/* -*- Mode: C++; tab-width: 2; indent-tabs-mode: nil; c-basic-offset: 2 -*- * * 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 "nsNSSIOLayer.h" #include #include "NSSCertDBTrustDomain.h" #include "NSSErrorsService.h" #include "PSMRunnable.h" #include "SSLServerCertVerification.h" #include "ScopedNSSTypes.h" #include "SharedSSLState.h" #include "keyhi.h" #include "mozilla/Casting.h" #include "mozilla/DebugOnly.h" #include "mozilla/Logging.h" #include "mozilla/Move.h" #include "mozilla/Preferences.h" #include "nsArray.h" #include "nsArrayUtils.h" #include "nsCharSeparatedTokenizer.h" #include "nsClientAuthRemember.h" #include "nsContentUtils.h" #include "nsIClientAuthDialogs.h" #include "nsIConsoleService.h" #include "nsIPrefService.h" #include "nsISocketProvider.h" #include "nsIWebProgressListener.h" #include "nsNSSCertHelper.h" #include "nsNSSComponent.h" #include "nsPrintfCString.h" #include "nsServiceManagerUtils.h" #include "pkix/pkixtypes.h" #include "prmem.h" #include "prnetdb.h" #include "secder.h" #include "secerr.h" #include "ssl.h" #include "sslerr.h" #include "sslproto.h" using namespace mozilla; using namespace mozilla::psm; //#define DEBUG_SSL_VERBOSE //Enable this define to get minimal //reports when doing SSL read/write //#define DUMP_BUFFER //Enable this define along with //DEBUG_SSL_VERBOSE to dump SSL //read/write buffer to a log. //Uses PR_LOG except on Mac where //we always write out to our own //file. namespace { #define MAX_ALPN_LENGTH 255 void getSiteKey(const nsACString& hostName, uint16_t port, /*out*/ nsCSubstring& key) { key = hostName; key.AppendASCII(":"); key.AppendInt(port); } // Historically, we have required that the server negotiate ALPN or NPN in // order to false start, as a compatibility hack to work around // implementations that just stop responding during false start. However, now // false start is resricted to modern crypto (TLS 1.2 and AEAD cipher suites) // so it is less likely that requring NPN or ALPN is still necessary. static const bool FALSE_START_REQUIRE_NPN_DEFAULT = false; } // unnamed namespace extern LazyLogModule gPIPNSSLog; nsNSSSocketInfo::nsNSSSocketInfo(SharedSSLState& aState, uint32_t providerFlags) : mFd(nullptr), mCertVerificationState(before_cert_verification), mSharedState(aState), mForSTARTTLS(false), mHandshakePending(true), mRememberClientAuthCertificate(false), mPreliminaryHandshakeDone(false), mNPNCompleted(false), mEarlyDataAccepted(false), mFalseStartCallbackCalled(false), mFalseStarted(false), mIsFullHandshake(false), mHandshakeCompleted(false), mJoined(false), mSentClientCert(false), mNotedTimeUntilReady(false), mFailedVerification(false), mKEAUsed(nsISSLSocketControl::KEY_EXCHANGE_UNKNOWN), mKEAKeyBits(0), mSSLVersionUsed(nsISSLSocketControl::SSL_VERSION_UNKNOWN), mMACAlgorithmUsed(nsISSLSocketControl::SSL_MAC_UNKNOWN), mBypassAuthentication(false), mProviderFlags(providerFlags), mSocketCreationTimestamp(TimeStamp::Now()), mPlaintextBytesRead(0), mClientCert(nullptr) { mTLSVersionRange.min = 0; mTLSVersionRange.max = 0; } nsNSSSocketInfo::~nsNSSSocketInfo() { } NS_IMPL_ISUPPORTS_INHERITED(nsNSSSocketInfo, TransportSecurityInfo, nsISSLSocketControl, nsIClientAuthUserDecision) NS_IMETHODIMP nsNSSSocketInfo::GetProviderFlags(uint32_t* aProviderFlags) { *aProviderFlags = mProviderFlags; return NS_OK; } NS_IMETHODIMP nsNSSSocketInfo::GetKEAUsed(int16_t* aKea) { *aKea = mKEAUsed; return NS_OK; } NS_IMETHODIMP nsNSSSocketInfo::GetKEAKeyBits(uint32_t* aKeyBits) { *aKeyBits = mKEAKeyBits; return NS_OK; } NS_IMETHODIMP nsNSSSocketInfo::GetSSLVersionUsed(int16_t* aSSLVersionUsed) { *aSSLVersionUsed = mSSLVersionUsed; return NS_OK; } NS_IMETHODIMP nsNSSSocketInfo::GetSSLVersionOffered(int16_t* aSSLVersionOffered) { *aSSLVersionOffered = mTLSVersionRange.max; return NS_OK; } NS_IMETHODIMP nsNSSSocketInfo::GetMACAlgorithmUsed(int16_t* aMac) { *aMac = mMACAlgorithmUsed; return NS_OK; } NS_IMETHODIMP nsNSSSocketInfo::GetClientCert(nsIX509Cert** aClientCert) { NS_ENSURE_ARG_POINTER(aClientCert); *aClientCert = mClientCert; NS_IF_ADDREF(*aClientCert); return NS_OK; } NS_IMETHODIMP nsNSSSocketInfo::SetClientCert(nsIX509Cert* aClientCert) { mClientCert = aClientCert; return NS_OK; } NS_IMETHODIMP nsNSSSocketInfo::GetBypassAuthentication(bool* arg) { *arg = mBypassAuthentication; return NS_OK; } NS_IMETHODIMP nsNSSSocketInfo::GetFailedVerification(bool* arg) { *arg = mFailedVerification; return NS_OK; } NS_IMETHODIMP nsNSSSocketInfo::GetRememberClientAuthCertificate(bool* aRemember) { NS_ENSURE_ARG_POINTER(aRemember); *aRemember = mRememberClientAuthCertificate; return NS_OK; } NS_IMETHODIMP nsNSSSocketInfo::SetRememberClientAuthCertificate(bool aRemember) { mRememberClientAuthCertificate = aRemember; return NS_OK; } NS_IMETHODIMP nsNSSSocketInfo::GetNotificationCallbacks(nsIInterfaceRequestor** aCallbacks) { *aCallbacks = mCallbacks; NS_IF_ADDREF(*aCallbacks); return NS_OK; } NS_IMETHODIMP nsNSSSocketInfo::SetNotificationCallbacks(nsIInterfaceRequestor* aCallbacks) { if (!aCallbacks) { mCallbacks = nullptr; return NS_OK; } mCallbacks = aCallbacks; return NS_OK; } void nsNSSSocketInfo::NoteTimeUntilReady() { if (mNotedTimeUntilReady) return; mNotedTimeUntilReady = true; MOZ_LOG(gPIPNSSLog, LogLevel::Debug, ("[%p] nsNSSSocketInfo::NoteTimeUntilReady\n", mFd)); } void nsNSSSocketInfo::SetHandshakeCompleted() { // Remove the plain text layer as it is not needed anymore. // The plain text layer is not always present - so its not a fatal error // if it cannot be removed PRFileDesc* poppedPlaintext = PR_GetIdentitiesLayer(mFd, nsSSLIOLayerHelpers::nsSSLPlaintextLayerIdentity); if (poppedPlaintext) { PR_PopIOLayer(mFd, nsSSLIOLayerHelpers::nsSSLPlaintextLayerIdentity); poppedPlaintext->dtor(poppedPlaintext); } mHandshakeCompleted = true; MOZ_LOG(gPIPNSSLog, LogLevel::Debug, ("[%p] nsNSSSocketInfo::SetHandshakeCompleted\n", (void*) mFd)); mIsFullHandshake = false; // reset for next handshake on this connection } void nsNSSSocketInfo::SetNegotiatedNPN(const char* value, uint32_t length) { if (!value) { mNegotiatedNPN.Truncate(); } else { mNegotiatedNPN.Assign(value, length); } mNPNCompleted = true; } NS_IMETHODIMP nsNSSSocketInfo::GetNegotiatedNPN(nsACString& aNegotiatedNPN) { if (!mNPNCompleted) return NS_ERROR_NOT_CONNECTED; aNegotiatedNPN = mNegotiatedNPN; return NS_OK; } NS_IMETHODIMP nsNSSSocketInfo::GetAlpnEarlySelection(nsACString& aAlpnSelected) { nsNSSShutDownPreventionLock locker; if (isAlreadyShutDown() || isPK11LoggedOut()) { return NS_ERROR_NOT_AVAILABLE; } SSLNextProtoState alpnState; unsigned char chosenAlpn[MAX_ALPN_LENGTH]; unsigned int chosenAlpnLen; SECStatus rv = SSL_GetNextProto(mFd, &alpnState, chosenAlpn, &chosenAlpnLen, AssertedCast(ArrayLength(chosenAlpn))); if (rv != SECSuccess || alpnState != SSL_NEXT_PROTO_EARLY_VALUE || chosenAlpnLen == 0) { return NS_ERROR_NOT_AVAILABLE; } aAlpnSelected.Assign(BitwiseCast(chosenAlpn), chosenAlpnLen); return NS_OK; } NS_IMETHODIMP nsNSSSocketInfo::GetEarlyDataAccepted(bool* aAccepted) { *aAccepted = mEarlyDataAccepted; return NS_OK; } void nsNSSSocketInfo::SetEarlyDataAccepted(bool aAccepted) { mEarlyDataAccepted = aAccepted; } NS_IMETHODIMP nsNSSSocketInfo::DriveHandshake() { nsNSSShutDownPreventionLock locker; if (isAlreadyShutDown() || isPK11LoggedOut()) { return NS_ERROR_NOT_AVAILABLE; } if (!mFd) { return NS_ERROR_FAILURE; } PRErrorCode errorCode = GetErrorCode(); if (errorCode) { return GetXPCOMFromNSSError(errorCode); } SECStatus rv = SSL_ForceHandshake(mFd); if (rv != SECSuccess) { errorCode = PR_GetError(); if (errorCode == PR_WOULD_BLOCK_ERROR) { return NS_BASE_STREAM_WOULD_BLOCK; } SetCanceled(errorCode, PlainErrorMessage); return GetXPCOMFromNSSError(errorCode); } return NS_OK; } NS_IMETHODIMP nsNSSSocketInfo::IsAcceptableForHost(const nsACString& hostname, bool* _retval) { NS_ENSURE_ARG(_retval); *_retval = false; // If this is the same hostname then the certicate status does not // need to be considered. They are joinable. if (hostname.Equals(GetHostName())) { *_retval = true; return NS_OK; } // Before checking the server certificate we need to make sure the // handshake has completed. if (!mHandshakeCompleted || !SSLStatus() || !SSLStatus()->HasServerCert()) { return NS_OK; } // If the cert has error bits (e.g. it is untrusted) then do not join. // The