/* Handling of recursive HTTP retrieving. Copyright (C) 1996, 1997, 1998, 1999, 2000, 2001, 2002, 2003, 2004, 2005, 2006, 2007, 2008 Free Software Foundation, Inc. This file is part of GNU Wget. GNU Wget 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 3 of the License, or (at your option) any later version. GNU Wget 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 Wget. If not, see . Additional permission under GNU GPL version 3 section 7 If you modify this program, or any covered work, by linking or combining it with the OpenSSL project's OpenSSL library (or a modified version of that library), containing parts covered by the terms of the OpenSSL or SSLeay licenses, the Free Software Foundation grants you additional permission to convey the resulting work. Corresponding Source for a non-source form of such a combination shall include the source code for the parts of OpenSSL used as well as that of the covered work. */ #include "wget.h" #include #include #include #ifdef HAVE_UNISTD_H # include #endif /* HAVE_UNISTD_H */ #include #include #include "url.h" #include "recur.h" #include "utils.h" #include "retr.h" #include "ftp.h" #include "host.h" #include "hash.h" #include "res.h" #include "convert.h" #include "spider.h" #include "iri.h" /* Functions for maintaining the URL queue. */ struct queue_element { const char *url; /* the URL to download */ const char *referer; /* the referring document */ int depth; /* the depth */ bool html_allowed; /* whether the document is allowed to be treated as HTML. */ char *remote_encoding; struct queue_element *next; /* next element in queue */ }; struct url_queue { struct queue_element *head; struct queue_element *tail; int count, maxcount; }; /* Create a URL queue. */ static struct url_queue * url_queue_new (void) { struct url_queue *queue = xnew0 (struct url_queue); return queue; } /* Delete a URL queue. */ static void url_queue_delete (struct url_queue *queue) { xfree (queue); } /* Enqueue a URL in the queue. The queue is FIFO: the items will be retrieved ("dequeued") from the queue in the order they were placed into it. */ static void url_enqueue (struct url_queue *queue, const char *url, const char *referer, int depth, bool html_allowed) { struct queue_element *qel = xnew (struct queue_element); char *charset = get_current_charset (); qel->url = url; qel->referer = referer; qel->depth = depth; qel->html_allowed = html_allowed; qel->next = NULL; if (charset) qel->remote_encoding = xstrdup (charset); else qel->remote_encoding = NULL; ++queue->count; if (queue->count > queue->maxcount) queue->maxcount = queue->count; DEBUGP (("Enqueuing %s at depth %d\n", url, depth)); DEBUGP (("Queue count %d, maxcount %d.\n", queue->count, queue->maxcount)); /*printf ("[Enqueuing %s with %s\n", url, qel->remote_encoding);*/ if (queue->tail) queue->tail->next = qel; queue->tail = qel; if (!queue->head) queue->head = queue->tail; } /* Take a URL out of the queue. Return true if this operation succeeded, or false if the queue is empty. */ static bool url_dequeue (struct url_queue *queue, const char **url, const char **referer, int *depth, bool *html_allowed) { struct queue_element *qel = queue->head; if (!qel) return false; queue->head = queue->head->next; if (!queue->head) queue->tail = NULL; set_remote_charset (qel->remote_encoding); if (qel->remote_encoding) xfree (qel->remote_encoding); *url = qel->url; *referer = qel->referer; *depth = qel->depth; *html_allowed = qel->html_allowed; --queue->count; DEBUGP (("Dequeuing %s at depth %d\n", qel->url, qel->depth)); DEBUGP (("Queue count %d, maxcount %d.\n", queue->count, queue->maxcount)); xfree (qel); return true; } static bool download_child_p (const struct urlpos *, struct url *, int, struct url *, struct hash_table *); static bool descend_redirect_p (const char *, const char *, int, struct url *, struct hash_table *); /* Retrieve a part of the web beginning with START_URL. This used to be called "recursive retrieval", because the old function was recursive and implemented depth-first search. retrieve_tree on the other hand implements breadth-search traversal of the tree, which results in much nicer ordering of downloads. The algorithm this function uses is simple: 1. put START_URL in the queue. 