void NodeHandshakeExtension::HandshakeEndpoint::query(const dtn::data::EID &origin)
		{
			{
				ibrcommon::MutexLock l(_blacklist_lock);
				// only query once each 60 seconds
				if (_blacklist[origin] > dtn::utils::Clock::getUnixTimestamp()) return;
				_blacklist[origin] = dtn::utils::Clock::getUnixTimestamp() + 60;
			}

			// create a new request for the summary vector of the neighbor
			NodeHandshake request(NodeHandshake::HANDSHAKE_REQUEST);

			// walk through all extensions to generate a request
			(*_callback).requestHandshake(origin, request);

			IBRCOMMON_LOGGER_DEBUG_TAG(NodeHandshakeExtension::TAG, 15) << "handshake query from " << origin.getString() << ": " << request.toString() << IBRCOMMON_LOGGER_ENDL;

			// create a new bundle
			dtn::data::Bundle req;

			// set the source of the bundle
			req.source = getWorkerURI();

			// set the destination of the bundle
			req.set(dtn::data::PrimaryBlock::DESTINATION_IS_SINGLETON, true);

			if (origin.isCompressable())
				req.destination = origin.add(origin.getDelimiter() + "50");
			else
				req.destination = origin.add(origin.getDelimiter() + "routing");

			// limit the lifetime to 60 seconds
			req.lifetime = 60;

			// set high priority
			req.set(dtn::data::PrimaryBlock::PRIORITY_BIT1, false);
			req.set(dtn::data::PrimaryBlock::PRIORITY_BIT2, true);

			dtn::data::PayloadBlock &p = req.push_back<PayloadBlock>();
			ibrcommon::BLOB::Reference ref = p.getBLOB();

			// serialize the request into the payload
			{
				ibrcommon::BLOB::iostream ios = ref.iostream();
				(*ios) << request;
			}

			// add a schl block
			dtn::data::ScopeControlHopLimitBlock &schl = req.push_front<dtn::data::ScopeControlHopLimitBlock>();
			schl.setLimit(1);

			// add an age block (to prevent expiring due to wrong clocks)
			req.push_front<dtn::data::AgeBlock>();

			// send the bundle
			transmit(req);
		}
		void DeliveryPredictabilityMap::update(const dtn::data::EID &host_b, const DeliveryPredictabilityMap &dpm, const float &p_encounter_first)
		{
			float p_ab = 0.0f;

			try {
				p_ab = get(host_b);
			} catch (const DeliveryPredictabilityMap::ValueNotFoundException&) {
				p_ab = p_encounter_first;
			}

			/**
			 * Calculate transitive values
			 */
			for (predictmap::const_iterator it = dpm._predictmap.begin(); it != dpm._predictmap.end(); ++it)
			{
				const dtn::data::EID &host_c = it->first;
				const float &p_bc = it->second;

				// do not update values for the origin host
				if (host_b.sameHost(host_c)) continue;

				// do not process values with our own EID
				if (dtn::core::BundleCore::local.sameHost(host_c)) continue;

				predictmap::iterator dp_it;
				if ((dp_it = _predictmap.find(host_c)) != _predictmap.end()) {
					dp_it->second = std::max(dp_it->second, p_ab * p_bc * _beta);
				} else {
					_predictmap[host_c] = p_ab * p_bc * _beta;
				}
			}
		}
Example #3
0
		bool ForwardingStrategy::isBackrouteValid(const DeliveryPredictabilityMap& neighbor_dpm, const dtn::data::EID& source) const
		{
			ibrcommon::MutexLock dpm_lock(_prophet_router->_deliveryPredictabilityMap);

			// check if we know a way to the source
			try {
				if (_prophet_router->_deliveryPredictabilityMap.get(source.getNode()) > 0.0) return true;
			} catch (const dtn::routing::DeliveryPredictabilityMap::ValueNotFoundException&) { }

			// check if the peer know a way to the source
			try {
				if (neighbor_dpm.get(source.getNode()) > 0.0) return true;
			} catch (const dtn::routing::DeliveryPredictabilityMap::ValueNotFoundException&) { }

			return false;
		}
Example #4
0
		bool ForwardingStrategy::neighborDPIsGreater(const DeliveryPredictabilityMap& neighbor_dpm, const dtn::data::EID& destination) const
		{
			const dtn::data::EID destnode = destination.getNode();

			try {
				float local_pv = 0.0f;