value of mHaveCertErrorBits is only reliable because we know that // the handshake completed. if (SSLStatus()->mHaveCertErrorBits) return NS_OK; // If the connection is using client certificates then do not join // because the user decides on whether to send client certs to hosts on a // per-domain basis. if (mSentClientCert) return NS_OK; // Ensure that the server certificate covers the hostname that would // like to join this connection UniqueCERTCertificate nssCert; nsCOMPtr cert; if (NS_FAILED(SSLStatus()->GetServerCert(getter_AddRefs(cert)))) { return NS_OK; } if (cert) { nssCert.reset(cert->GetCert()); } if (!nssCert) { return NS_OK; } // Attempt to verify the joinee's certificate using the joining hostname. // This ensures that any hostname-specific verification logic (e.g. key // pinning) is satisfied by the joinee's certificate chain. // This verification only uses local information; since we're on the network // thread, we would be blocking on ourselves if we attempted any network i/o. // TODO(bug 1056935): The certificate chain built by this verification may be // different than the certificate chain originally built during the joined // connection's TLS handshake. Consequently, we may report a wrong and/or // misleading certificate chain for HTTP transactions coalesced onto this // connection. This may become problematic in the future. For example, // if/when we begin relying on intermediate certificates being stored in the // securityInfo of a cached HTTPS response, that cached certificate chain may // actually be the wrong chain. We should consider having JoinConnection // return the certificate chain built here, so that the calling Necko code // can associate the correct certificate chain with the HTTP transactions it // is trying to join onto this connection. RefPtr certVerifier(GetDefaultCertVerifier()); if (!certVerifier) { return NS_OK; } nsAutoCString hostnameFlat(PromiseFlatCString(hostname)); CertVerifier::Flags flags = CertVerifier::FLAG_LOCAL_ONLY; UniqueCERTCertList unusedBuiltChain; mozilla::pkix::Result result = certVerifier->VerifySSLServerCert(nssCert, nullptr, // stapledOCSPResponse nullptr, // sctsFromTLSExtension mozilla::pkix::Now(), nullptr, // pinarg hostnameFlat.get(), unusedBuiltChain, false, // save intermediates flags); if (result != mozilla::pkix::Success) { return NS_OK; } // All tests pass *_retval = true; return NS_OK; } NS_IMETHODIMP nsNSSSocketInfo::JoinConnection(const nsACString& npnProtocol, const nsACString& hostname, int32_t port, bool* _retval) { *_retval = false; // Different ports may not be joined together if (port != GetPort()) return NS_OK; // Make sure NPN has been completed and matches requested npnProtocol if (!mNPNCompleted || !mNegotiatedNPN.Equals(npnProtocol)) return NS_OK; if (mBypassAuthentication) { // An unauthenticated connection does not know whether or not it // is acceptable for a particular hostname return NS_OK; } IsAcceptableForHost(hostname, _retval); if (*_retval) { // All tests pass - this is joinable mJoined = true; } return NS_OK; } bool nsNSSSocketInfo::GetForSTARTTLS() { return mForSTARTTLS; } void nsNSSSocketInfo::SetForSTARTTLS(bool aForSTARTTLS) { mForSTARTTLS = aForSTARTTLS; } NS_IMETHODIMP nsNSSSocketInfo::ProxyStartSSL() { return ActivateSSL(); } NS_IMETHODIMP nsNSSSocketInfo::StartTLS() { return ActivateSSL(); } NS_IMETHODIMP nsNSSSocketInfo::SetNPNList(nsTArray& protocolArray) { nsNSSShutDownPreventionLock locker; if (isAlreadyShutDown()) return NS_ERROR_NOT_AVAILABLE; if (!mFd) return NS_ERROR_FAILURE; // the npn list is a concatenated list of 8 bit byte strings. nsCString npnList; for (uint32_t index = 0; index < protocolArray.Length(); ++index) { if (protocolArray[index].IsEmpty() || protocolArray[index].Length() > 255) return NS_ERROR_ILLEGAL_VALUE; npnList.Append(protocolArray[index].Length()); npnList.Append(protocolArray[index]); } if (SSL_SetNextProtoNego( mFd, BitwiseCast(npnList.get()), npnList.Length()) != SECSuccess) return NS_ERROR_FAILURE; return NS_OK; } nsresult nsNSSSocketInfo::ActivateSSL() { nsNSSShutDownPreventionLock locker; if (isAlreadyShutDown()) return NS_ERROR_NOT_AVAILABLE; if (SECSuccess != SSL_OptionSet(mFd, SSL_SECURITY, true)) return NS_ERROR_FAILURE; if (SECSuccess != SSL_ResetHandshake(mFd, false)) return NS_ERROR_FAILURE; mHandshakePending = true; return NS_OK; } nsresult nsNSSSocketInfo::GetFileDescPtr(PRFileDesc** aFilePtr) { *aFilePtr = mFd; return NS_OK; } nsresult nsNSSSocketInfo::SetFileDescPtr(PRFileDesc* aFilePtr) { mFd = aFilePtr; return NS_OK; } void nsNSSSocketInfo::SetCertVerificationWaiting() { // mCertVerificationState may be before_cert_verification for the first // handshake on the connection, or after_cert_verification for subsequent // renegotiation handshakes. NS_ASSERTION(mCertVerificationState != waiting_for_cert_verification, "Invalid state transition to waiting_for_cert_verification"); mCertVerificationState = waiting_for_cert_verification; } // Be careful that SetCertVerificationResult does NOT get called while we are // processing a SSL callback function, because SSL_AuthCertificateComplete will // attempt to acquire locks that are already held by libssl when it calls // callbacks. void nsNSSSocketInfo::SetCertVerificationResult(PRErrorCode errorCode, SSLErrorMessageType errorMessageType) { NS_ASSERTION(mCertVerificationState == waiting_for_cert_verification, "Invalid state transition to cert_verification_finished"); if (mFd) { SECStatus rv = SSL_AuthCertificateComplete(mFd, errorCode); // Only replace errorCode if there was originally no error if (rv != SECSuccess && errorCode == 0) { errorCode = PR_GetError(); errorMessageType = PlainErrorMessage; if (errorCode == 0) { NS_ERROR("SSL_AuthCertificateComplete didn't set error code"); errorCode = PR_INVALID_STATE_ERROR; } } } if (errorCode) { mFailedVerification = true; SetCanceled(errorCode, errorMessageType); } mCertVerificationState = after_cert_verification; } SharedSSLState& nsNSSSocketInfo::SharedState() { return mSharedState; } void nsSSLIOLayerHelpers::Cleanup() { MutexAutoLock lock(mutex); mTLSIntoleranceInfo.Clear(); mInsecureFallbackSites.Clear(); } static void nsHandleSSLError(nsNSSSocketInfo* socketInfo, ::mozilla::psm::SSLErrorMessageType errtype, PRErrorCode err) { if (!NS_IsMainThread()) { NS_ERROR("nsHandleSSLError called off the main thread"); return; } // SetCanceled is only called by the main thread or the socket transport // thread. Whenever this function is called on the main thread, the SSL // thread is blocked on it. So, no mutex is necessary for // SetCanceled()/GetError*(). if (socketInfo->GetErrorCode()) { // If the socket has been flagged as canceled, // the code who did was responsible for setting the error code. return; } // We must cancel first, which sets the error code. socketInfo->SetCanceled(err, PlainErrorMessage); nsXPIDLString errorString; socketInfo->GetErrorLogMessage(err, errtype, errorString); if (!errorString.IsEmpty()) { nsContentUtils::LogSimpleConsoleError(errorString, "SSL"); } } namespace { enum Operation { reading, writing, not_reading_or_writing }; int32_t checkHandshake(int32_t bytesTransfered, bool wasReading, PRFileDesc* ssl_layer_fd, nsNSSSocketInfo* socketInfo); nsNSSSocketInfo* getSocketInfoIfRunning(PRFileDesc* fd, Operation op, const nsNSSShutDownPreventionLock& /*proofOfLock*/) { if (!fd || !fd->lower || !fd->secret || fd->identity != nsSSLIOLayerHelpers::nsSSLIOLayerIdentity) { NS_ERROR("bad file descriptor passed to getSocketInfoIfRunning"); PR_SetError(PR_BAD_DESCRIPTOR_ERROR, 0); return nullptr; } nsNSSSocketInfo* socketInfo = (nsNSSSocketInfo*) fd->secret; if (socketInfo->isAlreadyShutDown() || socketInfo->isPK11LoggedOut()) { PR_SetError(PR_SOCKET_SHUTDOWN_ERROR, 0); return nullptr; } if (socketInfo->GetErrorCode()) { PRErrorCode err = socketInfo->GetErrorCode(); PR_SetError(err, 0); if (op == reading || op == writing) { // We must do TLS intolerance checks for reads and writes, for timeouts // in particular. (void) checkHandshake(-1, op == reading, fd, socketInfo); } // If we get here, it is probably because cert verification failed and this // is the first I/O attempt since that failure. return nullptr; } return socketInfo; } } // namespace static PRStatus nsSSLIOLayerConnect(PRFileDesc* fd, const PRNetAddr* addr, PRIntervalTime