/* -*- Mode: C++; tab-width: 4; indent-tabs-mode: nil; c-basic-offset: 4 -*- */ /* 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/. */ #ifndef nsHttpHandler_h__ #define nsHttpHandler_h__ #include "nsHttp.h" #include "nsHttpAuthCache.h" #include "nsHttpConnectionMgr.h" #include "ASpdySession.h" #include "nsString.h" #include "nsCOMPtr.h" #include "nsWeakReference.h" #include "nsIHttpProtocolHandler.h" #include "nsIObserver.h" #include "nsISpeculativeConnect.h" #include "nsICache.h" class nsIHttpChannel; class nsIPrefBranch; class nsICancelable; class nsICookieService; class nsIIOService; class nsIObserverService; class nsISiteSecurityService; class nsIStreamConverterService; class nsITimer; namespace mozilla { namespace net { class ATokenBucketEvent; class EventTokenBucket; class Tickler; class nsHttpConnection; class nsHttpConnectionInfo; class nsHttpTransaction; //----------------------------------------------------------------------------- // nsHttpHandler - protocol handler for HTTP and HTTPS //----------------------------------------------------------------------------- class nsHttpHandler : public nsIHttpProtocolHandler , public nsIObserver , public nsSupportsWeakReference , public nsISpeculativeConnect { public: NS_DECL_THREADSAFE_ISUPPORTS NS_DECL_NSIPROTOCOLHANDLER NS_DECL_NSIPROXIEDPROTOCOLHANDLER NS_DECL_NSIHTTPPROTOCOLHANDLER NS_DECL_NSIOBSERVER NS_DECL_NSISPECULATIVECONNECT nsHttpHandler(); virtual ~nsHttpHandler(); nsresult Init(); nsresult AddStandardRequestHeaders(nsHttpHeaderArray *); nsresult AddConnectionHeader(nsHttpHeaderArray *, uint32_t capabilities); bool IsAcceptableEncoding(const char *encoding); const nsAFlatCString &UserAgent(); nsHttpVersion HttpVersion() { return mHttpVersion; } nsHttpVersion ProxyHttpVersion() { return mProxyHttpVersion; } uint8_t ReferrerLevel() { return mReferrerLevel; } bool SpoofReferrerSource() { return mSpoofReferrerSource; } uint8_t ReferrerTrimmingPolicy() { return mReferrerTrimmingPolicy; } uint8_t ReferrerXOriginPolicy() { return mReferrerXOriginPolicy; } bool SendSecureXSiteReferrer() { return mSendSecureXSiteReferrer; } uint8_t RedirectionLimit() { return mRedirectionLimit; } PRIntervalTime IdleTimeout() { return mIdleTimeout; } PRIntervalTime SpdyTimeout() { return mSpdyTimeout; } PRIntervalTime ResponseTimeout() { return mResponseTimeout; } uint16_t MaxRequestAttempts() { return mMaxRequestAttempts; } const char *DefaultSocketType() { return mDefaultSocketType.get(); /* ok to return null */ } uint32_t PhishyUserPassLength() { return mPhishyUserPassLength; } uint8_t GetQoSBits() { return mQoSBits; } uint16_t GetIdleSynTimeout() { return mIdleSynTimeout; } bool FastFallbackToIPv4() { return mFastFallbackToIPv4; } bool ProxyPipelining() { return mProxyPipelining; } uint32_t MaxSocketCount(); bool EnforceAssocReq() { return mEnforceAssocReq; } bool IsPersistentHttpsCachingEnabled() { return mEnablePersistentHttpsCaching; } bool IsTelemetryEnabled() { return mTelemetryEnabled; } bool AllowExperiments() { return mTelemetryEnabled && mAllowExperiments; } bool IsSpdyEnabled() { return mEnableSpdy; } bool IsSpdyV3Enabled() { return mSpdyV3; } bool IsSpdyV31Enabled() { return mSpdyV31; } bool IsHttp2DraftEnabled() { return mHttp2DraftEnabled; } bool EnforceHttp2TlsProfile() { return mEnforceHttp2TlsProfile; } bool CoalesceSpdy() { return mCoalesceSpdy; } bool UseSpdyPersistentSettings() { return mSpdyPersistentSettings; } uint32_t