/* * vtables (and methods that call through them) for the 4 types of * SSLSockets supported. Only one type is still supported. * Various other functions. * * 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 "seccomon.h" #include "cert.h" #include "keyhi.h" #include "ssl.h" #include "sslimpl.h" #include "sslproto.h" #include "nspr.h" #include "private/pprio.h" #ifndef NO_PKCS11_BYPASS #include "blapi.h" #endif #include "nss.h" #include "pk11pqg.h" #define SET_ERROR_CODE /* reminder */ static const sslSocketOps ssl_default_ops = { /* No SSL. */ ssl_DefConnect, NULL, ssl_DefBind, ssl_DefListen, ssl_DefShutdown, ssl_DefClose, ssl_DefRecv, ssl_DefSend, ssl_DefRead, ssl_DefWrite, ssl_DefGetpeername, ssl_DefGetsockname }; static const sslSocketOps ssl_secure_ops = { /* SSL. */ ssl_SecureConnect, NULL, ssl_DefBind, ssl_DefListen, ssl_SecureShutdown, ssl_SecureClose, ssl_SecureRecv, ssl_SecureSend, ssl_SecureRead, ssl_SecureWrite, ssl_DefGetpeername, ssl_DefGetsockname }; /* ** default settings for socket enables */ static sslOptions ssl_defaults = { { siBuffer, NULL, 0 }, /* nextProtoNego */ PR_TRUE, /* useSecurity */ PR_FALSE, /* useSocks */ PR_FALSE, /* requestCertificate */ 2, /* requireCertificate */ PR_FALSE, /* handshakeAsClient */ PR_FALSE, /* handshakeAsServer */ PR_FALSE, /* enableSSL2 */ /* now defaults to off in NSS 3.13 */ PR_FALSE, /* unusedBit9 */ PR_FALSE, /* unusedBit10 */ PR_FALSE, /* noCache */ PR_FALSE, /* fdx */ PR_FALSE, /* v2CompatibleHello */ /* now defaults to off in NSS 3.13 */ PR_TRUE, /* detectRollBack */ PR_FALSE, /* noStepDown */ PR_FALSE, /* bypassPKCS11 */ PR_FALSE, /* noLocks */ PR_FALSE, /* enableSessionTickets */ PR_FALSE, /* enableDeflate */ 2, /* enableRenegotiation (default: requires extension) */ PR_FALSE, /* requireSafeNegotiation */ PR_FALSE, /* enableFalseStart */ PR_TRUE, /* cbcRandomIV */ PR_FALSE, /* enableOCSPStapling */ PR_TRUE, /* enableNPN */ PR_FALSE, /* enableALPN */ PR_TRUE, /* reuseServerECDHEKey */ PR_FALSE, /* enableFallbackSCSV */ PR_TRUE, /* enableServerDhe */ PR_FALSE /* enableExtendedMS */ }; /* * default range of enabled SSL/TLS protocols */ static SSLVersionRange versions_defaults_stream = { SSL_LIBRARY_VERSION_TLS_1_0, SSL_LIBRARY_VERSION_TLS_1_2 }; static SSLVersionRange versions_defaults_datagram = { SSL_LIBRARY_VERSION_TLS_1_1, SSL_LIBRARY_VERSION_TLS_1_2 }; #define VERSIONS_DEFAULTS(variant) \ (variant == ssl_variant_stream ? &versions_defaults_stream : \ &versions_defaults_datagram) sslSessionIDLookupFunc ssl_sid_lookup; sslSessionIDCacheFunc ssl_sid_cache; sslSessionIDUncacheFunc ssl_sid_uncache; static PRBool ssl_inited = PR_FALSE; static PRDescIdentity ssl_layer_id; PRBool locksEverDisabled; /* implicitly PR_FALSE */ PRBool ssl_force_locks; /* implicitly PR_FALSE */ int ssl_lock_readers = 1; /* default true. */ char ssl_debug; char ssl_trace; FILE * ssl_trace_iob; FILE * ssl_keylog_iob; char lockStatus[] = "Locks are ENABLED. "; #define LOCKSTATUS_OFFSET 10 /* offset of ENABLED */ /* SRTP_NULL_HMAC_SHA1_80 and SRTP_NULL_HMAC_SHA1_32 are not implemented. */ static const PRUint16 srtpCiphers[] = { SRTP_AES128_CM_HMAC_SHA1_80, SRTP_AES128_CM_HMAC_SHA1_32, 0 }; /* forward declarations. */ static sslSocket *ssl_NewSocket(PRBool makeLocks, SSLProtocolVariant variant); static SECStatus ssl_MakeLocks(sslSocket *ss); static void ssl_SetDefaultsFromEnvironment(void); static PRStatus ssl_PushIOLayer(sslSocket *ns, PRFileDesc *stack, PRDescIdentity id); /************************************************************************/ /* ** Lookup a socket structure from a file descriptor. ** Only functions called through the PRIOMethods table should use this. ** Other app-callable functions should use ssl_FindSocket. */ static sslSocket * ssl_GetPrivate(PRFileDesc *fd) { sslSocket *ss; PORT_Assert(fd != NULL); PORT_Assert(fd->methods->file_type == PR_DESC_LAYERED); PORT_Assert(fd->identity == ssl_layer_id); if (fd->methods->file_type != PR_DESC_LAYERED || fd->identity != ssl_layer_id) { PORT_SetError(PR_BAD_DESCRIPTOR_ERROR); return NULL; } ss = (sslSocket *)fd->secret; /* Set ss->fd lazily. We can't rely on the value of ss->fd set by * ssl_PushIOLayer because another PR_PushIOLayer call will switch the * contents of the PRFileDesc pointed by ss->fd and the new layer. * See bug 807250. */ ss->fd = fd; return ss; } /* This function tries to find the SSL layer in the stack. * It searches for the first SSL layer at or below the argument fd, * and failing that, it searches for the nearest SSL layer above the * argument fd. It returns the private sslSocket from the found layer. */ sslSocket * ssl_FindSocket(PRFileDesc *fd) { PRFileDesc *layer; sslSocket *ss; PORT_Assert(fd != NULL); PORT_Assert(ssl_layer_id != 0); layer = PR_GetIdentitiesLayer(fd, ssl_layer_id); if (layer == NULL) { PORT_SetError(PR_BAD_DESCRIPTOR_ERROR); return NULL; } ss = (sslSocket *)layer->secret; /* Set ss->fd lazily. We can't rely on the value of ss->fd set by * ssl_PushIOLayer because another PR_PushIOLayer call will switch the * contents of the PRFileDesc pointed by ss->fd and the new layer. * See bug 807250. */ ss->fd = layer; return ss; } static sslSocket * ssl_DupSocket(sslSocket *os) { sslSocket *ss; SECStatus rv; ss = ssl_NewSocket((PRBool)(!os->opt.noLocks), os->protocolVariant); if (ss) { ss->opt = os->opt; ss->opt.useSocks = PR_FALSE; ss->vrange = os->vrange; ss->peerID = !os->peerID ? NULL : PORT_Strdup(os->peerID); ss->url = !os->url ? NULL : PORT_Strdup(os->url); ss->ops = os->ops; ss->rTimeout = os->rTimeout; ss->wTimeout = os->wTimeout; ss->cTimeout = os->cTimeout; ss->dbHandle = os->dbHandle; /* copy ssl2&3 policy & prefs, even if it's not selected (yet) */ ss->allowedByPolicy = os->allowedByPolicy; ss->maybeAllowedByPolicy= os->maybeAllowedByPolicy; ss->chosenPreference = os->chosenPreference; PORT_Memcpy(ss->cipherSuites, os->cipherSuites, sizeof os->cipherSuites); PORT_Memcpy(ss->ssl3.dtlsSRTPCiphers, os->ssl3.dtlsSRTPCiphers, sizeof(PRUint16) * os->ssl3.dtlsSRTPCipherCount); ss->ssl3.dtlsSRTPCipherCount = os->ssl3.dtlsSRTPCipherCount; PORT_Memcpy(ss->ssl3.signatureAlgorithms, os->ssl3.signatureAlgorithms, sizeof(ss->ssl3.signatureAlgorithms[0]) * os->ssl3.signatureAlgorithmCount); ss->ssl3.signatureAlgorithmCount = os->ssl3.signatureAlgorithmCount; ss->ssl3.dheWeakGroupEnabled = os->ssl3.dheWeakGroupEnabled; ss->ssl3.numDHEGroups = os->ssl3.numDHEGroups; if (os->ssl3.dheGroups) { ss->ssl3.dheGroups = PORT_NewArray(SSLDHEGroupType, os->ssl3.numDHEGroups); if (!ss->ssl3.dheGroups) { goto loser; } PORT_Memcpy(ss->ssl3.dheGroups, os->ssl3.dheGroups, sizeof(SSLDHEGroupType) * os->ssl3.numDHEGroups); } else { ss->ssl3.dheGroups = NULL; } if (os->cipherSpecs) { ss->cipherSpecs = (unsigned char*)PORT_Alloc(os->sizeCipherSpecs); if (ss->cipherSpecs) PORT_Memcpy(ss->cipherSpecs, os->cipherSpecs, os->sizeCipherSpecs); ss->sizeCipherSpecs = os->sizeCipherSpecs; ss->preferredCipher = os->preferredCipher; } else { ss->cipherSpecs = NULL; /* produced lazily */ ss->sizeCipherSpecs = 0; ss->preferredCipher = NULL; } if (ss->opt.useSecurity) { /* This int should be SSLKEAType, but CC on Irix complains, * during the for loop. */ int i; sslServerCerts * oc = os->serverCerts; sslServerCerts * sc = ss->serverCerts; for (i=kt_null; i < kt_kea_size; i++, oc++, sc++) { if (oc->serverCert && oc->serverCertChain) { sc->serverCert = CERT_DupCertificate(oc->serverCert); sc->serverCertChain = CERT_DupCertList(oc->serverCertChain); if (!sc->serverCertChain) goto loser; } else { sc->serverCert = NULL; sc->serverCertChain = NULL; } sc->serverKeyPair = oc->serverKeyPair ? ssl3_GetKeyPairRef(oc->serverKeyPair) : NULL; if (oc->serverKeyPair && !sc->serverKeyPair) goto loser; sc->serverKeyBits = oc->serverKeyBits; ss->certStatusArray[i] = !os->certStatusArray[i] ? NULL : SECITEM_DupArray(NULL, os->certStatusArray[i]); } ss->stepDownKeyPair = !os->stepDownKeyPair ? NULL : ssl3_GetKeyPairRef(os->stepDownKeyPair); ss->ephemeralECDHKeyPair = !os->ephemeralECDHKeyPair ? NULL : ssl3_GetKeyPairRef(os->ephemeralECDHKeyPair); ss->dheKeyPair = !os->dheKeyPair ? NULL : ssl3_GetKeyPairRef(os->dheKeyPair); ss->dheParams = os->dheParams; /* * XXX the preceding CERT_ and SECKEY_ functions can fail and return NULL. * XXX We should detect this, and not just march on with NULL pointers. */ ss->authCertificate = os->authCertificate; ss->authCertificateArg = os->authCertificateArg; ss->getClientAuthData = os->getClientAuthData; ss->getClientAuthDataArg = os->getClientAuthDataArg; ss->sniSocketConfig = os->sniSocketConfig; ss->sniSocketConfigArg = os->sniSocketConfigArg; ss->handleBadCert = os->handleBadCert; ss->badCertArg = os->badCertArg; ss->handshakeCallback = os->handshakeCallback; ss->handshakeCallbackData = os->handshakeCallbackData; ss->canFalseStartCallback = os->canFalseStartCallback; ss->canFalseStartCallbackData = os->canFalseStartCallbackData; ss->pkcs11PinArg = os->pkcs11PinArg; /* Create security data */ rv = ssl_CopySecurityInfo(ss, os); if (rv != SECSuccess) { goto loser; } } } return ss; loser: ssl_FreeSocket(ss); return NULL; } static void ssl_DestroyLocks(sslSocket *ss) { /* Destroy locks. */ if (ss->firstHandshakeLock) { PZ_DestroyMonitor(ss->firstHandshakeLock); ss->firstHandshakeLock = NULL; } if (ss->ssl3HandshakeLock) { PZ_DestroyMonitor(ss->ssl3HandshakeLock); ss->ssl3HandshakeLock = NULL; } if (ss->specLock) { NSSRWLock_Destroy(ss->specLock); ss->specLock = NULL; } if (ss->recvLock) { PZ_DestroyLock(ss->recvLock); ss->recvLock = NULL; } if (ss->sendLock) { PZ_DestroyLock(ss->sendLock); ss->sendLock = NULL; } if (ss->xmitBufLock) { PZ_DestroyMonitor(ss->xmitBufLock); ss->xmitBufLock = NULL; } if (ss->recvBufLock) { PZ_DestroyMonitor(ss->recvBufLock); ss->recvBufLock = NULL; } } /* Caller holds any relevant locks */ static void ssl_DestroySocketContents(sslSocket *ss) { /* "i" should be of type SSLKEAType, but CC on IRIX complains during * the for loop. */ int i; /* Free up socket */ ssl_DestroySecurityInfo(&ss->sec); ssl3_DestroySSL3Info(ss); PORT_Free(ss->saveBuf.buf); PORT_Free(ss->pendingBuf.buf); ssl_DestroyGather(&ss->gs); if (ss->peerID != NULL) PORT_Free(ss->peerID); if (ss->url != NULL) PORT_Free((void *)ss->url); /* CONST */ if (ss->cipherSpecs) { PORT_Free(ss->cipherSpecs); ss->cipherSpecs = NULL; ss->sizeCipherSpecs = 0; } /* Clean up server configuration */ for (i=kt_null; i < kt_kea_size; i++) { sslServerCerts * sc = ss->serverCerts + i; if (sc->serverCert != NULL) CERT_DestroyCertificate(sc->serverCert); if (sc->serverCertChain != NULL) CERT_DestroyCertificateList(sc->serverCertChain); if (sc->serverKeyPair != NULL) ssl3_FreeKeyPair(sc->serverKeyPair); if (ss->certStatusArray[i] != NULL) { SECITEM_FreeArray(ss->certStatusArray[i], PR_TRUE); ss->certStatusArray[i] = NULL; } } if (ss->stepDownKeyPair) { ssl3_FreeKeyPair(ss->stepDownKeyPair); ss->stepDownKeyPair = NULL; } if (ss->ephemeralECDHKeyPair) { ssl3_FreeKeyPair(ss->ephemeralECDHKeyPair); ss->ephemeralECDHKeyPair = NULL; } if (ss->dheKeyPair) { ssl3_FreeKeyPair(ss->dheKeyPair); ss->dheKeyPair = NULL; } SECITEM_FreeItem(&ss->opt.nextProtoNego, PR_FALSE); if (ss->xtnData.sniNameArr) { PORT_Free(ss->xtnData.sniNameArr); ss->xtnData.sniNameArr = NULL; } } /* * free an sslSocket struct, and all the stuff that hangs off of it */ void ssl_FreeSocket(sslSocket *ss) { /* Get every lock you can imagine! ** Caller already holds these: ** SSL_LOCK_READER(ss); ** SSL_LOCK_WRITER(ss); */ ssl_Get1stHandshakeLock(ss); ssl_GetRecvBufLock(ss); ssl_GetSSL3HandshakeLock(ss); ssl_GetXmitBufLock(ss); ssl_GetSpecWriteLock(ss); ssl_DestroySocketContents(ss); /* Release all the locks acquired above. */ SSL_UNLOCK_READER(ss); SSL_UNLOCK_WRITER(ss); ssl_Release1stHandshakeLock(ss); ssl_ReleaseRecvBufLock(ss); ssl_ReleaseSSL3HandshakeLock(ss); ssl_ReleaseXmitBufLock(ss); ssl_ReleaseSpecWriteLock(ss); ssl_DestroyLocks(ss); #ifdef DEBUG PORT_Memset(ss, 0x1f, sizeof *ss); #endif PORT_Free(ss); return; } /************************************************************************/ SECStatus ssl_EnableNagleDelay(sslSocket *ss, PRBool enabled) { PRFileDesc * osfd = ss->fd->lower; SECStatus rv = SECFailure; PRSocketOptionData opt; opt.option = PR_SockOpt_NoDelay; opt.value.no_delay = (PRBool)!enabled; if (osfd->methods->setsocketoption) { rv = (SECStatus) osfd->methods->setsocketoption(osfd, &opt); } else { PR_SetError(PR_NOT_IMPLEMENTED_ERROR, 0); } return rv; } static void ssl_ChooseOps(sslSocket *ss) { ss->ops = ss->opt.useSecurity ? &ssl_secure_ops : &ssl_default_ops; } /* Called from SSL_Enable (immediately below) */ static SECStatus PrepareSocket(sslSocket *ss) { SECStatus rv = SECSuccess; ssl_ChooseOps(ss); return rv; } SECStatus SSL_Enable(PRFileDesc *fd, int which, PRBool on) { return SSL_OptionSet(fd, which, on); } #ifndef NO_PKCS11_BYPASS static const PRCallOnceType pristineCallOnce; static PRCallOnceType setupBypassOnce; static SECStatus SSL_BypassShutdown(void* appData, void* nssData) { /* unload freeBL shared library from memory */ BL_Unload(); setupBypassOnce = pristineCallOnce; return SECSuccess; } static PRStatus SSL_BypassRegisterShutdown(void) { SECStatus rv = NSS_RegisterShutdown(SSL_BypassShutdown, NULL); PORT_Assert(SECSuccess == rv); return SECSuccess == rv ? PR_SUCCESS : PR_FAILURE; } #endif static PRStatus SSL_BypassSetup(void) { #ifdef NO_PKCS11_BYPASS /* Guarantee binary compatibility */ return PR_SUCCESS; #else return PR_CallOnce(&setupBypassOnce, &SSL_BypassRegisterShutdown); #endif } /* Implements the semantics for SSL_OptionSet(SSL_ENABLE_TLS, on) described in * ssl.h in the section "SSL version range setting API". */ static void ssl_EnableTLS(SSLVersionRange *vrange, PRBool on) { if (SSL3_ALL_VERSIONS_DISABLED(vrange)) { if (on) { vrange->min = SSL_LIBRARY_VERSION_TLS_1_0; vrange->max = SSL_LIBRARY_VERSION_TLS_1_0; } /* else don't change anything */ return; } if (on) { /* Expand the range of enabled version to include TLS 1.0 */ vrange->min = PR_MIN(vrange->min, SSL_LIBRARY_VERSION_TLS_1_0); vrange->max = PR_MAX(vrange->max, SSL_LIBRARY_VERSION_TLS_1_0); } else { /* Disable all TLS versions, leaving only SSL 3.0 if it was enabled */ if (vrange->min == SSL_LIBRARY_VERSION_3_0) { vrange->max = SSL_LIBRARY_VERSION_3_0; } else { /* Only TLS was enabled, so now no versions are. */ vrange->min = SSL_LIBRARY_VERSION_NONE; vrange->max = SSL_LIBRARY_VERSION_NONE; } } } /* Implements the semantics for SSL_OptionSet(SSL_ENABLE_SSL3, on) described in * ssl.h in the section "SSL version range setting API". */ static void ssl_EnableSSL3(SSLVersionRange *vrange, PRBool on) { if (SSL3_ALL_VERSIONS_DISABLED(vrange)) { if (on) { vrange->min = SSL_LIBRARY_VERSION_3_0; vrange->max = SSL_LIBRARY_VERSION_3_0; } /* else don't change anything */ return; } if (on) { /* Expand the range of enabled versions to include SSL 3.0. We know * SSL 3.0 or some version of TLS is already enabled at this point, so * we don't need to change vrange->max. */ vrange->min = SSL_LIBRARY_VERSION_3_0; } else { /* Disable SSL 3.0, leaving TLS unaffected. */ if (vrange->max > SSL_LIBRARY_VERSION_3_0) { vrange->min = PR_MAX(vrange->min, SSL_LIBRARY_VERSION_TLS_1_0); } else { /* Only SSL 3.0 was enabled, so now no versions are. */ vrange->min = SSL_LIBRARY_VERSION_NONE; vrange->max = SSL_LIBRARY_VERSION_NONE; } } } SECStatus SSL_OptionSet(PRFileDesc *fd, PRInt32 which, PRBool on) { sslSocket *ss = ssl_FindSocket(fd); SECStatus rv = SECSuccess; PRBool holdingLocks; if (!ss) { SSL_DBG(("%d: SSL[%d]: bad socket in Enable", SSL_GETPID(), fd)); return SECFailure; } holdingLocks = (!ss->opt.noLocks); ssl_Get1stHandshakeLock(ss); ssl_GetSSL3HandshakeLock(ss); switch (which) { case SSL_SOCKS: ss->opt.useSocks = PR_FALSE; rv = PrepareSocket(ss); if (on) { PORT_SetError(SEC_ERROR_INVALID_ARGS); rv = SECFailure; } break; case SSL_SECURITY: ss->opt.useSecurity = on; rv = PrepareSocket(ss); break; case SSL_REQUEST_CERTIFICATE: ss->opt.requestCertificate = on; break; case SSL_REQUIRE_CERTIFICATE: ss->opt.requireCertificate = on; break; case SSL_HANDSHAKE_AS_CLIENT: if ( ss->opt.handshakeAsServer && on ) { PORT_SetError(SEC_ERROR_INVALID_ARGS); rv = SECFailure; break; } ss->opt.handshakeAsClient = on; break; case SSL_HANDSHAKE_AS_SERVER: if ( ss->opt.handshakeAsClient && on ) { PORT_SetError(SEC_ERROR_INVALID_ARGS); rv = SECFailure; break; } ss->opt.handshakeAsServer = on; break; case SSL_ENABLE_TLS: if (IS_DTLS(ss)) { if (on) { PORT_SetError(SEC_ERROR_INVALID_ARGS); rv = SECFailure; /* not allowed */ } break; } ssl_EnableTLS(&ss->vrange, on); ss->preferredCipher = NULL; if (ss->cipherSpecs) { PORT_Free(ss->cipherSpecs); ss->cipherSpecs = NULL; ss->sizeCipherSpecs = 0; } break; case SSL_ENABLE_SSL3: if (IS_DTLS(ss)) { if (on) { PORT_SetError(SEC_ERROR_INVALID_ARGS); rv = SECFailure; /* not allowed */ } break; } ssl_EnableSSL3(&ss->vrange, on); ss->preferredCipher = NULL; if (ss->cipherSpecs) { PORT_Free(ss->cipherSpecs); ss->cipherSpecs = NULL; ss->sizeCipherSpecs = 0; } break; case SSL_ENABLE_SSL2: if (IS_DTLS(ss)) { if (on) { PORT_SetError(SEC_ERROR_INVALID_ARGS); rv = SECFailure; /* not allowed */ } break; } ss->opt.enableSSL2 = on; if (on) { ss->opt.v2CompatibleHello = on; } ss->preferredCipher = NULL; if (ss->cipherSpecs) { PORT_Free(ss->cipherSpecs); ss->cipherSpecs = NULL; ss->sizeCipherSpecs = 0; } break; case SSL_NO_CACHE: ss->opt.noCache = on; break; case SSL_ENABLE_FDX: if (on && ss->opt.noLocks) { PORT_SetError(SEC_ERROR_INVALID_ARGS); rv = SECFailure; } ss->opt.fdx = on; break; case SSL_V2_COMPATIBLE_HELLO: if (IS_DTLS(ss)) { if (on) { PORT_SetError(SEC_ERROR_INVALID_ARGS); rv = SECFailure; /* not allowed */ } break; } ss->opt.v2CompatibleHello = on; if (!on) { ss->opt.enableSSL2 = on; } break; case SSL_ROLLBACK_DETECTION: ss->opt.detectRollBack = on; break; case SSL_NO_STEP_DOWN: ss->opt.noStepDown = on; if (on) SSL_DisableExportCipherSuites(fd); break; case SSL_BYPASS_PKCS11: if (ss->handshakeBegun) { PORT_SetError(PR_INVALID_STATE_ERROR); rv = SECFailure; } else { if (PR_FALSE != on) { if (PR_SUCCESS == SSL_BypassSetup() ) { #ifdef NO_PKCS11_BYPASS ss->opt.bypassPKCS11 = PR_FALSE; #else ss->opt.bypassPKCS11 = on; #endif } else { rv = SECFailure; } } else { ss->opt.bypassPKCS11 = PR_FALSE; } } break; case SSL_NO_LOCKS: if (on && ss->opt.fdx) { PORT_SetError(SEC_ERROR_INVALID_ARGS); rv = SECFailure; } if (on && ssl_force_locks) on = PR_FALSE; /* silent override */ ss->opt.noLocks = on; if (on) { locksEverDisabled = PR_TRUE; strcpy(lockStatus + LOCKSTATUS_OFFSET, "DISABLED."); } else if (!holdingLocks) { rv = ssl_MakeLocks(ss); if (rv != SECSuccess) { ss->opt.noLocks = PR_TRUE; } } break; case SSL_ENABLE_SESSION_TICKETS: ss->opt.enableSessionTickets = on; break; case SSL_ENABLE_DEFLATE: ss->opt.enableDeflate = on; break; case SSL_ENABLE_RENEGOTIATION: ss->opt.enableRenegotiation = on; break; case SSL_REQUIRE_SAFE_NEGOTIATION: ss->opt.requireSafeNegotiation = on; break; case SSL_ENABLE_FALSE_START: ss->opt.enableFalseStart = on; break; case SSL_CBC_RANDOM_IV: ss->opt.cbcRandomIV = on; break; case SSL_ENABLE_OCSP_STAPLING: ss->opt.enableOCSPStapling = on; break; case SSL_ENABLE_NPN: ss->opt.enableNPN = on; break; case SSL_ENABLE_ALPN: ss->opt.enableALPN = on; break; case SSL_REUSE_SERVER_ECDHE_KEY: ss->opt.reuseServerECDHEKey = on; break; case SSL_ENABLE_FALLBACK_SCSV: ss->opt.enableFallbackSCSV = on; break; case SSL_ENABLE_SERVER_DHE: ss->opt.enableServerDhe = on; break; case SSL_ENABLE_EXTENDED_MASTER_SECRET: ss->opt.enableExtendedMS = on; break; default: PORT_SetError(SEC_ERROR_INVALID_ARGS); rv = SECFailure; } /* We can't use the macros for releasing the locks here, * because ss->opt.noLocks might have changed just above. * We must release these locks (monitors) here, if we aquired them above, * regardless of the current value of ss->opt.noLocks. */ if (holdingLocks) { PZ_ExitMonitor((ss)->ssl3HandshakeLock); PZ_ExitMonitor((ss)->firstHandshakeLock); } return rv; } SECStatus SSL_OptionGet(PRFileDesc *fd, PRInt32 which, PRBool *pOn) { sslSocket *ss = ssl_FindSocket(fd); SECStatus rv = SECSuccess; PRBool on = PR_FALSE; if (!pOn) { PORT_SetError(SEC_ERROR_INVALID_ARGS); return SECFailure; } if (!ss) { SSL_DBG(("%d: SSL[%d]: bad socket in Enable", SSL_GETPID(), fd)); *pOn = PR_FALSE; return SECFailure; } ssl_Get1stHandshakeLock(ss); ssl_GetSSL3HandshakeLock(ss); switch (which) { case SSL_SOCKS: on = PR_FALSE; break; case SSL_SECURITY: on = ss->opt.useSecurity; break; case SSL_REQUEST_CERTIFICATE: on = ss->opt.requestCertificate; break; case SSL_REQUIRE_CERTIFICATE: on = ss->opt.requireCertificate; break; case SSL_HANDSHAKE_AS_CLIENT: on = ss->opt.handshakeAsClient; break; case SSL_HANDSHAKE_AS_SERVER: on = ss->opt.handshakeAsServer; break; case SSL_ENABLE_TLS: on = ss->vrange.max >= SSL_LIBRARY_VERSION_TLS_1_0; break; case SSL_ENABLE_SSL3: on = ss->vrange.min == SSL_LIBRARY_VERSION_3_0; break; case SSL_ENABLE_SSL2: on = ss->opt.enableSSL2; break; case SSL_NO_CACHE: on = ss->opt.noCache; break; case SSL_ENABLE_FDX: on = ss->opt.fdx; break; case SSL_V2_COMPATIBLE_HELLO: on = ss->opt.v2CompatibleHello; break; case SSL_ROLLBACK_DETECTION: on = ss->opt.detectRollBack; break; case SSL_NO_STEP_DOWN: on = ss->opt.noStepDown; break; case SSL_BYPASS_PKCS11: on = ss->opt.bypassPKCS11; break; case SSL_NO_LOCKS: on = ss->opt.noLocks; break; case SSL_ENABLE_SESSION_TICKETS: on = ss->opt.enableSessionTickets; break; case SSL_ENABLE_DEFLATE: on = ss->opt.enableDeflate; break; case SSL_ENABLE_RENEGOTIATION: on = ss->opt.enableRenegotiation; break; case SSL_REQUIRE_SAFE_NEGOTIATION: on = ss->opt.requireSafeNegotiation; break; case SSL_ENABLE_FALSE_START: on = ss->opt.enableFalseStart; break; case SSL_CBC_RANDOM_IV: on = ss->opt.cbcRandomIV; break; case SSL_ENABLE_OCSP_STAPLING: on = ss->opt.enableOCSPStapling; break; case SSL_ENABLE_NPN: on = ss->opt.enableNPN; break; case SSL_ENABLE_ALPN: on = ss->opt.enableALPN; break; case SSL_REUSE_SERVER_ECDHE_KEY: on = ss->opt.reuseServerECDHEKey; break; case SSL_ENABLE_FALLBACK_SCSV: on = ss->opt.enableFallbackSCSV; break; case SSL_ENABLE_SERVER_DHE: on = ss->opt.enableServerDhe; break; case SSL_ENABLE_EXTENDED_MASTER_SECRET: on = ss->opt.enableExtendedMS; break; default: PORT_SetError(SEC_ERROR_INVALID_ARGS); rv = SECFailure; } ssl_ReleaseSSL3HandshakeLock(ss); ssl_Release1stHandshakeLock(ss); *pOn = on; return rv; } SECStatus SSL_OptionGetDefault(PRInt32 which, PRBool *pOn) { SECStatus rv = SECSuccess; PRBool on = PR_FALSE; if (!pOn) { PORT_SetError(SEC_ERROR_INVALID_ARGS); return SECFailure; } ssl_SetDefaultsFromEnvironment(); switch (which) { case SSL_SOCKS: on = PR_FALSE; break; case SSL_SECURITY: on = ssl_defaults.useSecurity; break; case SSL_REQUEST_CERTIFICATE: on = ssl_defaults.requestCertificate; break; case SSL_REQUIRE_CERTIFICATE: on = ssl_defaults.requireCertificate; break; case SSL_HANDSHAKE_AS_CLIENT: on = ssl_defaults.handshakeAsClient; break; case SSL_HANDSHAKE_AS_SERVER: on = ssl_defaults.handshakeAsServer; break; case SSL_ENABLE_TLS: on = versions_defaults_stream.max >= SSL_LIBRARY_VERSION_TLS_1_0; break; case SSL_ENABLE_SSL3: on = versions_defaults_stream.min == SSL_LIBRARY_VERSION_3_0; break; case SSL_ENABLE_SSL2: on = ssl_defaults.enableSSL2; break; case SSL_NO_CACHE: on = ssl_defaults.noCache; break; case SSL_ENABLE_FDX: on = ssl_defaults.fdx; break; case SSL_V2_COMPATIBLE_HELLO: on = ssl_defaults.v2CompatibleHello; break; case SSL_ROLLBACK_DETECTION: on = ssl_defaults.detectRollBack; break; case SSL_NO_STEP_DOWN: on = ssl_defaults.noStepDown; break; case SSL_BYPASS_PKCS11: on = ssl_defaults.bypassPKCS11; break; case SSL_NO_LOCKS: on = ssl_defaults.noLocks; break; case SSL_ENABLE_SESSION_TICKETS: on = ssl_defaults.enableSessionTickets; break; case SSL_ENABLE_DEFLATE: on = ssl_defaults.enableDeflate; break; case SSL_ENABLE_RENEGOTIATION: on = ssl_defaults.enableRenegotiation; break; case SSL_REQUIRE_SAFE_NEGOTIATION: on = ssl_defaults.requireSafeNegotiation; break; case SSL_ENABLE_FALSE_START: on = ssl_defaults.enableFalseStart; break; case SSL_CBC_RANDOM_IV: on = ssl_defaults.cbcRandomIV; break; case SSL_ENABLE_OCSP_STAPLING: on = ssl_defaults.enableOCSPStapling; break; case SSL_ENABLE_NPN: on = ssl_defaults.enableNPN; break; case SSL_ENABLE_ALPN: on = ssl_defaults.enableALPN; break; case SSL_REUSE_SERVER_ECDHE_KEY: on = ssl_defaults.reuseServerECDHEKey; break; case SSL_ENABLE_FALLBACK_SCSV: on = ssl_defaults.enableFallbackSCSV; break; case SSL_ENABLE_SERVER_DHE: on = ssl_defaults.enableServerDhe; break; case SSL_ENABLE_EXTENDED_MASTER_SECRET: on = ssl_defaults.enableExtendedMS; break; default: PORT_SetError(SEC_ERROR_INVALID_ARGS); rv = SECFailure; } *pOn = on; return rv; } /* XXX Use Global Lock to protect this stuff. */ SECStatus SSL_EnableDefault(int which, PRBool on) { return SSL_OptionSetDefault(which, on); } SECStatus SSL_OptionSetDefault(PRInt32 which, PRBool on) { SECStatus status = ssl_Init(); if (status != SECSuccess) { return status; } ssl_SetDefaultsFromEnvironment(); switch (which) { case SSL_SOCKS: ssl_defaults.useSocks = PR_FALSE; if (on) { PORT_SetError(SEC_ERROR_INVALID_ARGS); return SECFailure; } break; case SSL_SECURITY: ssl_defaults.useSecurity = on; break; case SSL_REQUEST_CERTIFICATE: ssl_defaults.requestCertificate = on; break; case SSL_REQUIRE_CERTIFICATE: ssl_defaults.requireCertificate = on; break; case SSL_HANDSHAKE_AS_CLIENT: if ( ssl_defaults.handshakeAsServer && on ) { PORT_SetError(SEC_ERROR_INVALID_ARGS); return SECFailure; } ssl_defaults.handshakeAsClient = on; break; case SSL_HANDSHAKE_AS_SERVER: if ( ssl_defaults.handshakeAsClient && on ) { PORT_SetError(SEC_ERROR_INVALID_ARGS); return SECFailure; } ssl_defaults.handshakeAsServer = on; break; case SSL_ENABLE_TLS: ssl_EnableTLS(&versions_defaults_stream, on); break; case SSL_ENABLE_SSL3: ssl_EnableSSL3(&versions_defaults_stream, on); break; case SSL_ENABLE_SSL2: ssl_defaults.enableSSL2 = on; if (on) { ssl_defaults.v2CompatibleHello = on; } break; case SSL_NO_CACHE: ssl_defaults.noCache = on; break; case SSL_ENABLE_FDX: if (on && ssl_defaults.noLocks) { PORT_SetError(SEC_ERROR_INVALID_ARGS); return SECFailure; } ssl_defaults.fdx = on; break; case SSL_V2_COMPATIBLE_HELLO: ssl_defaults.v2CompatibleHello = on; if (!on) { ssl_defaults.enableSSL2 = on; } break; case SSL_ROLLBACK_DETECTION: ssl_defaults.detectRollBack = on; break; case SSL_NO_STEP_DOWN: ssl_defaults.noStepDown = on; if (on) SSL_DisableDefaultExportCipherSuites(); break; case SSL_BYPASS_PKCS11: if (PR_FALSE != on) { if (PR_SUCCESS == SSL_BypassSetup()) { #ifdef NO_PKCS11_BYPASS ssl_defaults.bypassPKCS11 = PR_FALSE; #else ssl_defaults.bypassPKCS11 = on; #endif } else { return SECFailure; } } else { ssl_defaults.bypassPKCS11 = PR_FALSE; } break; case SSL_NO_LOCKS: if (on && ssl_defaults.fdx) { PORT_SetError(SEC_ERROR_INVALID_ARGS); return SECFailure; } if (on && ssl_force_locks) on = PR_FALSE; /* silent override */ ssl_defaults.noLocks = on; if (on) { locksEverDisabled = PR_TRUE; strcpy(lockStatus + LOCKSTATUS_OFFSET, "DISABLED."); } break; case SSL_ENABLE_SESSION_TICKETS: ssl_defaults.enableSessionTickets = on; break; case SSL_ENABLE_DEFLATE: ssl_defaults.enableDeflate = on; break; case SSL_ENABLE_RENEGOTIATION: ssl_defaults.enableRenegotiation = on; break; case SSL_REQUIRE_SAFE_NEGOTIATION: ssl_defaults.requireSafeNegotiation = on; break; case SSL_ENABLE_FALSE_START: ssl_defaults.enableFalseStart = on; break; case SSL_CBC_RANDOM_IV: ssl_defaults.cbcRandomIV = on; break; case SSL_ENABLE_OCSP_STAPLING: ssl_defaults.enableOCSPStapling = on; break; case SSL_ENABLE_NPN: ssl_defaults.enableNPN = on; break; case SSL_ENABLE_ALPN: ssl_defaults.enableALPN = on; break; case SSL_REUSE_SERVER_ECDHE_KEY: ssl_defaults.reuseServerECDHEKey = on; break; case SSL_ENABLE_FALLBACK_SCSV: ssl_defaults.enableFallbackSCSV = on; break; case SSL_ENABLE_SERVER_DHE: ssl_defaults.enableServerDhe = on; break; case SSL_ENABLE_EXTENDED_MASTER_SECRET: ssl_defaults.enableExtendedMS = on; break; default: PORT_SetError(SEC_ERROR_INVALID_ARGS); return SECFailure; } return SECSuccess; } /* function tells us if the cipher suite is one that we no longer support. */ static PRBool ssl_IsRemovedCipherSuite(PRInt32 suite) { switch (suite) { case SSL_FORTEZZA_DMS_WITH_NULL_SHA: case SSL_FORTEZZA_DMS_WITH_FORTEZZA_CBC_SHA: case SSL_FORTEZZA_DMS_WITH_RC4_128_SHA: return PR_TRUE; default: return PR_FALSE; } } /* Part of the public NSS API. * Since this is a global (not per-socket) setting, we cannot use the * HandshakeLock to protect this. Probably want a global lock. */ SECStatus SSL_SetPolicy(long which, int policy) { if ((which & 0xfffe) == SSL_RSA_OLDFIPS_WITH_3DES_EDE_CBC_SHA) { /* one of the two old FIPS ciphers */ if (which == SSL_RSA_OLDFIPS_WITH_3DES_EDE_CBC_SHA) which = SSL_RSA_FIPS_WITH_3DES_EDE_CBC_SHA; else if (which == SSL_RSA_OLDFIPS_WITH_DES_CBC_SHA) which = SSL_RSA_FIPS_WITH_DES_CBC_SHA; } if (ssl_IsRemovedCipherSuite(which)) return SECSuccess; return SSL_CipherPolicySet(which, policy); } SECStatus SSL_CipherPolicySet(PRInt32 which, PRInt32 policy) { SECStatus rv = ssl_Init(); if (rv != SECSuccess) { return rv; } if (ssl_IsRemovedCipherSuite(which)) { rv = SECSuccess; } else if (SSL_IS_SSL2_CIPHER(which)) { rv = ssl2_SetPolicy(which, policy); } else { rv = ssl3_SetPolicy((ssl3CipherSuite)which, policy); } return rv; } SECStatus SSL_CipherPolicyGet(PRInt32 which, PRInt32 *oPolicy) { SECStatus rv; if (!oPolicy) { PORT_SetError(SEC_ERROR_INVALID_ARGS); return SECFailure; } if (ssl_IsRemovedCipherSuite(which)) { *oPolicy = SSL_NOT_ALLOWED; rv = SECSuccess; } else if (SSL_IS_SSL2_CIPHER(which)) { rv = ssl2_GetPolicy(which, oPolicy); } else { rv = ssl3_GetPolicy((ssl3CipherSuite)which, oPolicy); } return rv; } /* Part of the public NSS API. * Since this is a global (not per-socket) setting, we cannot use the * HandshakeLock to protect this. Probably want a global lock. * These changes have no effect on any sslSockets already created. */ SECStatus SSL_EnableCipher(long which, PRBool enabled) { if ((which & 0xfffe) == SSL_RSA_OLDFIPS_WITH_3DES_EDE_CBC_SHA) { /* one of the two old FIPS ciphers */ if (which == SSL_RSA_OLDFIPS_WITH_3DES_EDE_CBC_SHA) which = SSL_RSA_FIPS_WITH_3DES_EDE_CBC_SHA; else if (which == SSL_RSA_OLDFIPS_WITH_DES_CBC_SHA) which = SSL_RSA_FIPS_WITH_DES_CBC_SHA; } if (ssl_IsRemovedCipherSuite(which)) return SECSuccess; return SSL_CipherPrefSetDefault(which, enabled); } SECStatus SSL_CipherPrefSetDefault(PRInt32 which, PRBool enabled) { SECStatus rv = ssl_Init(); if (rv != SECSuccess) { return rv; } if (ssl_IsRemovedCipherSuite(which)) return SECSuccess; if (enabled && ssl_defaults.noStepDown && SSL_IsExportCipherSuite(which)) { PORT_SetError(SEC_ERROR_INVALID_ALGORITHM); return SECFailure; } if (SSL_IS_SSL2_CIPHER(which)) { rv = ssl2_CipherPrefSetDefault(which, enabled); } else { rv = ssl3_CipherPrefSetDefault((ssl3CipherSuite)which, enabled); } return rv; } SECStatus SSL_CipherPrefGetDefault(PRInt32 which, PRBool *enabled) { SECStatus rv; if (!enabled) { PORT_SetError(SEC_ERROR_INVALID_ARGS); return SECFailure; } if (ssl_IsRemovedCipherSuite(which)) { *enabled = PR_FALSE; rv = SECSuccess; } else if (SSL_IS_SSL2_CIPHER(which)) { rv = ssl2_CipherPrefGetDefault(which, enabled); } else { rv = ssl3_CipherPrefGetDefault((ssl3CipherSuite)which, enabled); } return rv; } SECStatus SSL_CipherPrefSet(PRFileDesc *fd, PRInt32 which, PRBool enabled) { SECStatus rv; sslSocket *ss = ssl_FindSocket(fd); if (!ss) { SSL_DBG(("%d: SSL[%d]: bad socket in CipherPrefSet", SSL_GETPID(), fd)); return SECFailure; } if (ssl_IsRemovedCipherSuite(which)) return SECSuccess; if (enabled && ss->opt.noStepDown && SSL_IsExportCipherSuite(which)) { PORT_SetError(SEC_ERROR_INVALID_ALGORITHM); return SECFailure; } if (SSL_IS_SSL2_CIPHER(which)) { rv = ssl2_CipherPrefSet(ss, which, enabled); } else { rv = ssl3_CipherPrefSet(ss, (ssl3CipherSuite)which, enabled); } return rv; } SECStatus SSL_CipherPrefGet(PRFileDesc *fd, PRInt32 which, PRBool *enabled) { SECStatus rv; sslSocket *ss = ssl_FindSocket(fd); if (!enabled) { PORT_SetError(SEC_ERROR_INVALID_ARGS); return SECFailure; } if (!ss) { SSL_DBG(("%d: SSL[%d]: bad socket in CipherPrefGet", SSL_GETPID(), fd)); *enabled = PR_FALSE; return SECFailure; } if (ssl_IsRemovedCipherSuite(which)) { *enabled = PR_FALSE; rv = SECSuccess; } else if (SSL_IS_SSL2_CIPHER(which)) { rv = ssl2_CipherPrefGet(ss, which, enabled); } else { rv = ssl3_CipherPrefGet(ss, (ssl3CipherSuite)which, enabled); } return rv; } SECStatus NSS_SetDomesticPolicy(void) { SECStatus status = SECSuccess; const PRUint16 *cipher; for (cipher = SSL_ImplementedCiphers; *cipher != 0; ++cipher) { status = SSL_SetPolicy(*cipher, SSL_ALLOWED); if (status != SECSuccess) break; } return status; } SECStatus NSS_SetExportPolicy(void) { return NSS_SetDomesticPolicy(); } SECStatus NSS_SetFrancePolicy(void) { return NSS_SetDomesticPolicy(); } SECStatus SSL_DHEGroupPrefSet(PRFileDesc *fd, SSLDHEGroupType *groups, PRUint16 num_groups) { sslSocket *ss; if ((num_groups && !groups) || (!num_groups && groups)) { PORT_SetError(SEC_ERROR_INVALID_ARGS); return SECFailure; } ss = ssl_FindSocket(fd); if (!ss) { SSL_DBG(("%d: SSL[%d]: bad socket in SSL_DHEGroupPrefSet", SSL_GETPID(), fd)); return SECFailure; } if (ss->ssl3.dheGroups) { PORT_Free(ss->ssl3.dheGroups); ss->ssl3.dheGroups = NULL; ss->ssl3.numDHEGroups = 0; } if (groups) { ss->ssl3.dheGroups = PORT_NewArray(SSLDHEGroupType, num_groups); if (!ss->ssl3.dheGroups) { PORT_SetError(SEC_ERROR_NO_MEMORY); return SECFailure; } PORT_Memcpy(ss->ssl3.dheGroups, groups, sizeof(SSLDHEGroupType) * num_groups); } return SECSuccess; } PRCallOnceType gWeakDHParamsRegisterOnce; int gWeakDHParamsRegisterError; PRCallOnceType gWeakDHParamsOnce; int gWeakDHParamsError; /* As our code allocates type PQGParams, we'll keep it around, * even though we only make use of it's parameters through gWeakDHParam. */ static PQGParams *gWeakParamsPQG; static ssl3DHParams *gWeakDHParams; static PRStatus ssl3_CreateWeakDHParams(void) { PQGVerify *vfy; SECStatus rv, passed; PORT_Assert(!gWeakDHParams && !gWeakParamsPQG); rv = PK11_PQG_ParamGenV2(1024, 160, 64 /*maximum seed that will work*/, &gWeakParamsPQG, &vfy); if (rv != SECSuccess) { gWeakDHParamsError = PORT_GetError(); return PR_FAILURE; } rv = PK11_PQG_VerifyParams(gWeakParamsPQG, vfy, &passed); if (rv != SECSuccess || passed != SECSuccess) { SSL_DBG(("%d: PK11_PQG_VerifyParams failed in ssl3_CreateWeakDHParams", SSL_GETPID())); gWeakDHParamsError = PORT_GetError(); return PR_FAILURE; } gWeakDHParams = PORT_ArenaNew(gWeakParamsPQG->arena, ssl3DHParams); if (!gWeakDHParams) { gWeakDHParamsError = PORT_GetError(); return PR_FAILURE; } gWeakDHParams->prime.data = gWeakParamsPQG->prime.data; gWeakDHParams->prime.len = gWeakParamsPQG->prime.len; gWeakDHParams->base.data = gWeakParamsPQG->base.data; gWeakDHParams->base.len = gWeakParamsPQG->base.len; PK11_PQG_DestroyVerify(vfy); return PR_SUCCESS; } static SECStatus ssl3_WeakDHParamsShutdown(void *appData, void *nssData) { if (gWeakParamsPQG) { PK11_PQG_DestroyParams(gWeakParamsPQG); gWeakParamsPQG = NULL; gWeakDHParams = NULL; } return SECSuccess; } static PRStatus ssl3_WeakDHParamsRegisterShutdown(void) { SECStatus rv; rv = NSS_RegisterShutdown(ssl3_WeakDHParamsShutdown, NULL); if (rv != SECSuccess) { gWeakDHParamsRegisterError = PORT_GetError(); } return (PRStatus)rv; } /* global init strategy inspired by ssl3_CreateECDHEphemeralKeys */ SECStatus SSL_EnableWeakDHEPrimeGroup(PRFileDesc *fd, PRBool enabled) { sslSocket *ss; PRStatus status; if (enabled) { status = PR_CallOnce(&gWeakDHParamsRegisterOnce, ssl3_WeakDHParamsRegisterShutdown); if (status != PR_SUCCESS) { PORT_SetError(gWeakDHParamsRegisterError); return SECFailure; } status = PR_CallOnce(&gWeakDHParamsOnce, ssl3_CreateWeakDHParams); if (status != PR_SUCCESS) { PORT_SetError(gWeakDHParamsError); return SECFailure; } } if (!fd) return SECSuccess; ss = ssl_FindSocket(fd); if (!ss) { SSL_DBG(("%d: SSL[%d]: bad socket in SSL_DHEGroupPrefSet", SSL_GETPID(), fd)); return SECFailure; } ss->ssl3.dheWeakGroupEnabled = enabled; return SECSuccess; } #include "dhe-param.c" static const SSLDHEGroupType ssl_default_dhe_groups[] = { ssl_ff_dhe_2048_group }; /* Keep this array synchronized with the index definitions in SSLDHEGroupType */ static const ssl3DHParams *all_ssl3DHParams[] = { NULL, /* ssl_dhe_group_none */ &ff_dhe_2048, &ff_dhe_3072, &ff_dhe_4096, &ff_dhe_6144, &ff_dhe_8192, }; static SSLDHEGroupType selectDHEGroup(sslSocket *ss, const SSLDHEGroupType *groups, PRUint16 num_groups) { if (!groups || !num_groups) return ssl_dhe_group_none; /* We don't have automatic group parameter selection yet * (potentially) based on socket parameters, e.g. key sizes. * For now, we return the first available group from the allowed list. */ return groups[0]; } /* Ensure DH parameters have been selected */ SECStatus ssl3_SelectDHParams(sslSocket *ss) { SSLDHEGroupType selectedGroup = ssl_dhe_group_none; if (ss->ssl3.dheWeakGroupEnabled) { ss->dheParams = gWeakDHParams; } else { if (ss->ssl3.dheGroups) { selectedGroup = selectDHEGroup(ss, ss->ssl3.dheGroups, ss->ssl3.numDHEGroups); } else { size_t number_of_default_groups = PR_ARRAY_SIZE(ssl_default_dhe_groups); selectedGroup = selectDHEGroup(ss, ssl_default_dhe_groups, number_of_default_groups); } if (selectedGroup == ssl_dhe_group_none || selectedGroup >= ssl_dhe_group_max) { return SECFailure; } ss->dheParams = all_ssl3DHParams[selectedGroup]; } return SECSuccess; } /* LOCKS ??? XXX */ static PRFileDesc * ssl_ImportFD(PRFileDesc *model, PRFileDesc *fd, SSLProtocolVariant variant) { sslSocket * ns = NULL; PRStatus rv; PRNetAddr addr; SECStatus status = ssl_Init(); if (status != SECSuccess) { return NULL; } if (model == NULL) { /* Just create a default socket if we're given NULL for the model */ ns = ssl_NewSocket((PRBool)(!ssl_defaults.noLocks), variant); } else { sslSocket * ss = ssl_FindSocket(model); if (ss == NULL || ss->protocolVariant != variant) { SSL_DBG(("%d: SSL[%d]: bad model socket in ssl_ImportFD", SSL_GETPID(), model)); return NULL; } ns = ssl_DupSocket(ss); } if (ns == NULL) return NULL; rv = ssl_PushIOLayer(ns, fd, PR_TOP_IO_LAYER); if (rv != PR_SUCCESS) { ssl_FreeSocket(ns); SET_ERROR_CODE return NULL; } #if defined(DEBUG) || defined(FORCE_PR_ASSERT) { sslSocket * ss = ssl_FindSocket(fd); PORT_Assert(ss == ns); } #endif ns->TCPconnected = (PR_SUCCESS == ssl_DefGetpeername(ns, &addr)); return fd; } PRFileDesc * SSL_ImportFD(PRFileDesc *model, PRFileDesc *fd) { return ssl_ImportFD(model, fd, ssl_variant_stream); } PRFileDesc * DTLS_ImportFD(PRFileDesc *model, PRFileDesc *fd) { return ssl_ImportFD(model, fd, ssl_variant_datagram); } /* SSL_SetNextProtoCallback is used to select an application protocol * for ALPN and NPN. For ALPN, this runs on the server; for NPN