// Copyright (c) 2006-2008 The Chromium Authors. All rights reserved. // Use of this source code is governed by a BSD-style license that can be // found in the LICENSE file. // Portions of this code based on Mozilla: // (netwerk/cookie/src/nsCookieService.cpp) /* ***** BEGIN LICENSE BLOCK ***** * Version: MPL 1.1/GPL 2.0/LGPL 2.1 * * The contents of this file are subject to the Mozilla Public License Version * 1.1 (the "License"); you may not use this file except in compliance with * the License. You may obtain a copy of the License at * http://www.mozilla.org/MPL/ * * Software distributed under the License is distributed on an "AS IS" basis, * WITHOUT WARRANTY OF ANY KIND, either express or implied. See the License * for the specific language governing rights and limitations under the * License. * * The Original Code is mozilla.org code. * * The Initial Developer of the Original Code is * Netscape Communications Corporation. * Portions created by the Initial Developer are Copyright (C) 2003 * the Initial Developer. All Rights Reserved. * * Contributor(s): * Daniel Witte (dwitte@stanford.edu) * Michiel van Leeuwen (mvl@exedo.nl) * * Alternatively, the contents of this file may be used under the terms of * either the GNU General Public License Version 2 or later (the "GPL"), or * the GNU Lesser General Public License Version 2.1 or later (the "LGPL"), * in which case the provisions of the GPL or the LGPL are applicable instead * of those above. If you wish to allow use of your version of this file only * under the terms of either the GPL or the LGPL, and not to allow others to * use your version of this file under the terms of the MPL, indicate your * decision by deleting the provisions above and replace them with the notice * and other provisions required by the GPL or the LGPL. If you do not delete * the provisions above, a recipient may use your version of this file under * the terms of any one of the MPL, the GPL or the LGPL. * * ***** END LICENSE BLOCK ***** */ #include "net/base/cookie_monster.h" #include #include "base/basictypes.h" #include "base/format_macros.h" #include "base/logging.h" #include "base/scoped_ptr.h" #include "base/string_tokenizer.h" #include "base/string_util.h" #include "googleurl/src/gurl.h" #include "net/base/net_util.h" #include "net/base/registry_controlled_domain.h" // #define COOKIE_LOGGING_ENABLED #ifdef COOKIE_LOGGING_ENABLED #define COOKIE_DLOG(severity) DLOG_IF(INFO, 1) #else #define COOKIE_DLOG(severity) DLOG_IF(INFO, 0) #endif using base::Time; using base::TimeDelta; namespace net { // Cookie garbage collection thresholds. Based off of the Mozilla defaults. // It might seem scary to have a high purge value, but really it's not. You // just make sure that you increase the max to cover the increase in purge, // and we would have been purging the same amount of cookies. We're just // going through the garbage collection process less often. static const size_t kNumCookiesPerHost = 70; // ~50 cookies static const size_t kNumCookiesPerHostPurge = 20; static const size_t kNumCookiesTotal = 3300; // ~3000 cookies static const size_t kNumCookiesTotalPurge = 300; // Default minimum delay after updating a cookie's LastAccessDate before we // will update it again. static const int kDefaultAccessUpdateThresholdSeconds = 60; // static bool CookieMonster::enable_file_scheme_ = false; // static void CookieMonster::EnableFileScheme() { enable_file_scheme_ = true; } CookieMonster::CookieMonster() : initialized_(false), store_(NULL), last_access_threshold_( TimeDelta::FromSeconds(kDefaultAccessUpdateThresholdSeconds)) { SetDefaultCookieableSchemes(); } CookieMonster::CookieMonster(PersistentCookieStore* store) : initialized_(false), store_(store), last_access_threshold_( TimeDelta::FromSeconds(kDefaultAccessUpdateThresholdSeconds)) { SetDefaultCookieableSchemes(); } CookieMonster::~CookieMonster() { DeleteAll(false); } void CookieMonster::InitStore() { DCHECK(store_) << "Store must exist to initialize"; // Initialize the store and sync in any saved persistent cookies. We don't // care if it's expired, insert it so it can be garbage collected, removed, // and sync'd. std::vector cookies; // Reserve space for the maximum amount of cookies a database should have. // This prevents multiple vector growth / copies as we append cookies. cookies.reserve(kNumCookiesTotal); store_->Load(&cookies); for (std::vector::const_iterator it = cookies.begin(); it != cookies.end(); ++it) { InternalInsertCookie(it->first, it->second, false); } } void CookieMonster::SetDefaultCookieableSchemes() { // Note: file must be the last scheme. static const char* kDefaultCookieableSchemes[] = { "http", "https", "file" }; int num_schemes = enable_file_scheme_ ? 