Provided is a machine-implemented method of operating a device, comprising entering the device into a membership relation with a first self-organizing subnet at a first rank in a hierarchy of subnets of the network; receiving at the device a message from a second device making known parameters of a second subnet at a second rank in the hierarchy of subnets of the network; and responsive to receipt of the message, sending a message from the first device making known parameters of the first subnet at the first rank to the second device to render the subnet at the second rank operable to merge with the subnet at the first rank.

A method and system for a first node to transmit packets to a second none, comprising receiving a packet from a local area network (LAN) interface, inspecting the packet; determining whether the packet satisfies at least one packet condition; transmitting the packet through a predefined tunnel if the packet satisfies the at least one packet condition; transmitting the packet through a second tunnel if the packet does not satisfy the at least one packet condition. The predefined tunnel is a first tunnel and is established before the packet is received by the first node. The second tunnel belongs to a first tunnel group or a second tunnel group. The first tunnel, the second tunnel and other tunnels may together form an aggregated connection. Further, the use of predefined tunnel may be based on whether the packets satisfy a session condition.

A network includes a plurality of endpoint routers and intermediate routers. When a new data stream is detected at any endpoint router, the first packet is sent to a virtual routing server with knowledge of the entire network topology. Based on the topology, current usage, and historical usage, the virtual routing server determined a path for the data stream and begins to update the routing tables of the intermediate routers to reflect the determined path. Until the update is complete, all packets in the data stream are routed first to the virtual routing server and then to their destination. Once the update is complete, packets in the data stream are routed directly along the determined path.

Methods and apparatus are disclosed for transmitting flows of data units across a data communication network from a transmitting node towards an intended destination via one or more intermediate nodes, the data units having destination indications, the intermediate nodes being configured to receive data units, identify therefrom a transmission mode that has been selected from at least two transmission modes for the data units, and forward the data units according to the selected transmission mode. The method involves selecting a transmission mode for the flow in dependence on an estimate of the difference in the amount of a resource required to transmit the flow by one or the other transmission mode, a resource-usage measure indicative of the amount of the resource required to identify a route and reserve sufficient capacity thereon for transmission of the flow, and a probability measure indicative of a likelihood of success of an attempt to identify and reserve sufficient capacity for the flow.

An illustrative embodiment disclosed herein is an apparatus including a processor having programmed instructions to determine that a first packet, received from a first VM on a first host, has a destination address associated with a second VM on the first host, send the first packet to a service-focused bridge, generate a rule to redirect the first packet to the second VM based on the destination address, and generate execute the rule in response to receiving the first packet from the service-focused bridge.

A computer system for communicating with an industrial system includes: a data collection server for receiving equipment data from the industrial system and providing a data stream by pre-processing the equipment data according to a plurality of pre-determined rules; a first uni-directional interface for transmitting the data stream to one or more further computer systems; and a second uni-directional interface for receiving a data packet from the one or more further computer systems, the data packet including a control instruction that allows a modification of at least a particular rule of the plurality of the pre-determined rules. The first uni-directional interface includes a data diode. The second unidirectional interface receives the control instruction in a first part of the data packet. The first uni-directional interface receives the first part of the data packet in a size limitation that corresponds to amounts of data required to identify the modification.

A communication control system includes a first processor, and a second processor coupled to the first processor via a plurality of communication lines and the second processor configured to select, for each packet of a plurality of packets, a communication line from the plurality of communication lines in specific order, and sequentially transmit each packet of the plurality of packets by using the selected communication line of the plurality of communication lines, wherein the first processor is configured to sequentially receive each packet of the plurality of packets by selecting a communication line from the plurality of communication lines in the specific order.

A system and method for facilitating communication between one or more of a plurality of user virtual machines and external devices is disclosed. The system includes a plurality of uplink bridges configured to facilitate communication between the plurality of user virtual machines and the external devices, a plurality of local bridges, with each of the plurality of user virtual machines being connected to one or more of the plurality of local bridges, and a first multiplexing bridge connected to the plurality of local bridges. The first multiplexing bridge is configured to direct data between the plurality of user virtual machines and the plurality of uplink bridges. The system also includes a second multiplexing bridge connected to the first multiplexing bridge and the plurality of uplink bridges. The second multiplexing bridge is configured to direct the data between the first multiplexing bridge and the plurality of uplink bridges.

Provided is a virtual circuit-based data packet processing method, which includes that: identification information of a next-hop Provider Edge (PE) node of a routing packet and identification information of an Original PE (OPE) node of the routing packet are determined according to the routing packet corresponding to a Virtual Private Network (VPN) service instance; a context virtual circuit is determined, wherein nodes at both ends of the context virtual circuit are respectively the current PE node and the OPE node; a virtual circuit label of the context virtual circuit is determined; a final data packet to be forwarded is obtained by carrying a VPN label of the routing packet and the virtual circuit label with an initial data packet of the VPN service instance; and the final data packet to be forwarded is forwarded to the next-hop PE node.

A method for connecting graph processing cut endpoints is disclosed. The method comprises determining a first capability matrix comprising capability values, applying weights to the capability values of the first capability matrix resulting in a first weighted capability matrix, and determining a second capability matrix comprising, for each pairing of another side of the cut endpoint, capability values. For both, the first capability matrix and second capability matrix, the capability values relate at least to a platform, a runtime framework, a connection technology, a protocol for a connection of a node of the stream processing system. The method comprises further determining a joint weighted capability matrix for two corresponding cut endpoints of a cut by multiplying corresponding capability matrix values of the first weighted capability matrix and the second capability matrix, and selecting a preferred connection for the cut endpoints.