SpdySendingChunkSize() { return mSpdySendingChunkSize; } uint32_t SpdySendBufferSize() { return mSpdySendBufferSize; } uint32_t SpdyPushAllowance() { return mSpdyPushAllowance; } PRIntervalTime SpdyPingThreshold() { return mSpdyPingThreshold; } PRIntervalTime SpdyPingTimeout() { return mSpdyPingTimeout; } bool AllowPush() { return mAllowPush; } uint32_t ConnectTimeout() { return mConnectTimeout; } uint32_t ParallelSpeculativeConnectLimit() { return mParallelSpeculativeConnectLimit; } bool CriticalRequestPrioritization() { return mCriticalRequestPrioritization; } double BypassCacheLockThreshold() { return mBypassCacheLockThreshold; } bool UseRequestTokenBucket() { return mRequestTokenBucketEnabled; } uint16_t RequestTokenBucketMinParallelism() { return mRequestTokenBucketMinParallelism; } uint32_t RequestTokenBucketHz() { return mRequestTokenBucketHz; } uint32_t RequestTokenBucketBurst() {return mRequestTokenBucketBurst; } bool PromptTempRedirect() { return mPromptTempRedirect; } // TCP Keepalive configuration values. // Returns true if TCP keepalive should be enabled for short-lived conns. bool TCPKeepaliveEnabledForShortLivedConns() { return mTCPKeepaliveShortLivedEnabled; } // Return time (secs) that a connection is consider short lived (for TCP // keepalive purposes). After this time, the connection is long-lived. int32_t GetTCPKeepaliveShortLivedTime() { return mTCPKeepaliveShortLivedTimeS; } // Returns time (secs) before first TCP keepalive probes should be sent; // same time used between successful keepalive probes. int32_t GetTCPKeepaliveShortLivedIdleTime() { return mTCPKeepaliveShortLivedIdleTimeS; } // Returns true if TCP keepalive should be enabled for long-lived conns. bool TCPKeepaliveEnabledForLongLivedConns() { return mTCPKeepaliveLongLivedEnabled; } // Returns time (secs) before first TCP keepalive probes should be sent; // same time used between successful keepalive probes. int32_t GetTCPKeepaliveLongLivedIdleTime() { return mTCPKeepaliveLongLivedIdleTimeS; } nsHttpAuthCache *AuthCache(bool aPrivate) { return aPrivate ? &mPrivateAuthCache : &mAuthCache; } nsHttpConnectionMgr *ConnMgr() { return mConnMgr; } // cache support bool UseCache() const { return mUseCache; } uint32_t GenerateUniqueID() { return ++mLastUniqueID; } uint32_t SessionStartTime() { return mSessionStartTime; } // // Connection management methods: // // - the handler only owns idle connections; it does not own active // connections. // // - the handler keeps a count of active connections to enforce the // steady-state max-connections pref. // // Called to kick-off a new transaction, by default the transaction // will be put on the pending transaction queue if it cannot be // initiated at this time. Callable from any thread. nsresult InitiateTransaction(nsHttpTransaction *trans, int32_t priority) { return mConnMgr->AddTransaction(trans, priority); } // Called to change the priority of an existing transaction that has // already been initiated. nsresult RescheduleTransaction(nsHttpTransaction *trans, int32_t priority) { return mConnMgr->RescheduleTransaction(trans, priority); } // Called to cancel a transaction, which may or may not be assigned to // a connection. Callable from any thread. nsresult CancelTransaction(nsHttpTransaction *trans, nsresult reason) { return mConnMgr->CancelTransaction(trans, reason); } // Called when a connection is done processing a transaction. Callable // from any thread. nsresult ReclaimConnection(nsHttpConnection *conn) { return mConnMgr->ReclaimConnection(conn); } nsresult ProcessPendingQ(nsHttpConnectionInfo *cinfo) { return mConnMgr->ProcessPendingQ(cinfo); } nsresult ProcessPendingQ() { return mConnMgr->ProcessPendingQ(); } nsresult GetSocketThreadTarget(nsIEventTarget **target) { return mConnMgr->GetSocketThreadTarget(target); } nsresult SpeculativeConnect(nsHttpConnectionInfo *ci, nsIInterfaceRequestor *callbacks, uint32_t caps = 0) { TickleWifi(callbacks); return mConnMgr->SpeculativeConnect(ci, callbacks, caps); } // // The HTTP handler caches pointers to specific XPCOM services, and // provides the following helper routines for accessing those services: // nsresult GetStreamConverterService(nsIStreamConverterService **); nsresult GetIOService(nsIIOService** service); nsICookieService * GetCookieService(); // not addrefed nsISiteSecurityService * GetSSService(); // callable from socket thread only uint32_t Get32BitsOfPseudoRandom(); // Called by the channel synchronously during asyncOpen void OnOpeningRequest(nsIHttpChannel *chan) { NotifyObservers(chan, NS_HTTP_ON_OPENING_REQUEST_TOPIC); } // Called by the channel before writing a request void OnModifyRequest(nsIHttpChannel *chan) { NotifyObservers(chan, NS_HTTP_ON_MODIFY_REQUEST_TOPIC); } // Called by the channel once headers are available void OnExamineResponse(nsIHttpChannel *chan) { NotifyObservers(chan, NS_HTTP_ON_EXAMINE_RESPONSE_TOPIC); } // Called by the channel once headers have been merged with cached headers void OnExamineMergedResponse(nsIHttpChannel *chan) { NotifyObservers(chan, NS_HTTP_ON_EXAMINE_MERGED_RESPONSE_TOPIC); } // Called by channels before a redirect happens. This notifies both the // channel's and the global redirect observers. nsresult AsyncOnChannelRedirect(nsIChannel* oldChan, nsIChannel* newChan, uint32_t flags); // Called by the channel when the response is read from the cache without // communicating with the server. void OnExamineCachedResponse(nsIHttpChannel *chan) { NotifyObservers(chan, NS_HTTP_ON_EXAMINE_CACHED_RESPONSE_TOPIC); } // Generates the host:port string for use in the Host: header as well as the // CONNECT line for proxies. This handles IPv6 literals correctly. static nsresult GenerateHostPort(const nsCString& host, int32_t port, nsCString& hostLine); bool GetPipelineAggressive() { return mPipelineAggressive; } void GetMaxPipelineObjectSize(int64_t *outVal) { *outVal = mMaxPipelineObjectSize; } bool GetPipelineEnabled() { return mCapabilities & NS_HTTP_ALLOW_PIPELINING; } bool GetPipelineRescheduleOnTimeout() { return mPipelineRescheduleOnTimeout; } PRIntervalTime GetPipelineRescheduleTimeout() { return mPipelineRescheduleTimeout; } PRIntervalTime GetPipelineTimeout() { return mPipelineReadTimeout; } SpdyInformation *SpdyInfo() { return &mSpdyInfo; } // returns true in between Init and Shutdown states bool Active() { return mHandlerActive; } static void GetCacheSessionNameForStoragePolicy( nsCacheStoragePolicy storagePolicy, bool isPrivate, uint32_t appId, bool inBrowser, nsACString& sessionName); // When the disk cache is responding slowly its use is suppressed // for 1 minute for most requests. Callable from main thread only. TimeStamp GetCacheSkippedUntil() { return mCacheSkippedUntil; } void SetCacheSkippedUntil(TimeStamp arg) { mCacheSkippedUntil = arg; } void ClearCacheSkippedUntil() { mCacheSkippedUntil = TimeStamp(); } private: // // Useragent/prefs helper methods // void BuildUserAgent(); void InitUserAgentComponents(); void PrefsChanged(nsIPrefBranch *prefs, const char *pref); nsresult SetAccept(const char *); nsresult SetAcceptLanguages(const char *); nsresult SetAcceptEncodings(const char *); nsresult InitConnectionMgr(); void NotifyObservers(nsIHttpChannel *chan, const char *event); static void TimerCallback(nsITimer * aTimer, void * aClosure); private: // cached services nsMainThreadPtrHandle mIOService; nsMainThreadPtrHandle mStreamConvSvc; nsMainThreadPtrHandle mObserverService; nsMainThreadPtrHandle mCookieService; nsMainThreadPtrHandle mSSService; // the authentication credentials cache nsHttpAuthCache mAuthCache; nsHttpAuthCache mPrivateAuthCache; // the connection manager nsHttpConnectionMgr *mConnMgr; // // prefs // uint8_t mHttpVersion; uint8_t mProxyHttpVersion; uint32_t mCapabilities; uint8_t mReferrerLevel; uint8_t mSpoofReferrerSource; uint8_t mReferrerTrimmingPolicy; uint8_t mReferrerXOriginPolicy; bool mFastFallbackToIPv4; bool mProxyPipelining; PRIntervalTime mIdleTimeout; PRIntervalTime mSpdyTimeout; PRIntervalTime mResponseTimeout; uint16_t mMaxRequestAttempts; uint16_t mMaxRequestDelay; uint16_t mIdleSynTimeout; bool mPipeliningEnabled; uint16_t mMaxConnections; uint8_t mMaxPersistentConnectionsPerServer; uint8_t mMaxPersistentConnectionsPerProxy; uint16_t mMaxPipelinedRequests; uint16_t mMaxOptimisticPipelinedRequests; bool mPipelineAggressive; int64_t mMaxPipelineObjectSize; bool mPipelineRescheduleOnTimeout; PRIntervalTime mPipelineRescheduleTimeout; PRIntervalTime mPipelineReadTimeout; nsCOMPtr mPipelineTestTimer; uint8_t mRedirectionLimit; // we'll warn the user if we load an URL containing a userpass field // unless its length is less than this threshold. this warning is // intended to protect the user against spoofing attempts that use // the userpass field of the URL to obscure the actual origin server. uint8_t mPhishyUserPassLength; uint8_t mQoSBits; bool mPipeliningOverSSL; bool mEnforceAssocReq; nsCString mAccept; nsCString mAcceptLanguages; nsCString mAcceptEncodings; nsXPIDLCString mDefaultSocketType; // cache support uint32_t mLastUniqueID; uint32_t mSessionStartTime; // useragent components nsCString mLegacyAppName; nsCString mLegacyAppVersion; nsCString mPlatform; nsCString mOscpu; nsCString mMisc; nsCString mProduct; nsXPIDLCString mProductSub; nsXPIDLCString mAppName; nsXPIDLCString mAppVersion; nsCString mCompatFirefox; bool mCompatFirefoxEnabled; nsXPIDLCString mCompatDevice; nsCString mUserAgent; nsXPIDLCString mUserAgentOverride; bool mUserAgentIsDirty; // true if mUserAgent should be rebuilt bool mUseCache; bool mPromptTempRedirect; // mSendSecureXSiteReferrer: default is false, // if true allow referrer headers between secure non-matching hosts bool mSendSecureXSiteReferrer; // Persistent HTTPS caching flag bool mEnablePersistentHttpsCaching; // For broadcasting tracking preference bool mDoNotTrackEnabled; uint8_t mDoNotTrackValue; // Whether telemetry is reported or not uint32_t mTelemetryEnabled : 1; // The value of network.allow-experiments uint32_t mAllowExperiments : 1; // true in between init and shutdown states uint32_t mHandlerActive : 1; uint32_t mEnableSpdy : 1; uint32_t mSpdyV3 : 1; uint32_t mSpdyV31 : 1; uint32_t mHttp2DraftEnabled : 1; uint32_t mEnforceHttp2TlsProfile : 1; uint32_t mCoalesceSpdy : 1; uint32_t