3 : 2; SetCookieableSchemes(kDefaultCookieableSchemes, num_schemes); } // The system resolution is not high enough, so we can have multiple // set cookies that result in the same system time. When this happens, we // increment by one Time unit. Let's hope computers don't get too fast. Time CookieMonster::CurrentTime() { return std::max(Time::Now(), Time::FromInternalValue(last_time_seen_.ToInternalValue() + 1)); } // Parse a cookie expiration time. We try to be lenient, but we need to // assume some order to distinguish the fields. The basic rules: // - The month name must be present and prefix the first 3 letters of the // full month name (jan for January, jun for June). // - If the year is <= 2 digits, it must occur after the day of month. // - The time must be of the format hh:mm:ss. // An average cookie expiration will look something like this: // Sat, 15-Apr-17 21:01:22 GMT Time CookieMonster::ParseCookieTime(const std::string& time_string) { static const char* kMonths[] = { "jan", "feb", "mar", "apr", "may", "jun", "jul", "aug", "sep", "oct", "nov", "dec" }; static const int kMonthsLen = arraysize(kMonths); // We want to be pretty liberal, and support most non-ascii and non-digit // characters as a delimiter. We can't treat : as a delimiter, because it // is the delimiter for hh:mm:ss, and we want to keep this field together. // We make sure to include - and +, since they could prefix numbers. // If the cookie attribute came in in quotes (ex expires="XXX"), the quotes // will be preserved, and we will get them here. So we make sure to include // quote characters, and also \ for anything that was internally escaped. static const char* kDelimiters = "\t !\"#$%&'()*+,-./;<=>?@[\\]^_`{|}~"; Time::Exploded exploded = {0}; StringTokenizer tokenizer(time_string, kDelimiters); bool found_day_of_month = false; bool found_month = false; bool found_time = false; bool found_year = false; while (tokenizer.GetNext()) { const std::string token = tokenizer.token(); DCHECK(!token.empty()); bool numerical = IsAsciiDigit(token[0]); // String field if (!numerical) { if (!found_month) { for (int i = 0; i < kMonthsLen; ++i) { // Match prefix, so we could match January, etc if (base::strncasecmp(token.c_str(), kMonths[i], 3) == 0) { exploded.month = i + 1; found_month = true; break; } } } else { // If we've gotten here, it means we've already found and parsed our // month, and we have another string, which we would expect to be the // the time zone name. According to the RFC and my experiments with // how sites format their expirations, we don't have much of a reason // to support timezones. We don't want to ever barf on user input, // but this DCHECK should pass for well-formed data. // DCHECK(token == "GMT"); } // Numeric field w/ a colon } else if (token.find(':') != std::string::npos) { if (!found_time && #ifdef COMPILER_MSVC sscanf_s( #else sscanf( #endif token.c_str(), "%2u:%2u:%2u", &exploded.hour, &exploded.minute, &exploded.second) == 3) { found_time = true; } else { // We should only ever encounter one time-like thing. If we're here, // it means we've found a second, which shouldn't happen. We keep // the first. This check should be ok for well-formed input: // NOTREACHED(); } // Numeric field } else { // Overflow with atoi() is unspecified, so we enforce a max length. if (!found_day_of_month && token.length() <= 2) { exploded.day_of_month = atoi(token.c_str()); found_day_of_month = true; } else if (!found_year && token.length() <= 5) { exploded.year = atoi(token.c_str()); found_year = true; } else { // If we're here, it means we've either found an extra numeric field, // or a numeric field which was too long. For well-formed input, the // following check would be reasonable: // NOTREACHED(); } } } if (!found_day_of_month || !found_month || !found_time || !found_year) { // We didn't find all of the fields we need. For well-formed input, the // following check would be reasonable: // NOTREACHED() << "Cookie parse expiration failed: " << time_string; return Time(); } // Normalize the year to expand abbreviated years to the full year. if (exploded.year >= 69 && exploded.year <= 99) exploded.year += 1900; if (exploded.year >= 0 && exploded.year <= 68) exploded.year += 2000; // If our values are within their correct ranges, we got our time. if (exploded.day_of_month >= 1 && exploded.day_of_month <= 31 && exploded.month >= 1 && exploded.month <= 12 && exploded.year >= 1601 && exploded.year <= 30827 && exploded.hour <= 23 && exploded.minute <= 59 && exploded.second <= 59) { return Time::FromUTCExploded(exploded); } // One of our values was out of expected range. For well-formed input, // the following check would be reasonable: // NOTREACHED() << "Cookie exploded expiration failed: " << time_string; return Time(); } // Returns the effective TLD+1 for a given host. This only makes sense for http // and https schemes. For other schemes, the host will be returned unchanged // (minus any leading .). static std::string GetEffectiveDomain(const std::string& scheme, const std::string& host) { if (scheme == "http" || scheme == "https") return RegistryControlledDomainService::GetDomainAndRegistry(host); if (!host.empty() && host[0] == '.') return host.substr(1); return host; } // Determine the cookie domain key to use for setting the specified cookie. // On success returns true, and sets cookie_domain_key to either a // -host cookie key (ex: "google.com") // -domain cookie key (ex: ".google.com") static bool GetCookieDomainKey(const GURL& url, const CookieMonster::ParsedCookie& pc, std::string* cookie_domain_key) { const std::string url_host(url.host()); // If no domain was specified in the cookie, default to a host cookie. // We match IE/Firefox in allowing a domain=IPADDR if it matches the url // ip address hostname exactly. It should be treated as a host cookie. if (!pc.HasDomain() || pc.Domain().empty() || (url.HostIsIPAddress() && url_host == pc.Domain())) { *cookie_domain_key = url_host; DCHECK((*cookie_domain_key)[0] != '.'); return true; } // Get the normalized domain specified in cookie line. // Note: The RFC says we can reject a cookie if the domain // attribute does not start with a dot. IE/FF/Safari however, allow a cookie // of the form domain=my.domain.com, treating it the same as // domain=.my.domain.com -- for compatibility we do the same here. Firefox // also treats domain=.....my.domain.com like domain=.my.domain.com, but // neither IE nor Safari do this, and we don't either. url_canon::CanonHostInfo ignored; std::string cookie_domain(net::CanonicalizeHost(pc.Domain(), &ignored)); if (cookie_domain.empty()) return false; if (cookie_domain[0] != '.') cookie_domain = "." + cookie_domain; // Ensure |url| and |cookie_domain| have the same domain+registry. const std::string url_scheme(url.scheme()); const std::string url_domain_and_registry( GetEffectiveDomain(url_scheme, url_host)); if (url_domain_and_registry.empty()) return false; // IP addresses/intranet hosts can't set domain cookies. const std::string cookie_domain_and_registry( GetEffectiveDomain(url_scheme, cookie_domain)); if (url_domain_and_registry != cookie_domain_and_registry) return false; // Can't set a cookie on a different domain + registry. // Ensure |url_host| is |cookie_domain| or one of its subdomains. Given that // we know the domain+registry are the same from the above checks, this is // basically a simple string suffix check. if ((url_host.length() < cookie_domain.length()) ? (cookie_domain != ("." + url_host)) : url_host.compare(url_host.length() - cookie_domain.length(), cookie_domain.length(), cookie_domain)) return false; *cookie_domain_key = cookie_domain; return true; } static std::string CanonPath(const GURL& url, const CookieMonster::ParsedCookie& pc) { // The RFC says the path should be a prefix of the current URL path. // However, Mozilla allows you to set any path for compatibility with // broken websites. We unfortunately will mimic this behavior. We try // to be generous and accept cookies with an invalid path attribute, and // default the path to something reasonable. // The path was supplied in the cookie, we'll take it. if (pc.HasPath() && !pc.Path().empty() && pc.Path()[0] == '/') return pc.Path(); // The path was not supplied in the cookie or invalid, we will default // to the current URL path. // """Defaults to the path of the request URL that generated the // Set-Cookie response, up to, but not including, the // right-most /.""" // How would this work for a cookie on /? We will include it then. const std::string& url_path = url.path(); size_t idx = url_path.find_last_of('/'); // The cookie path was invalid or a single '/'. if (idx == 0 || idx == std::string::npos) return std::string("/"); // Return up to the rightmost '/'. return url_path.substr(0, idx); } static Time CanonExpiration(const CookieMonster::ParsedCookie& pc, const Time& current) { // First, try the Max-Age attribute. uint64 max_age = 0; if (pc.HasMaxAge() && #ifdef COMPILER_MSVC sscanf_s( #else sscanf( #endif pc.MaxAge().c_str(), " %" PRIu64, &max_age) == 1) { return current + TimeDelta::FromSeconds(max_age); } // Try the Expires attribute. if (pc.HasExpires()) return CookieMonster::ParseCookieTime(pc.Expires()); // Invalid or no expiration, persistent cookie. return Time(); } bool CookieMonster::HasCookieableScheme(const GURL& url) { // Make sure the request is on a cookie-able url scheme. for (size_t i = 0; i < cookieable_schemes_.size(); ++i) { // We matched a scheme. if (url.SchemeIs(cookieable_schemes_[i].c_str())) { // We've matched a supported scheme. return true; } } // The scheme didn't match any in our whitelist. COOKIE_DLOG(WARNING) << "Unsupported cookie scheme: " << url.scheme(); return false; } void CookieMonster::SetCookieableSchemes( const char* schemes[], size_t num_schemes) { cookieable_schemes_.clear(); cookieable_schemes_.insert(cookieable_schemes_.end(), schemes, schemes + num_schemes); } bool CookieMonster::SetCookieWithCreationTimeAndOptions( const GURL& url, const std::string& cookie_line, const Time& creation_time_or_null, const