/* -*- Mode: C++; tab-width: 8; indent-tabs-mode: nil; c-basic-offset: 2 -*- */ /* vim: set ts=2 et sw=2 tw=80: */ /* 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/. */ // Original author: ekr@rtfm.com #include #include #include "logging.h" #include "ssl.h" #include "sslerr.h" #include "sslproto.h" #include "keyhi.h" #include "nsCOMPtr.h" #include "nsComponentManagerUtils.h" #include "nsIEventTarget.h" #include "nsNetCID.h" #include "nsComponentManagerUtils.h" #include "nsServiceManagerUtils.h" #include "dtlsidentity.h" #include "transportflow.h" #include "transportlayerdtls.h" namespace mozilla { MOZ_MTLOG_MODULE("mtransport") static PRDescIdentity transport_layer_identity = PR_INVALID_IO_LAYER; // TODO: Implement a mode for this where // the channel is not ready until confirmed externally // (e.g., after cert check). #define UNIMPLEMENTED \ MOZ_MTLOG(ML_ERROR, \ "Call to unimplemented function "<< __FUNCTION__); \ MOZ_ASSERT(false); \ PR_SetError(PR_NOT_IMPLEMENTED_ERROR, 0) // We need to adapt the NSPR/libssl model to the TransportFlow model. // The former wants pull semantics and TransportFlow wants push. // // - A TransportLayerDtls assumes it is sitting on top of another // TransportLayer, which means that events come in asynchronously. // - NSS (libssl) wants to sit on top of a PRFileDesc and poll. // - The TransportLayerNSPRAdapter is a PRFileDesc containing a // FIFO. // - When TransportLayerDtls.PacketReceived() is called, we insert // the packets in the FIFO and then do a PR_Recv() on the NSS // PRFileDesc, which eventually reads off the FIFO. // // All of this stuff is assumed to happen solely in a single thread // (generally the SocketTransportService thread) struct Packet { Packet() : data_(nullptr), len_(0), offset_(0) {} void Assign(const void *data, int32_t len) { data_ = new uint8_t[len]; memcpy(data_, data, len); len_ = len; } ScopedDeleteArray data_; int32_t len_; int32_t offset_; }; void TransportLayerNSPRAdapter::PacketReceived(const void *data, int32_t len) { input_.push(new Packet()); input_.back()->Assign(data, len); } int32_t TransportLayerNSPRAdapter::Read(void *data, int32_t len) { if (input_.empty()) { PR_SetError(PR_WOULD_BLOCK_ERROR, 0); return TE_WOULDBLOCK; } Packet* front = input_.front(); int32_t to_read = std::min(len, front->len_ - front->offset_); memcpy(data, front->data_, to_read); front->offset_ += to_read; if (front->offset_ == front->len_) { input_.pop(); delete front; } return to_read; } int32_t TransportLayerNSPRAdapter::Write(const void *buf, int32_t length) { TransportResult r = output_->SendPacket( static_cast(buf), length); if (r >= 0) { return r; } if (r == TE_WOULDBLOCK) { PR_SetError(PR_WOULD_BLOCK_ERROR, 0); } else { PR_SetError(PR_IO_ERROR, 0); } return -1; } // Implementation of NSPR methods static PRStatus TransportLayerClose(PRFileDesc *f) { f->secret = nullptr; return PR_SUCCESS; } static int32_t TransportLayerRead(PRFileDesc *f, void *buf, int32_t length) { TransportLayerNSPRAdapter *io = reinterpret_cast(f->secret); return io->Read(buf, length); } static int32_t TransportLayerWrite(PRFileDesc *f, const void *buf, int32_t length) { TransportLayerNSPRAdapter *io = reinterpret_cast(f->secret); return io->Write(buf, length); } static int32_t TransportLayerAvailable(PRFileDesc *f) { UNIMPLEMENTED; return -1; } int64_t TransportLayerAvailable64(PRFileDesc *f) { UNIMPLEMENTED; return -1; } static PRStatus TransportLayerSync(PRFileDesc *f) { UNIMPLEMENTED; return PR_FAILURE; } static int32_t TransportLayerSeek(PRFileDesc *f, int32_t offset, PRSeekWhence how) { UNIMPLEMENTED; return -1; } static int64_t TransportLayerSeek64(PRFileDesc *f, int64_t offset, PRSeekWhence how) { UNIMPLEMENTED; return -1; } static PRStatus TransportLayerFileInfo(PRFileDesc *f, PRFileInfo *info) { UNIMPLEMENTED; return PR_FAILURE; } static PRStatus TransportLayerFileInfo64(PRFileDesc *f, PRFileInfo64 *info) { UNIMPLEMENTED; return PR_FAILURE; } static int32_t TransportLayerWritev(PRFileDesc *f, const PRIOVec *iov, int32_t iov_size, PRIntervalTime to) { UNIMPLEMENTED; return -1; } static PRStatus TransportLayerConnect(PRFileDesc *f, const PRNetAddr *addr, PRIntervalTime to) { UNIMPLEMENTED; return PR_FAILURE; } static PRFileDesc *TransportLayerAccept(PRFileDesc *sd, PRNetAddr *addr, PRIntervalTime to) { UNIMPLEMENTED; return nullptr; } static PRStatus TransportLayerBind(PRFileDesc *f, const PRNetAddr *addr) { UNIMPLEMENTED; return PR_FAILURE; } static PRStatus TransportLayerListen(PRFileDesc *f, int32_t depth) { UNIMPLEMENTED; return PR_FAILURE; } static PRStatus TransportLayerShutdown(PRFileDesc *f, int32_t how) { UNIMPLEMENTED; return PR_FAILURE; } // This function does not support peek. static int32_t TransportLayerRecv(PRFileDesc *f, void *buf, int32_t amount, int32_t flags, PRIntervalTime to) { MOZ_ASSERT(flags == 0); if (flags != 0) { PR_SetError(PR_NOT_IMPLEMENTED_ERROR, 0); return -1; } return TransportLayerRead(f, buf, amount); } // Note: this is always nonblocking and assumes a zero timeout. static int32_t TransportLayerSend(PRFileDesc *f, const void *buf, int32_t amount, int32_t flags, PRIntervalTime to) { int32_t written = TransportLayerWrite(f, buf, amount); return written; } static int32_t TransportLayerRecvfrom(PRFileDesc *f, void *buf, int32_t amount, int32_t flags, PRNetAddr *addr, PRIntervalTime to) { UNIMPLEMENTED; return -1; } static int32_t TransportLayerSendto(PRFileDesc *f, const void *buf, int32_t amount, int32_t flags, const PRNetAddr *addr, PRIntervalTime to) { UNIMPLEMENTED; return -1; } static int16_t TransportLayerPoll(PRFileDesc *f, int16_t in_flags, int16_t *out_flags) { UNIMPLEMENTED; return -1; } static int32_t TransportLayerAcceptRead(PRFileDesc *sd, PRFileDesc **nd, PRNetAddr **raddr, void *buf, int32_t amount, PRIntervalTime t) { UNIMPLEMENTED; return -1; } static int32_t TransportLayerTransmitFile(PRFileDesc *sd, PRFileDesc *f, const void *headers, int32_t hlen, PRTransmitFileFlags flags, PRIntervalTime t) { UNIMPLEMENTED; return -1; } static PRStatus TransportLayerGetpeername(PRFileDesc *f, PRNetAddr *addr) { // TODO: Modify to return unique names for each channel // somehow, as opposed to always the same static address. The current // implementation messes up the session cache, which is why it's off // elsewhere addr->inet.family = PR_AF_INET; addr->inet.port = 0; addr->inet.ip = 0; return PR_SUCCESS; } static PRStatus TransportLayerGetsockname(PRFileDesc *f, PRNetAddr *addr) { UNIMPLEMENTED; return PR_FAILURE; } static PRStatus TransportLayerGetsockoption(PRFileDesc *f, PRSocketOptionData *opt) { switch (opt->option) { case PR_SockOpt_Nonblocking: opt->value.non_blocking = PR_TRUE; return PR_SUCCESS; default: UNIMPLEMENTED; break; } return PR_FAILURE; } // Imitate setting socket options. These are mostly noops. static PRStatus TransportLayerSetsockoption(PRFileDesc *f, const PRSocketOptionData *opt) { switch (opt->option) { case PR_SockOpt_Nonblocking: return PR_SUCCESS; case PR_SockOpt_NoDelay: return PR_SUCCESS; default: UNIMPLEMENTED; break; } return PR_FAILURE; } static int32_t TransportLayerSendfile(PRFileDesc *out, PRSendFileData *in, PRTransmitFileFlags flags, PRIntervalTime to) { UNIMPLEMENTED; return -1; } static PRStatus TransportLayerConnectContinue(PRFileDesc *f, int16_t flags) { UNIMPLEMENTED; return PR_FAILURE; } static int32_t TransportLayerReserved(PRFileDesc *f) { UNIMPLEMENTED; return -1; } static const struct PRIOMethods TransportLayerMethods = { PR_DESC_LAYERED, TransportLayerClose, TransportLayerRead, TransportLayerWrite, TransportLayerAvailable, TransportLayerAvailable64, TransportLayerSync, TransportLayerSeek, TransportLayerSeek64, TransportLayerFileInfo, TransportLayerFileInfo64, TransportLayerWritev, TransportLayerConnect, TransportLayerAccept, TransportLayerBind, TransportLayerListen, TransportLayerShutdown, TransportLayerRecv, TransportLayerSend, TransportLayerRecvfrom, TransportLayerSendto, TransportLayerPoll, TransportLayerAcceptRead, TransportLayerTransmitFile, TransportLayerGetsockname, TransportLayerGetpeername, TransportLayerReserved, TransportLayerReserved, TransportLayerGetsockoption, TransportLayerSetsockoption, TransportLayerSendfile, TransportLayerConnectContinue, TransportLayerReserved, TransportLayerReserved, TransportLayerReserved, TransportLayerReserved }; TransportLayerDtls::~TransportLayerDtls() { if (timer_) { timer_->Cancel(); } } nsresult TransportLayerDtls::InitInternal() { // Get the transport service as an event target nsresult rv; target_ = do_GetService(NS_SOCKETTRANSPORTSERVICE_CONTRACTID, &rv); if (NS_FAILED(rv)) { MOZ_MTLOG(ML_ERROR, "Couldn't get socket transport service"); return rv; } timer_ = do_CreateInstance(NS_TIMER_CONTRACTID, &rv); if (NS_FAILED(rv)) { MOZ_MTLOG(ML_ERROR, "Couldn't get timer"); return rv; } return NS_OK; } void TransportLayerDtls::WasInserted() { // Connect to the lower layers if (!Setup()) { SetState(TS_ERROR); } } nsresult TransportLayerDtls::SetVerificationAllowAll() { // Defensive programming if (verification_mode_ != VERIFY_UNSET) return NS_ERROR_ALREADY_INITIALIZED; verification_mode_ = VERIFY_ALLOW_ALL; return NS_OK; } nsresult TransportLayerDtls::SetVerificationDigest(const std::string digest_algorithm, const unsigned char *digest_value, size_t digest_len) { // Defensive programming if (verification_mode_ != VERIFY_UNSET && verification_mode_ != VERIFY_DIGEST) { return NS_ERROR_ALREADY_INITIALIZED; } // Note that we do not sanity check these values for length. // We merely ensure they will fit into the