/* vim:set ts=4 sw=4 sts=4 et cin: */ /* This Source Code Form is subject to the terms of the Mozilla Public * License, v. 2.0. If a copy of the MPL was not distributed with this * file, You can obtain one at http://mozilla.org/MPL/2.0/. */ #if defined(MOZ_LOGGING) #define FORCE_PR_LOG #endif #if defined(HAVE_RES_NINIT) #include #include #include #include #include #define RES_RETRY_ON_FAILURE #endif #include #include "nsHostResolver.h" #include "nsError.h" #include "nsISupportsBase.h" #include "nsISupportsUtils.h" #include "nsAutoPtr.h" #include "pratom.h" #include "prthread.h" #include "prerror.h" #include "prtime.h" #include "prlong.h" #include "prlog.h" #include "pldhash.h" #include "plstr.h" #include "nsURLHelper.h" #include "nsThreadUtils.h" #include "mozilla/HashFunctions.h" #include "mozilla/TimeStamp.h" #include "mozilla/Telemetry.h" using namespace mozilla; using namespace mozilla::net; //---------------------------------------------------------------------------- // Use a persistent thread pool in order to avoid spinning up new threads all the time. // In particular, thread creation results in a res_init() call from libc which is // quite expensive. // // The pool dynamically grows between 0 and MAX_RESOLVER_THREADS in size. New requests // go first to an idle thread. If that cannot be found and there are fewer than MAX_RESOLVER_THREADS // currently in the pool a new thread is created for high priority requests. If // the new request is at a lower priority a new thread will only be created if // there are fewer than HighThreadThreshold currently outstanding. If a thread cannot be // created or an idle thread located for the request it is queued. // // When the pool is greater than HighThreadThreshold in size a thread will be destroyed after // ShortIdleTimeoutSeconds of idle time. Smaller pools use LongIdleTimeoutSeconds for a // timeout period. #define HighThreadThreshold MAX_RESOLVER_THREADS_FOR_ANY_PRIORITY #define LongIdleTimeoutSeconds 300 // for threads 1 -> HighThreadThreshold #define ShortIdleTimeoutSeconds 60 // for threads HighThreadThreshold+1 -> MAX_RESOLVER_THREADS PR_STATIC_ASSERT (HighThreadThreshold <= MAX_RESOLVER_THREADS); //---------------------------------------------------------------------------- #if defined(PR_LOGGING) static PRLogModuleInfo *gHostResolverLog = nullptr; #define LOG(args) PR_LOG(gHostResolverLog, PR_LOG_DEBUG, args) #else #define LOG(args) #endif //---------------------------------------------------------------------------- static inline void MoveCList(PRCList &from, PRCList &to) { if (!PR_CLIST_IS_EMPTY(&from)) { to.next = from.next; to.prev = from.prev; to.next->prev = &to; to.prev->next = &to; PR_INIT_CLIST(&from); } } static uint32_t NowInMinutes() { return uint32_t(PR_Now() / int64_t(60 * PR_USEC_PER_SEC)); } //---------------------------------------------------------------------------- #if defined(RES_RETRY_ON_FAILURE) // this class represents the resolver state for a given thread. if we // encounter a lookup failure, then we can invoke the Reset method on an // instance of this class to reset the resolver (in case /etc/resolv.conf // for example changed). this is mainly an issue on GNU systems since glibc // only reads in /etc/resolv.conf once per thread. it may be an issue on // other systems as well. class nsResState { public: nsResState() // initialize mLastReset to the time when this object // is created. this means that a reset will not occur // if a thread is too young. the alternative would be // to initialize this to the beginning of time, so that // the first failure would cause a reset, but since the // thread would have just started up, it likely would // already have current /etc/resolv.conf info. : mLastReset(PR_IntervalNow()) { } bool Reset() { // reset no more than once per second if (PR_IntervalToSeconds(PR_IntervalNow() - mLastReset) < 1) return false; LOG(("Calling 'res_ninit'.