CookieOptions& options) { if (!HasCookieableScheme(url)) { return false; } AutoLock autolock(lock_); InitIfNecessary(); COOKIE_DLOG(INFO) << "SetCookie() line: " << cookie_line; Time creation_time = creation_time_or_null; if (creation_time.is_null()) { creation_time = CurrentTime(); last_time_seen_ = creation_time; } // Parse the cookie. ParsedCookie pc(cookie_line); if (!pc.IsValid()) { COOKIE_DLOG(WARNING) << "Couldn't parse cookie"; return false; } if (options.exclude_httponly() && pc.IsHttpOnly()) { COOKIE_DLOG(INFO) << "SetCookie() not setting httponly cookie"; return false; } std::string cookie_domain; if (!GetCookieDomainKey(url, pc, &cookie_domain)) { return false; } std::string cookie_path = CanonPath(url, pc); scoped_ptr cc; Time cookie_expires = CanonExpiration(pc, creation_time); cc.reset(new CanonicalCookie(pc.Name(), pc.Value(), cookie_path, pc.IsSecure(), pc.IsHttpOnly(), creation_time, creation_time, !cookie_expires.is_null(), cookie_expires)); if (!cc.get()) { COOKIE_DLOG(WARNING) << "Failed to allocate CanonicalCookie"; return false; } if (DeleteAnyEquivalentCookie(cookie_domain, *cc, options.exclude_httponly())) { COOKIE_DLOG(INFO) << "SetCookie() not clobbering httponly cookie"; return false; } COOKIE_DLOG(INFO) << "SetCookie() cc: " << cc->DebugString(); // Realize that we might be setting an expired cookie, and the only point // was to delete the cookie which we've already done. if (!cc->IsExpired(creation_time)) InternalInsertCookie(cookie_domain, cc.release(), true); // We assume that hopefully setting a cookie will be less common than // querying a cookie. Since setting a cookie can put us over our limits, // make sure that we garbage collect... We can also make the assumption that // if a cookie was set, in the common case it will be used soon after, // and we will purge the expired cookies in GetCookies(). GarbageCollect(creation_time, cookie_domain); return true; } void CookieMonster::InternalInsertCookie(const std::string& key, CanonicalCookie* cc, bool sync_to_store) { if (cc->IsPersistent() && store_ && sync_to_store) store_->AddCookie(key, *cc); cookies_.insert(CookieMap::value_type(key, cc)); } void CookieMonster::InternalUpdateCookieAccessTime(CanonicalCookie* cc) { // Based off the Mozilla code. When a cookie has been accessed recently, // don't bother updating its access time again. This reduces the number of // updates we do during pageload, which in turn reduces the chance our storage // backend will hit its batch thresholds and be forced to update. const Time current = Time::Now(); if ((current - cc->LastAccessDate()) < last_access_threshold_) return; cc->SetLastAccessDate(current); if (cc->IsPersistent() && store_) store_->UpdateCookieAccessTime(*cc); } void CookieMonster::InternalDeleteCookie(CookieMap::iterator it, bool sync_to_store) { CanonicalCookie* cc = it->second; COOKIE_DLOG(INFO) << "InternalDeleteCookie() cc: " << cc->DebugString(); if (cc->IsPersistent() && store_ && sync_to_store) store_->DeleteCookie(*cc); cookies_.erase(it); delete cc; } bool CookieMonster::DeleteAnyEquivalentCookie(const std::string& key, const CanonicalCookie& ecc, bool skip_httponly) { bool found_equivalent_cookie = false; bool skipped_httponly = false; for (CookieMapItPair its = cookies_.equal_range(key); its.first != its.second; ) { CookieMap::iterator curit = its.first; CanonicalCookie* cc = curit->second; ++its.first; if (ecc.IsEquivalent(*cc)) { // We should never have more than one equivalent cookie, since they should // overwrite each other. DCHECK(!found_equivalent_cookie) << "Duplicate equivalent cookies found, cookie store is corrupted."; if (skip_httponly && cc->IsHttpOnly()) { skipped_httponly = true; } else { InternalDeleteCookie(curit, true); } found_equivalent_cookie = true; #ifdef NDEBUG // Speed optimization: No point looping through the rest of the cookies // since we're only doing it as a consistency check. break; #endif } } return skipped_httponly; } int CookieMonster::GarbageCollect(const Time& current, const std::string& key) { int num_deleted = 0; // Collect garbage for this key. if (cookies_.count(key) > kNumCookiesPerHost) { COOKIE_DLOG(INFO) << "GarbageCollect() key: " << key; num_deleted += GarbageCollectRange(current, cookies_.equal_range(key), kNumCookiesPerHost, kNumCookiesPerHostPurge); } // Collect garbage for everything. if (cookies_.size() > kNumCookiesTotal) { COOKIE_DLOG(INFO) << "GarbageCollect() everything"; num_deleted += GarbageCollectRange(current, CookieMapItPair(cookies_.begin(), cookies_.end()), kNumCookiesTotal, kNumCookiesTotalPurge); } return num_deleted; } static bool LRUCookieSorter(const CookieMonster::CookieMap::iterator& it1, const CookieMonster::CookieMap::iterator& it2) { // Cookies accessed less recently should be deleted first. if (it1->second->LastAccessDate() != it2->second->LastAccessDate()) return it1->second->LastAccessDate() < it2->second->LastAccessDate(); // In rare cases we might