it * runs on the client. */ /* Note: The ALPN version doesn't allow for the use of a default, setting a * status of SSL_NEXT_PROTO_NO_OVERLAP is treated as a failure. */ SECStatus SSL_SetNextProtoCallback(PRFileDesc *fd, SSLNextProtoCallback callback, void *arg) { sslSocket *ss = ssl_FindSocket(fd); if (!ss) { SSL_DBG(("%d: SSL[%d]: bad socket in SSL_SetNextProtoCallback", SSL_GETPID(), fd)); return SECFailure; } ssl_GetSSL3HandshakeLock(ss); ss->nextProtoCallback = callback; ss->nextProtoArg = arg; ssl_ReleaseSSL3HandshakeLock(ss); return SECSuccess; } /* ssl_NextProtoNegoCallback is set as an ALPN/NPN callback when * SSL_SetNextProtoNego is used. */ static SECStatus ssl_NextProtoNegoCallback(void *arg, PRFileDesc *fd, const unsigned char *protos, unsigned int protos_len, unsigned char *protoOut, unsigned int *protoOutLen, unsigned int protoMaxLen) { unsigned int i, j; const unsigned char *result; sslSocket *ss = ssl_FindSocket(fd); if (!ss) { SSL_DBG(("%d: SSL[%d]: bad socket in ssl_NextProtoNegoCallback", SSL_GETPID(), fd)); return SECFailure; } /* For each protocol in server preference, see if we support it. */ for (i = 0; i < protos_len; ) { for (j = 0; j < ss->opt.nextProtoNego.len; ) { if (protos[i] == ss->opt.nextProtoNego.data[j] && PORT_Memcmp(&protos[i+1], &ss->opt.nextProtoNego.data[j+1], protos[i]) == 0) { /* We found a match. */ ss->ssl3.nextProtoState = SSL_NEXT_PROTO_NEGOTIATED; result = &protos[i]; goto found; } j += 1 + (unsigned int)ss->opt.nextProtoNego.data[j]; } i += 1 + (unsigned int)protos[i]; } /* The other side supports the extension, and either doesn't have any * protocols configured, or none of its options match ours. In this case we * request our favoured protocol. */ /* This will be treated as a failure for ALPN. */ ss->ssl3.nextProtoState = SSL_NEXT_PROTO_NO_OVERLAP; result = ss->opt.nextProtoNego.data; found: if (protoMaxLen < result[0]) { PORT_SetError(SEC_ERROR_OUTPUT_LEN); return SECFailure; } memcpy(protoOut, result + 1, result[0]); *protoOutLen = result[0]; return SECSuccess; } SECStatus SSL_SetNextProtoNego(PRFileDesc *fd, const unsigned char *data, unsigned int length) { sslSocket *ss; SECStatus rv; SECItem dataItem = { siBuffer, (unsigned char *) data, length }; ss = ssl_FindSocket(fd); if (!ss) { SSL_DBG(("%d: SSL[%d]: bad socket in SSL_SetNextProtoNego", SSL_GETPID(), fd)); return SECFailure; } if (ssl3_ValidateNextProtoNego(data, length) != SECSuccess) return SECFailure; ssl_GetSSL3HandshakeLock(ss); SECITEM_FreeItem(&ss->opt.nextProtoNego, PR_FALSE); rv = SECITEM_CopyItem(NULL, &ss->opt.nextProtoNego, &dataItem); ssl_ReleaseSSL3HandshakeLock(ss); if (rv != SECSuccess) return rv; return SSL_SetNextProtoCallback(fd, ssl_NextProtoNegoCallback, NULL); } SECStatus SSL_GetNextProto(PRFileDesc *fd, SSLNextProtoState *state, unsigned char *buf, unsigned int *bufLen, unsigned int bufLenMax) { sslSocket *ss = ssl_FindSocket(fd); if (!ss) { SSL_DBG(("%d: SSL[%d]: bad socket in SSL_GetNextProto", SSL_GETPID(), fd)); return SECFailure; } if (!state || !buf || !bufLen) { PORT_SetError(SEC_ERROR_INVALID_ARGS); return SECFailure; } *state = ss->ssl3.nextProtoState; if (ss->ssl3.nextProtoState != SSL_NEXT_PROTO_NO_SUPPORT && ss->ssl3.nextProto.data) { if (ss->ssl3.nextProto.len > bufLenMax) { PORT_SetError(SEC_ERROR_OUTPUT_LEN); return SECFailure; } PORT_Memcpy(buf, ss->ssl3.nextProto.data, ss->ssl3.nextProto.len); *bufLen = ss->ssl3.nextProto.len; } else { *bufLen = 0; } return SECSuccess; } SECStatus SSL_SetSRTPCiphers(PRFileDesc *fd, const PRUint16 *ciphers, unsigned int numCiphers) { sslSocket *ss; unsigned int i; ss = ssl_FindSocket(fd); if (!ss || !IS_DTLS(ss)) { SSL_DBG(("%d: SSL[%d]: bad socket in SSL_SetSRTPCiphers", SSL_GETPID(), fd)); PORT_SetError(SEC_ERROR_INVALID_ARGS); return SECFailure; } if (numCiphers > MAX_DTLS_SRTP_CIPHER_SUITES) { PORT_SetError(SEC_ERROR_INVALID_ARGS); return SECFailure; } ss->ssl3.dtlsSRTPCipherCount = 0; for (i = 0; i < numCiphers; i++) { const PRUint16 *srtpCipher = srtpCiphers; while (*srtpCipher) { if (ciphers[i] == *srtpCipher) break; srtpCipher++; } if (*srtpCipher) { ss->ssl3.dtlsSRTPCiphers[ss->ssl3.dtlsSRTPCipherCount++] = ciphers[i]; } else { SSL_DBG(("%d: SSL[%d]: invalid or unimplemented SRTP cipher " "suite specified: 0x%04hx", SSL_GETPID(), fd, ciphers[i])); } } if (ss->ssl3.dtlsSRTPCipherCount == 0) { PORT_SetError(SEC_ERROR_INVALID_ARGS); return SECFailure; } return SECSuccess; } SECStatus SSL_GetSRTPCipher(PRFileDesc *fd, PRUint16 *cipher) { sslSocket * ss; ss = ssl_FindSocket(fd); if (!ss) { SSL_DBG(("%d: SSL[%d]: bad socket in SSL_GetSRTPCipher", SSL_GETPID(), fd)); PORT_SetError(SEC_ERROR_INVALID_ARGS); return SECFailure; } if (!ss->ssl3.dtlsSRTPCipherSuite) { PORT_SetError(SEC_ERROR_INVALID_ARGS); return SECFailure; } *cipher = ss->ssl3.dtlsSRTPCipherSuite; return SECSuccess; } PRFileDesc * SSL_ReconfigFD(PRFileDesc *model, PRFileDesc *fd) { sslSocket * sm = NULL, *ss = NULL; int i; sslServerCerts * mc = NULL; sslServerCerts * sc = NULL; if (model == NULL) { PR_SetError(SEC_ERROR_INVALID_ARGS, 0); return NULL; } sm = ssl_FindSocket(model); if (sm == NULL) { SSL_DBG(("%d: SSL[%d]: bad model socket in ssl_ReconfigFD", SSL_GETPID(), model)); return NULL; } ss = ssl_FindSocket(fd); PORT_Assert(ss); if (ss == NULL) { PORT_SetError(SEC_ERROR_INVALID_ARGS); return NULL; } ss->opt = sm->opt; ss->vrange = sm->vrange; PORT_Memcpy(ss->cipherSuites, sm->cipherSuites, sizeof sm->cipherSuites); PORT_Memcpy(ss->ssl3.dtlsSRTPCiphers, sm->ssl3.dtlsSRTPCiphers, sizeof(PRUint16) * sm->ssl3.dtlsSRTPCipherCount); ss->ssl3.dtlsSRTPCipherCount = sm->ssl3.dtlsSRTPCipherCount; PORT_Memcpy(ss->ssl3.signatureAlgorithms, sm->ssl3.signatureAlgorithms, sizeof(ss->ssl3.signatureAlgorithms[0]) * sm->ssl3.signatureAlgorithmCount); ss->ssl3.signatureAlgorithmCount = sm->ssl3.signatureAlgorithmCount; if (!ss->opt.useSecurity) { PORT_SetError(SEC_ERROR_INVALID_ARGS); return NULL; } /* This int should be SSLKEAType, but CC on Irix complains, * during the for loop. */ for (i=kt_null; i < kt_kea_size; i++) { mc = &(sm->serverCerts[i]); sc = &(ss->serverCerts[i]); if (mc->serverCert && mc->serverCertChain) { if (sc->serverCert) { CERT_DestroyCertificate(sc->serverCert); } sc->serverCert = CERT_DupCertificate(mc->serverCert); if (sc->serverCertChain) { CERT_DestroyCertificateList(sc->serverCertChain); } sc->serverCertChain = CERT_DupCertList(mc->serverCertChain); if (!sc->serverCertChain) goto loser; if (sm->certStatusArray[i]) { if (ss->certStatusArray[i]) { SECITEM_FreeArray(ss->certStatusArray[i], PR_TRUE); ss->certStatusArray[i] = NULL; } ss->certStatusArray[i] = SECITEM_DupArray(NULL, sm->certStatusArray[i]); if (!ss->certStatusArray[i]) goto loser; } } if (mc->serverKeyPair) { if (sc->serverKeyPair) { ssl3_FreeKeyPair(sc->serverKeyPair); } sc->serverKeyPair = ssl3_GetKeyPairRef(mc->serverKeyPair); sc->serverKeyBits = mc->serverKeyBits; } } if (sm->stepDownKeyPair) { if (ss->stepDownKeyPair) { ssl3_FreeKeyPair(ss->stepDownKeyPair); } ss->stepDownKeyPair = ssl3_GetKeyPairRef(sm->stepDownKeyPair); } if (sm->ephemeralECDHKeyPair) { if (ss->ephemeralECDHKeyPair) { ssl3_FreeKeyPair(ss->ephemeralECDHKeyPair); } ss->ephemeralECDHKeyPair = ssl3_GetKeyPairRef(sm->ephemeralECDHKeyPair); } /* copy trust anchor names */ if (sm->ssl3.ca_list) { if (ss->ssl3.ca_list) { CERT_FreeDistNames(ss->ssl3.ca_list); } ss->ssl3.ca_list = CERT_DupDistNames(sm->ssl3.ca_list); if (!ss->ssl3.ca_list) { goto loser; } } if (sm->authCertificate) ss->authCertificate = sm->authCertificate; if (sm->authCertificateArg) ss->authCertificateArg = sm->authCertificateArg; if (sm->getClientAuthData) ss->getClientAuthData = sm->getClientAuthData; if (sm->getClientAuthDataArg) ss->getClientAuthDataArg = sm->getClientAuthDataArg; if (sm->sniSocketConfig) ss->sniSocketConfig = sm->sniSocketConfig; if (sm->sniSocketConfigArg) ss->sniSocketConfigArg = sm->sniSocketConfigArg; if (sm->handleBadCert) ss->handleBadCert = sm->handleBadCert; if (sm->badCertArg) ss->badCertArg = sm->badCertArg; if (sm->handshakeCallback) ss->handshakeCallback = sm->handshakeCallback; if (sm->handshakeCallbackData) ss->handshakeCallbackData = sm->handshakeCallbackData; if (sm->pkcs11PinArg) ss->pkcs11PinArg = sm->pkcs11PinArg; return fd; loser: return NULL; } PRBool ssl3_VersionIsSupported(SSLProtocolVariant protocolVariant, SSL3ProtocolVersion version) { switch (protocolVariant) { case ssl_variant_stream: return (version >= SSL_LIBRARY_VERSION_3_0 && version <= SSL_LIBRARY_VERSION_MAX_SUPPORTED); case ssl_variant_datagram: return (version >= SSL_LIBRARY_VERSION_TLS_1_1 && version <= SSL_LIBRARY_VERSION_MAX_SUPPORTED); default: /* Can't get here */ PORT_Assert(PR_FALSE); return PR_FALSE; } } /* Returns PR_TRUE if the given version range is valid and ** fully supported; otherwise, returns PR_FALSE. */ static PRBool ssl3_VersionRangeIsValid(SSLProtocolVariant protocolVariant, const SSLVersionRange *vrange) { return vrange && vrange->min <= vrange->max && ssl3_VersionIsSupported(protocolVariant, vrange->min) && ssl3_VersionIsSupported(protocolVariant, vrange->max); } SECStatus SSL_VersionRangeGetSupported(SSLProtocolVariant protocolVariant, SSLVersionRange *vrange) { if (!vrange) { PORT_SetError(SEC_ERROR_INVALID_ARGS); return SECFailure; } switch (protocolVariant) { case ssl_variant_stream: vrange->min = SSL_LIBRARY_VERSION_3_0; vrange->max = SSL_LIBRARY_VERSION_MAX_SUPPORTED; break; case ssl_variant_datagram: vrange->min = SSL_LIBRARY_VERSION_TLS_1_1; vrange->max = SSL_LIBRARY_VERSION_MAX_SUPPORTED; break; default: PORT_SetError(SEC_ERROR_INVALID_ARGS); return SECFailure; } return SECSuccess; } SECStatus SSL_VersionRangeGetDefault(SSLProtocolVariant