\n")); mLastReset = PR_IntervalNow(); return (res_ninit(&_res) == 0); } private: PRIntervalTime mLastReset; }; #endif // RES_RETRY_ON_FAILURE //---------------------------------------------------------------------------- // this macro filters out any flags that are not used when constructing the // host key. the significant flags are those that would affect the resulting // host record (i.e., the flags that are passed down to PR_GetAddrInfoByName). #define RES_KEY_FLAGS(_f) ((_f) & nsHostResolver::RES_CANON_NAME) nsHostRecord::nsHostRecord(const nsHostKey *key) : addr_info_lock("nsHostRecord.addr_info_lock") , addr_info_gencnt(0) , addr_info(nullptr) , addr(nullptr) , negative(false) , resolving(false) , onQueue(false) , usingAnyThread(false) { host = ((char *) this) + sizeof(nsHostRecord); memcpy((char *) host, key->host, strlen(key->host) + 1); flags = key->flags; af = key->af; expiration = NowInMinutes(); PR_INIT_CLIST(this); PR_INIT_CLIST(&callbacks); } nsresult nsHostRecord::Create(const nsHostKey *key, nsHostRecord **result) { size_t hostLen = strlen(key->host) + 1; size_t size = hostLen + sizeof(nsHostRecord); // Use placement new to create the object with room for the hostname // allocated after it. void *place = ::operator new(size); *result = new(place) nsHostRecord(key); NS_ADDREF(*result); return NS_OK; } nsHostRecord::~nsHostRecord() { delete addr_info; delete addr; } bool nsHostRecord::Blacklisted(NetAddr *aQuery) { // must call locked LOG(("Checking blacklist for host [%s], host record [%p].\n", host, this)); // skip the string conversion for the common case of no blacklist if (!mBlacklistedItems.Length()) { return false; } char buf[kIPv6CStrBufSize]; if (!NetAddrToString(aQuery, buf, sizeof(buf))) { return false; } nsDependentCString strQuery(buf); for (uint32_t i = 0; i < mBlacklistedItems.Length(); i++) { if (mBlacklistedItems.ElementAt(i).Equals(strQuery)) { LOG(("Address [%s] is blacklisted for host [%s].\n", buf, host)); return true; } } return false; } void nsHostRecord::ReportUnusable(NetAddr *aAddress) { // must call locked LOG(("Adding address to blacklist for host [%s], host record [%p].\n", host, this)); char buf[kIPv6CStrBufSize]; if (NetAddrToString(aAddress, buf, sizeof(buf))) { LOG(("Successfully adding address [%s] to blacklist for host [%s].\n", buf, host)); mBlacklistedItems.AppendElement(nsCString(buf)); } } void nsHostRecord::ResetBlacklist() { // must call locked LOG(("Resetting blacklist for host [%s], host record [%p].\n", host, this)); mBlacklistedItems.Clear(); } //---------------------------------------------------------------------------- struct nsHostDBEnt : PLDHashEntryHdr { nsHostRecord *rec; }; static PLDHashNumber HostDB_HashKey(PLDHashTable *table, const void *key) { const nsHostKey *hk = static_cast(key); return AddToHash(HashString(hk->host), RES_KEY_FLAGS(hk->flags), hk->af); } static bool HostDB_MatchEntry(PLDHashTable *table, const PLDHashEntryHdr *entry, const void *key) { const nsHostDBEnt *he = static_cast(entry); const nsHostKey *hk = static_cast(key); return !strcmp(he->rec->host, hk->host) && RES_KEY_FLAGS (he->rec->flags) == RES_KEY_FLAGS(hk->flags) && he->rec->af == hk->af; } static void HostDB_MoveEntry(PLDHashTable *table, const PLDHashEntryHdr *from, PLDHashEntryHdr *to) { static_cast(to)->rec = static_cast(from)->rec; } static void HostDB_ClearEntry(PLDHashTable *table, PLDHashEntryHdr *entry) { nsHostDBEnt *he = static_cast(entry); MOZ_ASSERT(he, "nsHostDBEnt is null!"); nsHostRecord *hr = he->rec; MOZ_ASSERT(hr, "nsHostDBEnt has null host record!"); LOG(("Clearing cache db entry for host [%s].\n", hr->host)); #if defined(DEBUG) && defined(PR_LOGGING) { MutexAutoLock lock(hr->addr_info_lock); if (!hr->addr_info) { LOG(("No address info for host [%s].\n", hr->host)); } else { int32_t now = (int32_t) NowInMinutes(); int32_t diff = (int32_t) hr->expiration - now; LOG(("Record for [%s] expires in %d minute(s).\n", hr->host, diff)); NetAddrElement *addrElement = nullptr; char buf[kIPv6CStrBufSize]; do { if (!addrElement) { addrElement = hr->addr_info->mAddresses.getFirst(); } else { addrElement = addrElement->getNext(); } if (addrElement) { NetAddrToString(&addrElement->mAddress, buf, sizeof(buf)); LOG((" [%s]\n", buf)); } } while (addrElement); } } #endif NS_RELEASE(he->rec); } static bool HostDB_InitEntry(PLDHashTable *table, PLDHashEntryHdr *entry, const void *key) { nsHostDBEnt *he = static_cast(entry); nsHostRecord::Create(static_cast(key), &he->rec); return true; } static PLDHashTableOps gHostDB_ops = { PL_DHashAllocTable, PL_DHashFreeTable, HostDB_HashKey, HostDB_MatchEntry, HostDB_MoveEntry, HostDB_ClearEntry, PL_DHashFinalizeStub, HostDB_InitEntry, }; static PLDHashOperator HostDB_RemoveEntry(PLDHashTable *table, PLDHashEntryHdr *hdr, uint32_t number, void *arg) { return PL_DHASH_REMOVE; } //---------------------------------------------------------------------------- nsHostResolver::nsHostResolver(uint32_t maxCacheEntries, uint32_t maxCacheLifetime, uint32_t lifetimeGracePeriod) : mMaxCacheEntries(maxCacheEntries) , mMaxCacheLifetime(maxCacheLifetime) , mGracePeriod(lifetimeGracePeriod) , mLock("nsHostResolver.mLock") , mIdleThreadCV(mLock, "nsHostResolver.mIdleThreadCV") , mNumIdleThreads(0) , mThreadCount(0) , mActiveAnyThreadCount(0) , mEvictionQSize(0) , mPendingCount(0) , mShutdown(true) { mCreationTime = PR_Now(); PR_INIT_CLIST(&mHighQ); PR_INIT_CLIST(&mMediumQ); PR_INIT_CLIST(&mLowQ); PR_INIT_CLIST(&mEvictionQ); mLongIdleTimeout = PR_SecondsToInterval(LongIdleTimeoutSeconds); mShortIdleTimeout = PR_SecondsToInterval(ShortIdleTimeoutSeconds); } nsHostResolver::~nsHostResolver() { PL_DHashTableFinish(&mDB); } nsresult nsHostResolver::Init() { PL_DHashTableInit(&mDB, &gHostDB_ops, nullptr, sizeof(nsHostDBEnt), 0); mShutdown = false; #if defined(HAVE_RES_NINIT) // We want to make sure the system is using the correct resolver settings, // so we force it to reload those settings whenever we startup a subsequent // nsHostResolver instance. We assume that there is no reason to do this // for the first nsHostResolver instance since that is usually created // during application startup. static int initCount = 0; if (initCount++ > 0) { LOG(("Calling 'res_ninit'.\n")); res_ninit(&_res); } #endif return NS_OK; } void nsHostResolver::ClearPendingQueue(PRCList *aPendingQ) { // loop through pending queue, erroring out pending lookups. if (!PR_CLIST_IS_EMPTY(aPendingQ)) { PRCList *node = aPendingQ->next; while (node != aPendingQ) { nsHostRecord *rec = static_cast(node); node = node->next; OnLookupComplete(rec, NS_ERROR_ABORT, nullptr); } } } void nsHostResolver::Shutdown() { LOG(("Shutting down host resolver.