have two cookies with identical last access times. // To preserve the stability of the sort, in these cases prefer to delete // older cookies over newer ones. CreationDate() is guaranteed to be unique. return it1->second->CreationDate() < it2->second->CreationDate(); } int CookieMonster::GarbageCollectRange(const Time& current, const CookieMapItPair& itpair, size_t num_max, size_t num_purge) { // First, delete anything that's expired. std::vector cookie_its; int num_deleted = GarbageCollectExpired(current, itpair, &cookie_its); // If the range still has too many cookies, delete the least recently used. if (cookie_its.size() > num_max) { COOKIE_DLOG(INFO) << "GarbageCollectRange() Deep Garbage Collect."; // Purge down to (|num_max| - |num_purge|) total cookies. DCHECK(num_purge <= num_max); num_purge += cookie_its.size() - num_max; std::partial_sort(cookie_its.begin(), cookie_its.begin() + num_purge, cookie_its.end(), LRUCookieSorter); for (size_t i = 0; i < num_purge; ++i) InternalDeleteCookie(cookie_its[i], true); num_deleted += num_purge; } return num_deleted; } int CookieMonster::GarbageCollectExpired( const Time& current, const CookieMapItPair& itpair, std::vector* cookie_its) { int num_deleted = 0; for (CookieMap::iterator it = itpair.first, end = itpair.second; it != end;) { CookieMap::iterator curit = it; ++it; if (curit->second->IsExpired(current)) { InternalDeleteCookie(curit, true); ++num_deleted; } else if (cookie_its) { cookie_its->push_back(curit); } } return num_deleted; } int CookieMonster::DeleteAll(bool sync_to_store) { AutoLock autolock(lock_); InitIfNecessary(); int num_deleted = 0; for (CookieMap::iterator it = cookies_.begin(); it != cookies_.end();) { CookieMap::iterator curit = it; ++it; InternalDeleteCookie(curit, sync_to_store); ++num_deleted; } return num_deleted; } int CookieMonster::DeleteAllCreatedBetween(const Time& delete_begin, const Time& delete_end, bool sync_to_store) { AutoLock autolock(lock_); InitIfNecessary(); int num_deleted = 0; for (CookieMap::iterator it = cookies_.begin(); it != cookies_.end();) { CookieMap::iterator curit = it; CanonicalCookie* cc = curit->second; ++it; if (cc->CreationDate() >= delete_begin && (delete_end.is_null() || cc->CreationDate() < delete_end)) { InternalDeleteCookie(curit, sync_to_store); ++num_deleted; } } return num_deleted; } int CookieMonster::DeleteAllCreatedAfter(const Time& delete_begin, bool sync_to_store) { return DeleteAllCreatedBetween(delete_begin, Time(), sync_to_store); } bool CookieMonster::DeleteCookie(const std::string& domain, const CanonicalCookie& cookie, bool sync_to_store) { AutoLock autolock(lock_); InitIfNecessary(); for (CookieMapItPair its = cookies_.equal_range(domain); its.first != its.second; ++its.first) { // The creation date acts as our unique index... if (its.first->second->CreationDate() == cookie.CreationDate()) { InternalDeleteCookie(its.first, sync_to_store); return true; } } return false; } // Mozilla sorts on the path length (longest first), and then it // sorts by creation time (oldest first). // The RFC says the sort order for the domain attribute is undefined. static bool CookieSorter(CookieMonster::CanonicalCookie* cc1, CookieMonster::CanonicalCookie* cc2) { if (cc1->Path().length() == cc2->Path().length()) return cc1->CreationDate() < cc2->CreationDate(); return cc1->Path().length() > cc2->Path().length(); } bool CookieMonster::SetCookieWithOptions(const GURL& url, const std::string& cookie_line, const CookieOptions& options) { return SetCookieWithCreationTimeAndOptions(url, cookie_line, Time(), options); } // Currently our cookie datastructure is based on Mozilla's approach. We have a // hash keyed on the cookie's domain, and for any query we walk down the domain // components and probe for cookies until we reach the TLD, where we stop. // For example, a.b.blah.com, we would probe // - a.b.blah.com // - .a.b.blah.com (TODO should we check this first or second?) // - .b.blah.com // - .blah.com // There are some alternative datastructures we could try, like a // search/prefix trie, where we reverse the hostname and query for all // keys that are a prefix of our hostname. I think the hash probing // should be fast and simple enough for now. std::string CookieMonster::GetCookiesWithOptions(const GURL& url, const CookieOptions& options) { if (!HasCookieableScheme(url)) { return std::string(); } // Get the cookies for this host and its domain(s). std::vector cookies; FindCookiesForHostAndDomain(url, options, &cookies); std::sort(cookies.begin(), cookies.end(), CookieSorter); std::string cookie_line; for (std::vector::const_iterator it = cookies.begin(); it != cookies.end(); ++it) { if (it != cookies.begin()) cookie_line += "; "; // In Mozilla if you set a cookie like AAAA, it will have an empty token // and a value of AAAA. When it sends the cookie back, it will send AAAA, // so we need to avoid sending =AAAA for a blank token value. if (!