buffer. // TODO: is there a Data construct we could use? if (digest_len > kMaxDigestLength) return NS_ERROR_INVALID_ARG; digests_.push_back(new VerificationDigest( digest_algorithm, digest_value, digest_len)); verification_mode_ = VERIFY_DIGEST; return NS_OK; } // TODO: make sure this is called from STS. Otherwise // we have thread safety issues bool TransportLayerDtls::Setup() { CheckThread(); SECStatus rv; if (!downward_) { MOZ_MTLOG(ML_ERROR, "DTLS layer with nothing below. This is useless"); return false; } nspr_io_adapter_ = new TransportLayerNSPRAdapter(downward_); if (!identity_) { MOZ_MTLOG(ML_ERROR, "Can't start DTLS without an identity"); return false; } if (verification_mode_ == VERIFY_UNSET) { MOZ_MTLOG(ML_ERROR, "Can't start DTLS without specifying a verification mode"); return false; } if (transport_layer_identity == PR_INVALID_IO_LAYER) { transport_layer_identity = PR_GetUniqueIdentity("nssstreamadapter"); } ScopedPRFileDesc pr_fd(PR_CreateIOLayerStub(transport_layer_identity, &TransportLayerMethods)); MOZ_ASSERT(pr_fd != nullptr); if (!pr_fd) return false; pr_fd->secret = reinterpret_cast(nspr_io_adapter_.get()); ScopedPRFileDesc ssl_fd; if (mode_ == DGRAM) { ssl_fd = DTLS_ImportFD(nullptr, pr_fd); } else { ssl_fd = SSL_ImportFD(nullptr, pr_fd); } MOZ_ASSERT(ssl_fd != nullptr); // This should never happen if (!ssl_fd) { return false; } pr_fd.forget(); // ownership transfered to ssl_fd; if (role_ == CLIENT) { MOZ_MTLOG(ML_DEBUG, "Setting up DTLS as client"); rv = SSL_GetClientAuthDataHook(ssl_fd, GetClientAuthDataHook, this); if (rv != SECSuccess) { MOZ_MTLOG(ML_ERROR, "Couldn't set identity"); return false; } } else { MOZ_MTLOG(ML_DEBUG, "Setting up DTLS as server"); // Server side rv = SSL_ConfigSecureServer(ssl_fd, identity_->cert(), identity_->privkey(), kt_rsa); if (rv != SECSuccess) { MOZ_MTLOG(ML_ERROR, "Couldn't set identity"); return false; } // Insist on a certificate from the client rv = SSL_OptionSet(ssl_fd, SSL_REQUEST_CERTIFICATE, PR_TRUE); if (rv != SECSuccess) { MOZ_MTLOG(ML_ERROR, "Couldn't request certificate"); return false; } rv = SSL_OptionSet(ssl_fd, SSL_REQUIRE_CERTIFICATE, PR_TRUE); if (rv != SECSuccess) { MOZ_MTLOG(ML_ERROR, "Couldn't require certificate"); return false; } } // Require TLS 1.1. Perhaps some day in the future we will allow // TLS 1.0 for stream modes. SSLVersionRange version_range = { SSL_LIBRARY_VERSION_TLS_1_1, SSL_LIBRARY_VERSION_TLS_1_1 }; rv = SSL_VersionRangeSet(ssl_fd, &version_range); if (rv != SECSuccess) { MOZ_MTLOG(ML_ERROR, "Can't disable SSLv3"); return false; } rv = SSL_OptionSet(ssl_fd, SSL_ENABLE_SESSION_TICKETS, PR_FALSE); if (rv != SECSuccess) { MOZ_MTLOG(ML_ERROR, "Couldn't disable session tickets"); return false; } rv = SSL_OptionSet(ssl_fd, SSL_NO_CACHE, PR_TRUE); if (rv != SECSuccess) { MOZ_MTLOG(ML_ERROR, "Couldn't disable session caching"); return false; } rv = SSL_OptionSet(ssl_fd, SSL_ENABLE_DEFLATE, PR_FALSE); if (rv != SECSuccess) { MOZ_MTLOG(ML_ERROR, "Couldn't disable deflate"); return false; } rv = SSL_OptionSet(ssl_fd, SSL_ENABLE_RENEGOTIATION, SSL_RENEGOTIATE_NEVER); if (rv != SECSuccess) { MOZ_MTLOG(ML_ERROR, "Couldn't disable