protocolVariant, SSLVersionRange *vrange) { if ((protocolVariant != ssl_variant_stream && protocolVariant != ssl_variant_datagram) || !vrange) { PORT_SetError(SEC_ERROR_INVALID_ARGS); return SECFailure; } *vrange = *VERSIONS_DEFAULTS(protocolVariant); return SECSuccess; } SECStatus SSL_VersionRangeSetDefault(SSLProtocolVariant protocolVariant, const SSLVersionRange *vrange) { if (!ssl3_VersionRangeIsValid(protocolVariant, vrange)) { PORT_SetError(SSL_ERROR_INVALID_VERSION_RANGE); return SECFailure; } *VERSIONS_DEFAULTS(protocolVariant) = *vrange; return SECSuccess; } SECStatus SSL_VersionRangeGet(PRFileDesc *fd, SSLVersionRange *vrange) { sslSocket *ss = ssl_FindSocket(fd); if (!ss) { SSL_DBG(("%d: SSL[%d]: bad socket in SSL3_VersionRangeGet", SSL_GETPID(), fd)); return SECFailure; } if (!vrange) { PORT_SetError(SEC_ERROR_INVALID_ARGS); return SECFailure; } ssl_Get1stHandshakeLock(ss); ssl_GetSSL3HandshakeLock(ss); *vrange = ss->vrange; ssl_ReleaseSSL3HandshakeLock(ss); ssl_Release1stHandshakeLock(ss); return SECSuccess; } SECStatus SSL_VersionRangeSet(PRFileDesc *fd, const SSLVersionRange *vrange) { sslSocket *ss = ssl_FindSocket(fd); if (!ss) { SSL_DBG(("%d: SSL[%d]: bad socket in SSL3_VersionRangeSet", SSL_GETPID(), fd)); return SECFailure; } if (!ssl3_VersionRangeIsValid(ss->protocolVariant, vrange)) { PORT_SetError(SSL_ERROR_INVALID_VERSION_RANGE); return SECFailure; } ssl_Get1stHandshakeLock(ss); ssl_GetSSL3HandshakeLock(ss); ss->vrange = *vrange; ssl_ReleaseSSL3HandshakeLock(ss); ssl_Release1stHandshakeLock(ss); return SECSuccess; } const SECItemArray * SSL_PeerStapledOCSPResponses(PRFileDesc *fd) { sslSocket *ss = ssl_FindSocket(fd); if (!ss) { SSL_DBG(("%d: SSL[%d]: bad socket in SSL_PeerStapledOCSPResponses", SSL_GETPID(), fd)); return NULL; } if (!ss->sec.ci.sid) { PORT_SetError(SEC_ERROR_NOT_INITIALIZED); return NULL; } return &ss->sec.ci.sid->peerCertStatus; } /************************************************************************/ /* The following functions are the TOP LEVEL SSL functions. ** They all get called through the NSPRIOMethods table below. */ static PRFileDesc * PR_CALLBACK ssl_Accept(PRFileDesc *fd, PRNetAddr *sockaddr, PRIntervalTime timeout) { sslSocket *ss; sslSocket *ns = NULL; PRFileDesc *newfd = NULL; PRFileDesc *osfd; PRStatus status; ss = ssl_GetPrivate(fd); if (!ss) { SSL_DBG(("%d: SSL[%d]: bad socket in accept", SSL_GETPID(), fd)); return NULL; } /* IF this is a listen socket, there shouldn't be any I/O going on */ SSL_LOCK_READER(ss); SSL_LOCK_WRITER(ss); ssl_Get1stHandshakeLock(ss); ssl_GetSSL3HandshakeLock(ss); ss->cTimeout = timeout; osfd = ss->fd->lower; /* First accept connection */ newfd = osfd->methods->accept(osfd, sockaddr, timeout); if (newfd == NULL) { SSL_DBG(("%d: SSL[%d]: accept failed, errno=%d", SSL_GETPID(), ss->fd, PORT_GetError())); } else { /* Create ssl module */ ns = ssl_DupSocket(ss); } ssl_ReleaseSSL3HandshakeLock(ss); ssl_Release1stHandshakeLock(ss); SSL_UNLOCK_WRITER(ss); SSL_UNLOCK_READER(ss); /* ss isn't used below here. */ if (ns == NULL) goto loser; /* push ssl module onto the new socket */ status = ssl_PushIOLayer(ns, newfd, PR_TOP_IO_LAYER); if (status != PR_SUCCESS) goto loser; /* Now start server connection handshake with client. ** Don't need locks here because nobody else has a reference to ns yet. */ if ( ns->opt.useSecurity ) { if ( ns->opt.handshakeAsClient ) { ns->handshake = ssl2_BeginClientHandshake; ss->handshaking = sslHandshakingAsClient; } else { ns->handshake = ssl2_BeginServerHandshake; ss->handshaking = sslHandshakingAsServer; } } ns->TCPconnected = 1; return newfd; loser: if (ns != NULL) ssl_FreeSocket(ns); if (newfd != NULL) PR_Close(newfd); return NULL; } static PRStatus PR_CALLBACK ssl_Connect(PRFileDesc *fd, const PRNetAddr *sockaddr, PRIntervalTime timeout) { sslSocket *ss; PRStatus rv; ss = ssl_GetPrivate(fd); if (!ss) { SSL_DBG(("%d: SSL[%d]: bad socket in connect", SSL_GETPID(), fd)); return PR_FAILURE; } /* IF this is a listen socket, there shouldn't be any I/O going on */ SSL_LOCK_READER(ss); SSL_LOCK_WRITER(ss); ss->cTimeout = timeout; rv = (PRStatus)(*ss->ops->connect)(ss, sockaddr); SSL_UNLOCK_WRITER(ss); SSL_UNLOCK_READER(ss); return rv; } static PRStatus PR_CALLBACK ssl_Bind(PRFileDesc *fd, const PRNetAddr *addr) { sslSocket * ss = ssl_GetPrivate(fd); PRStatus rv; if (!ss) { SSL_DBG(("%d: SSL[%d]: bad socket in bind", SSL_GETPID(), fd)); return PR_FAILURE; } SSL_LOCK_READER(ss); SSL_LOCK_WRITER(ss); rv = (PRStatus)(*ss->ops->bind)(ss, addr); SSL_UNLOCK_WRITER(ss); SSL_UNLOCK_READER(ss); return rv; } static PRStatus PR_CALLBACK ssl_Listen(PRFileDesc *fd, PRIntn backlog) { sslSocket * ss = ssl_GetPrivate(fd); PRStatus rv; if (!ss) { SSL_DBG(("%d: SSL[%d]: bad socket in listen", SSL_GETPID(), fd)); return PR_FAILURE; } SSL_LOCK_READER(ss); SSL_LOCK_WRITER(ss); rv = (PRStatus)(*ss->ops->listen)(ss, backlog); SSL_UNLOCK_WRITER(ss); SSL_UNLOCK_READER(ss); return rv; } static PRStatus PR_CALLBACK ssl_Shutdown(PRFileDesc *fd, PRIntn how) { sslSocket * ss = ssl_GetPrivate(fd); PRStatus rv; if (!ss) { SSL_DBG(("%d: SSL[%d]: bad socket in shutdown", SSL_GETPID(), fd)); return PR_FAILURE; } if (how == PR_SHUTDOWN_RCV || how == PR_SHUTDOWN_BOTH) { SSL_LOCK_READER(ss); } if (how == PR_SHUTDOWN_SEND || how == PR_SHUTDOWN_BOTH) { SSL_LOCK_WRITER(ss); } rv = (PRStatus)(*ss->ops->shutdown)(ss, how); if (how == PR_SHUTDOWN_SEND || how == PR_SHUTDOWN_BOTH) { SSL_UNLOCK_WRITER(ss); } if (how == PR_SHUTDOWN_RCV || how == PR_SHUTDOWN_BOTH) { SSL_UNLOCK_READER(ss); } return rv; } static PRStatus PR_CALLBACK ssl_Close(PRFileDesc *fd) { sslSocket *ss; PRStatus rv; ss = ssl_GetPrivate(fd); if (!ss) { SSL_DBG(("%d: SSL[%d]: bad socket in close", SSL_GETPID(), fd)); return PR_FAILURE; } /* There must not be any I/O going on */ SSL_LOCK_READER(ss); SSL_LOCK_WRITER(ss); /* By the time this function returns, ** ss is an invalid pointer, and the locks to which it points have ** been unlocked and freed. So, this is the ONE PLACE in all of SSL ** where the LOCK calls and the corresponding UNLOCK calls are not in ** the same function scope. The unlock calls are in ssl_FreeSocket(). */ rv = (PRStatus)(*ss->ops->close)(ss); return rv; } static int PR_CALLBACK ssl_Recv(PRFileDesc *fd, void *buf, PRInt32 len, PRIntn flags, PRIntervalTime timeout) { sslSocket *ss; int rv; ss = ssl_GetPrivate(fd); if (!ss) { SSL_DBG(("%d: SSL[%d]: bad socket in recv", SSL_GETPID(), fd)); return SECFailure; } SSL_LOCK_READER(ss); ss->rTimeout = timeout; if (!ss->opt.fdx) ss->wTimeout = timeout; rv = (*ss->ops->recv)(ss, (unsigned char*)buf, len, flags); SSL_UNLOCK_READER(ss); return rv; } static int PR_CALLBACK ssl_Send(PRFileDesc *fd, const void *buf, PRInt32 len, PRIntn flags, PRIntervalTime timeout) { sslSocket *ss; int rv; ss = ssl_GetPrivate(fd); if (!ss) { SSL_DBG(("%d: SSL[%d]: bad socket in send", SSL_GETPID(), fd)); return SECFailure; } SSL_LOCK_WRITER(ss); ss->wTimeout = timeout; if (!ss->opt.fdx) ss->rTimeout = timeout; rv = (*ss->ops->send)(ss, (const unsigned char*)buf, len, flags); SSL_UNLOCK_WRITER(ss); return rv; } static int PR_CALLBACK ssl_Read(PRFileDesc *fd, void *buf, PRInt32 len) { sslSocket *ss; int rv; ss = ssl_GetPrivate(fd); if (!ss) { SSL_DBG(("%d: SSL[%d]: bad socket in read", SSL_GETPID(), fd)); return SECFailure; } SSL_LOCK_READER(ss); ss->rTimeout = PR_INTERVAL_NO_TIMEOUT; if (!ss->opt.fdx) ss->wTimeout = PR_INTERVAL_NO_TIMEOUT; rv = (*ss->ops->read)(ss, (unsigned char*)buf, len); SSL_UNLOCK_READER(ss); return rv; } static int PR_CALLBACK ssl_Write(PRFileDesc *fd, const void *buf, PRInt32 len) { sslSocket *ss; int rv; ss = ssl_GetPrivate(fd); if (!ss) { SSL_DBG(("%d: SSL[%d]: bad socket in write", SSL_GETPID(), fd)); return SECFailure; } SSL_LOCK_WRITER(ss); ss->wTimeout = PR_INTERVAL_NO_TIMEOUT; if (!ss->opt.fdx) ss->rTimeout = PR_INTERVAL_NO_TIMEOUT; rv = (*ss->ops->write)(ss, (const unsigned char*)buf, len); SSL_UNLOCK_WRITER(ss); return rv; } static PRStatus PR_CALLBACK ssl_GetPeerName(PRFileDesc *fd, PRNetAddr *addr) { sslSocket *ss; ss = ssl_GetPrivate(fd); if (!ss) { SSL_DBG(("%d: SSL[%d]: bad socket in getpeername", SSL_GETPID(), fd)); return PR_FAILURE; } return (PRStatus)(*ss->ops->getpeername)(ss, addr); } /* */ SECStatus ssl_GetPeerInfo(sslSocket *ss) { PRFileDesc * osfd; int rv; PRNetAddr sin; osfd = ss->fd->lower; PORT_Memset(&sin, 0, sizeof(sin)); rv = osfd->methods->getpeername(osfd, &sin); if (rv < 0) { return SECFailure; } ss->TCPconnected = 1; if (sin.inet.family == PR_AF_INET) { PR_ConvertIPv4AddrToIPv6(sin.inet.ip, &ss->sec.ci.peer); ss->sec.ci.port = sin.inet.port; } else if (sin.ipv6.family == PR_AF_INET6) { ss->sec.ci.peer = sin.ipv6.ip; ss->sec.ci.port = sin.ipv6.port; } else { PORT_SetError(PR_ADDRESS_NOT_SUPPORTED_ERROR); return SECFailure; } return SECSuccess; } static PRStatus PR_CALLBACK ssl_GetSockName(PRFileDesc *fd, PRNetAddr *name) { sslSocket *ss; ss = ssl_GetPrivate(fd); if (!ss) { SSL_DBG(("%d: SSL[%d]: bad socket in getsockname", SSL_GETPID(), fd)); return PR_FAILURE; } return (PRStatus)(*ss->ops->getsockname)(ss, name); } SECStatus SSL_SetStapledOCSPResponses(PRFileDesc *fd, const SECItemArray *responses, SSLKEAType kea) { sslSocket *ss; ss = ssl_FindSocket(fd); if (!ss) { SSL_DBG(("%d: SSL[%d]: bad socket in SSL_SetStapledOCSPResponses", SSL_GETPID(), fd)); return SECFailure; } if ( kea <= 0 || kea >= kt_kea_size) { SSL_DBG(("%d: SSL[%d]: invalid key in SSL_SetStapledOCSPResponses", SSL_GETPID(), fd)); return SECFailure; } if (ss->certStatusArray[kea]) { SECITEM_FreeArray(ss->certStatusArray[kea], PR_TRUE); ss->certStatusArray[kea] = NULL; } if (responses) { ss->certStatusArray[kea] = SECITEM_DupArray(NULL, responses); } return (ss->certStatusArray[kea] || !responses) ? SECSuccess : SECFailure; } SECStatus SSL_SetSockPeerID(PRFileDesc *fd, const char *peerID) { sslSocket *ss; ss = ssl_FindSocket(fd); if (!ss) { SSL_DBG(("%d: SSL[%d]: bad socket in SSL_SetSockPeerID", SSL_GETPID(), fd)); return SECFailure; } if (ss->peerID) { PORT_Free(ss->peerID); ss->peerID = NULL; } if (peerID) ss->peerID = PORT_Strdup(peerID); return (ss->peerID || !peerID) ? SECSuccess : SECFailure; } #define PR_POLL_RW (PR_POLL_WRITE | PR_POLL_READ) static PRInt16 PR_CALLBACK ssl_Poll(PRFileDesc *fd, PRInt16 how_flags, PRInt16 *p_out_flags) { sslSocket *ss; PRInt16 new_flags = how_flags; /* should select on these flags. */ PRNetAddr addr; *p_out_flags = 0; ss = ssl_GetPrivate(fd); if (!ss) { SSL_DBG(("%d: SSL[%d]: bad socket in SSL_Poll", SSL_GETPID(), fd)); return 0; /* don't poll on this socket */ } if (ss->opt.useSecurity && ss->handshaking != sslHandshakingUndetermined && !ss->firstHsDone && (how_flags & PR_POLL_RW)) { if (!ss->TCPconnected) { ss->TCPconnected = (PR_SUCCESS == ssl_DefGetpeername(ss, &addr)); } /* If it's not connected, then presumably the application is polling ** on read or write appropriately, so don't change it. */ if (ss->TCPconnected) { if (!ss->handshakeBegun) { /* If the handshake has not begun, poll on read or write ** based on the local application's role in the handshake, ** not based on what the application requested. */ new_flags &= ~PR_POLL_RW; if (ss->handshaking == sslHandshakingAsClient) { new_flags |= PR_POLL_WRITE; } else { /* handshaking as server */ new_flags |= PR_POLL_READ; } } else /* First handshake is in progress */ if (ss->lastWriteBlocked) { if (new_flags & PR_POLL_READ) { /* The caller is waiting for data to be received, ** but the initial handshake is blocked on write, or the ** client's first handshake record has not been written. ** The code should select on write, not read. */ new_flags ^= PR_POLL_READ; /* don't select on read. */ new_flags |= PR_POLL_WRITE; /* do select on write. */ } } else if (new_flags & PR_POLL_WRITE) { /* The caller is trying to write, but the handshake is ** blocked waiting for data to read, and the first ** handshake has been sent. So do NOT to poll on write ** unless we did false start. */ if (!(ss->version >= SSL_LIBRARY_VERSION_3_0 && ss->ssl3.hs.canFalseStart)) { new_flags ^= PR_POLL_WRITE; /* don't select on write. */ } new_flags |= PR_POLL_READ; /* do select on read. */ } } } else if ((new_flags & PR_POLL_READ) && (SSL_DataPending(fd) > 0)) { *p_out_flags = PR_POLL_READ; /* it's ready already. */ return new_flags; } else if ((ss->lastWriteBlocked) && (how_flags & PR_POLL_READ) && (ss->pendingBuf.len != 0)) { /* write data waiting to be sent */ new_flags |= PR_POLL_WRITE; /* also select on write. */ } if (ss->version >= SSL_LIBRARY_VERSION_3_0 && ss->ssl3.hs.restartTarget != NULL) { /* Read and write will block until the asynchronous callback completes * (e.g. until SSL_AuthCertificateComplete is called), so don't tell * the caller to poll the socket unless there is pending write data. */ if (ss->lastWriteBlocked && ss->pendingBuf.len != 0) { /* Ignore any newly-received data on the socket, but do wait for * the socket to become writable again. Here, it is OK for an error * to be detected, because our logic for sending pending write data * will allow us to report the error to the caller without the risk * of the application spinning. */ new_flags &= (PR_POLL_WRITE | PR_POLL_EXCEPT); } else { /* Unfortunately, clearing new_flags will make it impossible for * the application to detect errors that it would otherwise be * able to detect with PR_POLL_EXCEPT, until the asynchronous * callback completes. However, we must clear all the flags to * prevent the application from spinning (alternating between * calling PR_Poll that would return PR_POLL_EXCEPT, and send/recv * which won't actually report the I/O error while we are waiting * for the asynchronous callback to complete). */ new_flags = 0; } } if (new_flags && (fd->lower->methods->poll != NULL)) { PRInt16 lower_out_flags = 0; PRInt16 lower_new_flags; lower_new_flags = fd->lower->methods->poll(fd->lower, new_flags, &lower_out_flags); if ((lower_new_flags & lower_out_flags) && (how_flags != new_flags)) { PRInt16 out_flags = lower_out_flags & ~PR_POLL_RW; if (lower_out_flags & PR_POLL_READ) out_flags |= PR_POLL_WRITE; if (lower_out_flags & PR_POLL_WRITE) out_flags |= PR_POLL_READ; *p_out_flags = out_flags; new_flags = how_flags; } else { *p_out_flags = lower_out_flags; new_flags = lower_new_flags; } } return new_flags; } static PRInt32 PR_CALLBACK ssl_TransmitFile(PRFileDesc *sd, PRFileDesc *fd, const void *headers, PRInt32 hlen, PRTransmitFileFlags flags, PRIntervalTime timeout) { PRSendFileData sfd; sfd.fd = fd; sfd.file_offset = 0; sfd.file_nbytes = 0; sfd.header = headers; sfd.hlen = hlen; sfd.trailer = NULL; sfd.tlen = 0; return sd->methods->sendfile(sd, &sfd, flags, timeout); } PRBool ssl_FdIsBlocking(PRFileDesc *fd) { PRSocketOptionData opt; PRStatus status; opt.option = PR_SockOpt_Nonblocking; opt.value.non_blocking = PR_FALSE; status = PR_GetSocketOption(fd, &opt); if (status != PR_SUCCESS) return PR_FALSE; return (PRBool)!opt.value.non_blocking; } PRBool ssl_SocketIsBlocking(sslSocket *ss) { return ssl_FdIsBlocking(ss->fd); } PRInt32 sslFirstBufSize = 8 * 1024; PRInt32 sslCopyLimit = 1024; static PRInt32 PR_CALLBACK ssl_WriteV(PRFileDesc *fd, const PRIOVec *iov, PRInt32 vectors, PRIntervalTime timeout) { PRInt32 i; PRInt32 bufLen; PRInt32 left; PRInt32 rv; PRInt32 sent = 0; const PRInt32 first_len = sslFirstBufSize; const PRInt32 limit = sslCopyLimit; PRBool blocking; PRIOVec myIov = { 0, 0 }; char buf[MAX_FRAGMENT_LENGTH]; if (vectors < 0) { PORT_SetError(PR_INVALID_ARGUMENT_ERROR); return -1; } if (vectors > PR_MAX_IOVECTOR_SIZE) { PORT_SetError(PR_BUFFER_OVERFLOW_ERROR); return -1; } for (i = 0; i < vectors; i++) { if (iov[i].iov_len < 0) { PORT_SetError(PR_INVALID_ARGUMENT_ERROR); return -1; } } blocking = ssl_FdIsBlocking(fd); #define K16 sizeof(buf) #define KILL_VECTORS while (vectors && !iov->iov_len) { ++iov; --vectors; } #define GET_VECTOR do { myIov = *iov++; --vectors; KILL_VECTORS } while (0) #define HANDLE_ERR(rv, len) \ if (rv != len) { \ if (rv < 0) { \ if (!blocking \ && (PR_GetError() == PR_WOULD_BLOCK_ERROR) \ && (sent > 0)) { \ return sent; \ } else { \ return -1; \ } \ } \ /* Only a nonblocking socket can have partial sends */ \ PR_ASSERT(!blocking); \ return sent + rv; \ } #define SEND(bfr, len) \ do { \ rv = ssl_Send(fd, bfr, len, 0, timeout); \ HANDLE_ERR(rv, len) \ sent += len; \ } while (0) /* Make sure the first write is at least 8 KB, if possible. */ KILL_VECTORS if (!vectors) return ssl_Send(fd, 0, 0, 0, timeout); GET_VECTOR; if (!vectors) { return ssl_Send(fd, myIov.iov_base, myIov.iov_len, 0, timeout); } if (myIov.iov_len < first_len) { PORT_Memcpy(buf, myIov.iov_base, myIov.iov_len); bufLen = myIov.iov_len; left = first_len - bufLen; while (vectors && left) { int toCopy; GET_VECTOR; toCopy = PR_MIN(left, myIov.iov_len); PORT_Memcpy(buf + bufLen, myIov.iov_base, toCopy); bufLen += toCopy; left -= toCopy; myIov.iov_base += toCopy; myIov.iov_len -= toCopy; } SEND( buf, bufLen ); } while (vectors || myIov.iov_len) { PRInt32 addLen; if (!myIov.iov_len) { GET_VECTOR; } while (myIov.iov_len >= K16) { SEND(myIov.iov_base, K16); myIov.iov_base += K16; myIov.iov_len -= K16; } if (!myIov.iov_len) continue; if (!vectors || myIov.iov_len > limit) { addLen = 0; } else if ((addLen = iov->iov_len % K16) + myIov.iov_len <= limit) { /* Addlen is already computed. */; } else if (vectors > 1 && iov[1].iov_len % K16 + addLen + myIov.iov_len <= 2 * limit) { addLen = limit - myIov.iov_len; } else addLen = 0; if (!addLen) { SEND( myIov.iov_base, myIov.iov_len ); myIov.iov_len = 0; continue; } PORT_Memcpy(buf, myIov.iov_base, myIov.iov_len); bufLen = myIov.iov_len; do { GET_VECTOR; PORT_Memcpy(buf + bufLen, myIov.iov_base, addLen); myIov.iov_base += addLen; myIov.iov_len -= addLen; bufLen += addLen; left = PR_MIN( limit, K16 - bufLen); if (!vectors /* no more left */ || myIov.iov_len > 0 /* we didn't use that one all up */ || bufLen >= K16 /* it's full. */ ) { addLen = 0; } else if ((addLen = iov->iov_len % K16) <= left) { /* Addlen is already computed. */; } else if (vectors > 1 && iov[1].iov_len % K16 + addLen <= left + limit) { addLen = left; } else addLen = 0; } while (addLen); SEND( buf, bufLen ); } return sent; } /* * These functions aren't implemented. */ static PRInt32 PR_CALLBACK ssl_Available(PRFileDesc *fd) { PORT_Assert(0); PR_SetError(PR_NOT_IMPLEMENTED_ERROR, 0); return SECFailure; } static PRInt64 PR_CALLBACK ssl_Available64(PRFileDesc *fd) { PRInt64 res; PORT_Assert(0); PR_SetError(PR_NOT_IMPLEMENTED_ERROR, 0); LL_I2L(res, -1L); return res; } static PRStatus PR_CALLBACK ssl_FSync(PRFileDesc *fd) { PORT_Assert(0); PR_SetError(PR_NOT_IMPLEMENTED_ERROR, 0); return PR_FAILURE; } static PRInt32 PR_CALLBACK ssl_Seek(PRFileDesc *fd, PRInt32 offset, PRSeekWhence how) { PORT_Assert(0); PR_SetError(PR_NOT_IMPLEMENTED_ERROR, 0); return SECFailure; } static PRInt64 PR_CALLBACK ssl_Seek64(PRFileDesc *fd, PRInt64 offset, PRSeekWhence how) { PRInt64 res; PORT_Assert(0); PR_SetError(PR_NOT_IMPLEMENTED_ERROR, 0); LL_I2L(res, -1L); return res; } static PRStatus PR_CALLBACK ssl_FileInfo(PRFileDesc *fd, PRFileInfo *info) { PORT_Assert(0); PR_SetError(PR_NOT_IMPLEMENTED_ERROR, 0); return PR_FAILURE; } static PRStatus PR_CALLBACK ssl_FileInfo64(PRFileDesc *fd, PRFileInfo64 *info) { PORT_Assert(0); PR_SetError(PR_NOT_IMPLEMENTED_ERROR, 0); return PR_FAILURE; } static PRInt32 PR_CALLBACK ssl_RecvFrom(PRFileDesc *fd, void *buf, PRInt32 amount, PRIntn