(*it)->Name().empty()) cookie_line += (*it)->Name() + "="; cookie_line += (*it)->Value(); } COOKIE_DLOG(INFO) << "GetCookies() result: " << cookie_line; return cookie_line; } void CookieMonster::DeleteCookie(const GURL& url, const std::string& cookie_name) { if (!HasCookieableScheme(url)) return; CookieOptions options; options.set_include_httponly(); // Get the cookies for this host and its domain(s). std::vector cookies; FindCookiesForHostAndDomain(url, options, &cookies); std::set matching_cookies; for (std::vector::const_iterator it = cookies.begin(); it != cookies.end(); ++it) { if ((*it)->Name() != cookie_name) continue; if (url.path().find((*it)->Path())) continue; matching_cookies.insert(*it); } for (CookieMap::iterator it = cookies_.begin(); it != cookies_.end();) { CookieMap::iterator curit = it; ++it; if (matching_cookies.find(curit->second) != matching_cookies.end()) InternalDeleteCookie(curit, true); } } CookieMonster::CookieList CookieMonster::GetAllCookies() { AutoLock autolock(lock_); InitIfNecessary(); // This function is being called to scrape the cookie list for management UI // or similar. We shouldn't show expired cookies in this list since it will // just be confusing to users, and this function is called rarely enough (and // is already slow enough) that it's OK to take the time to garbage collect // the expired cookies now. // // Note that this does not prune cookies to be below our limits (if we've // exceeded them) the way that calling GarbageCollect() would. GarbageCollectExpired(Time::Now(), CookieMapItPair(cookies_.begin(), cookies_.end()), NULL); CookieList cookie_list; for (CookieMap::iterator it = cookies_.begin(); it != cookies_.end(); ++it) cookie_list.push_back(CookieListPair(it->first, *it->second)); return cookie_list; } CookieMonster::CookieList CookieMonster::GetAllCookiesForURL(const GURL& url) { AutoLock autolock(lock_); InitIfNecessary(); // Do not return removed cookies. GarbageCollectExpired(Time::Now(), CookieMapItPair(cookies_.begin(), cookies_.end()), NULL); CookieList cookie_list; if (!HasCookieableScheme(url)) return cookie_list; bool secure = url.SchemeIsSecure(); // Query for the full host, For example: 'a.c.blah.com'. std::string key(url.host()); FindRawCookies(key, secure, &cookie_list); // See if we can search for domain cookies, i.e. if the host has a TLD + 1. const std::string domain(GetEffectiveDomain(url.scheme(), key)); if (domain.empty()) return cookie_list; // Use same logic as in FindCookiesForHostAndDomain. DCHECK_LE(domain.length(), key.length()); DCHECK_EQ(0, key.compare(key.length() - domain.length(), domain.length(), domain)); for (key = "." + key; key.length() > domain.length(); ) { FindRawCookies(key, secure, &cookie_list); const size_t next_dot = key.find('.', 1); // Skip over leading dot. key.erase(0, next_dot); } return cookie_list; } void CookieMonster::FindCookiesForHostAndDomain( const GURL& url, const CookieOptions& options, std::vector* cookies) { AutoLock autolock(lock_); InitIfNecessary(); const Time current_time(CurrentTime()); // Query for the full host, For example: 'a.c.blah.com'. std::string key(url.host()); FindCookiesForKey(key, url, options, current_time, cookies); // See if we can search for domain cookies, i.e. if the host has a TLD + 1. const std::string domain(GetEffectiveDomain(url.scheme(), key)); if (domain.empty()) return; DCHECK_LE(domain.length(), key.length()); DCHECK_EQ(0, key.compare(key.length() - domain.length(), domain.length(), domain)); // Walk through the string and query at the dot points (GURL should have // canonicalized the dots, so this should be safe). Stop once we reach the // domain + registry; we can't write cookies past this point, and with some // registrars other domains can, in which case we don't want to read their // cookies. for (key = "." + key; key.length() > domain.length(); ) { FindCookiesForKey(key, url, options, current_time, cookies); const size_t next_dot = key.find('.', 1); // Skip over leading dot. key.erase(0, next_dot); } } void CookieMonster::FindCookiesForKey( const std::string& key, const GURL& url, const CookieOptions& options, const Time& current, std::vector* cookies) { bool secure = url.SchemeIsSecure(); for (CookieMapItPair its = cookies_.equal_range(key); its.first != its.second; ) { CookieMap::iterator curit = its.first; CanonicalCookie* cc = curit->second; ++its.first; // If the cookie is expired, delete it. if (cc->IsExpired(current)) { InternalDeleteCookie(curit, true); continue; } // Filter out HttpOnly cookies, per options. if (options.exclude_httponly() && cc->IsHttpOnly()) continue; // Filter out secure cookies unless we're https. if (!secure && cc->IsSecure()) continue; if (!cc->IsOnPath(url.path())) continue; // Add this cookie to the set of matching cookies. Since we're reading the // cookie, update its last access time. InternalUpdateCookieAccessTime(cc); cookies->push_back(cc); } } void CookieMonster::FindRawCookies(const