// RHMesh.cpp // // Define addressed datagram // // Part of the Arduino RH library for operating with HopeRF RH compatible transceivers // (see http://www.hoperf.com) // RHDatagram will be received only by the addressed node or all nodes within range if the // to address is RH_BROADCAST_ADDRESS // // Author: Mike McCauley (mikem@airspayce.com) // Copyright (C) 2011 Mike McCauley // $Id: RHMesh.cpp,v 1.9 2015/08/13 02:45:47 mikem Exp $ #include uint8_t RHMesh::_tmpMessage[RH_ROUTER_MAX_MESSAGE_LEN]; //////////////////////////////////////////////////////////////////// // Constructors RHMesh::RHMesh(RHGenericDriver& driver, uint8_t thisAddress) : RHRouter(driver, thisAddress) { } //////////////////////////////////////////////////////////////////// // Public methods //////////////////////////////////////////////////////////////////// // Discovers a route to the destination (if necessary), sends and // waits for delivery to the next hop (but not for delivery to the final destination) uint8_t RHMesh::sendtoWait(uint8_t* buf, uint8_t len, uint8_t address, uint8_t flags) { if (len > RH_MESH_MAX_MESSAGE_LEN) return RH_ROUTER_ERROR_INVALID_LENGTH; if (address != RH_BROADCAST_ADDRESS) { RoutingTableEntry* route = getRouteTo(address); if (!route && !doArp(address)) return RH_ROUTER_ERROR_NO_ROUTE; } // Now have a route. Contruct an application layer message and send it via that route MeshApplicationMessage* a = (MeshApplicationMessage*)&_tmpMessage; a->header.msgType = RH_MESH_MESSAGE_TYPE_APPLICATION; memcpy(a->data, buf, len); return RHRouter::sendtoWait(_tmpMessage, sizeof(RHMesh::MeshMessageHeader) + len, address, flags); } //////////////////////////////////////////////////////////////////// bool RHMesh::doArp(uint8_t address) { // Need to discover a route // Broadcast a route discovery message with nothing in it MeshRouteDiscoveryMessage* p = (MeshRouteDiscoveryMessage*)&_tmpMessage; p->header.msgType = RH_MESH_MESSAGE_TYPE_ROUTE_DISCOVERY_REQUEST; p->destlen = 1; p->dest = address; // Who we are looking for uint8_t error = RHRouter::sendtoWait((uint8_t*)p, sizeof(RHMesh::MeshMessageHeader) + 2, RH_BROADCAST_ADDRESS); if (error != RH_ROUTER_ERROR_NONE) return false; // Wait for a reply, which will be unicast back to us // It will contain the complete route to the destination uint8_t messageLen = sizeof(_tmpMessage); // FIXME: timeout should be configurable unsigned long starttime = millis(); int32_t timeLeft; while ((timeLeft = RH_MESH_ARP_TIMEOUT - (millis() - starttime)) > 0) { if (waitAvailableTimeout(timeLeft)) { if (RHRouter::recvfromAck(_tmpMessage, &messageLen)) { if ( messageLen > 1 && p->header.msgType == RH_MESH_MESSAGE_TYPE_ROUTE_DISCOVERY_RESPONSE) { // Got a reply, now add the next hop to the dest to the routing table // The first hop taken is the first octet addRouteTo(address, headerFrom()); return true; } } } YIELD; } return false; } //////////////////////////////////////////////////////////////////// // Called by RHRouter::recvfromAck whenever a message goes past void RHMesh::peekAtMessage(RoutedMessage* message, uint8_t messageLen) { MeshMessageHeader* m = (MeshMessageHeader*)message->data; if ( messageLen > 1 && m->msgType == RH_MESH_MESSAGE_TYPE_ROUTE_DISCOVERY_RESPONSE) { // This is a unicast RH_MESH_MESSAGE_TYPE_ROUTE_DISCOVERY_RESPONSE messages // being routed back to the originator here. Want to scrape some routing data out of the response // We can find the routes to all the nodes between here and the responding node MeshRouteDiscoveryMessage* d = (MeshRouteDiscoveryMessage*)message->data; addRouteTo(d->dest, headerFrom()); uint8_t numRoutes = messageLen - sizeof(RoutedMessageHeader) - sizeof(MeshMessageHeader) - 2; uint8_t i; // Find us in the list of nodes that were traversed to get to the responding node for (i = 0; i < numRoutes; i++) if (d->route[i] == _thisAddress) break; i++; while (i++ < numRoutes) addRouteTo(d->route[i], headerFrom()); } else if ( messageLen > 1 && m->msgType == RH_MESH_MESSAGE_TYPE_ROUTE_FAILURE) { MeshRouteFailureMessage* d = (MeshRouteFailureMessage*)message->data; deleteRouteTo(d->dest); } } //////////////////////////////////////////////////////////////////// // This