rnew->finfo, rnew->filename, APR_FINFO_MIN, rnew->pool)) != APR_SUCCESS) && (rv != APR_INCOMPLETE)) { rnew->finfo.filetype = 0; } } else { if (((rv = apr_lstat(&rnew->finfo, rnew->filename, APR_FINFO_MIN, rnew->pool)) != APR_SUCCESS) && (rv != APR_INCOMPLETE)) { rnew->finfo.filetype = 0; } } } else { memcpy(&rnew->finfo, dirent, sizeof(apr_finfo_t)); } if (rnew->finfo.filetype == APR_LNK) { /* * Resolve this symlink. We should tie this back to dir_walk's cache */ if ((res = resolve_symlink(rnew->filename, &rnew->finfo, ap_allow_options(rnew), rnew->pool)) != OK) { rnew->status = res; return rnew; } } if (rnew->finfo.filetype == APR_DIR) { /* ap_make_full_path overallocated the buffers * by one character to help us out here. */ strcpy(rnew->filename + strlen(rnew->filename), "/"); if (!rnew->path_info || !*rnew->path_info) { strcpy(rnew->uri + strlen(rnew->uri ), "/"); } } /* fill in parsed_uri values */ if (r->args && *r->args && (subtype == AP_SUBREQ_MERGE_ARGS)) { ap_parse_uri(rnew, apr_pstrcat(r->pool, rnew->uri, "?", r->args, NULL)); } else { ap_parse_uri(rnew, rnew->uri); } if ((res = ap_process_request_internal(rnew))) { rnew->status = res; } return rnew; } AP_DECLARE(request_rec *) ap_sub_req_lookup_file(const char *new_file, const request_rec *r, ap_filter_t *next_filter) { request_rec *rnew; int res; char *fdir; apr_size_t fdirlen; rnew = make_sub_request(r, next_filter); fdir = ap_make_dirstr_parent(rnew->pool, r->filename); fdirlen = strlen(fdir); /* Translate r->filename, if it was canonical, it stays canonical */ if (r->canonical_filename == r->filename) { rnew->canonical_filename = (char*)(1); } if (apr_filepath_merge(&rnew->filename, fdir, new_file, APR_FILEPATH_TRUENAME, rnew->pool) != APR_SUCCESS) { rnew->status = HTTP_FORBIDDEN; return rnew; } if (rnew->canonical_filename) { rnew->canonical_filename = rnew->filename; } /* * Check for a special case... if there are no '/' characters in new_file * at all, and the path was the same, then we are looking at a relative * lookup in the same directory. Fixup the URI to match. */ if (strncmp(rnew->filename, fdir, fdirlen) == 0 && rnew->filename[fdirlen] && ap_strchr_c(rnew->filename + fdirlen, '/') == NULL) { apr_status_t rv; if (ap_allow_options(rnew) & OPT_SYM_LINKS) { if (((rv = apr_stat(&rnew->finfo, rnew->filename, APR_FINFO_MIN, rnew->pool)) != APR_SUCCESS) && (rv != APR_INCOMPLETE)) { rnew->finfo.filetype = 0; } } else { if (((rv = apr_lstat(&rnew->finfo, rnew->filename, APR_FINFO_MIN, rnew->pool)) != APR_SUCCESS) && (rv != APR_INCOMPLETE)) { rnew->finfo.filetype = 0; } } if (r->uri && *r->uri) { char *udir = ap_make_dirstr_parent(rnew->pool, r->uri); rnew->uri = ap_make_full_path(rnew->pool, udir, rnew->filename + fdirlen); ap_parse_uri(rnew, rnew->uri); /* fill in parsed_uri values */ } else { ap_parse_uri(rnew, new_file); /* fill in parsed_uri values */ rnew->uri = apr_pstrdup(rnew->pool, ""); } } else { /* XXX: @@@: What should be done with the parsed_uri values? * We would be better off stripping down to the 'common' elements * of the path, then reassembling the URI as best as we can. */ ap_parse_uri(rnew, new_file); /* fill in parsed_uri values */ /* * XXX: this should be set properly like it is in the same-dir case * but it's actually sometimes to impossible to do it... because the * file may not have a uri associated with it -djg */ rnew->uri = apr_pstrdup(rnew->pool, ""); } if ((res = ap_process_request_internal(rnew))) { rnew->status = res; } return rnew; } AP_DECLARE(int) ap_run_sub_req(request_rec *r) { int retval = DECLINED; /* Run the quick handler if the subrequest is not a dirent or file * subrequest */ if (!(r->filename && r->finfo.filetype)) { retval = ap_run_quick_handler(r, 0); } if (retval != OK) { retval = ap_invoke_handler(r); } ap_finalize_sub_req_protocol(r); return retval; } AP_DECLARE(void) ap_destroy_sub_req(request_rec *r) { /* Reclaim the space */ apr_pool_destroy(r->pool); } /* * Function to set the r->mtime field to the specified value if it's later * than what's already there. */ AP_DECLARE(void) ap_update_mtime(request_rec *r, apr_time_t dependency_mtime) { if (r->mtime < dependency_mtime) { r->mtime = dependency_mtime; } } /* * Is it the initial main request, which we only get *once* per HTTP request? */ AP_DECLARE(int) ap_is_initial_req(request_rec *r) { return (r->main == NULL) /* otherwise, this is a sub-request */ && (r->prev == NULL); /* otherwise, this is an internal redirect */ }