				// get the local value
				{
					ibrcommon::MutexLock dpm_lock(_prophet_router->_deliveryPredictabilityMap);
					const DeliveryPredictabilityMap& dp_map = _prophet_router->_deliveryPredictabilityMap;
					local_pv = dp_map.get(destnode);
				}

				try {
					// retrieve the value from the DeliveryPredictabilityMap of the neighbor
					float foreign_pv = neighbor_dpm.get(destnode);

					return (foreign_pv > local_pv);
				} catch (const DeliveryPredictabilityMap::ValueNotFoundException&) {
					// if the foreign router has no entry for the destination
					// then compare the local value with a fictitious initial value
					return (_prophet_router->_p_first_threshold > local_pv);
				}
			} catch (const DeliveryPredictabilityMap::ValueNotFoundException&) {
				// always forward if the destination is not in our own predictability map
			}

			return false;
		}
		std::string KeyExchangeSession::getSessionKey(const dtn::data::EID &peer, unsigned int uniqueId)
		{
			// generate session key
			std::stringstream sstm;
			sstm << uniqueId << "." << peer.getString();

			return sstm.str();
		}
		KeyExchangeSession::KeyExchangeSession(int protocol, const dtn::data::EID &peer, unsigned int uniqueId, SessionState *state)
		: _protocol(protocol), _unique_id(uniqueId), _peer(peer.getNode()), _state(state), _expiration(0)
		{
			// generate session key
			_session_key = getSessionKey(_peer, _unique_id);

			// set a expiration time (10 minutes)
			_expiration = dtn::utils::Clock::getMonotonicTimestamp() + 600;
		}
		dtn::security::SecurityKey SecurityKeyManager::get(const dtn::data::EID &ref, const dtn::security::SecurityKey::KeyType type) const throw (SecurityKey::KeyNotFoundException)
		{
			dtn::security::SecurityKey keydata;
			keydata.reference = ref.getNode();
			keydata.type = type;
			keydata.file = getKeyFile(keydata.reference, type);

			// load security key
			load(keydata);

			return keydata;
		}
void dtn::dht::DHTNameService::lookup(const dtn::data::EID &eid) {
	if (!dtn::core::BundleCore::local.sameHost(eid)) {
		if (this->_announced) {
			std::string eid_ = eid.getNode().getString();
			IBRCOMMON_LOGGER_DEBUG_TAG("DHTNameService", 30) << "DHT Lookup: " << eid_
						<< IBRCOMMON_LOGGER_ENDL;
			ibrcommon::MutexLock l(this->_libmutex);
			dtn_dht_lookup(&_context, eid_.c_str(), eid_.size());
		} else {
			this->cachedLookups.push_front(eid);
		}
	}
}
Example #9
0
		void NativeSession::removeRegistration(const dtn::data::EID &eid) throw (NativeSessionException)
		{
			// error checking
			if (eid == dtn::data::EID())
			{
				throw NativeSessionException("given endpoint is not acceptable");
			}
			else
			{
				_registration.unsubscribe(eid);
			}

			IBRCOMMON_LOGGER_DEBUG_TAG(NativeSession::TAG, 20) << "Registration " << eid.getString() << " removed" << IBRCOMMON_LOGGER_ENDL;
		}
		void PayloadIntegrityBlock::sign(dtn::data::Bundle &bundle, const SecurityKey &key, const dtn::data::EID& destination)
		{
			PayloadIntegrityBlock& pib = bundle.push_front<PayloadIntegrityBlock>();
			pib.set(REPLICATE_IN_EVERY_FRAGMENT, true);

			// check if this is a fragment
			if (bundle.get(dtn::data::PrimaryBlock::FRAGMENT))
			{
				dtn::data::PayloadBlock& plb = bundle.find<dtn::data::PayloadBlock>();
				ibrcommon::BLOB::Reference blobref = plb.getBLOB();
				ibrcommon::BLOB::iostream stream = blobref.iostream();
				addFragmentRange(pib._ciphersuite_params, bundle.fragmentoffset, stream.size());
			}