\n")); PRCList pendingQHigh, pendingQMed, pendingQLow, evictionQ; PR_INIT_CLIST(&pendingQHigh); PR_INIT_CLIST(&pendingQMed); PR_INIT_CLIST(&pendingQLow); PR_INIT_CLIST(&evictionQ); { MutexAutoLock lock(mLock); mShutdown = true; MoveCList(mHighQ, pendingQHigh); MoveCList(mMediumQ, pendingQMed); MoveCList(mLowQ, pendingQLow); MoveCList(mEvictionQ, evictionQ); mEvictionQSize = 0; mPendingCount = 0; if (mNumIdleThreads) mIdleThreadCV.NotifyAll(); // empty host database PL_DHashTableEnumerate(&mDB, HostDB_RemoveEntry, nullptr); } ClearPendingQueue(&pendingQHigh); ClearPendingQueue(&pendingQMed); ClearPendingQueue(&pendingQLow); if (!PR_CLIST_IS_EMPTY(&evictionQ)) { PRCList *node = evictionQ.next; while (node != &evictionQ) { nsHostRecord *rec = static_cast(node); node = node->next; NS_RELEASE(rec); } } #ifdef NS_BUILD_REFCNT_LOGGING // Logically join the outstanding worker threads with a timeout. // Use this approach instead of PR_JoinThread() because that does // not allow a timeout which may be necessary for a semi-responsive // shutdown if the thread is blocked on a very slow DNS resolution. // mThreadCount is read outside of mLock, but the worst case // scenario for that race is one extra 25ms sleep. PRIntervalTime delay = PR_MillisecondsToInterval(25); PRIntervalTime stopTime = PR_IntervalNow() + PR_SecondsToInterval(20); while (mThreadCount && PR_IntervalNow() < stopTime) PR_Sleep(delay); #endif } static inline bool IsHighPriority(uint16_t flags) { return !(flags & (nsHostResolver::RES_PRIORITY_LOW | nsHostResolver::RES_PRIORITY_MEDIUM)); } static inline bool IsMediumPriority(uint16_t flags) { return flags & nsHostResolver::RES_PRIORITY_MEDIUM; } static inline bool IsLowPriority(uint16_t flags) { return flags & nsHostResolver::RES_PRIORITY_LOW; } void nsHostResolver::MoveQueue(nsHostRecord *aRec, PRCList &aDestQ) { NS_ASSERTION(aRec->onQueue, "Moving Host Record Not Currently Queued"); PR_REMOVE_LINK(aRec); PR_APPEND_LINK(aRec, &aDestQ); } nsresult nsHostResolver::ResolveHost(const char *host, uint16_t flags, uint16_t af, nsResolveHostCallback *callback) { NS_ENSURE_TRUE(host && *host, NS_ERROR_UNEXPECTED); LOG(("Resolving host [%s].\n", host)); // ensure that we are working with a valid hostname before proceeding. see // bug 304904 for details. if (!net_IsValidHostName(nsDependentCString(host))) return NS_ERROR_UNKNOWN_HOST; // if result is set inside the lock, then we need to issue the // callback before returning. nsRefPtr result; nsresult status = NS_OK, rv = NS_OK; { MutexAutoLock lock(mLock); if (mShutdown) rv = NS_ERROR_NOT_INITIALIZED; else { // Used to try to parse to an IP address literal. PRNetAddr tempAddr; // Unfortunately, PR_StringToNetAddr does not properly initialize // the output buffer in the case of IPv6 input. See bug 223145. memset(&tempAddr, 0, sizeof(PRNetAddr)); // check to see if there is already an entry for this |host| // in the hash table. if so, then check to see if we can't // just reuse the lookup result. otherwise, if there are // any pending callbacks, then add to pending callbacks queue, // and return. otherwise, add ourselves as first pending // callback, and proceed to do the lookup. nsHostKey key = { host, flags, af }; nsHostDBEnt *he = static_cast (PL_DHashTableOperate(&mDB, &key, PL_DHASH_ADD)); // if the record is null, then HostDB_InitEntry failed. if (!he || !he->rec) rv = NS_ERROR_OUT_OF_MEMORY; // do we have a cached result that we can reuse? else if (!