flags, PRNetAddr *addr, PRIntervalTime timeout) { PORT_Assert(0); PR_SetError(PR_NOT_IMPLEMENTED_ERROR, 0); return SECFailure; } static PRInt32 PR_CALLBACK ssl_SendTo(PRFileDesc *fd, const void *buf, PRInt32 amount, PRIntn flags, const PRNetAddr *addr, PRIntervalTime timeout) { PORT_Assert(0); PR_SetError(PR_NOT_IMPLEMENTED_ERROR, 0); return SECFailure; } static const PRIOMethods ssl_methods = { PR_DESC_LAYERED, ssl_Close, /* close */ ssl_Read, /* read */ ssl_Write, /* write */ ssl_Available, /* available */ ssl_Available64, /* available64 */ ssl_FSync, /* fsync */ ssl_Seek, /* seek */ ssl_Seek64, /* seek64 */ ssl_FileInfo, /* fileInfo */ ssl_FileInfo64, /* fileInfo64 */ ssl_WriteV, /* writev */ ssl_Connect, /* connect */ ssl_Accept, /* accept */ ssl_Bind, /* bind */ ssl_Listen, /* listen */ ssl_Shutdown, /* shutdown */ ssl_Recv, /* recv */ ssl_Send, /* send */ ssl_RecvFrom, /* recvfrom */ ssl_SendTo, /* sendto */ ssl_Poll, /* poll */ PR_EmulateAcceptRead, /* acceptread */ ssl_TransmitFile, /* transmitfile */ ssl_GetSockName, /* getsockname */ ssl_GetPeerName, /* getpeername */ NULL, /* getsockopt OBSOLETE */ NULL, /* setsockopt OBSOLETE */ NULL, /* getsocketoption */ NULL, /* setsocketoption */ PR_EmulateSendFile, /* Send a (partial) file with header/trailer*/ NULL, /* reserved for future use */ NULL, /* reserved for future use */ NULL, /* reserved for future use */ NULL, /* reserved for future use */ NULL /* reserved for future use */ }; static PRIOMethods combined_methods; static void ssl_SetupIOMethods(void) { PRIOMethods *new_methods = &combined_methods; const PRIOMethods *nspr_methods = PR_GetDefaultIOMethods(); const PRIOMethods *my_methods = &ssl_methods; *new_methods = *nspr_methods; new_methods->file_type = my_methods->file_type; new_methods->close = my_methods->close; new_methods->read = my_methods->read; new_methods->write = my_methods->write; new_methods->available = my_methods->available; new_methods->available64 = my_methods->available64; new_methods->fsync = my_methods->fsync; new_methods->seek = my_methods->seek; new_methods->seek64 = my_methods->seek64; new_methods->fileInfo = my_methods->fileInfo; new_methods->fileInfo64 = my_methods->fileInfo64; new_methods->writev = my_methods->writev; new_methods->connect = my_methods->connect; new_methods->accept = my_methods->accept; new_methods->bind = my_methods->bind; new_methods->listen = my_methods->listen; new_methods->shutdown = my_methods->shutdown; new_methods->recv = my_methods->recv; new_methods->send = my_methods->send; new_methods->recvfrom = my_methods->recvfrom; new_methods->sendto = my_methods->sendto; new_methods->poll = my_methods->poll; new_methods->acceptread = my_methods->acceptread; new_methods->transmitfile = my_methods->transmitfile; new_methods->getsockname = my_methods->getsockname; new_methods->getpeername = my_methods->getpeername; /* new_methods->getsocketoption = my_methods->getsocketoption; */ /* new_methods->setsocketoption = my_methods->setsocketoption; */ new_methods->sendfile = my_methods->sendfile; } static PRCallOnceType initIoLayerOnce; static PRStatus ssl_InitIOLayer(void) { ssl_layer_id = PR_GetUniqueIdentity("SSL"); ssl_SetupIOMethods(); ssl_inited = PR_TRUE; return PR_SUCCESS; } static PRStatus ssl_PushIOLayer(sslSocket *ns, PRFileDesc *stack, PRDescIdentity id) { PRFileDesc *layer = NULL; PRStatus status; if (!ssl_inited) { status = PR_CallOnce(&initIoLayerOnce, &ssl_InitIOLayer); if (status != PR_SUCCESS) goto loser; } if (ns == NULL) goto loser; layer = PR_CreateIOLayerStub(ssl_layer_id, &combined_methods); if (layer == NULL) goto loser; layer->secret = (PRFilePrivate *)ns; /* Here, "stack" points to the PRFileDesc on the top of the stack. ** "layer" points to a new FD that is to be inserted into the stack. ** If layer is being pushed onto the top of the stack, then ** PR_PushIOLayer switches the contents of stack and layer, and then ** puts stack on top of layer, so that after it is done, the top of ** stack is the same "stack" as it was before, and layer is now the ** FD for the former top of stack. ** After this call, stack always points to the top PRFD on the stack. ** If this function fails, the contents of stack and layer are as ** they were before the call. */ status = PR_PushIOLayer(stack, id, layer); if (status != PR_SUCCESS) goto loser; ns->fd = (id == PR_TOP_IO_LAYER) ? stack : layer; return PR_SUCCESS; loser: if (layer) { layer->dtor(layer); /* free layer */ } return PR_FAILURE; } /* if this fails, caller must destroy socket. */ static SECStatus ssl_MakeLocks(sslSocket *ss) { ss->firstHandshakeLock = PZ_NewMonitor(nssILockSSL); if (!ss->firstHandshakeLock) goto loser; ss->ssl3HandshakeLock = PZ_NewMonitor(nssILockSSL); if (!ss->ssl3HandshakeLock) goto loser; ss->specLock = NSSRWLock_New(SSL_LOCK_RANK_SPEC, NULL); if (!ss->specLock) goto loser; ss->recvBufLock = PZ_NewMonitor(nssILockSSL); if (!ss->recvBufLock) goto loser; ss->xmitBufLock = PZ_NewMonitor(nssILockSSL); if (!ss->xmitBufLock) goto loser; ss->writerThread = NULL; if (ssl_lock_readers) { ss->recvLock = PZ_NewLock(nssILockSSL); if (!ss->recvLock) goto loser; ss->sendLock = PZ_NewLock(nssILockSSL); if (!ss->sendLock) goto loser; } return SECSuccess; loser: ssl_DestroyLocks(ss); return SECFailure; } #if defined(XP_UNIX) || defined(XP_WIN32) || defined(XP_BEOS) #define NSS_HAVE_GETENV 1 #endif #define LOWER(x) (x | 0x20) /* cheap ToLower function ignores LOCALE */ static void ssl_SetDefaultsFromEnvironment(void) { #if defined( NSS_HAVE_GETENV ) static int firsttime = 1; if (firsttime) { char * ev; firsttime = 0; #ifdef DEBUG ev = getenv("SSLDEBUGFILE"); if (ev && ev[0]) { ssl_trace_iob = fopen(ev, "w"); } if (!ssl_trace_iob) { ssl_trace_iob = stderr; } #ifdef TRACE ev = getenv("SSLTRACE"); if (ev && ev[0]) { ssl_trace = atoi(ev); SSL_TRACE(("SSL: tracing set to %d", ssl_trace)); } #endif /* TRACE */ ev = getenv("SSLDEBUG"); if (ev && ev[0]) { ssl_debug = atoi(ev); SSL_TRACE(("SSL: debugging set to %d", ssl_debug)); } #endif /* DEBUG */ ev = getenv("SSLKEYLOGFILE"); if (ev && ev[0]) { ssl_keylog_iob = fopen(ev, "a"); if (!ssl_keylog_iob) { SSL_TRACE(("SSL: failed to open key log file")); } else { if (ftell(ssl_keylog_iob) == 0) { fputs("# SSL/TLS secrets log file, generated by NSS\n", ssl_keylog_iob); } SSL_TRACE(("SSL: logging SSL/TLS secrets to %s", ev)); } } #ifndef NO_PKCS11_BYPASS ev = getenv("SSLBYPASS"); if (ev && ev[0]) { ssl_defaults.bypassPKCS11 = (ev[0] == '1'); SSL_TRACE(("SSL: bypass default set to %d", \ ssl_defaults.bypassPKCS11)); } #endif /* NO_PKCS11_BYPASS */ ev = getenv("SSLFORCELOCKS"); if (ev && ev[0] == '1') { ssl_force_locks = PR_TRUE; ssl_defaults.noLocks = 0; strcpy(lockStatus + LOCKSTATUS_OFFSET, "FORCED. "); SSL_TRACE(("SSL: force_locks set to %d", ssl_force_locks)); } ev = getenv("NSS_SSL_ENABLE_RENEGOTIATION"); if (ev) { if (ev[0] == '1' || LOWER(ev[0]) == 'u') ssl_defaults.enableRenegotiation = SSL_RENEGOTIATE_UNRESTRICTED; else if (ev[0] == '0' || LOWER(ev[0]) == 'n') ssl_defaults.enableRenegotiation = SSL_RENEGOTIATE_NEVER; else if (ev[0] == '2' || LOWER(ev[0]) == 'r') ssl_defaults.enableRenegotiation = SSL_RENEGOTIATE_REQUIRES_XTN; else if (ev[0] == '3' || LOWER(ev[0]) == 't') ssl_defaults.enableRenegotiation = SSL_RENEGOTIATE_TRANSITIONAL; SSL_TRACE(("SSL: enableRenegotiation set to %d", ssl_defaults.enableRenegotiation)); } ev = getenv("NSS_SSL_REQUIRE_SAFE_NEGOTIATION"); if (ev && ev[0] == '1') { ssl_defaults.requireSafeNegotiation = PR_TRUE; SSL_TRACE(("SSL: requireSafeNegotiation set to %d", PR_TRUE)); } ev = getenv("NSS_SSL_CBC_RANDOM_IV"); if (ev && ev[0] == '0') { ssl_defaults.cbcRandomIV = PR_FALSE; SSL_TRACE(("SSL: cbcRandomIV set to 0")); } } #endif /* NSS_HAVE_GETENV */ } /* ** Create a newsocket structure for a file descriptor. */ static sslSocket * ssl_NewSocket(PRBool makeLocks, SSLProtocolVariant protocolVariant) { sslSocket *ss; ssl_SetDefaultsFromEnvironment(); if (ssl_force_locks) makeLocks = PR_TRUE; /* Make a new socket and get it ready */ ss = (sslSocket*) PORT_ZAlloc(sizeof(sslSocket)); if (ss) { /* This should be of type SSLKEAType, but CC on IRIX * complains during the for loop. */ int i; SECStatus status; ss->opt = ssl_defaults; ss->opt.useSocks = PR_FALSE; ss->opt.noLocks = !makeLocks; ss->vrange = *VERSIONS_DEFAULTS(protocolVariant); ss->protocolVariant = protocolVariant; ss->peerID = NULL; ss->rTimeout = PR_INTERVAL_NO_TIMEOUT; ss->wTimeout = PR_INTERVAL_NO_TIMEOUT; ss->cTimeout = PR_INTERVAL_NO_TIMEOUT; ss->cipherSpecs = NULL; ss->sizeCipherSpecs = 0; /* produced lazily */ ss->preferredCipher = NULL; ss->url = NULL; for (i=kt_null; i < kt_kea_size; i++) { sslServerCerts * sc = ss->serverCerts + i; sc->serverCert = NULL; sc->serverCertChain = NULL; sc->serverKeyPair = NULL; sc->serverKeyBits = 0; ss->certStatusArray[i] = NULL; } ss->stepDownKeyPair = NULL; ss->dheParams = NULL; ss->dheKeyPair = NULL; ss->dbHandle = CERT_GetDefaultCertDB(); /* Provide default implementation of hooks */ ss->authCertificate = SSL_AuthCertificate; ss->authCertificateArg = (void *)ss->dbHandle; ss->sniSocketConfig = NULL; ss->sniSocketConfigArg = NULL; ss->getClientAuthData = NULL; ss->handleBadCert = NULL; ss->badCertArg = NULL; ss->pkcs11PinArg = NULL; ss->ephemeralECDHKeyPair = NULL; ssl_ChooseOps(ss); ssl2_InitSocketPolicy(ss); ssl3_InitSocketPolicy(ss); PR_INIT_CLIST(&ss->ssl3.hs.lastMessageFlight); if (makeLocks) { status = ssl_MakeLocks(ss); if (status != SECSuccess) goto loser; } status = ssl_CreateSecurityInfo(ss); if (status != SECSuccess) goto loser; status = ssl_InitGather(&ss->gs); if (status != SECSuccess) { loser: ssl_DestroySocketContents(ss); ssl_DestroyLocks(ss); PORT_Free(ss); ss = NULL; } } return ss; }