/* -*- Mode: C++; tab-width: 2; indent-tabs-mode: nil; c-basic-offset: 2 -*- */ /* vim:set ts=4 sw=2 cindent et: */ /* 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/. */ #include "mozilla/DebugOnly.h" #include "nsIOService.h" #include "nsIProtocolHandler.h" #include "nsIFileProtocolHandler.h" #include "nscore.h" #include "nsIURI.h" #include "prprf.h" #include "nsErrorService.h" #include "netCore.h" #include "nsIObserverService.h" #include "nsXPCOM.h" #include "nsIProxiedProtocolHandler.h" #include "nsIProxyInfo.h" #include "nsDNSService2.h" #include "nsEscape.h" #include "nsNetUtil.h" #include "nsNetCID.h" #include "nsCRT.h" #include "nsSimpleNestedURI.h" #include "nsTArray.h" #include "nsIConsoleService.h" #include "nsIUploadChannel2.h" #include "nsXULAppAPI.h" #include "nsIProtocolProxyCallback.h" #include "nsICancelable.h" #include "nsINetworkLinkService.h" #include "nsAsyncRedirectVerifyHelper.h" #include "nsURLHelper.h" #include "nsIProtocolProxyService2.h" #include "MainThreadUtils.h" #include "nsINode.h" #include "nsIWidget.h" #include "nsThreadUtils.h" #include "mozilla/AppShutdown.h" #include "mozilla/LoadInfo.h" #include "mozilla/net/NeckoCommon.h" #include "mozilla/Services.h" #include "mozilla/Telemetry.h" #include "mozilla/net/DNS.h" #include "mozilla/ipc/URIUtils.h" #include "mozilla/net/NeckoChild.h" #include "mozilla/net/NeckoParent.h" #include "mozilla/dom/ClientInfo.h" #include "mozilla/dom/ContentParent.h" #include "mozilla/dom/nsHTTPSOnlyUtils.h" #include "mozilla/dom/ServiceWorkerDescriptor.h" #include "mozilla/net/CaptivePortalService.h" #include "mozilla/net/NetworkConnectivityService.h" #include "mozilla/net/SocketProcessHost.h" #include "mozilla/net/SocketProcessParent.h" #include "mozilla/net/SSLTokensCache.h" #include "mozilla/Unused.h" #include "nsContentSecurityManager.h" #include "nsContentUtils.h" #include "mozilla/StaticPrefs_network.h" #include "mozilla/StaticPrefs_security.h" #include "nsNSSComponent.h" #include "ssl.h" #ifdef MOZ_WIDGET_GTK # include "nsGIOProtocolHandler.h" #endif namespace mozilla { namespace net { using mozilla::Maybe; using mozilla::dom::ClientInfo; using mozilla::dom::ServiceWorkerDescriptor; #define PORT_PREF_PREFIX "network.security.ports." #define PORT_PREF(x) PORT_PREF_PREFIX x #define MANAGE_OFFLINE_STATUS_PREF "network.manage-offline-status" // Nb: these have been misnomers since bug 715770 removed the buffer cache. // "network.segment.count" and "network.segment.size" would be better names, // but the old names are still used to preserve backward compatibility. #define NECKO_BUFFER_CACHE_COUNT_PREF "network.buffer.cache.count" #define NECKO_BUFFER_CACHE_SIZE_PREF "network.buffer.cache.size" #define NETWORK_CAPTIVE_PORTAL_PREF "network.captive-portal-service.enabled" #define WEBRTC_PREF_PREFIX "media.peerconnection." #define NETWORK_DNS_PREF "network.dns." #define MAX_RECURSION_COUNT 50 nsIOService* gIOService; static bool gHasWarnedUploadChannel2; static bool gCaptivePortalEnabled = false; static LazyLogModule gIOServiceLog("nsIOService"); #undef LOG #define LOG(args) MOZ_LOG(gIOServiceLog, LogLevel::Debug, args) // A general port blacklist. Connections to these ports will not be allowed // unless the protocol overrides. // // This list is to be kept in sync with "bad ports" as defined in the // WHATWG Fetch standard at int16_t gBadPortList[] = { 1, // tcpmux 7, // echo 9, // discard 11, // systat 13, // daytime 15, // netstat 17, // qotd 19, // chargen 20, // ftp-data 21, // ftp 22, // ssh 23, // telnet 25, // smtp 37, // time 42, // name 43, // nicname 53, // domain 69, // tftp 77, // priv-rjs 79, // finger 87, // ttylink 95, // supdup 101, // hostriame 102, // iso-tsap 103, // gppitnp 104, // acr-nema 109, // pop2 110, // pop3 111, // sunrpc 113, // auth 115, // sftp 117, // uucp-path 119, // nntp 123, // ntp 135, // loc-srv / epmap 137, // netbios 139, // netbios 143, // imap2 161, // snmp 179, // bgp 389, // ldap 427, // afp (alternate) 465, // smtp (alternate) 512, // print / exec 513, // login 514, // shell 515, // printer 526, // tempo 530, // courier 531, // chat 532, // netnews 540, // uucp 548, // afp 554, // rtsp 556, // remotefs 563, // nntp+ssl 587, // smtp (outgoing) 601, // syslog-conn 636, // ldap+ssl 989, // ftps-data 990, // ftps 993, // imap+ssl 995, // pop3+ssl 1719, // h323gatestat 1720, // h323hostcall 1723, // pptp 2049, // nfs 3659, // apple-sasl 4045, // lockd 5060, // sip 5061, // sips 6000, // x11 6566, // sane-port 6665, // irc (alternate) 6666, // irc (alternate) 6667, // irc (default) 6668, // irc (alternate) 6669, // irc (alternate) 6697, // irc+tls 10080, // amanda 0, // Sentinel value: This MUST be zero }; static const char kProfileChangeNetTeardownTopic[] = "profile-change-net-teardown"; static const char kProfileChangeNetRestoreTopic[] = "profile-change-net-restore"; static const char kProfileDoChange[] = "profile-do-change"; // Necko buffer defaults uint32_t nsIOService::gDefaultSegmentSize = 4096; uint32_t nsIOService::gDefaultSegmentCount = 24; uint32_t nsIOService::sSocketProcessCrashedCount = 0; //////////////////////////////////////////////////////////////////////////////// nsIOService::nsIOService() : mLastOfflineStateChange(PR_IntervalNow()), mLastConnectivityChange(PR_IntervalNow()), mLastNetworkLinkChange(PR_IntervalNow()) {} static const char* gCallbackPrefs[] = { PORT_PREF_PREFIX, MANAGE_OFFLINE_STATUS_PREF, NECKO_BUFFER_CACHE_COUNT_PREF, NECKO_BUFFER_CACHE_SIZE_PREF, NETWORK_CAPTIVE_PORTAL_PREF, nullptr, }; static const char* gCallbackPrefsForSocketProcess[] = { WEBRTC_PREF_PREFIX, NETWORK_DNS_PREF, "network.ssl_tokens_cache_enabled", "network.send_ODA_to_content_directly", "network.trr.", "doh-rollout.", "network.dns.disableIPv6", "network.dns.skipTRR-when-parental-control-enabled", "network.offline-mirrors-connectivity", "network.disable-localhost-when-offline", "network.proxy.parse_pac_on_socket_process", "network.proxy.allow_hijacking_localhost", "network.connectivity-service.", "network.captive-portal-service.testMode", nullptr, }; static const char* gCallbackSecurityPrefs[] = { // Note the prefs listed below should be in sync with the code in // HandleTLSPrefChange(). "security.tls.version.min", "security.tls.version.max", "security.tls.version.enable-deprecated", "security.tls.hello_downgrade_check", "security.ssl.require_safe_negotiation", "security.ssl.enable_false_start", "security.ssl.enable_alpn", "security.tls.enable_0rtt_data", "security.ssl.disable_session_identifiers", "security.tls.enable_post_handshake_auth", "security.tls.enable_delegated_credentials", // Note the prefs listed below should be in sync with the code in // SetValidationOptionsCommon(). "security.ssl.enable_ocsp_stapling", "security.ssl.enable_ocsp_must_staple", "security.pki.certificate_transparency.mode", nullptr, }; nsresult nsIOService::Init() { // XXX hack until xpidl supports error info directly (bug 13423) nsCOMPtr errorService = nsErrorService::GetOrCreate(); MOZ_ALWAYS_TRUE(errorService); errorService->RegisterErrorStringBundle(NS_ERROR_MODULE_NETWORK, NECKO_MSGS_URL); SSLTokensCache::Init(); InitializeCaptivePortalService(); // setup