(flags & RES_BYPASS_CACHE) && he->rec->HasResult() && NowInMinutes() <= he->rec->expiration + mGracePeriod) { LOG(("Using cached record for host [%s].\n", host)); // put reference to host record on stack... result = he->rec; Telemetry::Accumulate(Telemetry::DNS_LOOKUP_METHOD2, METHOD_HIT); // For entries that are in the grace period with a failed connect, // or all cached negative entries, use the cache but start a new lookup in // the background if ((((NowInMinutes() > he->rec->expiration) && he->rec->mBlacklistedItems.Length()) || he->rec->negative) && !he->rec->resolving) { LOG(("Using %s cache entry for host [%s] but starting async renewal.", he->rec->negative ? "negative" :"positive", host)); IssueLookup(he->rec); if (!he->rec->negative) { // negative entries are constantly being refreshed, only // track positive grace period induced renewals Telemetry::Accumulate(Telemetry::DNS_LOOKUP_METHOD2, METHOD_RENEWAL); } } if (he->rec->negative) { Telemetry::Accumulate(Telemetry::DNS_LOOKUP_METHOD2, METHOD_NEGATIVE_HIT); status = NS_ERROR_UNKNOWN_HOST; } } // if the host name is an IP address literal and has been parsed, // go ahead and use it. else if (he->rec->addr) { Telemetry::Accumulate(Telemetry::DNS_LOOKUP_METHOD2, METHOD_LITERAL); result = he->rec; } // try parsing the host name as an IP address literal to short // circuit full host resolution. (this is necessary on some // platforms like Win9x. see bug 219376 for more details.) else if (PR_StringToNetAddr(host, &tempAddr) == PR_SUCCESS) { // ok, just copy the result into the host record, and be done // with it! ;-) he->rec->addr = new NetAddr(); PRNetAddrToNetAddr(&tempAddr, he->rec->addr); // put reference to host record on stack... Telemetry::Accumulate(Telemetry::DNS_LOOKUP_METHOD2, METHOD_LITERAL); result = he->rec; } else if (mPendingCount >= MAX_NON_PRIORITY_REQUESTS && !IsHighPriority(flags) && !he->rec->resolving) { Telemetry::Accumulate(Telemetry::DNS_LOOKUP_METHOD2, METHOD_OVERFLOW); // This is a lower priority request and we are swamped, so refuse it. rv = NS_ERROR_DNS_LOOKUP_QUEUE_FULL; } else if (flags & RES_OFFLINE) { rv = NS_ERROR_OFFLINE; } // otherwise, hit the resolver... else { // Add callback to the list of pending callbacks. PR_APPEND_LINK(callback, &he->rec->callbacks); if (!he->rec->resolving) { he->rec->flags = flags; rv = IssueLookup(he->rec); Telemetry::Accumulate(Telemetry::DNS_LOOKUP_METHOD2, METHOD_NETWORK_FIRST); if (NS_FAILED(rv)) PR_REMOVE_AND_INIT_LINK(callback); else LOG(("DNS lookup for host [%s] blocking pending 'getaddrinfo' query.", host)); } else if (he->rec->onQueue) { Telemetry::Accumulate(Telemetry::DNS_LOOKUP_METHOD2, METHOD_NETWORK_SHARED); // Consider the case where we are on a pending queue of // lower priority than the request is being made at. // In that case we should upgrade to the higher queue. if (IsHighPriority(flags) && !IsHighPriority(he->rec->flags)) { // Move from (low|med) to high. MoveQueue(he->rec, mHighQ); he->rec->flags = flags; ConditionallyCreateThread(he->rec); } else if (IsMediumPriority(flags) && IsLowPriority(he->rec->flags)) { // Move from low to med. MoveQueue(he->rec, mMediumQ); he->rec->flags = flags; mIdleThreadCV.Notify(); } } } } } if (result) callback->OnLookupComplete(this, result, status); return rv; } void nsHostResolver::DetachCallback(const