timeout) { MOZ_LOG(gPIPNSSLog, LogLevel::Debug, ("[%p] connecting SSL socket\n", (void*) fd)); nsNSSShutDownPreventionLock locker; if (!getSocketInfoIfRunning(fd, not_reading_or_writing, locker)) return PR_FAILURE; PRStatus status = fd->lower->methods->connect(fd->lower, addr, timeout); if (status != PR_SUCCESS) { MOZ_LOG(gPIPNSSLog, LogLevel::Error, ("[%p] Lower layer connect error: %d\n", (void*) fd, PR_GetError())); return status; } MOZ_LOG(gPIPNSSLog, LogLevel::Debug, ("[%p] Connect\n", (void*) fd)); return status; } void nsSSLIOLayerHelpers::rememberTolerantAtVersion(const nsACString& hostName, int16_t port, uint16_t tolerant) { nsCString key; getSiteKey(hostName, port, key); MutexAutoLock lock(mutex); IntoleranceEntry entry; if (mTLSIntoleranceInfo.Get(key, &entry)) { entry.AssertInvariant(); entry.tolerant = std::max(entry.tolerant, tolerant); if (entry.intolerant != 0 && entry.intolerant <= entry.tolerant) { entry.intolerant = entry.tolerant + 1; entry.intoleranceReason = 0; // lose the reason } if (entry.strongCipherStatus == StrongCipherStatusUnknown) { entry.strongCipherStatus = StrongCiphersWorked; } } else { entry.tolerant = tolerant; entry.intolerant = 0; entry.intoleranceReason = 0; entry.strongCipherStatus = StrongCiphersWorked; } entry.AssertInvariant(); mTLSIntoleranceInfo.Put(key, entry); } void nsSSLIOLayerHelpers::forgetIntolerance(const nsACString& hostName, int16_t port) { nsCString key; getSiteKey(hostName, port, key); MutexAutoLock lock(mutex); IntoleranceEntry entry; if (mTLSIntoleranceInfo.Get(key, &entry)) { entry.AssertInvariant(); entry.intolerant = 0; entry.intoleranceReason = 0; if (entry.strongCipherStatus != StrongCiphersWorked) { entry.strongCipherStatus = StrongCipherStatusUnknown; } entry.AssertInvariant(); mTLSIntoleranceInfo.Put(key, entry); } } bool nsSSLIOLayerHelpers::fallbackLimitReached(const nsACString& hostName, uint16_t intolerant) { if (isInsecureFallbackSite(hostName)) { return intolerant <= SSL_LIBRARY_VERSION_TLS_1_0; } return intolerant <= mVersionFallbackLimit; } // returns true if we should retry the handshake bool nsSSLIOLayerHelpers::rememberIntolerantAtVersion(const nsACString& hostName, int16_t port, uint16_t minVersion, uint16_t intolerant, PRErrorCode intoleranceReason) { if (intolerant <= minVersion || fallbackLimitReached(hostName, intolerant)) { // We can't fall back any further. Assume that intolerance isn't the issue. forgetIntolerance(hostName, port); return false; } nsCString key; getSiteKey(hostName, port, key); MutexAutoLock lock(mutex); IntoleranceEntry entry; if (mTLSIntoleranceInfo.Get(key, &entry)) { entry.AssertInvariant(); if (intolerant <= entry.tolerant) { // We already know the server is tolerant at an equal or higher version. return false; } if ((entry.intolerant != 0 && intolerant >= entry.intolerant)) { // We already know that the server is intolerant at a lower version. return true; } } else { entry.tolerant = 0; entry.strongCipherStatus = StrongCipherStatusUnknown; } entry.intolerant = intolerant; entry.intoleranceReason = intoleranceReason; entry.AssertInvariant(); mTLSIntoleranceInfo.Put(key, entry); return true; } // returns true if we should retry the handshake bool nsSSLIOLayerHelpers::rememberStrongCiphersFailed(const nsACString& hostName, int16_t port, PRErrorCode intoleranceReason) { nsCString key; getSiteKey(hostName, port, key); MutexAutoLock lock(mutex); IntoleranceEntry entry; if (mTLSIntoleranceInfo.Get(key, &entry)) { entry.AssertInvariant(); if (entry.strongCipherStatus != StrongCipherStatusUnknown) { // We already know if the server supports a strong cipher. return false; } } else { entry.tolerant = 0; entry.intolerant = 0; entry.intoleranceReason = intoleranceReason; } entry.strongCipherStatus = StrongCiphersFailed; entry.AssertInvariant(); mTLSIntoleranceInfo.Put(key, entry); return true; } void nsSSLIOLayerHelpers::adjustForTLSIntolerance(const nsACString& hostName, int16_t port, /*in/out*/ SSLVersionRange& range, /*out*/ StrongCipherStatus& strongCipherStatus) { IntoleranceEntry entry; { nsCString key; getSiteKey(hostName, port, key); MutexAutoLock lock(mutex); if (!mTLSIntoleranceInfo.Get(key, &entry)) { return; } } entry.AssertInvariant(); if (entry.intolerant != 0) { // We've tried connecting at a higher range but failed, so try at the // version we haven't tried yet, unless we have reached the minimum. if (range.min < entry.intolerant) { range.max = entry.intolerant - 1; } } strongCipherStatus = entry.strongCipherStatus; } PRErrorCode nsSSLIOLayerHelpers::getIntoleranceReason(const nsACString& hostName, int16_t port) { IntoleranceEntry entry; { nsCString key; getSiteKey(hostName, port, key); MutexAutoLock lock(mutex); if (!mTLSIntoleranceInfo.Get(key, &entry)) { return 0; } } entry.AssertInvariant(); return entry.intoleranceReason; } bool nsSSLIOLayerHelpers::nsSSLIOLayerInitialized = false; PRDescIdentity nsSSLIOLayerHelpers::nsSSLIOLayerIdentity; PRDescIdentity nsSSLIOLayerHelpers::nsSSLPlaintextLayerIdentity; PRIOMethods nsSSLIOLayerHelpers::nsSSLIOLayerMethods; PRIOMethods nsSSLIOLayerHelpers::nsSSLPlaintextLayerMethods; static PRStatus nsSSLIOLayerClose(PRFileDesc* fd) { nsNSSShutDownPreventionLock locker; if (!fd) return PR_FAILURE; MOZ_LOG(gPIPNSSLog, LogLevel::Debug, ("[%p] Shutting down socket\n", (void*) fd)); nsNSSSocketInfo* socketInfo = (nsNSSSocketInfo*) fd->secret; NS_ASSERTION(socketInfo,"nsNSSSocketInfo was null for an fd"); return socketInfo->CloseSocketAndDestroy(locker); } PRStatus nsNSSSocketInfo::CloseSocketAndDestroy( const nsNSSShutDownPreventionLock& /*proofOfLock*/) { PRFileDesc* popped = PR_PopIOLayer(mFd, PR_TOP_IO_LAYER); NS_ASSERTION(popped && popped->identity == nsSSLIOLayerHelpers::nsSSLIOLayerIdentity, "SSL Layer not on top of stack"); // The plain text layer is not always present - so its not a fatal error // if it cannot be removed PRFileDesc* poppedPlaintext = PR_GetIdentitiesLayer(mFd, nsSSLIOLayerHelpers::nsSSLPlaintextLayerIdentity); if (poppedPlaintext) { PR_PopIOLayer(mFd, nsSSLIOLayerHelpers::nsSSLPlaintextLayerIdentity); poppedPlaintext->dtor(poppedPlaintext); } PRStatus status = mFd->methods->close(mFd); // the nsNSSSocketInfo instance can out-live the connection, so we need some // indication that the connection has been closed. mFd == nullptr is that // indication. This is needed, for example, when the connection is closed // before we have finished validating the server's certificate. mFd = nullptr; if (status != PR_SUCCESS) return status; popped->identity = PR_INVALID_IO_LAYER; NS_RELEASE_THIS(); popped->dtor(popped); return PR_SUCCESS; } #if defined(DEBUG_SSL_VERBOSE) && defined(DUMP_BUFFER) // Dumps a (potentially binary) buffer using SSM_DEBUG. (We could have used // the version in ssltrace.c, but that's specifically tailored to SSLTRACE.) #define DUMPBUF_LINESIZE 24 static void nsDumpBuffer(unsigned char* buf, int len) { char hexbuf[DUMPBUF_LINESIZE*3+1]; char chrbuf[DUMPBUF_LINESIZE+1]; static const char* hex = "0123456789abcdef"; int i = 0; int l = 0; char ch; char* c; char* h; if (len == 0) return; hexbuf[DUMPBUF_LINESIZE*3] = '\0'; chrbuf[DUMPBUF_LINESIZE] = '\0'; (void) memset(hexbuf, 0x20, DUMPBUF_LINESIZE*3); (void) memset(chrbuf, 0x20, DUMPBUF_LINESIZE); h = hexbuf; c = chrbuf; while (i < len) { ch = buf[i]; if (l == DUMPBUF_LINESIZE) { MOZ_LOG(gPIPNSSLog, LogLevel::Debug, ("%s%s\n", hexbuf, chrbuf)); (void) memset(hexbuf, 0x20, DUMPBUF_LINESIZE*3); (void) memset(chrbuf, 0x20, DUMPBUF_LINESIZE); h = hexbuf; c = chrbuf; l = 0; } // Convert a character to hex. *h++ = hex[(ch >> 4) & 0xf]; *h++ = hex[ch & 0xf]; h++; // Put the character (if it's printable) into the character buffer. if ((ch >= 0x20) && (ch <= 0x7e)) { *c++ = ch; } else { *c++ = '.'; } i++; l++; } MOZ_LOG(gPIPNSSLog, LogLevel::Debug, ("%s%s\n", hexbuf, chrbuf)); } #define DEBUG_DUMP_BUFFER(buf,len) nsDumpBuffer(buf,len) #else #define DEBUG_DUMP_BUFFER(buf,len) #endif class SSLErrorRunnable : public SyncRunnableBase { public: SSLErrorRunnable(nsNSSSocketInfo* infoObject, ::mozilla::psm::SSLErrorMessageType errtype, PRErrorCode errorCode) : mInfoObject(infoObject) , mErrType(errtype) , mErrorCode(errorCode) { } virtual void RunOnTargetThread() { nsHandleSSLError(mInfoObject, mErrType, mErrorCode); } RefPtr mInfoObject; ::mozilla::psm::SSLErrorMessageType