our bad port list stuff for (int i = 0; gBadPortList[i]; i++) { // We can't be accessed by another thread yet PUSH_IGNORE_THREAD_SAFETY mRestrictedPortList.AppendElement(gBadPortList[i]); POP_THREAD_SAFETY } // Further modifications to the port list come from prefs Preferences::RegisterPrefixCallbacks(nsIOService::PrefsChanged, gCallbackPrefs, this); PrefsChanged(); mSocketProcessTopicBlockedList.Insert( nsLiteralCString(NS_XPCOM_WILL_SHUTDOWN_OBSERVER_ID)); mSocketProcessTopicBlockedList.Insert( nsLiteralCString(NS_XPCOM_SHUTDOWN_OBSERVER_ID)); mSocketProcessTopicBlockedList.Insert("xpcom-shutdown-threads"_ns); mSocketProcessTopicBlockedList.Insert("profile-do-change"_ns); mSocketProcessTopicBlockedList.Insert("network:socket-process-crashed"_ns); // Register for profile change notifications mObserverService = services::GetObserverService(); AddObserver(this, kProfileChangeNetTeardownTopic, true); AddObserver(this, kProfileChangeNetRestoreTopic, true); AddObserver(this, kProfileDoChange, true); AddObserver(this, NS_XPCOM_SHUTDOWN_OBSERVER_ID, true); AddObserver(this, NS_NETWORK_LINK_TOPIC, true); AddObserver(this, NS_NETWORK_ID_CHANGED_TOPIC, true); AddObserver(this, NS_WIDGET_WAKE_OBSERVER_TOPIC, true); // Register observers for sending notifications to nsSocketTransportService if (XRE_IsParentProcess()) { AddObserver(this, "profile-initial-state", true); AddObserver(this, NS_WIDGET_SLEEP_OBSERVER_TOPIC, true); } if (IsSocketProcessChild()) { Preferences::RegisterCallbacks(nsIOService::OnTLSPrefChange, gCallbackSecurityPrefs, this); } gIOService = this; InitializeNetworkLinkService(); InitializeProtocolProxyService(); SetOffline(false); return NS_OK; } NS_IMETHODIMP nsIOService::AddObserver(nsIObserver* aObserver, const char* aTopic, bool aOwnsWeak) { if (!mObserverService) { return NS_ERROR_FAILURE; } // Register for the origional observer. nsresult rv = mObserverService->AddObserver(aObserver, aTopic, aOwnsWeak); if (NS_FAILED(rv)) { return rv; } if (!XRE_IsParentProcess()) { return NS_OK; } nsAutoCString topic(aTopic); // This happens when AddObserver() is called by nsIOService::Init(). We don't // want to add nsIOService again. if (SameCOMIdentity(aObserver, static_cast(this))) { mIOServiceTopicList.Insert(topic); return NS_OK; } if (!UseSocketProcess()) { return NS_OK; } if (mSocketProcessTopicBlockedList.Contains(topic)) { return NS_ERROR_FAILURE; } // Avoid registering duplicate topics. if (mObserverTopicForSocketProcess.Contains(topic)) { return NS_ERROR_FAILURE; } mObserverTopicForSocketProcess.Insert(topic); // Avoid registering duplicate topics. if (mIOServiceTopicList.Contains(topic)) { return NS_ERROR_FAILURE; } return mObserverService->AddObserver(this, aTopic, true); } NS_IMETHODIMP nsIOService::RemoveObserver(nsIObserver* aObserver, const char* aTopic) { return NS_ERROR_NOT_IMPLEMENTED; } NS_IMETHODIMP nsIOService::EnumerateObservers(const char* aTopic, nsISimpleEnumerator** anEnumerator) { return NS_ERROR_NOT_IMPLEMENTED; } NS_IMETHODIMP nsIOService::NotifyObservers(nsISupports* aSubject, const char* aTopic, const char16_t* aSomeData) { return NS_ERROR_NOT_IMPLEMENTED; } nsIOService::~nsIOService() { if (gIOService) { MOZ_ASSERT(gIOService == this); gIOService = nullptr; } } // static void nsIOService::OnTLSPrefChange(const char* aPref, void* aSelf) { MOZ_ASSERT(IsSocketProcessChild()); if (!EnsureNSSInitializedChromeOrContent()) { LOG(("NSS not initialized.")); return; } nsAutoCString pref(aPref); // The preferences listed in gCallbackSecurityPrefs need to be in sync with // the code in HandleTLSPrefChange() and SetValidationOptionsCommon(). if (HandleTLSPrefChange(pref)) { LOG(("HandleTLSPrefChange done")); } else if (pref.EqualsLiteral("security.ssl.enable_ocsp_stapling") || pref.EqualsLiteral("security.ssl.enable_ocsp_must_staple") || pref.EqualsLiteral("security.pki.certificate_transparency.mode")) { SetValidationOptionsCommon(); } } nsresult nsIOService::InitializeCaptivePortalService() { if (XRE_GetProcessType() != GeckoProcessType_Default) { // We only initalize a captive portal service in the main process return NS_OK; } mCaptivePortalService = do_GetService(NS_CAPTIVEPORTAL_CID); if (mCaptivePortalService) { return static_cast(mCaptivePortalService.get()) ->Initialize(); } // Instantiate and initialize the service RefPtr ncs = NetworkConnectivityService::GetSingleton(); return NS_OK; } nsresult nsIOService::InitializeSocketTransportService() { nsresult rv = NS_OK; if (!mSocketTransportService) { mSocketTransportService = do_GetService(NS_SOCKETTRANSPORTSERVICE_CONTRACTID, &rv); if (NS_FAILED(rv)) { NS_WARNING("failed to get socket transport service"); } } if (mSocketTransportService) { rv = mSocketTransportService->Init(); NS_ASSERTION(NS_SUCCEEDED(rv), "socket transport service init failed"); mSocketTransportService->SetOffline(false); } return rv; } nsresult nsIOService::InitializeNetworkLinkService() { nsresult rv = NS_OK; if (mNetworkLinkServiceInitialized) return rv; if (!NS_IsMainThread()) { NS_WARNING("Network link service should be created on main thread"); return NS_ERROR_FAILURE; } // go into managed mode if we can, and chrome process if (!XRE_IsParentProcess()) { return NS_ERROR_NOT_AVAILABLE; } mNetworkLinkService = do_GetService(NS_NETWORK_LINK_SERVICE_CONTRACTID, &rv); if (mNetworkLinkService) { mNetworkLinkServiceInitialized = true; } // After initializing the networkLinkService, query the connectivity state OnNetworkLinkEvent(NS_NETWORK_LINK_DATA_UNKNOWN); return rv; } nsresult nsIOService::InitializeProtocolProxyService() { nsresult rv = NS_OK; if (XRE_IsParentProcess()) { // for early-initialization Unused << do_GetService(NS_PROTOCOLPROXYSERVICE_CONTRACTID, &rv); } return rv; } already_AddRefed nsIOService::GetInstance() { if (!gIOService) { RefPtr ios = new nsIOService(); if (NS_SUCCEEDED(ios->Init())) { MOZ_ASSERT(gIOService == ios.get()); return ios.forget(); } } return do_AddRef(gIOService); } class SocketProcessListenerProxy : public SocketProcessHost::Listener { public: SocketProcessListenerProxy() = default; void OnProcessLaunchComplete(SocketProcessHost* aHost, bool aSucceeded) { if (!gIOService) { return; } gIOService->OnProcessLaunchComplete(aHost, aSucceeded); } void OnProcessUnexpectedShutdown(SocketProcessHost* aHost) { if (!gIOService) { return; } gIOService->OnProcessUnexpectedShutdown(aHost); } }; // static bool nsIOService::TooManySocketProcessCrash() { return sSocketProcessCrashedCount >= StaticPrefs::network_max_socket_process_failed_count(); } // static void nsIOService::IncreaseSocketProcessCrashCount() { MOZ_ASSERT(IsNeckoChild()); sSocketProcessCrashedCount++; } nsresult nsIOService::LaunchSocketProcess() { MOZ_ASSERT(NS_IsMainThread()); if (XRE_GetProcessType() != GeckoProcessType_Default) { return NS_OK; } // We shouldn't launch socket prcess when shutdown begins. if (AppShutdown::IsInOrBeyond(ShutdownPhase::AppShutdownConfirmed)) { return NS_OK; } if (mSocketProcess) { return NS_OK; } if (PR_GetEnv("MOZ_DISABLE_SOCKET_PROCESS")) { LOG(("nsIOService skipping LaunchSocketProcess because of the