std::string& key, bool include_secure, CookieList* list) { for (CookieMapItPair its = cookies_.equal_range(key); its.first != its.second; ++its.first) { CanonicalCookie* cc = its.first->second; if (include_secure || !cc->IsSecure()) list->push_back(CookieListPair(key, *cc)); } } CookieMonster::ParsedCookie::ParsedCookie(const std::string& cookie_line) : is_valid_(false), path_index_(0), domain_index_(0), expires_index_(0), maxage_index_(0), secure_index_(0), httponly_index_(0) { if (cookie_line.size() > kMaxCookieSize) { LOG(INFO) << "Not parsing cookie, too large: " << cookie_line.size(); return; } ParseTokenValuePairs(cookie_line); if (pairs_.size() > 0) { is_valid_ = true; SetupAttributes(); } } // Returns true if |c| occurs in |chars| // TODO maybe make this take an iterator, could check for end also? static inline bool CharIsA(const char c, const char* chars) { return strchr(chars, c) != NULL; } // Seek the iterator to the first occurrence of a character in |chars|. // Returns true if it hit the end, false otherwise. static inline bool SeekTo(std::string::const_iterator* it, const std::string::const_iterator& end, const char* chars) { for (; *it != end && !CharIsA(**it, chars); ++(*it)); return *it == end; } // Seek the iterator to the first occurrence of a character not in |chars|. // Returns true if it hit the end, false otherwise. static inline bool SeekPast(std::string::const_iterator* it, const std::string::const_iterator& end, const char* chars) { for (; *it != end && CharIsA(**it, chars); ++(*it)); return *it == end; } static inline bool SeekBackPast(std::string::const_iterator* it, const std::string::const_iterator& end, const char* chars) { for (; *it != end && CharIsA(**it, chars); --(*it)); return *it == end; } // Parse all token/value pairs and populate pairs_. void CookieMonster::ParsedCookie::ParseTokenValuePairs( const std::string& cookie_line) { static const char kTerminator[] = "\n\r\0"; static const int kTerminatorLen = sizeof(kTerminator) - 1; static const char kWhitespace[] = " \t"; static const char kValueSeparator[] = ";"; static const char kTokenSeparator[] = ";="; pairs_.clear(); // Ok, here we go. We should be expecting to be starting somewhere // before the cookie line, not including any header name... std::string::const_iterator start = cookie_line.begin(); std::string::const_iterator end = cookie_line.end(); std::string::const_iterator it = start; // TODO Make sure we're stripping \r\n in the network code. Then we // can log any unexpected terminators. size_t term_pos = cookie_line.find_first_of(std::string(kTerminator, kTerminatorLen)); if (term_pos != std::string::npos) { // We found a character we should treat as an end of string. end = start + term_pos; } for (int pair_num = 0; pair_num < kMaxPairs && it != end; ++pair_num) { TokenValuePair pair; std::string::const_iterator token_start, token_real_end, token_end; // Seek past any whitespace before the "token" (the name). // token_start should point at the first character in the token if (SeekPast(&it, end, kWhitespace)) break; // No token, whitespace or empty. token_start = it; // Seek over the token, to the token separator. // token_real_end should point at the token separator, i.e. '='. // If it == end after the seek, we probably have a token-value. SeekTo(&it, end, kTokenSeparator); token_real_end = it; // Ignore any whitespace between the token and the token separator. // token_end should point after the last interesting token character, // pointing at either whitespace, or at '=' (and equal to token_real_end). if (it != token_start) { // We could have an empty token name. --it; // Go back before the token separator. // Skip over any whitespace to the first non-whitespace character. SeekBackPast(&it, token_start, kWhitespace); // Point after it. ++it; } token_end = it; // Seek us back to the end of the token. it = token_real_end; if (it == end || *it != '=') { // We have a token-value, we didn't have any token name. if (pair_num == 0) { // For the first time around, we want to treat single values // as a value with an empty name. (Mozilla bug 169091). // IE seems to also have this behavior, ex "AAA", and "AAA=10" will // set 2 different cookies, and setting "BBB" will then replace "AAA". pair.first = ""; // Rewind to the beginning of what we thought was the token name, // and let it get parsed as a value. it = token_start; } else { // Any not-first attribute we want to treat a value as a // name with an empty value... This is so something like // "secure;" will get parsed as a Token name, and not a value. pair.first = std::string(token_start, token_end); } } else { // We have a TOKEN=VALUE. pair.first = std::string(token_start, token_end); ++it; // Skip past the '='. } // OK, now try to parse a value. std::string::const_iterator value_start, value_end; // Seek past any whitespace that might in-between the token and value. SeekPast(&it, end, kWhitespace); // value_start