mErrType; const PRErrorCode mErrorCode; }; namespace { bool retryDueToTLSIntolerance(PRErrorCode err, nsNSSSocketInfo* socketInfo) { // This function is supposed to decide which error codes should // be used to conclude server is TLS intolerant. // Note this only happens during the initial SSL handshake. SSLVersionRange range = socketInfo->GetTLSVersionRange(); nsSSLIOLayerHelpers& helpers = socketInfo->SharedState().IOLayerHelpers(); if (err == SSL_ERROR_UNSUPPORTED_VERSION && range.min == SSL_LIBRARY_VERSION_TLS_1_0) { socketInfo->SetSecurityState(nsIWebProgressListener::STATE_IS_INSECURE | nsIWebProgressListener::STATE_USES_SSL_3); } // NSS will return SSL_ERROR_RX_MALFORMED_SERVER_HELLO if anti-downgrade // detected the downgrade. if (err == SSL_ERROR_INAPPROPRIATE_FALLBACK_ALERT || err == SSL_ERROR_RX_MALFORMED_SERVER_HELLO) { // This is a clear signal that we've fallen back too many versions. Treat // this as a hard failure, but forget any intolerance so that later attempts // don't use this version (i.e., range.max) and trigger the error again. helpers.forgetIntolerance(socketInfo->GetHostName(), socketInfo->GetPort()); return false; } // Disallow PR_CONNECT_RESET_ERROR if fallback limit reached. bool fallbackLimitReached = helpers.fallbackLimitReached(socketInfo->GetHostName(), range.max); if (err == PR_CONNECT_RESET_ERROR && fallbackLimitReached) { return false; } if ((err == SSL_ERROR_NO_CYPHER_OVERLAP || err == PR_END_OF_FILE_ERROR || err == PR_CONNECT_RESET_ERROR) && nsNSSComponent::AreAnyWeakCiphersEnabled()) { if (helpers.isInsecureFallbackSite(socketInfo->GetHostName()) || helpers.mUnrestrictedRC4Fallback) { if (helpers.rememberStrongCiphersFailed(socketInfo->GetHostName(), socketInfo->GetPort(), err)) { return true; } } } // When not using a proxy we'll see a connection reset error. // When using a proxy, we'll see an end of file error. // Don't allow STARTTLS connections to fall back on connection resets or // EOF. if ((err == PR_CONNECT_RESET_ERROR || err == PR_END_OF_FILE_ERROR) && socketInfo->GetForSTARTTLS()) { return false; } if (!helpers.rememberIntolerantAtVersion(socketInfo->GetHostName(), socketInfo->GetPort(), range.min, range.max, err)) { return false; } return true; } // Ensure that we haven't added too many errors to fit. static_assert((SSL_ERROR_END_OF_LIST - SSL_ERROR_BASE) <= 256, "too many SSL errors"); static_assert((SEC_ERROR_END_OF_LIST - SEC_ERROR_BASE) <= 256, "too many SEC errors"); static_assert((PR_MAX_ERROR - PR_NSPR_ERROR_BASE) <= 128, "too many NSPR errors"); static_assert((mozilla::pkix::ERROR_BASE - mozilla::pkix::END_OF_LIST) < 31, "too many moz::pkix errors"); int32_t checkHandshake(int32_t bytesTransfered, bool wasReading, PRFileDesc* ssl_layer_fd, nsNSSSocketInfo* socketInfo) { const PRErrorCode originalError = PR_GetError(); PRErrorCode err = originalError; // This is where we work around all of those SSL servers that don't // conform to the SSL spec and shutdown a connection when we request // SSL v3.1 (aka TLS). The spec says the client says what version // of the protocol we're willing to perform, in our case SSL v3.1 // In its response, the server says which version it wants to perform. // Many servers out there only know how to do v3.0. Next, we're supposed // to send back the version of the protocol we requested (ie v3.1). At // this point many servers's implementations are broken and they shut // down the connection when they don't see the version they sent back. // This is supposed to prevent a man in the middle from forcing one // side to dumb down to a lower level of the protocol. Unfortunately, // there are enough broken servers out there that such a gross work-around // is necessary. :( // Do NOT assume TLS intolerance on a closed connection after bad cert ui was shown. // Simply retry. // This depends on the fact that Cert UI will not be shown again, // should the user override the bad cert. bool handleHandshakeResultNow = socketInfo->IsHandshakePending(); bool wantRetry = false; if (0 > bytesTransfered) { if (handleHandshakeResultNow) { if (PR_WOULD_BLOCK_ERROR == err) { PR_SetError(err, 0); return bytesTransfered; } wantRetry = retryDueToTLSIntolerance(err, socketInfo); } // This is the common place where we trigger non-cert-errors on a SSL // socket. This might be reached at any time of the connection. // // The socketInfo->GetErrorCode() check is here to ensure we don't try to // do the synchronous dispatch to the main thread unnecessarily after we've // already handled a certificate error. (SSLErrorRunnable calls // nsHandleSSLError, which has logic to avoid replacing the error message, // so without the !socketInfo->GetErrorCode(), it would just be an // expensive no-op.) if (!wantRetry && mozilla::psm::IsNSSErrorCode(err) && !socketInfo->GetErrorCode()) { RefPtr runnable(new SSLErrorRunnable(socketInfo, PlainErrorMessage, err)); (void) runnable->DispatchToMainThreadAndWait(); } } else if (wasReading && 0 == bytesTransfered) { // zero bytes on reading, socket closed if (handleHandshakeResultNow) { wantRetry = retryDueToTLSIntolerance(PR_END_OF_FILE_ERROR, socketInfo); } } if (wantRetry) { MOZ_LOG(gPIPNSSLog, LogLevel::Debug, ("[%p] checkHandshake: will retry with lower max TLS version\n", ssl_layer_fd)); // We want to cause the network layer to retry the connection. err = PR_CONNECT_RESET_ERROR; if (wasReading) bytesTransfered = -1; } // TLS intolerant servers only cause the first transfer to fail, so let's // set the HandshakePending attribute to false so that we don't try the logic // above again in a subsequent transfer. if (handleHandshakeResultNow) { socketInfo->SetHandshakeNotPending(); } if (bytesTransfered < 0) { // Remember that we encountered an error so that getSocketInfoIfRunning // will correctly cause us to fail if another part of Gecko // (erroneously) calls an I/O function (PR_Send/PR_Recv/etc.) again on // this socket. Note that we use the original error because if we use // PR_CONNECT_RESET_ERROR, we'll repeated try to reconnect. if (originalError != PR_WOULD_BLOCK_ERROR && !socketInfo->GetErrorCode()) { socketInfo->SetCanceled(originalError, PlainErrorMessage); } PR_SetError(err, 0); } return bytesTransfered; } } // namespace static int16_t nsSSLIOLayerPoll(PRFileDesc* fd, int16_t in_flags, int16_t* out_flags) { nsNSSShutDownPreventionLock locker; if (!out_flags) { NS_WARNING("nsSSLIOLayerPoll called with null out_flags"); return 0; } *out_flags = 0; nsNSSSocketInfo* socketInfo = getSocketInfoIfRunning(fd, not_reading_or_writing, locker); if (!socketInfo) { // If we get here, it is probably because certificate validation failed // and this is the first I/O operation after the failure. MOZ_LOG(gPIPNSSLog, LogLevel::Debug, ("[%p] polling SSL socket right after certificate verification failed " "or NSS shutdown or SDR logout %d\n", fd, (int) in_flags)); NS_ASSERTION(in_flags & PR_POLL_EXCEPT, "caller did not poll for EXCEPT (canceled)"); // Since this poll method cannot return errors, we want the caller to call // PR_Send/PR_Recv right away to get the error, so we tell that we are // ready for whatever I/O they are asking for. (See getSocketInfoIfRunning). *out_flags = in_flags | PR_POLL_EXCEPT; // see also bug 480619 return in_flags; } MOZ_LOG(gPIPNSSLog, LogLevel::Verbose, (socketInfo->IsWaitingForCertVerification() ? "[%p] polling SSL socket during certificate verification using lower %d\n" : "[%p] poll SSL socket using lower %d\n", fd, (int) in_flags)); // We want the handshake to continue during certificate validation, so we // don't need to do anything special here. libssl automatically blocks when // it reaches any point that would be unsafe to send/receive something before // cert validation is complete. int16_t result = fd->lower->methods->poll(fd->lower, in_flags, out_flags); MOZ_LOG(gPIPNSSLog, LogLevel::Verbose, ("[%p] poll SSL socket returned %d\n", (void*) fd, (int) result)); return result; } nsSSLIOLayerHelpers::nsSSLIOLayerHelpers() : mTreatUnsafeNegotiationAsBroken(false) , mTLSIntoleranceInfo() , mFalseStartRequireNPN(false) , mUnrestrictedRC4Fallback(false) , mVersionFallbackLimit(SSL_LIBRARY_VERSION_TLS_1_0) , mutex("nsSSLIOLayerHelpers.mutex") { } static int _PSM_InvalidInt(void) { MOZ_ASSERT_UNREACHABLE("I/O method is invalid"); PR_SetError(PR_INVALID_METHOD_ERROR, 