env")); return NS_OK; } if (!StaticPrefs::network_process_enabled()) { LOG(("nsIOService skipping LaunchSocketProcess because of the pref")); return NS_OK; } Preferences::RegisterPrefixCallbacks( nsIOService::NotifySocketProcessPrefsChanged, gCallbackPrefsForSocketProcess, this); // The subprocess is launched asynchronously, so we wait for a callback to // acquire the IPDL actor. mSocketProcess = new SocketProcessHost(new SocketProcessListenerProxy()); LOG(("nsIOService::LaunchSocketProcess")); if (!mSocketProcess->Launch()) { NS_WARNING("Failed to launch socket process!!"); DestroySocketProcess(); return NS_ERROR_FAILURE; } return NS_OK; } void nsIOService::DestroySocketProcess() { LOG(("nsIOService::DestroySocketProcess")); MOZ_ASSERT(NS_IsMainThread()); if (XRE_GetProcessType() != GeckoProcessType_Default || !mSocketProcess) { return; } Preferences::UnregisterPrefixCallbacks( nsIOService::NotifySocketProcessPrefsChanged, gCallbackPrefsForSocketProcess, this); mSocketProcess->Shutdown(); mSocketProcess = nullptr; } bool nsIOService::SocketProcessReady() { return mSocketProcess && mSocketProcess->IsConnected(); } static bool sUseSocketProcess = false; static bool sUseSocketProcessChecked = false; // static bool nsIOService::UseSocketProcess(bool aCheckAgain) { if (sUseSocketProcessChecked && !aCheckAgain) { return sUseSocketProcess; } sUseSocketProcessChecked = true; sUseSocketProcess = false; if (PR_GetEnv("MOZ_DISABLE_SOCKET_PROCESS")) { return sUseSocketProcess; } if (TooManySocketProcessCrash()) { LOG(("TooManySocketProcessCrash")); return sUseSocketProcess; } if (PR_GetEnv("MOZ_FORCE_USE_SOCKET_PROCESS")) { sUseSocketProcess = true; return sUseSocketProcess; } if (StaticPrefs::network_process_enabled()) { sUseSocketProcess = StaticPrefs::network_http_network_access_on_socket_process_enabled(); } return sUseSocketProcess; } // static void nsIOService::NotifySocketProcessPrefsChanged(const char* aName, void* aSelf) { static_cast(aSelf)->NotifySocketProcessPrefsChanged(aName); } void nsIOService::NotifySocketProcessPrefsChanged(const char* aName) { MOZ_ASSERT(NS_IsMainThread()); if (!XRE_IsParentProcess()) { return; } if (!StaticPrefs::network_process_enabled()) { return; } dom::Pref pref(nsCString(aName), /* isLocked */ false, /* isSanitized */ false, Nothing(), Nothing()); Preferences::GetPreference(&pref, GeckoProcessType_Socket, /* remoteType */ ""_ns); auto sendPrefUpdate = [pref]() { Unused << gIOService->mSocketProcess->GetActor()->SendPreferenceUpdate( pref); }; CallOrWaitForSocketProcess(sendPrefUpdate); } void nsIOService::OnProcessLaunchComplete(SocketProcessHost* aHost, bool aSucceeded) { MOZ_ASSERT(NS_IsMainThread()); LOG(("nsIOService::OnProcessLaunchComplete aSucceeded=%d\n", aSucceeded)); mSocketProcessLaunchComplete = aSucceeded; if (mShutdown || !SocketProcessReady() || !aSucceeded) { mPendingEvents.Clear(); return; } if (!mPendingEvents.IsEmpty()) { nsTArray> pendingEvents = std::move(mPendingEvents); for (auto& func : pendingEvents) { func(); } } } void nsIOService::CallOrWaitForSocketProcess( const std::function& aFunc) { MOZ_ASSERT(NS_IsMainThread()); if (IsSocketProcessLaunchComplete() && SocketProcessReady()) { aFunc(); } else { mPendingEvents.AppendElement(aFunc); // infallible LaunchSocketProcess(); } } int32_t nsIOService::SocketProcessPid() { if (!mSocketProcess) { return 0; } if (SocketProcessParent* actor = mSocketProcess->GetActor()) { return (int32_t)actor->OtherPid(); } return 0; } bool nsIOService::IsSocketProcessLaunchComplete() { MOZ_ASSERT(NS_IsMainThread()); return mSocketProcessLaunchComplete; } void nsIOService::OnProcessUnexpectedShutdown(SocketProcessHost* aHost) { MOZ_ASSERT(NS_IsMainThread()); LOG(("nsIOService::OnProcessUnexpectedShutdown\n")); DestroySocketProcess(); mPendingEvents.Clear(); // Nothing to do if socket process was not used before. if (!UseSocketProcess()) { return; } sSocketProcessCrashedCount++; if (TooManySocketProcessCrash()) { sUseSocketProcessChecked = false; DNSServiceWrapper::SwitchToBackupDNSService(); } nsCOMPtr observerService = services::GetObserverService(); if (observerService) { (void)observerService->NotifyObservers( nullptr, "network:socket-process-crashed", nullptr); } // UseSocketProcess() could return false if we have too many crashes, so we // should call it again. if (UseSocketProcess()) { MOZ_ALWAYS_SUCCEEDS(NS_DispatchToMainThread( NewRunnableMethod("nsIOService::LaunchSocketProcess", this, &nsIOService::LaunchSocketProcess))); } } RefPtr nsIOService::GetSocketProcessMemoryReporter() { // Check the prefs here again, since we don't want to create // SocketProcessMemoryReporter for some tests. if (!StaticPrefs::network_process_enabled() || !SocketProcessReady()) { return nullptr; } return new SocketProcessMemoryReporter(); } NS_IMETHODIMP nsIOService::SocketProcessTelemetryPing() { CallOrWaitForSocketProcess([]() { Unused << gIOService->mSocketProcess->GetActor() ->SendSocketProcessTelemetryPing(); }); return NS_OK; } NS_IMPL_ISUPPORTS(nsIOService, nsIIOService, nsINetUtil, nsISpeculativeConnect, nsIObserver, nsIIOServiceInternal, nsISupportsWeakReference, nsIObserverService) //////////////////////////////////////////////////////////////////////////////// nsresult nsIOService::RecheckCaptivePortal() { MOZ_ASSERT(NS_IsMainThread(), "Must be called on the main thread"); if (!mCaptivePortalService) { return NS_OK; } nsCOMPtr task = NewRunnableMethod( "nsIOService::RecheckCaptivePortal", mCaptivePortalService, &nsICaptivePortalService::RecheckCaptivePortal); return NS_DispatchToMainThread(task); } nsresult nsIOService::RecheckCaptivePortalIfLocalRedirect(nsIChannel* newChan) { nsresult rv; if (!mCaptivePortalService) { return NS_OK; } nsCOMPtr uri; rv = newChan->GetURI(getter_AddRefs(uri)); if (NS_FAILED(rv)) { return rv; } nsCString host; rv = uri->GetHost(host); if (NS_FAILED(rv)) { return rv; } NetAddr addr; // If the redirect wasn't to an IP literal, so there's probably no need // to trigger the captive portal detection right now. It can wait. if (NS_SUCCEEDED(addr.InitFromString(host)) && addr.IsIPAddrLocal()) { RecheckCaptivePortal(); } return NS_OK; } nsresult nsIOService::AsyncOnChannelRedirect( nsIChannel* oldChan, nsIChannel* newChan, uint32_t flags, nsAsyncRedirectVerifyHelper* helper) { // If a redirect to a local network address occurs, then chances are we // are in a captive portal, so we trigger a recheck. RecheckCaptivePortalIfLocalRedirect(newChan); // This is silly. I wish there was a simpler way to get at the global // reference of the contentSecurityManager. But it lives in the XPCOM // service registry. nsCOMPtr sink = do_GetService(NS_CONTENTSECURITYMANAGER_CONTRACTID); if (sink) { nsresult rv = helper->DelegateOnChannelRedirect(sink, oldChan, newChan, flags); if (NS_FAILED(rv)) return rv; } // Finally, our category nsCOMArray entries; mChannelEventSinks.GetEntries(entries); int32_t len = entries.Count(); for (int32_t i = 0; i < len; ++i) { nsresult rv = helper->DelegateOnChannelRedirect(entries[i], oldChan, newChan, flags); if (NS_FAILED(rv)) return rv; } nsCOMPtr httpChan(do_QueryInterface(oldChan)); // Collect