void Dtls::HandleUdpReceive(Message &aMessage, const Ip6::MessageInfo &aMessageInfo)
{
switch (mState)
{
case MeshCoP::Dtls::kStateClosed:
ExitNow();
case MeshCoP::Dtls::kStateOpen:
{
Ip6::SockAddr sockAddr;
sockAddr.mAddress = aMessageInfo.GetPeerAddr();
sockAddr.mPort = aMessageInfo.GetPeerPort();
mSocket.Connect(sockAddr);
mPeerAddress.SetPeerAddr(aMessageInfo.GetPeerAddr());
mPeerAddress.SetPeerPort(aMessageInfo.GetPeerPort());
mPeerAddress.SetInterfaceId(aMessageInfo.GetInterfaceId());
if (Get<ThreadNetif>().IsUnicastAddress(aMessageInfo.GetSockAddr()))
{
mPeerAddress.SetSockAddr(aMessageInfo.GetSockAddr());
}
mPeerAddress.SetSockPort(aMessageInfo.GetSockPort());
SuccessOrExit(Setup(false));
break;
}
default:
// Once DTLS session is started, communicate only with a peer.
VerifyOrExit((mPeerAddress.GetPeerAddr() == aMessageInfo.GetPeerAddr()) &&
(mPeerAddress.GetPeerPort() == aMessageInfo.GetPeerPort()));
break;
}
#if OPENTHREAD_ENABLE_BORDER_AGENT || OPENTHREAD_ENABLE_COMMISSIONER
if (mState == MeshCoP::Dtls::kStateConnecting)
{
SetClientId(mPeerAddress.GetPeerAddr().mFields.m8, sizeof(mPeerAddress.GetPeerAddr().mFields));
}
#endif
Receive(aMessage, aMessage.GetOffset(), aMessage.GetLength() - aMessage.GetOffset());
exit:
return;
}
RequestMetadata::RequestMetadata(bool aConfirmable, const Ip6::MessageInfo &aMessageInfo,
otCoapResponseHandler aHandler, void *aContext)
{
mSourceAddress = aMessageInfo.GetSockAddr();
mDestinationPort = aMessageInfo.GetPeerPort();
mDestinationAddress = aMessageInfo.GetPeerAddr();
mResponseHandler = aHandler;
mResponseContext = aContext;
mRetransmissionCount = 0;
mRetransmissionTimeout = Timer::SecToMsec(kAckTimeout);
mRetransmissionTimeout += otPlatRandomGet() %
(Timer::SecToMsec(kAckTimeout) * kAckRandomFactorNumerator / kAckRandomFactorDenominator -
Timer::SecToMsec(kAckTimeout) + 1);
if (aConfirmable)
{
// Set next retransmission timeout.
mNextTimerShot = Timer::GetNow() + mRetransmissionTimeout;
}
else
{
// Set overall response timeout.
mNextTimerShot = Timer::GetNow() + kMaxTransmitWait;
}
mAcknowledged = false;
mConfirmable = aConfirmable;
}
void JoinerRouter::HandleUdpReceive(Message &aMessage, const Ip6::MessageInfo &aMessageInfo)
{
ThreadNetif & netif = GetNetif();
otError error;
Coap::Message * message = NULL;
Ip6::MessageInfo messageInfo;
JoinerUdpPortTlv udpPort;
JoinerIidTlv iid;
JoinerRouterLocatorTlv rloc;
ExtendedTlv tlv;
uint16_t borderAgentRloc;
uint16_t offset;
otLogInfoMeshCoP("JoinerRouter::HandleUdpReceive");
SuccessOrExit(error = GetBorderAgentRloc(GetNetif(), borderAgentRloc));
VerifyOrExit((message = NewMeshCoPMessage(netif.GetCoap())) != NULL, error = OT_ERROR_NO_BUFS);
message->Init(OT_COAP_TYPE_NON_CONFIRMABLE, OT_COAP_CODE_POST);
message->SetToken(Coap::Message::kDefaultTokenLength);
message->AppendUriPathOptions(OT_URI_PATH_RELAY_RX);
message->SetPayloadMarker();
udpPort.Init();
udpPort.SetUdpPort(aMessageInfo.GetPeerPort());
SuccessOrExit(error = message->Append(&udpPort, sizeof(udpPort)));
iid.Init();
iid.SetIid(aMessageInfo.GetPeerAddr().mFields.m8 + 8);
SuccessOrExit(error = message->Append(&iid, sizeof(iid)));
rloc.Init();
rloc.SetJoinerRouterLocator(netif.GetMle().GetRloc16());
SuccessOrExit(error = message->Append(&rloc, sizeof(rloc)));
tlv.SetType(Tlv::kJoinerDtlsEncapsulation);
tlv.SetLength(aMessage.GetLength() - aMessage.GetOffset());
SuccessOrExit(error = message->Append(&tlv, sizeof(tlv)));
offset = message->GetLength();
SuccessOrExit(error = message->SetLength(offset + tlv.GetLength()));
aMessage.CopyTo(aMessage.GetOffset(), offset, tlv.GetLength(), *message);
messageInfo.SetSockAddr(netif.GetMle().GetMeshLocal16());