0); return -1; } static int64_t _PSM_InvalidInt64(void) { MOZ_ASSERT_UNREACHABLE("I/O method is invalid"); PR_SetError(PR_INVALID_METHOD_ERROR, 0); return -1; } static PRStatus _PSM_InvalidStatus(void) { MOZ_ASSERT_UNREACHABLE("I/O method is invalid"); PR_SetError(PR_INVALID_METHOD_ERROR, 0); return PR_FAILURE; } static PRFileDesc* _PSM_InvalidDesc(void) { MOZ_ASSERT_UNREACHABLE("I/O method is invalid"); PR_SetError(PR_INVALID_METHOD_ERROR, 0); return nullptr; } static PRStatus PSMGetsockname(PRFileDesc* fd, PRNetAddr* addr) { nsNSSShutDownPreventionLock locker; if (!getSocketInfoIfRunning(fd, not_reading_or_writing, locker)) return PR_FAILURE; return fd->lower->methods->getsockname(fd->lower, addr); } static PRStatus PSMGetpeername(PRFileDesc* fd, PRNetAddr* addr) { nsNSSShutDownPreventionLock locker; if (!getSocketInfoIfRunning(fd, not_reading_or_writing, locker)) return PR_FAILURE; return fd->lower->methods->getpeername(fd->lower, addr); } static PRStatus PSMGetsocketoption(PRFileDesc* fd, PRSocketOptionData* data) { nsNSSShutDownPreventionLock locker; if (!getSocketInfoIfRunning(fd, not_reading_or_writing, locker)) return PR_FAILURE; return fd->lower->methods->getsocketoption(fd, data); } static PRStatus PSMSetsocketoption(PRFileDesc* fd, const PRSocketOptionData* data) { nsNSSShutDownPreventionLock locker; if (!getSocketInfoIfRunning(fd, not_reading_or_writing, locker)) return PR_FAILURE; return fd->lower->methods->setsocketoption(fd, data); } static int32_t PSMRecv(PRFileDesc* fd, void* buf, int32_t amount, int flags, PRIntervalTime timeout) { nsNSSShutDownPreventionLock locker; nsNSSSocketInfo* socketInfo = getSocketInfoIfRunning(fd, reading, locker); if (!socketInfo) return -1; if (flags != PR_MSG_PEEK && flags != 0) { PR_SetError(PR_INVALID_ARGUMENT_ERROR, 0); return -1; } int32_t bytesRead = fd->lower->methods->recv(fd->lower, buf, amount, flags, timeout); MOZ_LOG(gPIPNSSLog, LogLevel::Verbose, ("[%p] read %d bytes\n", (void*) fd, bytesRead)); #ifdef DEBUG_SSL_VERBOSE DEBUG_DUMP_BUFFER((unsigned char*) buf, bytesRead); #endif return checkHandshake(bytesRead, true, fd, socketInfo); } static int32_t PSMSend(PRFileDesc* fd, const void* buf, int32_t amount, int flags, PRIntervalTime timeout) { nsNSSShutDownPreventionLock locker; nsNSSSocketInfo* socketInfo = getSocketInfoIfRunning(fd, writing, locker); if (!socketInfo) return -1; if (flags != 0) { PR_SetError(PR_INVALID_ARGUMENT_ERROR, 0); return -1; } #ifdef DEBUG_SSL_VERBOSE DEBUG_DUMP_BUFFER((unsigned char*) buf, amount); #endif int32_t bytesWritten = fd->lower->methods->send(fd->lower, buf, amount, flags, timeout); MOZ_LOG(gPIPNSSLog, LogLevel::Verbose, ("[%p] wrote %d bytes\n", fd, bytesWritten)); return checkHandshake(bytesWritten, false, fd, socketInfo); } static PRStatus PSMBind(PRFileDesc* fd, const PRNetAddr *addr) { nsNSSShutDownPreventionLock locker; if (!getSocketInfoIfRunning(fd, not_reading_or_writing, locker)) return PR_FAILURE; return fd->lower->methods->bind(fd->lower, addr); } static int32_t nsSSLIOLayerRead(PRFileDesc* fd, void* buf, int32_t amount) { return PSMRecv(fd, buf, amount, 0, PR_INTERVAL_NO_TIMEOUT); } static int32_t nsSSLIOLayerWrite(PRFileDesc* fd, const void* buf, int32_t amount) { return PSMSend(fd, buf, amount, 0, PR_INTERVAL_NO_TIMEOUT); } static PRStatus PSMConnectcontinue(PRFileDesc* fd, int16_t out_flags) { nsNSSShutDownPreventionLock locker; if (!getSocketInfoIfRunning(fd, not_reading_or_writing, locker)) { return PR_FAILURE; } return fd->lower->methods->connectcontinue(fd, out_flags); } static int PSMAvailable(void) { // This is called through PR_Available(), but is not implemented in PSM PR_SetError(PR_NOT_IMPLEMENTED_ERROR, 0); return -1; } static int64_t PSMAvailable64(void) { // This is called through PR_Available(), but is not implemented in PSM PR_SetError(PR_NOT_IMPLEMENTED_ERROR, 0); return -1; } namespace { class PrefObserver : public nsIObserver { public: NS_DECL_THREADSAFE_ISUPPORTS NS_DECL_NSIOBSERVER explicit PrefObserver(nsSSLIOLayerHelpers* aOwner) : mOwner(aOwner) {} protected: virtual ~PrefObserver() {} private: nsSSLIOLayerHelpers* mOwner; }; } // unnamed namespace NS_IMPL_ISUPPORTS(PrefObserver, nsIObserver) NS_IMETHODIMP PrefObserver::Observe(nsISupports* aSubject, const char* aTopic, const char16_t* someData) { if (nsCRT::strcmp(aTopic, NS_PREFBRANCH_PREFCHANGE_TOPIC_ID) == 0) { NS_ConvertUTF16toUTF8 prefName(someData); if (prefName.EqualsLiteral("security.ssl.treat_unsafe_negotiation_as_broken")) { bool enabled; Preferences::GetBool("security.ssl.treat_unsafe_negotiation_as_broken", &enabled); mOwner->setTreatUnsafeNegotiationAsBroken(enabled); } else if (prefName.EqualsLiteral("security.ssl.false_start.require-npn")) { mOwner->mFalseStartRequireNPN = Preferences::GetBool("security.ssl.false_start.require-npn", FALSE_START_REQUIRE_NPN_DEFAULT); } else if (prefName.EqualsLiteral("security.tls.version.fallback-limit")) { mOwner->loadVersionFallbackLimit(); } else if (prefName.EqualsLiteral("security.tls.insecure_fallback_hosts")) { // Changes to the whitelist on the public side will update the pref. // Don't propagate the changes to the private side. if (mOwner->isPublic()) { mOwner->initInsecureFallbackSites(); } } else if (prefName.EqualsLiteral("security.tls.unrestricted_rc4_fallback")) { mOwner->mUnrestrictedRC4Fallback = Preferences::GetBool("security.tls.unrestricted_rc4_fallback", false); } } return NS_OK; } static int32_t PlaintextRecv(PRFileDesc* fd, void* buf, int32_t amount, int flags, PRIntervalTime timeout) { // The shutdownlocker is not needed here because it will already be // held higher in the stack nsNSSSocketInfo* socketInfo = nullptr; int32_t bytesRead = fd->lower->methods->recv(fd->lower, buf, amount, flags, timeout); if (fd->identity == nsSSLIOLayerHelpers::nsSSLPlaintextLayerIdentity) socketInfo = (nsNSSSocketInfo*) fd->secret; if ((bytesRead > 0) && socketInfo) socketInfo->AddPlaintextBytesRead(bytesRead); return bytesRead; } nsSSLIOLayerHelpers::~nsSSLIOLayerHelpers() { // mPrefObserver will only be set if this->Init was called. The GTest tests // do not call Init. if (mPrefObserver) { Preferences::RemoveObserver(mPrefObserver, "security.ssl.treat_unsafe_negotiation_as_broken"); Preferences::RemoveObserver(mPrefObserver, "security.ssl.false_start.require-npn"); Preferences::RemoveObserver(mPrefObserver, "security.tls.version.fallback-limit"); Preferences::RemoveObserver(mPrefObserver, "security.tls.insecure_fallback_hosts"); Preferences::RemoveObserver(mPrefObserver, "security.tls.unrestricted_rc4_fallback"); } } nsresult nsSSLIOLayerHelpers::Init() { if (!nsSSLIOLayerInitialized) { nsSSLIOLayerInitialized = true; nsSSLIOLayerIdentity = PR_GetUniqueIdentity("NSS layer"); nsSSLIOLayerMethods = *PR_GetDefaultIOMethods(); nsSSLIOLayerMethods.available = (PRAvailableFN) PSMAvailable; nsSSLIOLayerMethods.available64 = (PRAvailable64FN) PSMAvailable64; nsSSLIOLayerMethods.fsync = (PRFsyncFN) _PSM_InvalidStatus; nsSSLIOLayerMethods.seek = (PRSeekFN) _PSM_InvalidInt; nsSSLIOLayerMethods.seek64 = (PRSeek64FN) _PSM_InvalidInt64; nsSSLIOLayerMethods.fileInfo = (PRFileInfoFN) _PSM_InvalidStatus; nsSSLIOLayerMethods.fileInfo64 = (PRFileInfo64FN) _PSM_InvalidStatus; nsSSLIOLayerMethods.writev = (PRWritevFN) _PSM_InvalidInt; nsSSLIOLayerMethods.accept = (PRAcceptFN) _PSM_InvalidDesc; nsSSLIOLayerMethods.listen = (PRListenFN) _PSM_InvalidStatus; nsSSLIOLayerMethods.shutdown = (PRShutdownFN) _PSM_InvalidStatus; nsSSLIOLayerMethods.recvfrom = (PRRecvfromFN) _PSM_InvalidInt; nsSSLIOLayerMethods.sendto = (PRSendtoFN) _PSM_InvalidInt; nsSSLIOLayerMethods.acceptread = (PRAcceptreadFN) _PSM_InvalidInt; nsSSLIOLayerMethods.transmitfile = (PRTransmitfileFN) _PSM_InvalidInt; nsSSLIOLayerMethods.sendfile = (PRSendfileFN) _PSM_InvalidInt; nsSSLIOLayerMethods.getsockname = PSMGetsockname; nsSSLIOLayerMethods.getpeername = PSMGetpeername; nsSSLIOLayerMethods.getsocketoption = PSMGetsocketoption; nsSSLIOLayerMethods.setsocketoption = PSMSetsocketoption; nsSSLIOLayerMethods.recv = PSMRecv; nsSSLIOLayerMethods.send = PSMSend; nsSSLIOLayerMethods.connectcontinue = PSMConnectcontinue; nsSSLIOLayerMethods.bind = PSMBind; nsSSLIOLayerMethods.connect = nsSSLIOLayerConnect; nsSSLIOLayerMethods.close = nsSSLIOLayerClose; nsSSLIOLayerMethods.write = nsSSLIOLayerWrite; nsSSLIOLayerMethods.read = nsSSLIOLayerRead; nsSSLIOLayerMethods.poll = nsSSLIOLayerPoll; nsSSLPlaintextLayerIdentity = PR_GetUniqueIdentity("Plaintxext PSM layer"); nsSSLPlaintextLayerMethods = *PR_GetDefaultIOMethods(); nsSSLPlaintextLayerMethods.recv = PlaintextRecv; } bool enabled = false; Preferences::GetBool("security.ssl.treat_unsafe_negotiation_as_broken", &enabled); setTreatUnsafeNegotiationAsBroken(enabled); mFalseStartRequireNPN = Preferences::GetBool("security.ssl.false_start.require-npn", FALSE_START_REQUIRE_NPN_DEFAULT); loadVersionFallbackLimit(); initInsecureFallbackSites(); mUnrestrictedRC4Fallback = Preferences::GetBool("security.tls.unrestricted_rc4_fallback", false); mPrefObserver = new PrefObserver(this); Preferences::AddStrongObserver(mPrefObserver, "security.ssl.treat_unsafe_negotiation_as_broken"); Preferences::AddStrongObserver(mPrefObserver, "security.ssl.false_start.require-npn"); Preferences::AddStrongObserver(mPrefObserver, "security.tls.version.fallback-limit"); Preferences::AddStrongObserver(mPrefObserver, "security.tls.insecure_fallback_hosts"); Preferences::AddStrongObserver(mPrefObserver, "security.tls.unrestricted_rc4_fallback"); return NS_OK; } void nsSSLIOLayerHelpers::loadVersionFallbackLimit() { // see nsNSSComponent::setEnabledTLSVersions for pref handling rules uint32_t limit = Preferences::GetUint("security.tls.version.fallback-limit", 3); // 3 = TLS 1.2 SSLVersionRange defaults = { SSL_LIBRARY_VERSION_TLS_1_2, SSL_LIBRARY_VERSION_TLS_1_2 }; SSLVersionRange filledInRange; nsNSSComponent::FillTLSVersionRange(filledInRange, limit, limit, defaults); if (filledInRange.max < SSL_LIBRARY_VERSION_TLS_1_2) { filledInRange.max = SSL_LIBRARY_VERSION_TLS_1_2; } mVersionFallbackLimit = filledInRange.max; } void nsSSLIOLayerHelpers::clearStoredData() { MutexAutoLock lock(mutex); mInsecureFallbackSites.Clear(); mTLSIntoleranceInfo.Clear(); } void nsSSLIOLayerHelpers::setInsecureFallbackSites(const nsCString& str) { MutexAutoLock lock(mutex); mInsecureFallbackSites.Clear(); if (str.IsEmpty()) { return; } nsCCharSeparatedTokenizer toker(str, ','); while (toker.hasMoreTokens()) { const nsCSubstring& host = toker.nextToken(); if (!host.IsEmpty()) { mInsecureFallbackSites.PutEntry(host); } } } void nsSSLIOLayerHelpers::initInsecureFallbackSites() { MOZ_ASSERT(NS_IsMainThread()); nsCString insecureFallbackHosts; Preferences::GetCString("security.tls.insecure_fallback_hosts", &insecureFallbackHosts); setInsecureFallbackSites(insecureFallbackHosts); } bool nsSSLIOLayerHelpers::isPublic() const { return this == &PublicSSLState()->IOLayerHelpers(); } void nsSSLIOLayerHelpers::addInsecureFallbackSite(const nsCString& hostname, bool temporary) { MOZ_ASSERT(NS_IsMainThread()); { MutexAutoLock lock(mutex); if (mInsecureFallbackSites.Contains(hostname)) { return; } mInsecureFallbackSites.PutEntry(hostname); } if (!isPublic() || temporary) { return; } nsCString value; Preferences::GetCString("security.tls.insecure_fallback_hosts", &value); if (!value.IsEmpty()) { value.Append(','); } value.Append(hostname); Preferences::SetCString("security.tls.insecure_fallback_hosts", value); } class FallbackPrefRemover final : public Runnable { public: explicit FallbackPrefRemover(const nsACString& aHost) : mHost(aHost) {} NS_IMETHOD Run() override; private: nsCString mHost; }; NS_IMETHODIMP FallbackPrefRemover::Run() { MOZ_ASSERT(NS_IsMainThread()); nsCString oldValue; Preferences::GetCString("security.tls.insecure_fallback_hosts", &oldValue); nsCCharSeparatedTokenizer toker(oldValue, ','); nsCString newValue; while (toker.hasMoreTokens()) { const nsCSubstring& host = toker.nextToken(); if (host.Equals(mHost)) { continue; } if (!newValue.IsEmpty()) { newValue.Append(','); } newValue.Append(host); } Preferences::SetCString("security.tls.insecure_fallback_hosts", newValue); return NS_OK; } void nsSSLIOLayerHelpers::removeInsecureFallbackSite(const nsACString& hostname, uint16_t port) { forgetIntolerance(hostname, port); { MutexAutoLock lock(mutex); if (!mInsecureFallbackSites.Contains(hostname)) { return; } mInsecureFallbackSites.RemoveEntry(hostname); } if (!isPublic()) { return; } RefPtr runnable = new FallbackPrefRemover(hostname); if (NS_IsMainThread()) { runnable->Run(); } else { NS_DispatchToMainThread(runnable); } } bool nsSSLIOLayerHelpers::isInsecureFallbackSite(const nsACString& hostname) { MutexAutoLock lock(mutex); return mInsecureFallbackSites.Contains(hostname); } void nsSSLIOLayerHelpers::setTreatUnsafeNegotiationAsBroken(bool broken) { MutexAutoLock lock(mutex); mTreatUnsafeNegotiationAsBroken = broken; } bool nsSSLIOLayerHelpers::treatUnsafeNegotiationAsBroken() { MutexAutoLock lock(mutex); return mTreatUnsafeNegotiationAsBroken; } nsresult nsSSLIOLayerNewSocket(int32_t family, const char* host, int32_t port, nsIProxyInfo *proxy, const NeckoOriginAttributes& originAttributes, PRFileDesc** fd, nsISupports** info, bool forSTARTTLS, uint32_t flags) { PRFileDesc* sock = PR_OpenTCPSocket(family); if (!sock) return NS_ERROR_OUT_OF_MEMORY; nsresult rv = nsSSLIOLayerAddToSocket(family, host, port, proxy, originAttributes, sock, info, forSTARTTLS, flags); if (NS_FAILED(rv)) { PR_Close(sock); return rv; } *fd = sock; return NS_OK; } // Creates CA names strings from (CERTDistNames* caNames) // // - arena: arena to allocate strings on // - caNameStrings: filled with CA names strings on return // - caNames: CERTDistNames to extract strings from // - return: SECSuccess if successful; error code otherwise // // Note: copied in its entirety from Nova code static SECStatus nsConvertCANamesToStrings(const UniquePLArenaPool& arena, char** caNameStrings, CERTDistNames* caNames) { MOZ_ASSERT(arena.get()); MOZ_ASSERT(caNameStrings); MOZ_ASSERT(caNames); if (!arena.get() || !caNameStrings || !caNames) { PR_SetError(SEC_ERROR_INVALID_ARGS, 0); return SECFailure; } SECItem* dername; int n; char* namestring; for (n = 0; n < caNames->nnames; n++) { dername = &caNames->names[n]; namestring = CERT_DerNameToAscii(dername); if (!namestring) { // XXX - keep going until we fail to convert the name caNameStrings[n] = const_cast(""); } else { caNameStrings[n] = PORT_ArenaStrdup(arena.get(), namestring); PR_Free(namestring); if (!caNameStrings[n]) { return SECFailure; } } } return SECSuccess; } // Possible behaviors for choosing a cert for client auth. enum class UserCertChoice { // Ask the user to choose a cert. Ask = 0, // Automatically choose a cert. Auto = 1, }; // Returns the most appropriate user cert choice based on the value of the // security.default_personal_cert preference. UserCertChoice nsGetUserCertChoice() { nsAutoCString value; nsresult rv = Preferences::GetCString("security.default_personal_cert", &value); if (NS_FAILED(rv)) { return UserCertChoice::Ask; } // There are three cases for what the preference could be set to: // 1. "Select Automatically" -> Auto. // 2. "Ask Every Time" -> Ask. // 3. Something else -> Ask. This might be a nickname from a migrated cert, // but we no longer support this case. return value.EqualsLiteral("Select Automatically") ? UserCertChoice::Auto : UserCertChoice::Ask; } static bool hasExplicitKeyUsageNonRepudiation(CERTCertificate* cert) { // There is no extension, v1 or v2 certificate if (!cert->extensions) return false; SECStatus srv; SECItem keyUsageItem; keyUsageItem.data = nullptr; srv = CERT_FindKeyUsageExtension(cert, &keyUsageItem); if (srv == SECFailure) return false; unsigned char keyUsage = keyUsageItem.data[0]; PORT_Free (keyUsageItem.data); return !!