should point at the first character of the value. value_start = it; // It is unclear exactly how quoted string values should be handled. // Major browsers do different things, for example, Firefox supports // semicolons embedded in a quoted value, while IE does not. Looking at // the specs, RFC 2109 and 2965 allow for a quoted-string as the value. // However, these specs were apparently written after browsers had // implemented cookies, and they seem very distant from the reality of // what is actually implemented and used on the web. The original spec // from Netscape is possibly what is closest to the cookies used today. // This spec didn't have explicit support for double quoted strings, and // states that ; is not allowed as part of a value. We had originally // implement the Firefox behavior (A="B;C"; -> A="B;C";). However, since // there is no standard that makes sense, we decided to follow the behavior // of IE and Safari, which is closer to the original Netscape proposal. // This means that A="B;C" -> A="B;. This also makes the code much simpler // and reduces the possibility for invalid cookies, where other browsers // like Opera currently reject those invalid cookies (ex A="B" "C";). // Just look for ';' to terminate ('=' allowed). // We can hit the end, maybe they didn't terminate. SeekTo(&it, end, kValueSeparator); // Will be pointed at the ; seperator or the end. value_end = it; // Ignore any unwanted whitespace after the value. if (value_end != value_start) { // Could have an empty value --value_end; SeekBackPast(&value_end, value_start, kWhitespace); ++value_end; } // OK, we're finished with a Token/Value. pair.second = std::string(value_start, value_end); // From RFC2109: "Attributes (names) (attr) are case-insensitive." if (pair_num != 0) StringToLowerASCII(&pair.first); pairs_.push_back(pair); // We've processed a token/value pair, we're either at the end of // the string or a ValueSeparator like ';', which we want to skip. if (it != end) ++it; } } void CookieMonster::ParsedCookie::SetupAttributes() { static const char kPathTokenName[] = "path"; static const char kDomainTokenName[] = "domain"; static const char kExpiresTokenName[] = "expires"; static const char kMaxAgeTokenName[] = "max-age"; static const char kSecureTokenName[] = "secure"; static const char kHttpOnlyTokenName[] = "httponly"; // We skip over the first token/value, the user supplied one. for (size_t i = 1; i < pairs_.size(); ++i) { if (pairs_[i].first == kPathTokenName) path_index_ = i; else if (pairs_[i].first == kDomainTokenName) domain_index_ = i; else if (pairs_[i].first == kExpiresTokenName) expires_index_ = i; else if (pairs_[i].first == kMaxAgeTokenName) maxage_index_ = i; else if (pairs_[i].first == kSecureTokenName) secure_index_ = i; else if (pairs_[i].first == kHttpOnlyTokenName) httponly_index_ = i; else { /* some attribute we don't know or don't care about. */ } } } // Create a cookie-line for the cookie. For debugging only! // If we want to use this for something more than debugging, we // should rewrite it better... std::string CookieMonster::ParsedCookie::DebugString() const { std::string out; for (PairList::const_iterator it = pairs_.begin(); it != pairs_.end(); ++it) { out.append(it->first); out.append("="); out.append(it->second); out.append("; "); } return out; } bool CookieMonster::CanonicalCookie::IsOnPath( const std::string& url_path) const { // A zero length would be unsafe for our trailing '/' checks, and // would also make no sense for our prefix match. The code that // creates a CanonicalCookie should make sure the path is never zero length, // but we double check anyway. if (path_.empty()) return false; // The Mozilla code broke it into 3 cases, if it's strings lengths // are less than, equal, or greater. I think this is simpler: // Make sure the cookie path is a prefix of the url path. If the // url path is shorter than the cookie path, then the cookie path // can't be a prefix. if (url_path.find(path_) != 0) return false; // Now we know that url_path is >= cookie_path, and that cookie_path // is a prefix of url_path. If they are the are the same length then // they are identical, otherwise we need an additional check: // In order to avoid in correctly matching a cookie path of /blah // with a request path of '/blahblah/', we need to make sure that either // the cookie path ends in a trailing '/', or that we prefix up to a '/' // in the url path. Since we know that the url path length is greater // than the cookie path length, it's safe to index one byte past. if (path_.length() != url_path.length() && path_[path_.length() - 1] != '/' && url_path[path_.length()] != '/') return false; return true; } std::string CookieMonster::CanonicalCookie::DebugString() const { return StringPrintf("name: %s value: %s path: %s creation: %" PRId64, name_.c_str(), value_.c_str(), path_.c_str(), static_cast(creation_date_.ToTimeT())); } } // namespace