the redirection from HTTP(S) only. if (httpChan) { MOZ_ASSERT(NS_IsMainThread()); nsCOMPtr newURI; newChan->GetURI(getter_AddRefs(newURI)); MOZ_ASSERT(newURI); nsAutoCString scheme; newURI->GetScheme(scheme); MOZ_ASSERT(!scheme.IsEmpty()); Telemetry::AccumulateCategoricalKeyed( scheme, oldChan->IsDocument() ? Telemetry::LABELS_NETWORK_HTTP_REDIRECT_TO_SCHEME::topLevel : Telemetry::LABELS_NETWORK_HTTP_REDIRECT_TO_SCHEME::subresource); } return NS_OK; } nsresult nsIOService::CacheProtocolHandler(const char* scheme, nsIProtocolHandler* handler) { MOZ_ASSERT(NS_IsMainThread()); for (unsigned int i = 0; i < NS_N(gScheme); i++) { if (!nsCRT::strcasecmp(scheme, gScheme[i])) { nsresult rv; NS_ASSERTION(!mWeakHandler[i], "Protocol handler already cached"); // Make sure the handler supports weak references. nsCOMPtr factoryPtr = do_QueryInterface(handler, &rv); if (!factoryPtr) { // Don't cache handlers that don't support weak reference as // there is real danger of a circular reference. #ifdef DEBUG_dp printf( "DEBUG: %s protcol handler doesn't support weak ref. Not cached.\n", scheme); #endif /* DEBUG_dp */ return NS_ERROR_FAILURE; } mWeakHandler[i] = do_GetWeakReference(handler); return NS_OK; } } return NS_ERROR_FAILURE; } nsresult nsIOService::GetCachedProtocolHandler(const char* scheme, nsIProtocolHandler** result, uint32_t start, uint32_t end) { MOZ_ASSERT(NS_IsMainThread()); uint32_t len = end - start - 1; for (unsigned int i = 0; i < NS_N(gScheme); i++) { if (!mWeakHandler[i]) continue; // handle unterminated strings // start is inclusive, end is exclusive, len = end - start - 1 if (end ? (!nsCRT::strncasecmp(scheme + start, gScheme[i], len) && gScheme[i][len] == '\0') : (!nsCRT::strcasecmp(scheme, gScheme[i]))) { return CallQueryReferent(mWeakHandler[i].get(), result); } } return NS_ERROR_FAILURE; } static bool UsesExternalProtocolHandler(const char* aScheme) { if ("file"_ns.Equals(aScheme) || "chrome"_ns.Equals(aScheme) || "resource"_ns.Equals(aScheme)) { // Don't allow file:, chrome: or resource: URIs to be handled with // nsExternalProtocolHandler, since internally we rely on being able to // use and read from these URIs. return false; } for (const auto& forcedExternalScheme : gForcedExternalSchemes) { if (!nsCRT::strcasecmp(forcedExternalScheme, aScheme)) { return true; } } nsAutoCString pref("network.protocol-handler.external."); pref += aScheme; return Preferences::GetBool(pref.get(), false); } NS_IMETHODIMP nsIOService::GetProtocolHandler(const char* scheme, nsIProtocolHandler** result) { nsresult rv; NS_ENSURE_ARG_POINTER(scheme); // XXX we may want to speed this up by introducing our own protocol // scheme -> protocol handler mapping, avoiding the string manipulation // and service manager stuff rv = GetCachedProtocolHandler(scheme, result); if (NS_SUCCEEDED(rv)) return rv; if (scheme[0] != '\0' && !UsesExternalProtocolHandler(scheme)) { nsAutoCString contractID(NS_NETWORK_PROTOCOL_CONTRACTID_PREFIX); contractID += scheme; ToLowerCase(contractID); rv = CallGetService(contractID.get(), result); if (NS_SUCCEEDED(rv)) { CacheProtocolHandler(scheme, *result); return rv; } #ifdef MOZ_WIDGET_GTK // check to see whether GVFS can handle this URI scheme. otherwise, we // failover to using the default protocol handler. RefPtr gioHandler = nsGIOProtocolHandler::GetSingleton(); if (gioHandler->IsSupportedProtocol(nsCString(scheme))) { gioHandler.forget(result); return NS_OK; } #endif } // Okay we don't have a protocol handler to handle this url type, so use // the default protocol handler. This will cause urls to get dispatched // out to the OS ('cause we can't do anything with them) when we try to // read from a channel created by the default protocol handler. rv = CallGetService(NS_NETWORK_PROTOCOL_CONTRACTID_PREFIX "default", result); if (NS_FAILED(rv)) return NS_ERROR_UNKNOWN_PROTOCOL; return rv; } NS_IMETHODIMP nsIOService::ExtractScheme(const nsACString& inURI, nsACString& scheme) { return net_ExtractURLScheme(inURI, scheme); } NS_IMETHODIMP nsIOService::HostnameIsLocalIPAddress(nsIURI* aURI, bool* aResult) { NS_ENSURE_ARG_POINTER(aURI); nsCOMPtr innerURI = NS_GetInnermostURI(aURI); NS_ENSURE_ARG_POINTER(innerURI); nsAutoCString host; nsresult rv = innerURI->GetAsciiHost(host); if (NS_FAILED(rv)) { return rv; } *aResult = false; NetAddr addr; if (NS_SUCCEEDED(addr.InitFromString(host)) && addr.IsIPAddrLocal()) { *aResult = true; } return NS_OK; } NS_IMETHODIMP nsIOService::HostnameIsSharedIPAddress(nsIURI* aURI, bool* aResult) { NS_ENSURE_ARG_POINTER(aURI); nsCOMPtr innerURI = NS_GetInnermostURI(aURI); NS_ENSURE_ARG_POINTER(innerURI); nsAutoCString host; nsresult rv = innerURI->GetAsciiHost(host); if (NS_FAILED(rv)) { return rv; } *aResult = false; NetAddr addr; if (NS_SUCCEEDED(addr.InitFromString(host)) && addr.IsIPAddrShared()) { *aResult = true; } return NS_OK; } NS_IMETHODIMP nsIOService::GetProtocolFlags(const char* scheme, uint32_t* flags) { nsCOMPtr handler; nsresult rv = GetProtocolHandler(scheme, getter_AddRefs(handler)); if (NS_FAILED(rv)) return rv; // We can't call DoGetProtocolFlags here because we don't have a URI. This // API is used by (and only used by) extensions, which is why it's still // around. Calling this on a scheme with dynamic flags will throw. rv = handler->GetProtocolFlags(flags); #if !IS_ORIGIN_IS_FULL_SPEC_DEFINED MOZ_RELEASE_ASSERT(!(*flags & nsIProtocolHandler::ORIGIN_IS_FULL_SPEC), "ORIGIN_IS_FULL_SPEC is unsupported but used"); #endif return rv; } class AutoIncrement { public: explicit AutoIncrement(uint32_t* var) : mVar(var) { ++*var; } ~AutoIncrement() { --*mVar; } private: uint32_t* mVar; }; nsresult nsIOService::NewURI(const nsACString& aSpec, const char* aCharset, nsIURI* aBaseURI, nsIURI** result) { return NS_NewURI(result, aSpec, aCharset, aBaseURI); } NS_IMETHODIMP nsIOService::NewFileURI(nsIFile* file, nsIURI** result) { nsresult rv; NS_ENSURE_ARG_POINTER(file); nsCOMPtr handler; rv = GetProtocolHandler("file", getter_AddRefs(handler)); if (NS_FAILED(rv)) return rv; nsCOMPtr fileHandler(do_QueryInterface(handler, &rv)); if (NS_FAILED(rv)) return rv; return fileHandler->NewFileURI(file, result); } // static already_AddRefed nsIOService::CreateExposableURI(nsIURI* aURI) { MOZ_ASSERT(aURI, "Must have a URI"); nsCOMPtr uri = aURI; nsAutoCString userPass; uri->GetUserPass(userPass); if (!userPass.IsEmpty()) { DebugOnly rv = NS_MutateURI(uri).SetUserPass(""_ns).Finalize(uri); MOZ_ASSERT(NS_SUCCEEDED(rv) && uri, "Mutating URI should never fail"); } return uri.forget(); } NS_IMETHODIMP nsIOService::CreateExposableURI(nsIURI* aURI, nsIURI** _result) { NS_ENSURE_ARG_POINTER(aURI); NS_ENSURE_ARG_POINTER(_result); nsCOMPtr exposableURI = CreateExposableURI(aURI); exposableURI.forget(_result); return NS_OK; } NS_IMETHODIMP nsIOService::NewChannelFromURI(nsIURI* aURI, nsINode* aLoadingNode, nsIPrincipal* aLoadingPrincipal, nsIPrincipal* aTriggeringPrincipal, uint32_t aSecurityFlags, nsContentPolicyType aContentPolicyType, nsIChannel** result) { return NewChannelFromURIWithProxyFlags(aURI, nullptr, // aProxyURI 0, // aProxyFlags