is called when a message is to be delivered to the next hop uint8_t RHMesh::route(RoutedMessage* message, uint8_t messageLen) { uint8_t from = headerFrom(); // Might get clobbered during call to superclass route() uint8_t ret = RHRouter::route(message, messageLen); if ( ret == RH_ROUTER_ERROR_NO_ROUTE || ret == RH_ROUTER_ERROR_UNABLE_TO_DELIVER) { // Cant deliver to the next hop. Delete the route deleteRouteTo(message->header.dest); if (message->header.source != _thisAddress) { // This is being proxied, so tell the originator about it MeshRouteFailureMessage* p = (MeshRouteFailureMessage*)&_tmpMessage; p->header.msgType = RH_MESH_MESSAGE_TYPE_ROUTE_FAILURE; p->dest = message->header.dest; // Who you were trying to deliver to // Make sure there is a route back towards whoever sent the original message addRouteTo(message->header.source, from); ret = RHRouter::sendtoWait((uint8_t*)p, sizeof(RHMesh::MeshMessageHeader) + 1, message->header.source); } } return ret; } //////////////////////////////////////////////////////////////////// // Subclasses may want to override bool RHMesh::isPhysicalAddress(uint8_t* address, uint8_t addresslen) { // Can only handle physical addresses 1 octet long, which is the physical node address return addresslen == 1 && address[0] == _thisAddress; } //////////////////////////////////////////////////////////////////// bool RHMesh::recvfromAck(uint8_t* buf, uint8_t* len, uint8_t* source, uint8_t* dest, uint8_t* id, uint8_t* flags) { uint8_t tmpMessageLen = sizeof(_tmpMessage); uint8_t _source; uint8_t _dest; uint8_t _id; uint8_t _flags; if (RHRouter::recvfromAck(_tmpMessage, &tmpMessageLen, &_source, &_dest, &_id, &_flags)) { MeshMessageHeader* p = (MeshMessageHeader*)&_tmpMessage; if ( tmpMessageLen >= 1 && p->msgType == RH_MESH_MESSAGE_TYPE_APPLICATION) { MeshApplicationMessage* a = (MeshApplicationMessage*)p; // Handle application layer messages, presumably for our caller if (source) *source = _source; if (dest) *dest = _dest; if (id) *id = _id; if (flags) *flags = _flags; uint8_t msgLen = tmpMessageLen - sizeof(MeshMessageHeader); if (*len > msgLen) *len = msgLen; memcpy(buf, a->data, *len); return true; } else if ( _dest == RH_BROADCAST_ADDRESS && tmpMessageLen > 1 && p->msgType == RH_MESH_MESSAGE_TYPE_ROUTE_DISCOVERY_REQUEST) { MeshRouteDiscoveryMessage* d = (MeshRouteDiscoveryMessage*)p; // Handle Route discovery requests // Message is an array of node addresses the route request has already passed through // If it originally came from us, ignore it if (_source == _thisAddress) return false; uint8_t numRoutes = tmpMessageLen - sizeof(MeshMessageHeader) - 2; uint8_t i; // Are we already mentioned? for (i = 0; i < numRoutes; i++) if (d->route[i] == _thisAddress) return false; // Already been through us. Discard // Hasnt been past us yet, record routes back to the earlier nodes addRouteTo(_source, headerFrom()); // The originator for (i = 0; i < numRoutes; i++) addRouteTo(d->route[i], headerFrom()); if (isPhysicalAddress(&d->dest, d->destlen)) { // This route discovery is for us. Unicast the whole route back to the originator // as a RH_MESH_MESSAGE_TYPE_ROUTE_DISCOVERY_RESPONSE // We are certain to have a route there, because we just got it d->header.msgType = RH_MESH_MESSAGE_TYPE_ROUTE_DISCOVERY_RESPONSE; RHRouter::sendtoWait((uint8_t*)d, tmpMessageLen, _source); } else if (i < _max_hops) { // Its for someone else, rebroadcast it, after adding ourselves to the list d->route[numRoutes] = _thisAddress; tmpMessageLen++; // Have to impersonate the source // REVISIT: if this fails what can we do? RHRouter::sendtoFromSourceWait(_tmpMessage, tmpMessageLen, RH_BROADCAST_ADDRESS, _source); } } } return false; } //////////////////////////////////////////////////////////////////// bool RHMesh::recvfromAckTimeout(uint8_t* buf, uint8_t* len, uint16_t timeout, uint8_t* from, uint8_t* to, uint8_t* id, uint8_t* flags) { unsigned long starttime = millis(); int32_t timeLeft; while ((timeLeft = timeout - (millis() - starttime)) > 0) { if (waitAvailableTimeout(timeLeft)) { if (recvfromAck(buf, len, from, to, id, flags)) return true; YIELD; } } return false; }