renegotiation"); return false; } rv = SSL_OptionSet(ssl_fd, SSL_ENABLE_FALSE_START, PR_FALSE); if (rv != SECSuccess) { MOZ_MTLOG(ML_ERROR, "Couldn't disable false start"); return false; } rv = SSL_OptionSet(ssl_fd, SSL_NO_LOCKS, PR_TRUE); if (rv != SECSuccess) { MOZ_MTLOG(ML_ERROR, "Couldn't disable locks"); return false; } // Set the SRTP ciphers if (srtp_ciphers_.size()) { // Note: std::vector is guaranteed to contiguous rv = SSL_SetSRTPCiphers(ssl_fd, &srtp_ciphers_[0], srtp_ciphers_.size()); if (rv != SECSuccess) { MOZ_MTLOG(ML_ERROR, "Couldn't set SRTP cipher suite"); return false; } } // Certificate validation rv = SSL_AuthCertificateHook(ssl_fd, AuthCertificateHook, reinterpret_cast(this)); if (rv != SECSuccess) { MOZ_MTLOG(ML_ERROR, "Couldn't set certificate validation hook"); return false; } // Now start the handshake rv = SSL_ResetHandshake(ssl_fd, role_ == SERVER ? PR_TRUE : PR_FALSE); if (rv != SECSuccess) { MOZ_MTLOG(ML_ERROR, "Couldn't reset handshake"); return false; } ssl_fd_ = ssl_fd.forget(); // Finally, get ready to receive data downward_->SignalStateChange.connect(this, &TransportLayerDtls::StateChange); downward_->SignalPacketReceived.connect(this, &TransportLayerDtls::PacketReceived); if (downward_->state() == TS_OPEN) { Handshake(); } return true; } void TransportLayerDtls::StateChange(TransportLayer *layer, State state) { if (state <= state_) { MOZ_MTLOG(ML_ERROR, "Lower layer state is going backwards from ours"); SetState(TS_ERROR); return; } switch (state) { case TS_NONE: MOZ_ASSERT(false); // Can't happen break; case TS_INIT: MOZ_MTLOG(ML_ERROR, LAYER_INFO << "State change of lower layer to INIT forbidden"); SetState(TS_ERROR); break; case TS_CONNECTING: MOZ_MTLOG(ML_ERROR, LAYER_INFO << "Lower lower is connecting."); break; case TS_OPEN: MOZ_MTLOG(ML_ERROR, LAYER_INFO << "Lower lower is now open; starting TLS"); Handshake(); break; case TS_CLOSED: MOZ_MTLOG(ML_ERROR, LAYER_INFO << "Lower lower is now closed"); SetState(TS_CLOSED); break; case TS_ERROR: MOZ_MTLOG(ML_ERROR, LAYER_INFO << "Lower lower experienced an error"); SetState(TS_ERROR); break; } } void TransportLayerDtls::Handshake() { SetState(TS_CONNECTING); // Clear the retransmit timer timer_->Cancel(); SECStatus rv = SSL_ForceHandshake(ssl_fd_); if (rv == SECSuccess) { MOZ_MTLOG(ML_NOTICE, LAYER_INFO << "****** SSL handshake completed ******"); if (!cert_ok_) { MOZ_MTLOG(ML_ERROR, LAYER_INFO << "Certificate check never occurred"); SetState(TS_ERROR); return; } SetState(TS_OPEN); } else { int32_t err = PR_GetError(); switch(err) { case SSL_ERROR_RX_MALFORMED_HANDSHAKE: if (mode_ != DGRAM) { MOZ_MTLOG(ML_ERROR, LAYER_INFO << "Malformed TLS message"); SetState(TS_ERROR); } else { MOZ_MTLOG(ML_ERROR, LAYER_INFO << "Malformed DTLS message; ignoring"); } // Fall through case PR_WOULD_BLOCK_ERROR: MOZ_MTLOG(ML_NOTICE, LAYER_INFO << "Would have blocked"); if (mode_ == DGRAM) { PRIntervalTime timeout; rv = DTLS_GetHandshakeTimeout(ssl_fd_, &timeout); if (rv == SECSuccess) { uint32_t timeout_ms = PR_IntervalToMilliseconds(timeout); MOZ_MTLOG(ML_DEBUG, LAYER_INFO << "Setting DTLS timeout to " << timeout_ms); timer_->SetTarget(target_); timer_->InitWithFuncCallback(TimerCallback, this, timeout_ms, nsITimer::TYPE_ONE_SHOT); } } break; default: MOZ_MTLOG(ML_ERROR, LAYER_INFO << "SSL handshake error "<< err); SetState(TS_ERROR); break; } } } void TransportLayerDtls::PacketReceived(TransportLayer* layer, const unsigned char *data, size_t len) { CheckThread(); MOZ_MTLOG(ML_DEBUG, LAYER_INFO << "PacketReceived(" << len << ")"); if (state_ != TS_CONNECTING && state_ != TS_OPEN) { MOZ_MTLOG(ML_DEBUG, LAYER_INFO << "Discarding packet in inappropriate state"); return; } nspr_io_adapter_->PacketReceived(data, len); // If we're still connecting, try to handshake if (state_ == TS_CONNECTING) { Handshake(); } // Now try a recv if we're open, since there might be data left if (state_ == TS_OPEN) { unsigned char buf[2000]; int32_t rv = PR_Recv(ssl_fd_, buf, sizeof(buf), 0, PR_INTERVAL_NO_WAIT); if (rv > 0) { // We have data MOZ_MTLOG(ML_DEBUG, LAYER_INFO << "Read " << rv << " bytes from NSS"); SignalPacketReceived(this, buf, rv); } else if (rv == 0) { SetState(TS_CLOSED); } else { int32_t err = PR_GetError(); if (err == PR_WOULD_BLOCK_ERROR) { // This gets ignored MOZ_MTLOG(ML_NOTICE, LAYER_INFO << "Would have blocked"); } else { MOZ_MTLOG(ML_NOTICE, LAYER_INFO << "NSS Error " << err); SetState(TS_ERROR); } } } } TransportResult TransportLayerDtls::SendPacket(const unsigned char *data, size_t len) { CheckThread(); if (state_ != TS_OPEN) { MOZ_MTLOG(ML_ERROR, LAYER_INFO << "Can't call SendPacket() in state " << state_); return TE_ERROR; } int32_t rv = PR_Send(ssl_fd_, data, len, 0, PR_INTERVAL_NO_WAIT); if (rv > 0) { // We have data MOZ_MTLOG(ML_DEBUG, LAYER_INFO << "Wrote " << rv << " bytes to SSL Layer"); return rv; } if (rv == 0) { SetState(TS_CLOSED); return 0; } int32_t err = PR_GetError(); if (err == PR_WOULD_BLOCK_ERROR) { // This gets ignored MOZ_MTLOG(ML_NOTICE, LAYER_INFO << "Would have blocked"); return TE_WOULDBLOCK; } MOZ_MTLOG(ML_NOTICE, LAYER_INFO << "NSS Error " << err); SetState(TS_ERROR); return TE_ERROR; } SECStatus TransportLayerDtls::GetClientAuthDataHook(void *arg, PRFileDesc *fd, CERTDistNames *caNames, CERTCertificate **pRetCert, SECKEYPrivateKey **pRetKey) { MOZ_MTLOG(ML_DEBUG, "Server requested client auth"); TransportLayerDtls *stream = reinterpret_cast(arg); stream->CheckThread(); if (!stream->identity_) { MOZ_MTLOG(ML_ERROR, "No identity available"); PR_SetError(SSL_ERROR_NO_CERTIFICATE, 0); return SECFailure; } *pRetCert = CERT_DupCertificate(stream->identity_->cert()); if (!*pRetCert) { PR_SetError(PR_OUT_OF_MEMORY_ERROR, 0); return SECFailure; } *pRetKey = SECKEY_CopyPrivateKey(stream->identity_->privkey()); if (!*pRetKey) { CERT_DestroyCertificate(*pRetCert); *pRetCert = nullptr; PR_SetError(PR_OUT_OF_MEMORY_ERROR, 0); return SECFailure; } return SECSuccess; } nsresult TransportLayerDtls::SetSrtpCiphers(std::vector ciphers) { // TODO: We should check these srtp_ciphers_ = ciphers; return NS_OK; } nsresult TransportLayerDtls::GetSrtpCipher(uint16_t *cipher) { CheckThread(); SECStatus rv = SSL_GetSRTPCipher(ssl_fd_, cipher); if (rv != SECSuccess) { MOZ_MTLOG(ML_DEBUG, "No SRTP cipher negotiated"); return NS_ERROR_FAILURE; } return NS_OK; } nsresult