aLoadingNode, aLoadingPrincipal, aTriggeringPrincipal, aSecurityFlags, aContentPolicyType, result); } nsresult nsIOService::NewChannelFromURIWithClientAndController( nsIURI* aURI, nsINode* aLoadingNode, nsIPrincipal* aLoadingPrincipal, nsIPrincipal* aTriggeringPrincipal, const Maybe& aLoadingClientInfo, const Maybe& aController, uint32_t aSecurityFlags, nsContentPolicyType aContentPolicyType, uint32_t aSandboxFlags, nsIChannel** aResult) { return NewChannelFromURIWithProxyFlagsInternal( aURI, nullptr, // aProxyURI 0, // aProxyFlags aLoadingNode, aLoadingPrincipal, aTriggeringPrincipal, aLoadingClientInfo, aController, aSecurityFlags, aContentPolicyType, aSandboxFlags, aResult); } NS_IMETHODIMP nsIOService::NewChannelFromURIWithLoadInfo(nsIURI* aURI, nsILoadInfo* aLoadInfo, nsIChannel** result) { return NewChannelFromURIWithProxyFlagsInternal(aURI, nullptr, // aProxyURI 0, // aProxyFlags aLoadInfo, result); } nsresult nsIOService::NewChannelFromURIWithProxyFlagsInternal( nsIURI* aURI, nsIURI* aProxyURI, uint32_t aProxyFlags, nsINode* aLoadingNode, nsIPrincipal* aLoadingPrincipal, nsIPrincipal* aTriggeringPrincipal, const Maybe& aLoadingClientInfo, const Maybe& aController, uint32_t aSecurityFlags, nsContentPolicyType aContentPolicyType, uint32_t aSandboxFlags, nsIChannel** result) { nsCOMPtr loadInfo = new LoadInfo( aLoadingPrincipal, aTriggeringPrincipal, aLoadingNode, aSecurityFlags, aContentPolicyType, aLoadingClientInfo, aController, aSandboxFlags); return NewChannelFromURIWithProxyFlagsInternal(aURI, aProxyURI, aProxyFlags, loadInfo, result); } nsresult nsIOService::NewChannelFromURIWithProxyFlagsInternal( nsIURI* aURI, nsIURI* aProxyURI, uint32_t aProxyFlags, nsILoadInfo* aLoadInfo, nsIChannel** result) { nsresult rv; NS_ENSURE_ARG_POINTER(aURI); // all channel creations must provide a valid loadinfo MOZ_ASSERT(aLoadInfo, "can not create channel without aLoadInfo"); NS_ENSURE_ARG_POINTER(aLoadInfo); nsAutoCString scheme; rv = aURI->GetScheme(scheme); if (NS_FAILED(rv)) return rv; nsCOMPtr handler; rv = GetProtocolHandler(scheme.get(), getter_AddRefs(handler)); if (NS_FAILED(rv)) return rv; uint32_t protoFlags; rv = handler->DoGetProtocolFlags(aURI, &protoFlags); if (NS_FAILED(rv)) return rv; nsCOMPtr channel; nsCOMPtr pph = do_QueryInterface(handler); if (pph) { rv = pph->NewProxiedChannel(aURI, nullptr, aProxyFlags, aProxyURI, aLoadInfo, getter_AddRefs(channel)); } else { rv = handler->NewChannel(aURI, aLoadInfo, getter_AddRefs(channel)); } if (NS_FAILED(rv)) return rv; // Make sure that all the individual protocolhandlers attach a loadInfo. nsCOMPtr loadInfo = channel->LoadInfo(); if (aLoadInfo != loadInfo) { MOZ_ASSERT(false, "newly created channel must have a loadinfo attached"); return NS_ERROR_UNEXPECTED; } // If we're sandboxed, make sure to clear any owner the channel // might already have. if (loadInfo->GetLoadingSandboxed()) { channel->SetOwner(nullptr); } // Some extensions override the http protocol handler and provide their own // implementation. The channels returned from that implementation doesn't // seem to always implement the nsIUploadChannel2 interface, presumably // because it's a new interface. // Eventually we should remove this and simply require that http channels // implement the new interface. // See bug 529041 if (!gHasWarnedUploadChannel2 && scheme.EqualsLiteral("http")) { nsCOMPtr uploadChannel2 = do_QueryInterface(channel); if (!uploadChannel2) { nsCOMPtr consoleService = do_GetService(NS_CONSOLESERVICE_CONTRACTID); if (consoleService) { consoleService->LogStringMessage( u"Http channel implementation " "doesn't support nsIUploadChannel2. An extension has " "supplied a non-functional http protocol handler. This will " "break behavior and in future releases not work at all."); } gHasWarnedUploadChannel2 = true; } } channel.forget(result); return NS_OK; } NS_IMETHODIMP nsIOService::NewChannelFromURIWithProxyFlags( nsIURI* aURI, nsIURI* aProxyURI, uint32_t aProxyFlags, nsINode* aLoadingNode, nsIPrincipal* aLoadingPrincipal, nsIPrincipal* aTriggeringPrincipal, uint32_t aSecurityFlags, nsContentPolicyType aContentPolicyType, nsIChannel** result) { return NewChannelFromURIWithProxyFlagsInternal( aURI, aProxyURI, aProxyFlags, aLoadingNode, aLoadingPrincipal, aTriggeringPrincipal, Maybe(), Maybe(), aSecurityFlags, aContentPolicyType, 0, result); } NS_IMETHODIMP nsIOService::NewChannel(const nsACString& aSpec, const char* aCharset, nsIURI* aBaseURI, nsINode* aLoadingNode, nsIPrincipal* aLoadingPrincipal, nsIPrincipal* aTriggeringPrincipal, uint32_t aSecurityFlags, nsContentPolicyType aContentPolicyType, nsIChannel** result) { nsresult rv; nsCOMPtr uri; rv = NewURI(aSpec, aCharset, aBaseURI, getter_AddRefs(uri)); if (NS_FAILED(rv)) return rv; return NewChannelFromURI(uri, aLoadingNode, aLoadingPrincipal, aTriggeringPrincipal, aSecurityFlags, aContentPolicyType, result); } bool nsIOService::IsLinkUp() { InitializeNetworkLinkService(); if (!mNetworkLinkService) { // We cannot decide, assume the link is up return true; } bool isLinkUp; nsresult rv; rv = mNetworkLinkService->GetIsLinkUp(&isLinkUp); if (NS_FAILED(rv)) { return true; } return isLinkUp; } NS_IMETHODIMP nsIOService::GetOffline(bool* offline) { if (StaticPrefs::network_offline_mirrors_connectivity()) { *offline = mOffline || !mConnectivity; } else { *offline = mOffline; } return NS_OK; } NS_IMETHODIMP nsIOService::SetOffline(bool offline) { return SetOfflineInternal(offline); } nsresult nsIOService::SetOfflineInternal(bool offline, bool notifySocketProcess) { LOG(("nsIOService::SetOffline offline=%d\n", offline)); // When someone wants to go online (!offline) after we got XPCOM shutdown // throw ERROR_NOT_AVAILABLE to prevent return to online state. if ((mShutdown || mOfflineForProfileChange) && !offline) { return NS_ERROR_NOT_AVAILABLE; } // SetOffline() may re-enter while it's shutting down services. // If that happens, save the most recent value and it will be // processed when the first SetOffline() call is done bringing // down the service. mSetOfflineValue = offline; if (mSettingOffline) { return NS_OK; } mSettingOffline = true; nsCOMPtr observerService = services::GetObserverService(); NS_ASSERTION(observerService, "The observer service should not be null"); if (XRE_IsParentProcess()) { if (observerService) { (void)observerService->NotifyObservers(nullptr, NS_IPC_IOSERVICE_SET_OFFLINE_TOPIC, offline ? u"true" : u"false"); } if (SocketProcessReady() && notifySocketProcess) { Unused << mSocketProcess->GetActor()->SendSetOffline(offline); } } nsIIOService* subject = static_cast(this); while (mSetOfflineValue != mOffline) { offline = mSetOfflineValue; if (offline && !mOffline) { mOffline = true; // indicate we're trying to shutdown // don't care if notifications fail if (observerService) { observerService->NotifyObservers(subject, NS_IOSERVICE_GOING_OFFLINE_TOPIC, u"" NS_IOSERVICE_OFFLINE); } if (mSocketTransportService) mSocketTransportService->SetOffline(true); mLastOfflineStateChange = PR_IntervalNow(); if (observerService) { observerService->NotifyObservers(subject, NS_IOSERVICE_OFFLINE_STATUS_TOPIC, u"" NS_IOSERVICE_OFFLINE); } } else if (!offline && mOffline) { // go