char *host, uint16_t flags, uint16_t af, nsResolveHostCallback *callback, nsresult status) { nsRefPtr rec; { MutexAutoLock lock(mLock); nsHostKey key = { host, flags, af }; nsHostDBEnt *he = static_cast (PL_DHashTableOperate(&mDB, &key, PL_DHASH_LOOKUP)); if (he && he->rec) { // walk list looking for |callback|... we cannot assume // that it will be there! PRCList *node = he->rec->callbacks.next; while (node != &he->rec->callbacks) { if (static_cast(node) == callback) { PR_REMOVE_LINK(callback); rec = he->rec; break; } node = node->next; } } } // complete callback with the given status code; this would only be done if // the record was in the process of being resolved. if (rec) callback->OnLookupComplete(this, rec, status); } nsresult nsHostResolver::ConditionallyCreateThread(nsHostRecord *rec) { if (mNumIdleThreads) { // wake up idle thread to process this lookup mIdleThreadCV.Notify(); } else if ((mThreadCount < HighThreadThreshold) || (IsHighPriority(rec->flags) && mThreadCount < MAX_RESOLVER_THREADS)) { // dispatch new worker thread NS_ADDREF_THIS(); // owning reference passed to thread mThreadCount++; PRThread *thr = PR_CreateThread(PR_SYSTEM_THREAD, ThreadFunc, this, PR_PRIORITY_NORMAL, PR_GLOBAL_THREAD, PR_UNJOINABLE_THREAD, 0); if (!thr) { mThreadCount--; NS_RELEASE_THIS(); return NS_ERROR_OUT_OF_MEMORY; } } #if defined(PR_LOGGING) else LOG(("Unable to find a thread for looking up host [%s].\n", rec->host)); #endif return NS_OK; } nsresult nsHostResolver::IssueLookup(nsHostRecord *rec) { nsresult rv = NS_OK; NS_ASSERTION(!rec->resolving, "record is already being resolved"); // Add rec to one of the pending queues, possibly removing it from mEvictionQ. // If rec is on mEvictionQ, then we can just move the owning // reference over to the new active queue. if (rec->next == rec) NS_ADDREF(rec); else { PR_REMOVE_LINK(rec); mEvictionQSize--; } if (IsHighPriority(rec->flags)) PR_APPEND_LINK(rec, &mHighQ); else if (IsMediumPriority(rec->flags)) PR_APPEND_LINK(rec, &mMediumQ); else PR_APPEND_LINK(rec, &mLowQ); mPendingCount++; rec->resolving = true; rec->onQueue = true; rv = ConditionallyCreateThread(rec); LOG (("DNS thread counters: total=%d any-live=%d idle=%d pending=%d\n", mThreadCount, mActiveAnyThreadCount, mNumIdleThreads, mPendingCount)); return rv; } void nsHostResolver::DeQueue(PRCList &aQ, nsHostRecord **aResult) { *aResult = static_cast(aQ.next); PR_REMOVE_AND_INIT_LINK(*aResult); mPendingCount--; (*aResult)->onQueue = false; } bool nsHostResolver::GetHostToLookup(nsHostRecord **result) { bool timedOut = false; PRIntervalTime epoch, now, timeout; MutexAutoLock lock(mLock); timeout = (mNumIdleThreads >= HighThreadThreshold) ? mShortIdleTimeout : mLongIdleTimeout; epoch = PR_IntervalNow(); while (!mShutdown) { // remove next record from Q; hand over owning reference. Check high, then med, then low if (!PR_CLIST_IS_EMPTY(&mHighQ)) { DeQueue (mHighQ, result); return true; } if (mActiveAnyThreadCount < HighThreadThreshold) { if (!PR_CLIST_IS_EMPTY(&mMediumQ)) { DeQueue (mMediumQ, result); mActiveAnyThreadCount++; (*result)->usingAnyThread = true; return true; } if (!PR_CLIST_IS_EMPTY(&mLowQ)) { DeQueue (mLowQ, result); mActiveAnyThreadCount++; (*result)->usingAnyThread = true; return true; } } // Determining timeout is racy, so allow one cycle through checking the queues // before exiting. if (timedOut) break; // wait for one or more of the following to occur: // (1) the pending queue has a