2. while there are URLs in the queue: 3. get next URL from the queue. 4. download it. 5. if the URL is HTML and its depth does not exceed maximum depth, get the list of URLs embedded therein. 6. for each of those URLs do the following: 7. if the URL is not one of those downloaded before, and if it satisfies the criteria specified by the various command-line options, add it to the queue. */ uerr_t retrieve_tree (const char *start_url) { uerr_t status = RETROK; bool utf8_encode = false; /* The queue of URLs we need to load. */ struct url_queue *queue; /* The URLs we do not wish to enqueue, because they are already in the queue, but haven't been downloaded yet. */ struct hash_table *blacklist; int up_error_code; struct url *start_url_parsed = url_parse (start_url, &up_error_code, &utf8_encode); if (!start_url_parsed) { logprintf (LOG_NOTQUIET, "%s: %s.\n", start_url, url_error (up_error_code)); return URLERROR; } queue = url_queue_new (); blacklist = make_string_hash_table (0); /* Enqueue the starting URL. Use start_url_parsed->url rather than just URL so we enqueue the canonical form of the URL. */ url_enqueue (queue, xstrdup (start_url_parsed->url), NULL, 0, true); string_set_add (blacklist, start_url_parsed->url); while (1) { bool descend = false; char *url, *referer, *file = NULL; int depth; bool html_allowed; bool dash_p_leaf_HTML = false; if (opt.quota && total_downloaded_bytes > opt.quota) break; if (status == FWRITEERR) break; /* Get the next URL from the queue... */ if (!url_dequeue (queue, (const char **)&url, (const char **)&referer, &depth, &html_allowed)) break; /* ...and download it. Note that this download is in most cases unconditional, as download_child_p already makes sure a file doesn't get enqueued twice -- and yet this check is here, and not in download_child_p. This is so that if you run `wget -r URL1 URL2', and a random URL is encountered once under URL1 and again under URL2, but at a different (possibly smaller) depth, we want the URL's children to be taken into account the second time. */ if (dl_url_file_map && hash_table_contains (dl_url_file_map, url)) { file = xstrdup (hash_table_get (dl_url_file_map, url)); DEBUGP (("Already downloaded \"%s\", reusing it from \"%s\".\n", url, file)); if (html_allowed && downloaded_html_set && string_set_contains (downloaded_html_set, file)) descend = true; } else { int dt = 0; char *redirected = NULL; status = retrieve_url (url, &file, &redirected, referer, &dt, false); if (html_allowed && file && status == RETROK && (dt & RETROKF) && (dt & TEXTHTML)) descend = true; if (redirected) { /* We have been redirected, possibly to another host, or different path, or wherever. Check whether we really want to follow it. */ if (descend) { if (!descend_redirect_p (redirected, url, depth, start_url_parsed, blacklist)) descend = false; else /* Make sure that the old pre-redirect form gets blacklisted. */ string_set_add (blacklist, url); } xfree (url); url = redirected; } } if (opt.spider) { visited_url (url, referer); } if (descend && depth >= opt.reclevel && opt.reclevel != INFINITE_RECURSION) { if (opt.page_requisites && (depth == opt.reclevel || depth == opt.reclevel + 1)) { /* When -p is specified, we are allowed to exceed the maximum depth, but only for the "inline" links, i.e. those that are needed to display the page. Originally this could exceed the depth at most by one, but we allow one more level so that the leaf pages that contain frames can be loaded correctly. */ dash_p_leaf_HTML = true; } else { /* Either -p wasn't specified or it was and we've already spent the two extra (pseudo-)levels that it affords us, so we need to bail out. */ DEBUGP (("Not descending further; at depth %d, max. %d.