TransportLayerDtls::ExportKeyingMaterial(const std::string& label, bool use_context, const std::string& context, unsigned char *out, unsigned int outlen) { CheckThread(); SECStatus rv = SSL_ExportKeyingMaterial(ssl_fd_, label.c_str(), label.size(), use_context, reinterpret_cast( context.c_str()), context.size(), out, outlen); if (rv != SECSuccess) { MOZ_MTLOG(ML_ERROR, "Couldn't export SSL keying material"); return NS_ERROR_FAILURE; } return NS_OK; } SECStatus TransportLayerDtls::AuthCertificateHook(void *arg, PRFileDesc *fd, PRBool checksig, PRBool isServer) { TransportLayerDtls *stream = reinterpret_cast(arg); stream->CheckThread(); return stream->AuthCertificateHook(fd, checksig, isServer); } SECStatus TransportLayerDtls::CheckDigest(const RefPtr& digest, CERTCertificate *peer_cert) { unsigned char computed_digest[kMaxDigestLength]; size_t computed_digest_len; MOZ_MTLOG(ML_DEBUG, LAYER_INFO << "Checking digest, algorithm=" << digest->algorithm_); nsresult res = DtlsIdentity::ComputeFingerprint(peer_cert, digest->algorithm_, computed_digest, sizeof(computed_digest), &computed_digest_len); if (NS_FAILED(res)) { MOZ_MTLOG(ML_ERROR, "Could not compute peer fingerprint for digest " << digest->algorithm_); // Go to end PR_SetError(SSL_ERROR_BAD_CERTIFICATE, 0); return SECFailure; } if (computed_digest_len != digest->len_) { MOZ_MTLOG(ML_ERROR, "Digest is wrong length " << digest->len_ << " should be " << computed_digest_len << " for algorithm " << digest->algorithm_); PR_SetError(SSL_ERROR_BAD_CERTIFICATE, 0); return SECFailure; } if (memcmp(digest->value_, computed_digest, computed_digest_len) != 0) { MOZ_MTLOG(ML_ERROR, "Digest does not match"); PR_SetError(SSL_ERROR_BAD_CERTIFICATE, 0); return SECFailure; } return SECSuccess; } SECStatus TransportLayerDtls::AuthCertificateHook(PRFileDesc *fd, PRBool checksig, PRBool isServer) { CheckThread(); ScopedCERTCertificate peer_cert; peer_cert = SSL_PeerCertificate(fd); // We are not set up to take this being called multiple // times. Change this if we ever add renegotiation. MOZ_ASSERT(!auth_hook_called_); if (auth_hook_called_) { PR_SetError(PR_UNKNOWN_ERROR, 0); return SECFailure; } auth_hook_called_ = true; MOZ_ASSERT(verification_mode_ != VERIFY_UNSET); MOZ_ASSERT(peer_cert_ == nullptr); switch (verification_mode_) { case VERIFY_UNSET: // Break out to error exit PR_SetError(PR_UNKNOWN_ERROR, 0); break; case VERIFY_ALLOW_ALL: peer_cert_ = peer_cert.forget(); cert_ok_ = true; return SECSuccess; case VERIFY_DIGEST: { MOZ_ASSERT(digests_.size() != 0); // Check all the provided digests // Checking functions call PR_SetError() SECStatus rv = SECFailure; for (size_t i = 0; i < digests_.size(); i++) { RefPtr digest = digests_[i]; rv = CheckDigest(digest, peer_cert); if (rv != SECSuccess) break; } if (rv == SECSuccess) { // Matches all digests, we are good to go cert_ok_ = true; peer_cert = peer_cert.forget(); return SECSuccess; } } break; default: MOZ_CRASH(); // Can't happen } return SECFailure; } void TransportLayerDtls::TimerCallback(nsITimer *timer, void *arg) { TransportLayerDtls *dtls = reinterpret_cast(arg); MOZ_MTLOG(ML_DEBUG, "DTLS timer expired"); dtls->Handshake(); } } // close namespace