host record to process // (2) the shutdown flag has been set // (3) the thread has been idle for too long mNumIdleThreads++; mIdleThreadCV.Wait(timeout); mNumIdleThreads--; now = PR_IntervalNow(); if ((PRIntervalTime)(now - epoch) >= timeout) timedOut = true; else { // It is possible that PR_WaitCondVar() was interrupted and returned early, // in which case we will loop back and re-enter it. In that case we want to // do so with the new timeout reduced to reflect time already spent waiting. timeout -= (PRIntervalTime)(now - epoch); epoch = now; } } // tell thread to exit... mThreadCount--; return false; } void nsHostResolver::OnLookupComplete(nsHostRecord *rec, nsresult status, AddrInfo *result) { // get the list of pending callbacks for this lookup, and notify // them that the lookup is complete. PRCList cbs; PR_INIT_CLIST(&cbs); { MutexAutoLock lock(mLock); // grab list of callbacks to notify MoveCList(rec->callbacks, cbs); // update record fields. We might have a rec->addr_info already if a // previous lookup result expired and we're reresolving it.. AddrInfo *old_addr_info; { MutexAutoLock lock(rec->addr_info_lock); old_addr_info = rec->addr_info; rec->addr_info = result; rec->addr_info_gencnt++; } delete old_addr_info; rec->expiration = NowInMinutes(); if (result) { rec->expiration += mMaxCacheLifetime; rec->negative = false; } else { rec->expiration += 1; /* one minute for negative cache */ rec->negative = true; } rec->resolving = false; if (rec->usingAnyThread) { mActiveAnyThreadCount--; rec->usingAnyThread = false; } if (rec->addr_info && !mShutdown) { // add to mEvictionQ PR_APPEND_LINK(rec, &mEvictionQ); NS_ADDREF(rec); if (mEvictionQSize < mMaxCacheEntries) mEvictionQSize++; else { // remove first element on mEvictionQ nsHostRecord *head = static_cast(PR_LIST_HEAD(&mEvictionQ)); PR_REMOVE_AND_INIT_LINK(head); PL_DHashTableOperate(&mDB, (nsHostKey *) head, PL_DHASH_REMOVE); if (!head->negative) { // record the age of the entry upon eviction. uint32_t age = NowInMinutes() - (head->expiration - mMaxCacheLifetime); Telemetry::Accumulate(Telemetry::DNS_CLEANUP_AGE, age); } // release reference to rec owned by mEvictionQ NS_RELEASE(head); } } } if (!PR_CLIST_IS_EMPTY(&cbs)) { PRCList *node = cbs.next; while (node != &cbs) { nsResolveHostCallback *callback = static_cast(node); node = node->next; callback->OnLookupComplete(this, rec, status); // NOTE: callback must not be dereferenced after this point!! } } NS_RELEASE(rec); } void nsHostResolver::CancelAsyncRequest(const char *host, uint16_t flags, uint16_t af, nsIDNSListener *aListener, nsresult status) { MutexAutoLock lock(mLock); // Lookup the host record associated with host, flags & address family nsHostKey key = { host, flags, af }; nsHostDBEnt *he = static_cast (PL_DHashTableOperate(&mDB, &key, PL_DHASH_LOOKUP)); if (he && he->rec) { nsHostRecord* recPtr = NULL; PRCList *node = he->rec->callbacks.next; // Remove the first nsDNSAsyncRequest callback which matches the // supplied listener object while (node != &he->rec->callbacks) { nsResolveHostCallback *callback = static_cast(node); if (callback && (callback->EqualsAsyncListener(aListener))) { // Remove from the list of callbacks PR_REMOVE_LINK(callback); recPtr = he->rec; callback->OnLookupComplete(this, recPtr, status); break; } node = node->next; } // If there are no more callbacks, remove the hash table entry if (recPtr && PR_CLIST_IS_EMPTY(&recPtr->callbacks)) { PL_DHashTableOperate(&mDB, (nsHostKey *)recPtr, PL_DHASH_REMOVE); // If record is on a Queue, remove it and then deref it if (recPtr->next != recPtr) { PR_REMOVE_LINK(recPtr); NS_RELEASE(recPtr); } } } } //---------------------------------------------------------------------------- void nsHostResolver::ThreadFunc(void *arg) { LOG(("DNS lookup thread starting execution.