mSpdyPersistentSettings : 1; uint32_t mAllowPush : 1; // Try to use SPDY features instead of HTTP/1.1 over SSL SpdyInformation mSpdyInfo; uint32_t mSpdySendingChunkSize; uint32_t mSpdySendBufferSize; uint32_t mSpdyPushAllowance; PRIntervalTime mSpdyPingThreshold; PRIntervalTime mSpdyPingTimeout; // The maximum amount of time to wait for socket transport to be // established. In milliseconds. uint32_t mConnectTimeout; // The maximum amount of time the nsICacheSession lock can be held // before a new transaction bypasses the cache. In milliseconds. double mBypassCacheLockThreshold; // The maximum number of current global half open sockets allowable // when starting a new speculative connection. uint32_t mParallelSpeculativeConnectLimit; // For Rate Pacing of HTTP/1 requests through a netwerk/base/src/EventTokenBucket // Active requests <= *MinParallelism are not subject to the rate pacing bool mRequestTokenBucketEnabled; uint16_t mRequestTokenBucketMinParallelism; uint32_t mRequestTokenBucketHz; // EventTokenBucket HZ uint32_t mRequestTokenBucketBurst; // EventTokenBucket Burst // Whether or not to block requests for non head js/css items (e.g. media) // while those elements load. bool mCriticalRequestPrioritization; // When the disk cache is responding slowly its use is suppressed // for 1 minute for most requests. TimeStamp mCacheSkippedUntil; // TCP Keepalive configuration values. // True if TCP keepalive is enabled for short-lived conns. bool mTCPKeepaliveShortLivedEnabled; // Time (secs) indicating how long a conn is considered short-lived. int32_t mTCPKeepaliveShortLivedTimeS; // Time (secs) before first keepalive probe; between successful probes. int32_t mTCPKeepaliveShortLivedIdleTimeS; // True if TCP keepalive is enabled for long-lived conns. bool mTCPKeepaliveLongLivedEnabled; // Time (secs) before first keepalive probe; between successful probes. int32_t mTCPKeepaliveLongLivedIdleTimeS; private: // For Rate Pacing Certain Network Events. Only assign this pointer on // socket thread. void MakeNewRequestTokenBucket(); nsRefPtr mRequestTokenBucket; public: // Socket thread only nsresult SubmitPacedRequest(ATokenBucketEvent *event, nsICancelable **cancel) { if (!mRequestTokenBucket) return NS_ERROR_UNEXPECTED; return mRequestTokenBucket->SubmitEvent(event, cancel); } // Socket thread only void SetRequestTokenBucket(EventTokenBucket *aTokenBucket) { mRequestTokenBucket = aTokenBucket; } private: nsRefPtr mWifiTickler; void TickleWifi(nsIInterfaceRequestor *cb); }; extern nsHttpHandler *gHttpHandler; //----------------------------------------------------------------------------- // nsHttpsHandler - thin wrapper to distinguish the HTTP handler from the // HTTPS handler (even though they share the same impl). //----------------------------------------------------------------------------- class nsHttpsHandler : public nsIHttpProtocolHandler , public nsSupportsWeakReference , public nsISpeculativeConnect { public: // we basically just want to override GetScheme and GetDefaultPort... // all other methods should be forwarded to the nsHttpHandler instance. NS_DECL_THREADSAFE_ISUPPORTS NS_DECL_NSIPROTOCOLHANDLER NS_FORWARD_NSIPROXIEDPROTOCOLHANDLER (gHttpHandler->) NS_FORWARD_NSIHTTPPROTOCOLHANDLER (gHttpHandler->) NS_FORWARD_NSISPECULATIVECONNECT (gHttpHandler->) nsHttpsHandler() { } virtual ~nsHttpsHandler() { } nsresult Init(); }; }} // namespace mozilla::net #endif // nsHttpHandler_h__