online InitializeSocketTransportService(); mOffline = false; // indicate success only AFTER we've // brought up the services mLastOfflineStateChange = PR_IntervalNow(); // don't care if notification fails // Only send the ONLINE notification if there is connectivity if (observerService && mConnectivity) { observerService->NotifyObservers(subject, NS_IOSERVICE_OFFLINE_STATUS_TOPIC, (u"" NS_IOSERVICE_ONLINE)); } } } // Don't notify here, as the above notifications (if used) suffice. if ((mShutdown || mOfflineForProfileChange) && mOffline) { if (mSocketTransportService) { DebugOnly rv = mSocketTransportService->Shutdown(mShutdown); NS_ASSERTION(NS_SUCCEEDED(rv), "socket transport service shutdown failed"); } } mSettingOffline = false; return NS_OK; } NS_IMETHODIMP nsIOService::GetConnectivity(bool* aConnectivity) { *aConnectivity = mConnectivity; return NS_OK; } NS_IMETHODIMP nsIOService::SetConnectivity(bool aConnectivity) { LOG(("nsIOService::SetConnectivity aConnectivity=%d\n", aConnectivity)); // This should only be called from ContentChild to pass the connectivity // value from the chrome process to the content process. if (XRE_IsParentProcess()) { return NS_ERROR_NOT_AVAILABLE; } return SetConnectivityInternal(aConnectivity); } nsresult nsIOService::SetConnectivityInternal(bool aConnectivity) { LOG(("nsIOService::SetConnectivityInternal aConnectivity=%d\n", aConnectivity)); if (mConnectivity == aConnectivity) { // Nothing to do here. return NS_OK; } mConnectivity = aConnectivity; // This is used for PR_Connect PR_Close telemetry so it is important that // we have statistic about network change event even if we are offline. mLastConnectivityChange = PR_IntervalNow(); if (mCaptivePortalService) { if (aConnectivity && gCaptivePortalEnabled) { // This will also trigger a captive portal check for the new network static_cast(mCaptivePortalService.get())->Start(); } else { static_cast(mCaptivePortalService.get())->Stop(); } } nsCOMPtr observerService = services::GetObserverService(); if (!observerService) { return NS_OK; } // This notification sends the connectivity to the child processes if (XRE_IsParentProcess()) { observerService->NotifyObservers(nullptr, NS_IPC_IOSERVICE_SET_CONNECTIVITY_TOPIC, aConnectivity ? u"true" : u"false"); if (SocketProcessReady()) { Unused << mSocketProcess->GetActor()->SendSetConnectivity(aConnectivity); } } if (mOffline) { // We don't need to send any notifications if we're offline return NS_OK; } if (aConnectivity) { // If we were previously offline due to connectivity=false, // send the ONLINE notification observerService->NotifyObservers(static_cast(this), NS_IOSERVICE_OFFLINE_STATUS_TOPIC, (u"" NS_IOSERVICE_ONLINE)); } else { // If we were previously online and lost connectivity // send the OFFLINE notification observerService->NotifyObservers(static_cast(this), NS_IOSERVICE_GOING_OFFLINE_TOPIC, u"" NS_IOSERVICE_OFFLINE); observerService->NotifyObservers(static_cast(this), NS_IOSERVICE_OFFLINE_STATUS_TOPIC, u"" NS_IOSERVICE_OFFLINE); } return NS_OK; } NS_IMETHODIMP nsIOService::AllowPort(int32_t inPort, const char* scheme, bool* _retval) { int32_t port = inPort; if (port == -1) { *_retval = true; return NS_OK; } if (port <= 0 || port > std::numeric_limits::max()) { *_retval = false; return NS_OK; } nsTArray restrictedPortList; { MutexAutoLock lock(mMutex); restrictedPortList.Assign(mRestrictedPortList); } // first check to see if the port is in our blacklist: int32_t badPortListCnt = restrictedPortList.Length(); for (int i = 0; i < badPortListCnt; i++) { if (port == restrictedPortList[i]) { *_retval = false; // check to see if the protocol wants to override if (!scheme) return NS_OK; // We don't support get protocol handler off main thread. if (!NS_IsMainThread()) { return NS_OK; } nsCOMPtr handler; nsresult rv = GetProtocolHandler(scheme, getter_AddRefs(handler)); if (NS_FAILED(rv)) return rv; // let the protocol handler decide return handler->AllowPort(port, scheme, _retval); } } *_retval = true; return NS_OK; } //////////////////////////////////////////////////////////////////////////////// // static void nsIOService::PrefsChanged(const char* pref, void* self) { static_cast(self)->PrefsChanged(pref); } void nsIOService::PrefsChanged(const char* pref) { // Look for extra ports to block if (!pref || strcmp(pref, PORT_PREF("banned")) == 0) { ParsePortList(PORT_PREF("banned"), false); } // ...as well as previous blocks to remove. if (!pref || strcmp(pref, PORT_PREF("banned.override")) == 0) { ParsePortList(PORT_PREF("banned.override"), true); } if (!pref || strcmp(pref, MANAGE_OFFLINE_STATUS_PREF) == 0) { bool manage; if (mNetworkLinkServiceInitialized && NS_SUCCEEDED( Preferences::GetBool(MANAGE_OFFLINE_STATUS_PREF, &manage))) { LOG(("nsIOService::PrefsChanged ManageOfflineStatus manage=%d\n", manage)); SetManageOfflineStatus(manage); } } if (!pref || strcmp(pref, NECKO_BUFFER_CACHE_COUNT_PREF) == 0) { int32_t count; if (NS_SUCCEEDED( Preferences::GetInt(NECKO_BUFFER_CACHE_COUNT_PREF, &count))) { /* check for bogus values and default if we find such a value */ if (count > 0) gDefaultSegmentCount = count; } } if (!pref || strcmp(pref, NECKO_BUFFER_CACHE_SIZE_PREF) == 0) { int32_t size; if (NS_SUCCEEDED( Preferences::GetInt(NECKO_BUFFER_CACHE_SIZE_PREF, &size))) { /* check for bogus values and default if we find such a value * the upper limit here is arbitrary. having a 1mb segment size * is pretty crazy. if you remove this, consider adding some * integer rollover test. */ if (size > 0 && size < 1024 * 1024) gDefaultSegmentSize = size; } NS_WARNING_ASSERTION(!(size & (size - 1)), "network segment size is not a power of 2!"); } if (!pref || strcmp(pref, NETWORK_CAPTIVE_PORTAL_PREF) == 0) { nsresult rv = Preferences::GetBool(NETWORK_CAPTIVE_PORTAL_PREF, &gCaptivePortalEnabled); if (NS_SUCCEEDED(rv) && mCaptivePortalService) { if (gCaptivePortalEnabled) { static_cast(mCaptivePortalService.get()) ->Start(); } else { static_cast(mCaptivePortalService.get())->Stop(); } } } } void nsIOService::ParsePortList(const char* pref, bool remove) { nsAutoCString portList; nsTArray restrictedPortList; { MutexAutoLock lock(mMutex); restrictedPortList.Assign(std::move(mRestrictedPortList)); } // Get a pref string and chop it up into a list of ports. Preferences::GetCString(pref, portList); if (!portList.IsVoid()) { nsTArray portListArray; ParseString(portList, ',', portListArray); uint32_t index; for (index = 0; index < portListArray.Length(); index++) { portListArray[index].StripWhitespace(); int32_t portBegin, portEnd; if (PR_sscanf(portListArray[index].get(), "%d-%d", &portBegin, &portEnd) == 2) { if ((portBegin < 65536) && (portEnd < 65536)) { int32_t curPort; if (remove) { for (curPort = portBegin; curPort <= portEnd; curPort++) { restrictedPortList.RemoveElement(curPort); } } else { for (curPort = portBegin; curPort <= portEnd; curPort++) { restrictedPortList.AppendElement(curPort); } } } } else { nsresult aErrorCode; int32_t port = portListArray[index].ToInteger(&aErrorCode); if (NS_SUCCEEDED(aErrorCode) && port < 65536) { if (remove) { restrictedPortList.RemoveElement(port); } else { restrictedPortList.AppendElement(port); } } } } } MutexAutoLock lock(mMutex); mRestrictedPortList.Assign(std::move(restrictedPortList)); } class nsWakeupNotifier : public Runnable { public: explicit nsWakeupNotifier(nsIIOServiceInternal* ioService) : Runnable("net::nsWakeupNotifier"), mIOService(ioService) {} NS_IMETHOD Run() override { return mIOService->NotifyWakeup(); } private: virtual ~nsWakeupNotifier() = default; nsCOMPtr mIOService; }; NS_IMETHODIMP nsIOService::NotifyWakeup() { nsCOMPtr observerService = services::GetObserverService(); NS_ASSERTION(observerService, "The observer service should not be null"); if (observerService && StaticPrefs::network_notify_changed()) { (void)observerService->NotifyObservers(nullptr, NS_NETWORK_LINK_TOPIC, (u"" NS_NETWORK_LINK_DATA_CHANGED)); } RecheckCaptivePortal(); return NS_OK; } void nsIOService::SetHttpHandlerAlreadyShutingDown() { if (!mShutdown && !mOfflineForProfileChange) { mNetTearingDownStarted = PR_IntervalNow(); mHttpHandlerAlreadyShutingDown = true; } } // nsIObserver interface NS_IMETHODIMP nsIOService::Observe(nsISupports* subject, const char* topic, const char16_t* data) { if (UseSocketProcess() && SocketProcessReady() && mObserverTopicForSocketProcess.Contains(nsDependentCString(topic))) { nsCString topicStr(topic); nsString dataStr(data); Unused << mSocketProcess->GetActor()->SendNotifyObserver(topicStr, dataStr); } if (!strcmp(topic, kProfileChangeNetTeardownTopic)) { if (!mHttpHandlerAlreadyShutingDown) { mNetTearingDownStarted = PR_IntervalNow(); } mHttpHandlerAlreadyShutingDown = false; if (!mOffline) { mOfflineForProfileChange = true; SetOfflineInternal(true, false); } } else if (!strcmp(topic, kProfileChangeNetRestoreTopic)) { if (mOfflineForProfileChange) { mOfflineForProfileChange = false; SetOfflineInternal(false, false); } } else if (!strcmp(topic, kProfileDoChange)) { if (data && u"startup"_ns.Equals(data)) { // Lazy initialization of network link service (see bug 620472) InitializeNetworkLinkService(); // Set up the initilization flag regardless the actuall result. // If we fail here, we will fail always on. mNetworkLinkServiceInitialized = true; // And now reflect the preference setting PrefsChanged(MANAGE_OFFLINE_STATUS_PREF); // Bug 870460 - Read cookie database at an early-as-possible time // off main thread. Hence, we have more chance to finish db query // before something calls into the cookie service. nsCOMPtr cookieServ = do_GetService(NS_COOKIESERVICE_CONTRACTID); } } else if (!strcmp(topic, NS_XPCOM_SHUTDOWN_OBSERVER_ID)) { // Remember we passed XPCOM shutdown notification to prevent any // changes of the offline status from now. We must not allow going // online after this point. mShutdown = true; if (!mHttpHandlerAlreadyShutingDown && !mOfflineForProfileChange) { mNetTearingDownStarted = PR_IntervalNow(); } mHttpHandlerAlreadyShutingDown = false; SetOfflineInternal(true, false); if (mCaptivePortalService) { static_cast(mCaptivePortalService.get())->Stop(); mCaptivePortalService = nullptr; } SSLTokensCache::Shutdown(); DestroySocketProcess(); if (IsSocketProcessChild()) { Preferences::UnregisterCallbacks(nsIOService::OnTLSPrefChange, gCallbackSecurityPrefs, this); NSSShutdownForSocketProcess(); } } else if (!strcmp(topic, NS_NETWORK_LINK_TOPIC)) { OnNetworkLinkEvent(NS_ConvertUTF16toUTF8(data).get()); } else if (!strcmp(topic, NS_NETWORK_ID_CHANGED_TOPIC)) { LOG(("nsIOService::OnNetworkLinkEvent Network id changed")); } else if (!strcmp(topic, NS_WIDGET_WAKE_OBSERVER_TOPIC)) { // coming back alive from sleep // this indirection brought to you by: // https://bugzilla.mozilla.org/show_bug.cgi?id=1152048#c19 nsCOMPtr wakeupNotifier = new nsWakeupNotifier(this); NS_DispatchToMainThread(wakeupNotifier); } return NS_OK; } // nsINetUtil interface NS_IMETHODIMP nsIOService::ParseRequestContentType(const nsACString& aTypeHeader, nsACString& aCharset, bool* aHadCharset, nsACString& aContentType) { net_ParseRequestContentType(aTypeHeader, aContentType, aCharset, aHadCharset); return NS_OK; } // nsINetUtil interface NS_IMETHODIMP nsIOService::ParseResponseContentType(const nsACString& aTypeHeader, nsACString& aCharset, bool* aHadCharset, nsACString& aContentType) { net_ParseContentType(aTypeHeader, aContentType, aCharset, aHadCharset); return NS_OK; } NS_IMETHODIMP nsIOService::ProtocolHasFlags(nsIURI* uri, uint32_t flags, bool* result) { NS_ENSURE_ARG(uri); *result = false; nsAutoCString scheme; nsresult rv = uri->GetScheme(scheme); NS_ENSURE_SUCCESS(rv, rv); // Grab the protocol flags from the URI. uint32_t protocolFlags; nsCOMPtr handler; rv = GetProtocolHandler(scheme.get(), getter_AddRefs(handler)); NS_ENSURE_SUCCESS(rv, rv); rv = handler->DoGetProtocolFlags(uri, &protocolFlags); NS_ENSURE_SUCCESS(rv, rv); *result = (protocolFlags & flags) == flags; return NS_OK; } NS_IMETHODIMP nsIOService::URIChainHasFlags(nsIURI* uri, uint32_t flags, bool* result) { nsresult rv = ProtocolHasFlags(uri, flags, result); NS_ENSURE_SUCCESS(rv, rv); if (*result) { return rv; } // Dig deeper into the chain. Note that this is not a do/while loop to // avoid the extra addref/release on |uri| in the common (non-nested) case. nsCOMPtr nestedURI = do_QueryInterface(uri); while (nestedURI) { nsCOMPtr innerURI; rv = nestedURI->GetInnerURI(getter_AddRefs(innerURI)); NS_ENSURE_SUCCESS(rv, rv); rv = ProtocolHasFlags(innerURI, flags, result); if (*result) { return rv; } nestedURI = do_QueryInterface(innerURI); } return rv; } NS_IMETHODIMP nsIOService::SetManageOfflineStatus(bool aManage) { LOG(("nsIOService::SetManageOfflineStatus aManage=%d\n", aManage)); mManageLinkStatus = aManage; // When detection is not activated, the default connectivity state is true. if (!mManageLinkStatus) { SetConnectivityInternal(true); return NS_OK; } InitializeNetworkLinkService(); // If the NetworkLinkService is already initialized, it does not call // OnNetworkLinkEvent. This is needed, when mManageLinkStatus goes from // false to true. OnNetworkLinkEvent(NS_NETWORK_LINK_DATA_UNKNOWN); return NS_OK; } NS_IMETHODIMP nsIOService::GetManageOfflineStatus(bool* aManage) { *aManage = mManageLinkStatus; return NS_OK; } // input argument 'data' is already UTF8'ed nsresult nsIOService::OnNetworkLinkEvent(const char* data) { if (IsNeckoChild() || IsSocketProcessChild()) { // There is nothing IO service could do on the child process // with this at the moment. Feel free to add functionality // here at will, though. return NS_OK; } if (mShutdown) { return NS_ERROR_NOT_AVAILABLE; } nsCString dataAsString(data); for (auto* cp : mozilla::dom::ContentParent::AllProcesses( mozilla::dom::ContentParent::eLive)) { PNeckoParent* neckoParent = SingleManagedOrNull(cp->ManagedPNeckoParent()); if (!neckoParent) { continue; } Unused << neckoParent->SendNetworkChangeNotification(dataAsString); } LOG(("nsIOService::OnNetworkLinkEvent data:%s\n", data)); if (!mNetworkLinkService) { return NS_ERROR_FAILURE; } if (!mManageLinkStatus) { LOG(("nsIOService::OnNetworkLinkEvent mManageLinkStatus=false\n")); return NS_OK; } bool isUp = true; if (!strcmp(data, NS_NETWORK_LINK_DATA_CHANGED)) { mLastNetworkLinkChange = PR_IntervalNow(); // CHANGED means UP/DOWN didn't change // but the status of the captive portal may have changed. RecheckCaptivePortal(); return NS_OK; } if (!strcmp(data, NS_NETWORK_LINK_DATA_DOWN)) { isUp = false; } else if (!strcmp(data, NS_NETWORK_LINK_DATA_UP)) { isUp = true; } else if (!strcmp(data, NS_NETWORK_LINK_DATA_UNKNOWN)) { nsresult rv = mNetworkLinkService->GetIsLinkUp(&isUp); NS_ENSURE_SUCCESS(rv, rv); } else { NS_WARNING("Unhandled network event!"); return NS_OK; } return SetConnectivityInternal(isUp); } NS_IMETHODIMP nsIOService::EscapeString(const nsACString& aString, uint32_t aEscapeType, nsACString& aResult) { NS_ENSURE_ARG_MAX(aEscapeType, 4); nsAutoCString stringCopy(aString); nsCString result; if (!NS_Escape(stringCopy, result, (nsEscapeMask)aEscapeType)) { return NS_ERROR_OUT_OF_MEMORY; } aResult.Assign(result); return NS_OK; } NS_IMETHODIMP nsIOService::EscapeURL(const nsACString& aStr, uint32_t aFlags, nsACString& aResult) { aResult.Truncate(); NS_EscapeURL(aStr.BeginReading(), aStr.Length(), aFlags | esc_AlwaysCopy, aResult); return NS_OK; } NS_IMETHODIMP nsIOService::UnescapeString(const nsACString& aStr, uint32_t aFlags, nsACString& aResult) { aResult.Truncate(); NS_UnescapeURL(aStr.BeginReading(), aStr.Length(), aFlags | esc_AlwaysCopy, aResult); return NS_OK; } NS_IMETHODIMP nsIOService::ExtractCharsetFromContentType(const nsACString& aTypeHeader, nsACString& aCharset, int32_t* aCharsetStart, int32_t* aCharsetEnd, bool* aHadCharset) { nsAutoCString ignored; net_ParseContentType(aTypeHeader, ignored, aCharset, aHadCharset, aCharsetStart, aCharsetEnd); if (*aHadCharset && *aCharsetStart == *aCharsetEnd) { *aHadCharset = false; } return NS_OK; } // nsISpeculativeConnect class IOServiceProxyCallback final : public nsIProtocolProxyCallback { ~IOServiceProxyCallback() = default; public: NS_DECL_ISUPPORTS NS_DECL_NSIPROTOCOLPROXYCALLBACK IOServiceProxyCallback(nsIInterfaceRequestor* aCallbacks, nsIOService* aIOService) : mCallbacks(aCallbacks), mIOService(aIOService) {} private: RefPtr mCallbacks; RefPtr mIOService; }; NS_IMPL_ISUPPORTS(IOServiceProxyCallback, nsIProtocolProxyCallback) NS_IMETHODIMP IOServiceProxyCallback::OnProxyAvailable(nsICancelable* request, nsIChannel* channel, nsIProxyInfo* pi, nsresult status) { // Checking proxy status for speculative connect nsAutoCString type; if (NS_SUCCEEDED(status) && pi && NS_SUCCEEDED(pi->GetType(type)) && !type.EqualsLiteral("direct")) { // proxies dont do speculative connect return NS_OK; } nsCOMPtr uri; nsresult rv = channel->GetURI(getter_AddRefs(uri)); if (NS_FAILED(rv)) { return NS_OK; } nsAutoCString scheme; rv = uri->GetScheme(scheme); if (NS_FAILED(rv)) return NS_OK; nsCOMPtr handler; rv = mIOService->GetProtocolHandler(scheme.get(), getter_AddRefs(handler)); if (NS_FAILED(rv)) return NS_OK; nsCOMPtr speculativeHandler = do_QueryInterface(handler); if (!speculativeHandler) return NS_OK; nsCOMPtr loadInfo = channel->LoadInfo(); nsCOMPtr principal = loadInfo->GetLoadingPrincipal(); nsLoadFlags loadFlags = 0; channel->GetLoadFlags(&loadFlags); if (loadFlags & nsIRequest::LOAD_ANONYMOUS) { speculativeHandler->SpeculativeAnonymousConnect(uri, principal, mCallbacks); } else { speculativeHandler->SpeculativeConnect(uri, principal, mCallbacks); } return NS_OK; } nsresult nsIOService::SpeculativeConnectInternal( nsIURI* aURI, nsIPrincipal* aPrincipal, nsIInterfaceRequestor* aCallbacks, bool aAnonymous) { NS_ENSURE_ARG(aURI); if (!aURI->SchemeIs("http") && !aURI->SchemeIs("https")) { // We don't speculatively connect to non-HTTP[S] URIs. return NS_OK; } if (IsNeckoChild()) { gNeckoChild->SendSpeculativeConnect(aURI, aPrincipal, aAnonymous); return NS_OK; } // Check for proxy information. If there is a proxy configured then a // speculative connect should not be performed because the potential // reward is slim with tcp peers closely located to the browser. nsresult rv; nsCOMPtr pps = do_GetService(NS_PROTOCOLPROXYSERVICE_CONTRACTID, &rv); NS_ENSURE_SUCCESS(rv, rv); nsCOMPtr loadingPrincipal = aPrincipal; MOZ_ASSERT(aPrincipal, "We expect passing a principal here."); if (!aPrincipal) { return NS_ERROR_INVALID_ARG; } // XXX Bug 1724080: Avoid TCP connections on port 80 when https-only // or https-first is enabled. Let's create a dummy loadinfo which we // only use to determine whether we need ot upgrade the speculative // connection from http to https. nsCOMPtr httpsURI; if (aURI->SchemeIs("http")) { nsCOMPtr httpsOnlyCheckLoadInfo = new LoadInfo(loadingPrincipal, loadingPrincipal, nullptr, nsILoadInfo::SEC_ONLY_FOR_EXPLICIT_CONTENTSEC_CHECK, nsIContentPolicy::TYPE_SPECULATIVE); // Check if https-only, or https-first would upgrade the request if (nsHTTPSOnlyUtils::ShouldUpgradeRequest(aURI, httpsOnlyCheckLoadInfo) || nsHTTPSOnlyUtils::ShouldUpgradeHttpsFirstRequest( aURI, httpsOnlyCheckLoadInfo)) { rv = NS_GetSecureUpgradedURI(aURI, getter_AddRefs(httpsURI)); NS_ENSURE_SUCCESS(rv, rv); aURI = httpsURI.get(); } } // dummy channel used to create a TCP connection. // we perform security checks on the *real* channel, responsible // for any network loads. this real channel just checks the TCP // pool if there is an available connection created by the // channel we create underneath - hence it's safe to use // the systemPrincipal as the loadingPrincipal for this channel. nsCOMPtr channel; rv = NewChannelFromURI( aURI, nullptr, // aLoadingNode, loadingPrincipal, nullptr, // aTriggeringPrincipal, nsILoadInfo::SEC_ALLOW_CROSS_ORIGIN_SEC_CONTEXT_IS_NULL, nsIContentPolicy::TYPE_SPECULATIVE, getter_AddRefs(channel)); NS_ENSURE_SUCCESS(rv, rv); if (aAnonymous) { nsLoadFlags loadFlags = 0; channel->GetLoadFlags(&loadFlags); loadFlags |= nsIRequest::LOAD_ANONYMOUS; channel->SetLoadFlags(loadFlags); } nsCOMPtr cancelable; RefPtr callback = new IOServiceProxyCallback(aCallbacks, this); nsCOMPtr pps2 = do_QueryInterface(pps); if (pps2) { return pps2->AsyncResolve2(channel, 0, callback, nullptr, getter_AddRefs(cancelable)); } return pps->AsyncResolve(channel, 0, callback, nullptr, getter_AddRefs(cancelable)); } NS_IMETHODIMP nsIOService::SpeculativeConnect(nsIURI* aURI, nsIPrincipal* aPrincipal, nsIInterfaceRequestor* aCallbacks) { return SpeculativeConnectInternal(aURI, aPrincipal, aCallbacks, false); } NS_IMETHODIMP nsIOService::SpeculativeAnonymousConnect(nsIURI* aURI, nsIPrincipal* aPrincipal, nsIInterfaceRequestor* aCallbacks) { return SpeculativeConnectInternal(aURI, aPrincipal, aCallbacks, true); } NS_IMETHODIMP nsIOService::NotImplemented() { return NS_ERROR_NOT_IMPLEMENTED; } NS_IMETHODIMP nsIOService::GetSocketProcessLaunched(bool* aResult) { NS_ENSURE_ARG_POINTER(aResult); *aResult = SocketProcessReady(); return NS_OK; } bool nsIOService::HasObservers(const char* aTopic) { MOZ_ASSERT(false, "Calling this method is unexpected"); return false; } NS_IMETHODIMP nsIOService::GetSocketProcessId(uint64_t* aPid) { NS_ENSURE_ARG_POINTER(aPid); *aPid = 0; if (!mSocketProcess) { return NS_OK; } if (SocketProcessParent* actor = mSocketProcess->GetActor()) { *aPid = (uint64_t)actor->OtherPid(); } return NS_OK; } } // namespace net } // namespace mozilla