\n")); static nsThreadPoolNaming naming; naming.SetThreadPoolName(NS_LITERAL_CSTRING("DNS Resolver")); #if defined(RES_RETRY_ON_FAILURE) nsResState rs; #endif nsHostResolver *resolver = (nsHostResolver *)arg; nsHostRecord *rec; PRAddrInfo *prai = nullptr; while (resolver->GetHostToLookup(&rec)) { LOG(("Calling getaddrinfo for host [%s].\n", rec->host)); int flags = PR_AI_ADDRCONFIG; if (!(rec->flags & RES_CANON_NAME)) flags |= PR_AI_NOCANONNAME; TimeStamp startTime = TimeStamp::Now(); prai = PR_GetAddrInfoByName(rec->host, rec->af, flags); #if defined(RES_RETRY_ON_FAILURE) if (!prai && rs.Reset()) prai = PR_GetAddrInfoByName(rec->host, rec->af, flags); #endif TimeDuration elapsed = TimeStamp::Now() - startTime; uint32_t millis = static_cast(elapsed.ToMilliseconds()); // convert error code to nsresult nsresult status; AddrInfo *ai = nullptr; if (prai) { ai = new AddrInfo(rec->host, prai); PR_FreeAddrInfo(prai); status = NS_OK; Telemetry::Accumulate(!rec->addr_info_gencnt ? Telemetry::DNS_LOOKUP_TIME : Telemetry::DNS_RENEWAL_TIME, millis); } else { status = NS_ERROR_UNKNOWN_HOST; Telemetry::Accumulate(Telemetry::DNS_FAILED_LOOKUP_TIME, millis); } // OnLookupComplete may release "rec", log before we lose it. LOG(("Lookup completed for host [%s].\n", rec->host)); resolver->OnLookupComplete(rec, status, ai); } NS_RELEASE(resolver); LOG(("DNS lookup thread ending execution.\n")); } //---------------------------------------------------------------------------- nsresult nsHostResolver::Create(uint32_t maxCacheEntries, uint32_t maxCacheLifetime, uint32_t lifetimeGracePeriod, nsHostResolver **result) { #if defined(PR_LOGGING) if (!gHostResolverLog) gHostResolverLog = PR_NewLogModule("nsHostResolver"); #endif nsHostResolver *res = new nsHostResolver(maxCacheEntries, maxCacheLifetime, lifetimeGracePeriod); if (!res) return NS_ERROR_OUT_OF_MEMORY; NS_ADDREF(res); nsresult rv = res->Init(); if (NS_FAILED(rv)) NS_RELEASE(res); *result = res; return rv; } PLDHashOperator CacheEntryEnumerator(PLDHashTable *table, PLDHashEntryHdr *entry, uint32_t number, void *arg) { // We don't pay attention to address literals, only resolved domains. // Also require a host. nsHostRecord *rec = static_cast(entry)->rec; if (!rec->addr_info || !rec->host) { return PL_DHASH_NEXT; } DNSCacheEntries info; info.hostname = rec->host; info.family = rec->af; info.expiration = ((int64_t)rec->expiration - NowInMinutes()) * 60; if (info.expiration <= 0) { // We only need valid DNS cache entries return PL_DHASH_NEXT; } { MutexAutoLock lock(rec->addr_info_lock); NetAddr *addr = nullptr; NetAddrElement *addrElement = rec->addr_info->mAddresses.getFirst(); if (addrElement) { addr = &addrElement->mAddress; } while (addr) { char buf[kIPv6CStrBufSize]; if (NetAddrToString(addr, buf, sizeof(buf))) { info.hostaddr.AppendElement(buf); } addr = nullptr; addrElement = addrElement->getNext(); if (addrElement) { addr = &addrElement->mAddress; } } } nsTArray *args = static_cast *>(arg); args->AppendElement(info); return PL_DHASH_NEXT; } void nsHostResolver::GetDNSCacheEntries(nsTArray *args) { PL_DHashTableEnumerate(&mDB, CacheEntryEnumerator, args); }