\n", depth, opt.reclevel)); descend = false; } } /* If the downloaded document was HTML, parse it and enqueue the links it contains. */ if (descend) { bool meta_disallow_follow = false; struct urlpos *children = get_urls_html (file, url, &meta_disallow_follow); if (opt.use_robots && meta_disallow_follow) { free_urlpos (children); children = NULL; } if (children) { struct urlpos *child = children; struct url *url_parsed = url_parsed = url_parse (url, NULL, &utf8_encode); char *referer_url = url; bool strip_auth = (url_parsed != NULL && url_parsed->user != NULL); assert (url_parsed != NULL); /* Strip auth info if present */ if (strip_auth) referer_url = url_string (url_parsed, URL_AUTH_HIDE); for (; child; child = child->next) { if (child->ignore_when_downloading) continue; if (dash_p_leaf_HTML && !child->link_inline_p) continue; if (download_child_p (child, url_parsed, depth, start_url_parsed, blacklist)) { url_enqueue (queue, xstrdup (child->url->url), xstrdup (referer_url), depth + 1, child->link_expect_html); /* We blacklist the URL we have enqueued, because we don't want to enqueue (and hence download) the same URL twice. */ string_set_add (blacklist, child->url->url); } } if (strip_auth) xfree (referer_url); url_free (url_parsed); free_urlpos (children); } } if (file && (opt.delete_after || opt.spider /* opt.recursive is implicitely true */ || !acceptable (file))) { /* Either --delete-after was specified, or we loaded this (otherwise unneeded because of --spider or rejected by -R) HTML file just to harvest its hyperlinks -- in either case, delete the local file. */ DEBUGP (("Removing file due to %s in recursive_retrieve():\n", opt.delete_after ? "--delete-after" : (opt.spider ? "--spider" : "recursive rejection criteria"))); logprintf (LOG_VERBOSE, (opt.delete_after || opt.spider ? _("Removing %s.\n") : _("Removing %s since it should be rejected.\n")), file); if (unlink (file)) logprintf (LOG_NOTQUIET, "unlink: %s\n", strerror (errno)); logputs (LOG_VERBOSE, "\n"); register_delete_file (file); } xfree (url); xfree_null (referer); xfree_null (file); } /* If anything is left of the queue due to a premature exit, free it now. */ { char *d1, *d2; int d3; bool d4; while (url_dequeue (queue, (const char **)&d1, (const char **)&d2, &d3, &d4)) { xfree (d1); xfree_null (d2); } } url_queue_delete (queue); if (start_url_parsed) url_free (start_url_parsed); string_set_free (blacklist); if (opt.quota && total_downloaded_bytes > opt.quota) return QUOTEXC; else if (status == FWRITEERR) return FWRITEERR; else return RETROK; } /* Based on the context provided by retrieve_tree, decide whether a URL is to be descended to. This is only ever called from retrieve_tree, but is in a separate function for clarity. The most expensive checks (such as those for robots) are memoized by storing these URLs to BLACKLIST. This may or may not help. It will help if those URLs are encountered many times. */ static bool download_child_p (const struct urlpos *upos, struct url *parent, int depth, struct url *start_url_parsed, struct hash_table *blacklist) { struct url *u = upos->url; const char *url = u->url; bool u_scheme_like_http; DEBUGP (("Deciding whether to enqueue \"%s\".\n", url)); if (string_set_contains (blacklist, url)) { if (opt.spider) { char *referrer = url_string (parent, URL_AUTH_HIDE_PASSWD); DEBUGP (("download_child_p: parent->url is: %s\n", quote (parent->url))); visited_url (url, referrer); xfree (referrer); } DEBUGP (("Already on the black list.\n")); goto out; } /* Several things to check for: 1. if scheme is not http, and we don't load it 2. check for relative links (if relative_only is set) 3. check for domain 4. check for no-parent 5. check for excludes && includes 6. check for suffix 7. check for same host (if spanhost is unset), with possible gethostbyname baggage 8. check for robots.txt Addendum: If the URL is FTP, and it is to be loaded, only the domain and suffix settings are "stronger". Note that .html files will get loaded regardless of suffix rules (but that is remedied later with unlink) unless the depth equals the maximum depth. More time- and memory- consuming tests should be put later on the list. */ /* Determine whether URL under consideration has a HTTP-like scheme. */ u_scheme_like_http = schemes_are_similar_p (u->scheme, SCHEME_HTTP); /* 1. Schemes other than HTTP are normally not recursed into. */ if (!u_scheme_like_http && !(u->scheme == SCHEME_FTP && opt.follow_ftp)) { DEBUGP (("Not following non-HTTP schemes.\n")); goto out; } /* 2. If it is an absolute link and they are not followed, throw it out. */ if (u_scheme_like_http) if (opt.relative_only && !upos->link_relative_p) { DEBUGP (("It doesn't really look like a relative link.