			// set the source and destination address of the new block
			if (!key.reference.sameHost(bundle.source)) pib.setSecuritySource( key.reference );
			if (!destination.sameHost(bundle.destination)) pib.setSecurityDestination( destination );

			pib.setResultSize(key);
			pib.setCiphersuiteId(SecurityBlock::PIB_RSA_SHA256);
			pib._ciphersuite_flags |= CONTAINS_SECURITY_RESULT;
			std::string sign = calcHash(bundle, key, pib);
			pib._security_result.set(SecurityBlock::integrity_signature, sign);
		}
Example #11
0
		/**
		 * Transfer one bundle to another node.
		 * @param destination The EID of the other node.
		 * @param id The ID of the bundle to transfer. This bundle must be stored in the storage.
		 */
		void RoutingExtension::transferTo(const dtn::data::EID &destination, const dtn::data::MetaBundle &meta)
		{
			// acquire the transfer of this bundle, could throw already in transit or no resource left exception
			{
				// lock the list of neighbors
				ibrcommon::MutexLock l((**this).getNeighborDB());

				// get the neighbor entry for the next hop
				NeighborDatabase::NeighborEntry &entry = (**this).getNeighborDB().get(destination, true);

				// acquire the transfer, could throw already in transit or no resource left exception
				entry.acquireTransfer(meta);
			}

			try {
				// create a new bundle transfer object
				dtn::net::BundleTransfer transfer(destination, meta);

				// transfer the bundle to the next hop
				dtn::core::BundleCore::getInstance().getConnectionManager().queue(transfer);

				IBRCOMMON_LOGGER_DEBUG_TAG(RoutingExtension::TAG, 20) << "bundle " << meta.toString() << " queued for " << destination.getString() << IBRCOMMON_LOGGER_ENDL;
			} catch (const dtn::core::P2PDialupException&) {
				// lock the list of neighbors
				ibrcommon::MutexLock l((**this).getNeighborDB());

				// get the neighbor entry for the next hop
				NeighborDatabase::NeighborEntry &entry = (**this).getNeighborDB().get(destination);

				// release the transfer
				entry.releaseTransfer(meta);

				// and abort the query
				throw NeighborDatabase::NeighborNotAvailableException();
			} catch (const ibrcommon::Exception &e) {
				// ignore any other error
			}
		}
Example #12
0
		void KeyExchangeEvent::raise(const dtn::data::EID &eid, const dtn::security::KeyExchangeData &data)
		{
			// raise the new event
			dtn::core::EventDispatcher<KeyExchangeEvent>::queue( new KeyExchangeEvent(eid.getNode(), data) );
		}
Example #13
0
		void NodeHandshakeExtension::HandshakeEndpoint::query(const dtn::data::EID &origin)
		{
			{
				ibrcommon::MutexLock l(_blacklist_lock);
				// only query once each 60 seconds
				if (_blacklist[origin] > dtn::utils::Clock::getMonotonicTimestamp()) return;
				_blacklist[origin] = dtn::utils::Clock::getMonotonicTimestamp() + 60;
			}

			// create a new request for the summary vector of the neighbor
			NodeHandshake request(NodeHandshake::HANDSHAKE_REQUEST);

#ifdef IBRDTN_SUPPORT_COMPRESSION
			// request compressed answer
			request.addRequest(NodeHandshakeItem::REQUEST_COMPRESSED_ANSWER);
#endif

			// walk through all extensions to generate a request
			(*_callback).requestHandshake(origin, request);

			IBRCOMMON_LOGGER_DEBUG_TAG(NodeHandshakeExtension::TAG, 15) << "handshake query from " << origin.getString() << ": " << request.toString() << IBRCOMMON_LOGGER_ENDL;

			// create a new bundle with a zero timestamp (+age block)
			dtn::data::Bundle req(true);

			// set the source of the bundle
			req.source = getWorkerURI();

			// set the destination of the bundle
			req.set(dtn::data::PrimaryBlock::DESTINATION_IS_SINGLETON, true);
			req.destination = origin;

			// set destination application
			req.destination.setApplication("routing");

			// limit the lifetime to 60 seconds
			req.lifetime = 60;

			// set high priority
			req.set(dtn::data::PrimaryBlock::PRIORITY_BIT1, false);
			req.set(dtn::data::PrimaryBlock::PRIORITY_BIT2, true);

			dtn::data::PayloadBlock &p = req.push_back<PayloadBlock>();
			ibrcommon::BLOB::Reference ref = p.getBLOB();

			// serialize the request into the payload
			{
				ibrcommon::BLOB::iostream ios = ref.iostream();
				(*ios) << request;
			}

			// add a schl block
			dtn::data::ScopeControlHopLimitBlock &schl = req.push_front<dtn::data::ScopeControlHopLimitBlock>();
			schl.setLimit(1);

			// send the bundle
			transmit(req);
		}