messageInfo.SetPeerAddr(netif.GetMle().GetMeshLocal16());
messageInfo.GetPeerAddr().mFields.m16[7] = HostSwap16(borderAgentRloc);
messageInfo.SetPeerPort(kCoapUdpPort);
SuccessOrExit(error = netif.GetCoap().SendMessage(*message, messageInfo));
otLogInfoMeshCoP("Sent relay rx");
exit:
if (error != OT_ERROR_NONE && message != NULL)
{
message->Free();
}
}
void CoapSecure::Receive(Message &aMessage, const Ip6::MessageInfo &aMessageInfo)
{
ThreadNetif &netif = GetNetif();
if (!netif.GetDtls().IsStarted())
{
Ip6::SockAddr sockAddr;
sockAddr.mAddress = aMessageInfo.GetPeerAddr();
sockAddr.mPort = aMessageInfo.GetPeerPort();
mSocket.Connect(sockAddr);
mPeerAddress.SetPeerAddr(aMessageInfo.GetPeerAddr());
mPeerAddress.SetPeerPort(aMessageInfo.GetPeerPort());
mPeerAddress.SetInterfaceId(aMessageInfo.GetInterfaceId());
if (netif.IsUnicastAddress(aMessageInfo.GetSockAddr()))
{
mPeerAddress.SetSockAddr(aMessageInfo.GetSockAddr());
}
mPeerAddress.SetSockPort(aMessageInfo.GetSockPort());
netif.GetDtls().Start(false, &CoapSecure::HandleDtlsConnected, &CoapSecure::HandleDtlsReceive,
CoapSecure::HandleDtlsSend, this);
}
else
{
// Once DTLS session is started, communicate only with a peer.
VerifyOrExit((mPeerAddress.GetPeerAddr() == aMessageInfo.GetPeerAddr()) &&
(mPeerAddress.GetPeerPort() == aMessageInfo.GetPeerPort()));
}
netif.GetDtls().SetClientId(mPeerAddress.GetPeerAddr().mFields.m8, sizeof(mPeerAddress.GetPeerAddr().mFields));
netif.GetDtls().Receive(aMessage, aMessage.GetOffset(), aMessage.GetLength() - aMessage.GetOffset());
exit:
return;
}
void Client::ProcessReceivedMessage(Message &aMessage, const Ip6::MessageInfo &aMessageInfo)
{
Header responseHeader;
Header requestHeader;
RequestMetadata requestMetadata;
Message *message = NULL;
ThreadError error;
SuccessOrExit(error = responseHeader.FromMessage(aMessage, false));
aMessage.MoveOffset(responseHeader.GetLength());
message = FindRelatedRequest(responseHeader, aMessageInfo, requestHeader, requestMetadata);
if (message == NULL)
{
ExitNow();
}
switch (responseHeader.GetType())
{
case kCoapTypeReset:
if (responseHeader.IsEmpty())
{
FinalizeCoapTransaction(*message, requestMetadata, NULL, NULL, NULL, kThreadError_Abort);
}
// Silently ignore non-empty reset messages (RFC 7252, p. 4.2).
break;
case kCoapTypeAcknowledgment:
if (responseHeader.IsEmpty())
{
// Empty acknowledgment.
if (requestMetadata.mConfirmable)
{
requestMetadata.mAcknowledged = true;
requestMetadata.UpdateIn(*message);
}
// Remove the message if response is not expected, otherwise await response.
if (requestMetadata.mResponseHandler == NULL)
{
DequeueMessage(*message);
}
}
else if (responseHeader.IsResponse() && responseHeader.IsTokenEqual(requestHeader))
{
// Piggybacked response.
FinalizeCoapTransaction(*message, requestMetadata, &responseHeader, &aMessage, &aMessageInfo, kThreadError_None);
}
// Silently ignore acknowledgments carrying requests (RFC 7252, p. 4.2)
// or with no token match (RFC 7252, p. 5.3.2)
break;
case kCoapTypeConfirmable:
case kCoapTypeNonConfirmable:
if (responseHeader.IsConfirmable())
{
// Send empty ACK if it is a CON message.
SendEmptyAck(aMessageInfo.GetPeerAddr(), aMessageInfo.GetPeerPort(), responseHeader.GetMessageId());
}
FinalizeCoapTransaction(*message, requestMetadata, &responseHeader, &aMessage, &aMessageInfo, kThreadError_None);
break;
}
exit:
if (error == kThreadError_None && message == NULL)
{
if (responseHeader.IsConfirmable() || responseHeader.IsNonConfirmable())
{
// Successfully parsed a header but no matching request was found - reject the message by sending reset.
SendReset(aMessageInfo.GetPeerAddr(), aMessageInfo.GetPeerPort(), responseHeader.GetMessageId());
}
}
}