\n")); goto out; } /* 3. If its domain is not to be accepted/looked-up, chuck it out. */ if (!accept_domain (u)) { DEBUGP (("The domain was not accepted.\n")); goto out; } /* 4. Check for parent directory. If we descended to a different host or changed the scheme, ignore opt.no_parent. Also ignore it for documents needed to display the parent page when in -p mode. */ if (opt.no_parent && schemes_are_similar_p (u->scheme, start_url_parsed->scheme) && 0 == strcasecmp (u->host, start_url_parsed->host) && u->port == start_url_parsed->port && !(opt.page_requisites && upos->link_inline_p)) { if (!subdir_p (start_url_parsed->dir, u->dir)) { DEBUGP (("Going to \"%s\" would escape \"%s\" with no_parent on.\n", u->dir, start_url_parsed->dir)); goto out; } } /* 5. If the file does not match the acceptance list, or is on the rejection list, chuck it out. The same goes for the directory exclusion and inclusion lists. */ if (opt.includes || opt.excludes) { if (!accdir (u->dir)) { DEBUGP (("%s (%s) is excluded/not-included.\n", url, u->dir)); goto out; } } /* 6. Check for acceptance/rejection rules. We ignore these rules for directories (no file name to match) and for non-leaf HTMLs, which can lead to other files that do need to be downloaded. (-p automatically implies non-leaf because with -p we can, if necesary, overstep the maximum depth to get the page requisites.) */ if (u->file[0] != '\0' && !(has_html_suffix_p (u->file) /* The exception only applies to non-leaf HTMLs (but -p always implies non-leaf because we can overstep the maximum depth to get the requisites): */ && (/* non-leaf */ opt.reclevel == INFINITE_RECURSION /* also non-leaf */ || depth < opt.reclevel - 1 /* -p, which implies non-leaf (see above) */ || opt.page_requisites))) { if (!acceptable (u->file)) { DEBUGP (("%s (%s) does not match acc/rej rules.\n", url, u->file)); goto out; } } /* 7. */ if (schemes_are_similar_p (u->scheme, parent->scheme)) if (!opt.spanhost && 0 != strcasecmp (parent->host, u->host)) { DEBUGP (("This is not the same hostname as the parent's (%s and %s).\n", u->host, parent->host)); goto out; } /* 8. */ if (opt.use_robots && u_scheme_like_http) { struct robot_specs *specs = res_get_specs (u->host, u->port); if (!specs) { char *rfile; if (res_retrieve_file (url, &rfile)) { specs = res_parse_from_file (rfile); /* Delete the robots.txt file if we chose to either delete the files after downloading or we're just running a spider. */ if (opt.delete_after || opt.spider) { logprintf (LOG_VERBOSE, "Removing %s.\n", rfile); if (unlink (rfile)) logprintf (LOG_NOTQUIET, "unlink: %s\n", strerror (errno)); } xfree (rfile); } else { /* If we cannot get real specs, at least produce dummy ones so that we can register them and stop trying to retrieve them. */ specs = res_parse ("", 0); } res_register_specs (u->host, u->port, specs); } /* Now that we have (or don't have) robots.txt specs, we can check what they say. */ if (!res_match_path (specs, u->path)) { DEBUGP (("Not following %s because robots.txt forbids it.\n", url)); string_set_add (blacklist, url); goto out; } } /* The URL has passed all the tests. It can be placed in the download queue. */ DEBUGP (("Decided to load it.\n")); return true; out: DEBUGP (("Decided NOT to load it.\n")); return false; } /* This function determines whether we will consider downloading the children of a URL whose download resulted in a redirection, possibly to another host, etc. It is needed very rarely, and thus it is merely a simple-minded wrapper around download_child_p. */ static bool descend_redirect_p (const char *redirected, const char *original, int depth, struct url *start_url_parsed, struct hash_table *blacklist) { struct url *orig_parsed, *new_parsed; struct urlpos *upos; bool success; bool utf8_encode = false; orig_parsed = url_parse (original, NULL, &utf8_encode); assert (orig_parsed != NULL); new_parsed = url_parse (redirected, NULL, &utf8_encode); assert (new_parsed != NULL); upos = xnew0 (struct urlpos); upos->url = new_parsed; success = download_child_p (upos, orig_parsed, depth, start_url_parsed, blacklist); url_free (orig_parsed); url_free (new_parsed); xfree (upos); if (!success) DEBUGP (("Redirection \"%s\" failed the test.\n", redirected)); return success; } /* vim:set sts=2 sw=2 cino+={s: */