(keyUsage & KU_NON_REPUDIATION); } class ClientAuthDataRunnable : public SyncRunnableBase { public: ClientAuthDataRunnable(CERTDistNames* caNames, CERTCertificate** pRetCert, SECKEYPrivateKey** pRetKey, nsNSSSocketInfo* info, const UniqueCERTCertificate& serverCert) : mRV(SECFailure) , mErrorCodeToReport(SEC_ERROR_NO_MEMORY) , mPRetCert(pRetCert) , mPRetKey(pRetKey) , mCANames(caNames) , mSocketInfo(info) , mServerCert(serverCert.get()) { } SECStatus mRV; // out PRErrorCode mErrorCodeToReport; // out CERTCertificate** const mPRetCert; // in/out SECKEYPrivateKey** const mPRetKey; // in/out protected: virtual void RunOnTargetThread(); private: CERTDistNames* const mCANames; // in nsNSSSocketInfo* const mSocketInfo; // in CERTCertificate* const mServerCert; // in }; // This callback function is used to pull client certificate // information upon server request // // - arg: SSL data connection // - socket: SSL socket we're dealing with // - caNames: list of CA names // - pRetCert: returns a pointer to a pointer to a valid certificate if // successful; otherwise nullptr // - pRetKey: returns a pointer to a pointer to the corresponding key if // successful; otherwise nullptr SECStatus nsNSS_SSLGetClientAuthData(void* arg, PRFileDesc* socket, CERTDistNames* caNames, CERTCertificate** pRetCert, SECKEYPrivateKey** pRetKey) { nsNSSShutDownPreventionLock locker; if (!socket || !caNames || !pRetCert || !pRetKey) { PR_SetError(PR_INVALID_ARGUMENT_ERROR, 0); return SECFailure; } RefPtr info( BitwiseCast(socket->higher->secret)); UniqueCERTCertificate serverCert(SSL_PeerCertificate(socket)); if (!serverCert) { NS_NOTREACHED("Missing server certificate should have been detected during " "server cert authentication."); PR_SetError(SSL_ERROR_NO_CERTIFICATE, 0); return SECFailure; } if (info->GetJoined()) { // We refuse to send a client certificate when there are multiple hostnames // joined on this connection, because we only show the user one hostname // (mHostName) in the client certificate UI. MOZ_LOG(gPIPNSSLog, LogLevel::Debug, ("[%p] Not returning client cert due to previous join\n", socket)); *pRetCert = nullptr; *pRetKey = nullptr; return SECSuccess; } // XXX: This should be done asynchronously; see bug 696976 RefPtr runnable( new ClientAuthDataRunnable(caNames, pRetCert, pRetKey, info, serverCert)); nsresult rv = runnable->DispatchToMainThreadAndWait(); if (NS_FAILED(rv)) { PR_SetError(SEC_ERROR_NO_MEMORY, 0); return SECFailure; } if (runnable->mRV != SECSuccess) { PR_SetError(runnable->mErrorCodeToReport, 0); } else if (*runnable->mPRetCert || *runnable->mPRetKey) { // Make joinConnection prohibit joining after we've sent a client cert info->SetSentClientCert(); } return runnable->mRV; } void ClientAuthDataRunnable::RunOnTargetThread() { // We check the value of a pref in this runnable, so this runnable should only // be run on the main thread. MOZ_ASSERT(NS_IsMainThread()); UniquePLArenaPool arena; char** caNameStrings; UniqueCERTCertificate cert; UniqueSECKEYPrivateKey privKey; void* wincx = mSocketInfo; nsresult rv; nsCOMPtr socketClientCert; mSocketInfo->GetClientCert(getter_AddRefs(socketClientCert)); // If a client cert preference was set on the socket info, use that and skip // the client cert UI and/or search of the user's past cert decisions. if (socketClientCert) { cert.reset(socketClientCert->GetCert()); if (!cert) { goto loser; } // Get the private key privKey.reset(PK11_FindKeyByAnyCert(cert.get(), wincx)); if (!privKey) { goto loser; } *mPRetCert = cert.release(); *mPRetKey = privKey.release(); mRV = SECSuccess; return; } // create caNameStrings arena.reset(PORT_NewArena(DER_DEFAULT_CHUNKSIZE)); if (!arena) { goto loser; } caNameStrings = static_cast( PORT_ArenaAlloc(arena.get(), sizeof(char*) * mCANames->nnames)); if (!caNameStrings) { goto loser; } mRV = nsConvertCANamesToStrings(arena, caNameStrings, mCANames); if (mRV != SECSuccess) { goto loser; } // find valid user cert and key pair if (nsGetUserCertChoice() == UserCertChoice::Auto) { // automatically find the right cert // find all user certs that are valid and for SSL UniqueCERTCertList certList( CERT_FindUserCertsByUsage(CERT_GetDefaultCertDB(), certUsageSSLClient, false, true, wincx)); if (!certList) { goto loser; } // filter the list to those issued by CAs supported by the server mRV = CERT_FilterCertListByCANames(certList.get(), mCANames->nnames, caNameStrings, certUsageSSLClient); if (mRV != SECSuccess) { goto loser; } // make sure the list is not empty if (CERT_LIST_END(CERT_LIST_HEAD(certList), certList)) { goto loser; } UniqueCERTCertificate lowPrioNonrepCert; // loop through the list until we find a cert with a key for (CERTCertListNode* node = CERT_LIST_HEAD(certList); !CERT_LIST_END(node, certList); node = CERT_LIST_NEXT(node)) { // if the certificate has restriction and we do not satisfy it we do not // use it privKey.reset(PK11_FindKeyByAnyCert(node->cert, wincx)); if (privKey) { if (hasExplicitKeyUsageNonRepudiation(node->cert)) { privKey = nullptr; // Not a preferred cert if (!lowPrioNonrepCert) { // did not yet find a low prio cert lowPrioNonrepCert.reset(CERT_DupCertificate(node->cert)); } } else { // this is a good cert to present cert.reset(CERT_DupCertificate(node->cert)); break; } } if (PR_GetError() == SEC_ERROR_BAD_PASSWORD) { // problem with password: bail goto loser; } } if (!cert && lowPrioNonrepCert) { cert = Move(lowPrioNonrepCert); privKey.reset(PK11_FindKeyByAnyCert(cert.get(), wincx)); } if (!cert) { goto loser; } } else { // Not Auto => ask // Get the SSL Certificate nsXPIDLCString hostname; mSocketInfo->GetHostName(getter_Copies(hostname)); RefPtr cars = mSocketInfo->SharedState().GetClientAuthRememberService(); bool hasRemembered = false; nsCString rememberedDBKey; if (cars) { bool found; rv = cars->HasRememberedDecision(hostname, mSocketInfo->GetOriginAttributes(), mServerCert, rememberedDBKey, &found); if (NS_SUCCEEDED(rv) && found) { hasRemembered = true; } } if (hasRemembered && !rememberedDBKey.IsEmpty()) { nsCOMPtr certdb = do_GetService(NS_X509CERTDB_CONTRACTID); if (certdb) { nsCOMPtr foundCert; rv = certdb->FindCertByDBKey(rememberedDBKey.get(), getter_AddRefs(foundCert)); if (NS_SUCCEEDED(rv) && foundCert) { nsNSSCertificate* objCert = BitwiseCast(foundCert.get()); if (objCert) { cert.reset(objCert->GetCert()); } } if (!cert) { hasRemembered = false; } } } if (!hasRemembered) { // user selects a cert to present nsCOMPtr dialogs; // find all user certs that are for SSL // note that we are allowing expired certs in this list UniqueCERTCertList certList( CERT_FindUserCertsByUsage(CERT_GetDefaultCertDB(), certUsageSSLClient, false, false, wincx)); if (!certList) { goto loser; } if (mCANames->nnames != 0) { // filter the list to those issued by CAs supported by the server mRV = CERT_FilterCertListByCANames(certList.get(), mCANames->nnames, caNameStrings, certUsageSSLClient); if (mRV != SECSuccess) { goto loser; } } if (CERT_LIST_END(CERT_LIST_HEAD(certList), certList)) { // list is empty - no matching certs goto loser; } int32_t port; mSocketInfo->GetPort(&port); UniquePORTString corg(CERT_GetOrgName(&mServerCert->subject)); nsAutoCString org(corg.get()); UniquePORTString cissuer(CERT_GetOrgName(&mServerCert->issuer)); nsAutoCString issuer(cissuer.get()); nsCOMPtr certArray = nsArrayBase::Create(); if (!certArray) { goto loser; } for (CERTCertListNode* node = CERT_LIST_HEAD(certList); !CERT_LIST_END(node, certList); node = CERT_LIST_NEXT(node)) { nsCOMPtr tempCert = nsNSSCertificate::Create(node->cert); if (!tempCert) { goto loser; } rv = certArray->AppendElement(tempCert, false); if (NS_FAILED(rv)) { goto loser; } } // Throw up the client auth dialog and get back the index of the selected cert rv = getNSSDialogs(getter_AddRefs(dialogs), NS_GET_IID(nsIClientAuthDialogs), NS_CLIENTAUTHDIALOGS_CONTRACTID); if (NS_FAILED(rv)) { goto loser; } uint32_t selectedIndex = 0; bool certChosen = false; rv = dialogs->ChooseCertificate(mSocketInfo, hostname, port, org, issuer, certArray, &selectedIndex, &certChosen); if (NS_FAILED(rv)) { goto loser; } // even if the user has canceled, we want to remember that, to avoid repeating prompts bool wantRemember = false; mSocketInfo->GetRememberClientAuthCertificate(&wantRemember); if (certChosen) { nsCOMPtr selectedCert = do_QueryElementAt(certArray, selectedIndex); if (!selectedCert) { goto loser; } cert.reset(selectedCert->GetCert()); } if (cars && wantRemember) { cars->RememberDecision(hostname, mSocketInfo->GetOriginAttributes(), mServerCert, certChosen ? cert.get() : nullptr); } } if (!cert) { goto loser; } // go get the private key privKey.reset(PK11_FindKeyByAnyCert(cert.get(), wincx)); if (!privKey) { goto loser; } } goto done; loser: if (mRV == SECSuccess) { mRV = SECFailure; } done: int error = PR_GetError(); *mPRetCert = cert.release(); *mPRetKey = privKey.release(); if (mRV == SECFailure) { mErrorCodeToReport = error; } } static PRFileDesc* nsSSLIOLayerImportFD(PRFileDesc* fd, nsNSSSocketInfo* infoObject, const char* host) { nsNSSShutDownPreventionLock locker; PRFileDesc* sslSock = SSL_ImportFD(nullptr, fd); if (!sslSock) { NS_ASSERTION(false, "NSS: Error importing socket"); return nullptr; } SSL_SetPKCS11PinArg(sslSock, (nsIInterfaceRequestor*) infoObject); SSL_HandshakeCallback(sslSock, HandshakeCallback, infoObject); SSL_SetCanFalseStartCallback(sslSock, CanFalseStartCallback, infoObject); // Disable this hook if we connect anonymously. See bug 466080. uint32_t flags = 0; infoObject->GetProviderFlags(&flags); if (flags & nsISocketProvider::ANONYMOUS_CONNECT) { SSL_GetClientAuthDataHook(sslSock, nullptr, infoObject); } else { SSL_GetClientAuthDataHook(sslSock, (SSLGetClientAuthData) nsNSS_SSLGetClientAuthData, infoObject); } if (flags & nsISocketProvider::MITM_OK) { MOZ_LOG(gPIPNSSLog, LogLevel::Debug, ("[%p] nsSSLIOLayerImportFD: bypass authentication flag\n", fd)); infoObject->SetBypassAuthentication(true); } if (SECSuccess != SSL_AuthCertificateHook(sslSock, AuthCertificateHook, infoObject)) { NS_NOTREACHED("failed to configure AuthCertificateHook"); goto loser; } if (SECSuccess != SSL_SetURL(sslSock, host)) { NS_NOTREACHED("SSL_SetURL failed"); goto loser; } return sslSock; loser: if (sslSock) { PR_Close(sslSock); } return nullptr; } // Please change getSignatureName in nsNSSCallbacks.cpp when changing the list // here. static const SSLSignatureScheme sEnabledSignatureSchemes[] = { ssl_sig_ecdsa_secp256r1_sha256, ssl_sig_ecdsa_secp384r1_sha384, ssl_sig_ecdsa_secp521r1_sha512, ssl_sig_rsa_pss_sha256, ssl_sig_rsa_pss_sha384, ssl_sig_rsa_pss_sha512, ssl_sig_rsa_pkcs1_sha256, ssl_sig_rsa_pkcs1_sha384, ssl_sig_rsa_pkcs1_sha512, ssl_sig_ecdsa_sha1, ssl_sig_rsa_pkcs1_sha1, }; static nsresult nsSSLIOLayerSetOptions(PRFileDesc* fd, bool forSTARTTLS, bool haveProxy, const char* host, int32_t port, nsNSSSocketInfo* infoObject) { nsNSSShutDownPreventionLock locker; if (forSTARTTLS || haveProxy) { if (SECSuccess != SSL_OptionSet(fd, SSL_SECURITY, false)) { return NS_ERROR_FAILURE; } } SSLVersionRange range; if (SSL_VersionRangeGet(fd, &range) != SECSuccess) { return NS_ERROR_FAILURE; } if ((infoObject->GetProviderFlags() & nsISocketProvider::BE_CONSERVATIVE) && (range.max > SSL_LIBRARY_VERSION_TLS_1_2)) { MOZ_LOG(gPIPNSSLog, LogLevel::Debug, ("[%p] nsSSLIOLayerSetOptions: range.max limited to 1.2 due to BE_CONSERVATIVE flag\n", fd)); range.max = SSL_LIBRARY_VERSION_TLS_1_2; } uint16_t maxEnabledVersion = range.max; StrongCipherStatus strongCiphersStatus = StrongCipherStatusUnknown; infoObject->SharedState().IOLayerHelpers() .adjustForTLSIntolerance(infoObject->GetHostName(), infoObject->GetPort(), range, strongCiphersStatus); MOZ_LOG(gPIPNSSLog, LogLevel::Debug, ("[%p] nsSSLIOLayerSetOptions: using TLS version range (0x%04x,0x%04x)%s\n", fd, static_cast(range.min), static_cast(range.max), strongCiphersStatus == StrongCiphersFailed ? " with weak ciphers" : "")); if (SSL_VersionRangeSet(fd, &range) != SECSuccess) { return NS_ERROR_FAILURE; } infoObject->SetTLSVersionRange(range); if (strongCiphersStatus == StrongCiphersFailed) { nsNSSComponent::UseWeakCiphersOnSocket(fd); } // when adjustForTLSIntolerance tweaks the maximum version downward, // we tell the server using this SCSV so they can detect a downgrade attack if (range.max < maxEnabledVersion) { MOZ_LOG(gPIPNSSLog, LogLevel::Debug, ("[%p] nsSSLIOLayerSetOptions: enabling TLS_FALLBACK_SCSV\n", fd)); // Some servers will choke if we send the fallback SCSV with TLS 1.2. if (range.max < SSL_LIBRARY_VERSION_TLS_1_2) { if (SECSuccess != SSL_OptionSet(fd, SSL_ENABLE_FALLBACK_SCSV, true)) { return NS_ERROR_FAILURE; } } // tell NSS the max enabled version to make anti-downgrade effective if (SECSuccess != SSL_SetDowngradeCheckVersion(fd, maxEnabledVersion)) { return NS_ERROR_FAILURE; } } // Include a modest set of named groups. // Please change getKeaGroupName in nsNSSCallbacks.cpp when changing the list // here. const SSLNamedGroup namedGroups[] = { ssl_grp_ec_curve25519, ssl_grp_ec_secp256r1, ssl_grp_ec_secp384r1, ssl_grp_ec_secp521r1, ssl_grp_ffdhe_2048, ssl_grp_ffdhe_3072 }; if (SECSuccess != SSL_NamedGroupConfig(fd, namedGroups, mozilla::ArrayLength(namedGroups))) { return NS_ERROR_FAILURE; } // This ensures that we send key shares for X25519 and P-256 in TLS 1.3, so // that servers are less likely to use HelloRetryRequest. if (SECSuccess != SSL_SendAdditionalKeyShares(fd, 1)) { return NS_ERROR_FAILURE; } if (SECSuccess != SSL_SignatureSchemePrefSet(fd, sEnabledSignatureSchemes, mozilla::ArrayLength(sEnabledSignatureSchemes))) { return NS_ERROR_FAILURE; } bool enabled = infoObject->SharedState().IsOCSPStaplingEnabled(); if (SECSuccess != SSL_OptionSet(fd, SSL_ENABLE_OCSP_STAPLING, enabled)) { return NS_ERROR_FAILURE; } bool sctsEnabled = infoObject->SharedState().IsSignedCertTimestampsEnabled(); if (SECSuccess != SSL_OptionSet(fd, SSL_ENABLE_SIGNED_CERT_TIMESTAMPS, sctsEnabled)) { return NS_ERROR_FAILURE; } if (SECSuccess != SSL_OptionSet(fd, SSL_HANDSHAKE_AS_CLIENT, true)) { return NS_ERROR_FAILURE; } // Set the Peer ID so that SSL proxy connections work properly and to // separate anonymous and/or private browsing connections. uint32_t flags = infoObject->GetProviderFlags(); nsAutoCString peerId; if (flags & nsISocketProvider::ANONYMOUS_CONNECT) { // See bug 466080 peerId.AppendLiteral("anon:"); } if (flags & nsISocketProvider::NO_PERMANENT_STORAGE) { peerId.AppendLiteral("private:"); } if (flags & nsISocketProvider::MITM_OK) { peerId.AppendLiteral("bypassAuth:"); } if (flags & nsISocketProvider::BE_CONSERVATIVE) { peerId.AppendLiteral("beConservative:"); } peerId.Append(host); peerId.Append(':'); peerId.AppendInt(port); nsAutoCString suffix; infoObject->GetOriginAttributes().CreateSuffix(suffix); peerId.Append(suffix); if (SECSuccess != SSL_SetSockPeerID(fd, peerId.get())) { return NS_ERROR_FAILURE; } return NS_OK; } nsresult nsSSLIOLayerAddToSocket(int32_t family, const char* host, int32_t port, nsIProxyInfo* proxy, const NeckoOriginAttributes& originAttributes, PRFileDesc* fd, nsISupports** info, bool forSTARTTLS, uint32_t providerFlags) { nsNSSShutDownPreventionLock locker; PRFileDesc* layer = nullptr; PRFileDesc* plaintextLayer = nullptr; nsresult rv; PRStatus stat; SharedSSLState* sharedState = providerFlags & nsISocketProvider::NO_PERMANENT_STORAGE ? PrivateSSLState() : PublicSSLState(); nsNSSSocketInfo* infoObject = new nsNSSSocketInfo(*sharedState, providerFlags); if (!infoObject) return NS_ERROR_FAILURE; NS_ADDREF(infoObject); infoObject->SetForSTARTTLS(forSTARTTLS); infoObject->SetHostName(host); infoObject->SetPort(port); infoObject->SetOriginAttributes(originAttributes); bool haveProxy = false; if (proxy) { nsCString proxyHost; proxy->GetHost(proxyHost); haveProxy = !proxyHost.IsEmpty(); } // A plaintext observer shim is inserted so we can observe some protocol // details without modifying nss plaintextLayer = PR_CreateIOLayerStub(nsSSLIOLayerHelpers::nsSSLPlaintextLayerIdentity, &nsSSLIOLayerHelpers::nsSSLPlaintextLayerMethods); if (plaintextLayer) { plaintextLayer->secret = (PRFilePrivate*) infoObject; stat = PR_PushIOLayer(fd, PR_TOP_IO_LAYER, plaintextLayer); if (stat == PR_FAILURE) { plaintextLayer->dtor(plaintextLayer); plaintextLayer = nullptr; } } PRFileDesc* sslSock = nsSSLIOLayerImportFD(fd, infoObject, host); if (!sslSock) { NS_ASSERTION(false, "NSS: Error importing socket"); goto loser; } infoObject->SetFileDescPtr(sslSock); rv = nsSSLIOLayerSetOptions(sslSock, forSTARTTLS, haveProxy, host, port, infoObject); if (NS_FAILED(rv)) goto loser; // Now, layer ourselves on top of the SSL socket... layer = PR_CreateIOLayerStub(nsSSLIOLayerHelpers::nsSSLIOLayerIdentity, &nsSSLIOLayerHelpers::nsSSLIOLayerMethods); if (!layer) goto loser; layer->secret = (PRFilePrivate*) infoObject; stat = PR_PushIOLayer(sslSock, PR_GetLayersIdentity(sslSock), layer); if (stat == PR_FAILURE) { goto loser; } MOZ_LOG(gPIPNSSLog, LogLevel::Debug, ("[%p] Socket set up\n", (void*) sslSock)); infoObject->QueryInterface(NS_GET_IID(nsISupports), (void**) (info)); // We are going use a clear connection first // if (forSTARTTLS || haveProxy) { infoObject->SetHandshakeNotPending(); } infoObject->SharedState().NoteSocketCreated(); return NS_OK; loser: NS_IF_RELEASE(infoObject); if (layer) { layer->dtor(layer); } if (plaintextLayer) { PR_PopIOLayer(fd, nsSSLIOLayerHelpers::nsSSLPlaintextLayerIdentity); plaintextLayer->dtor(plaintextLayer); } return NS_ERROR_FAILURE; }