A multi-logical port data traffic stream preservation system includes a networking device coupled to a computing device via its physical port, a first networking fabric via a first uplink, and a second networking fabric via a second uplink. The networking device receives communications from the computing device that identify first and second logical ports provided using the physical port on the computing device, a first data traffic type associated with the first networking fabric and transmitted on the first logical port, and a second data traffic type associated with the second networking fabric and transmitted on the second logical port. If the first uplink becomes unavailable, the networking device transmits a communication to the computing device that causes the computing device to stop transmitting the first data traffic type via the first logical port while continuing to transmit the second data traffic type via the second logical port.

An example operation may include a system, comprising one or more of receiving a heartbeat message from a peer virtualization network function component interface (VFCNI) indicating a current operational state of active when a VNFCI is in an active state, sending a first heartbeat message to the peer VNFCI indicating a current operational state as active, sending a next state request with an active state and split-brain condition to a virtual network function manager (VNFM), starting a response timer, sending a second heartbeat message to the peer VNFCI indicating the current operational state as active and a desired operational state as active when one or more of: the VNFCI is not a preferred standby instance, the response timer expires, stopping the response timer when a next state response message is received, sending a third heartbeat message to the peer VNFCI indicating the current operational state as active and a desired operational state as active when and an active state is contained in the next state response message, and transitioning a state of the VNFCI to a deactivating state when one or more of: the VCNFI is the preferred standby instance, and a standby state is contained in the next state response message.

A method of configuring at least one switch involves configuring the at least one switch to direct communication to at least one of a plurality of computers according to at least one outcome of simulated interaction of a plurality of virtual network routers. A method of simulating interaction of a plurality of virtual network routers involves: causing a first at least one processor circuit to simulate the interaction of the plurality of virtual network routers; and causing a second at least one processor circuit, different from the first at least one processor circuit, to simulate the interaction of the plurality of virtual network routers redundantly to the simulated interaction of the plurality of virtual network routers on the first at least one processor circuit. Apparatuses and computer-readable media are also disclosed.

A network includes a plurality of nodes and a plurality of links communicatively coupling each of the nodes to at least one respective adjacent node via a first communication channel and to another respective adjacent node via a second communication channel. The nodes and links have a braided ring topology. First and second nodes of the plurality of nodes source data, are adjacent nodes, and at least one is a source node. The first node sends a first communication to the second node via a third node that is adjacent the first node and via a fourth node that is adjacent the second node. The second node sends a second communication to the first node via the third node and via the fourth node. At least one of the first and second nodes terminates transmission of the first and second communications when the first and second communications do not match.

A relay apparatus includes: ports for transmitting and receiving communication data; a relay process portion that executes a relay process of transmitting the communication data received from at least one of the ports, from a destination port corresponding to the at least one of the ports connected to a destination device in accordance with a destination for the communication data; and a setting portion that, by an instruction from at least one external device, sets each of the ports to either a relay prohibition state in which relay of the communication data is prohibited or a relay allowance state in which the relay of the communication data is allowed. When the destination port, the relay process portion discards the received communication data without saving the received communication data.

A logical Network Interface Device (NID) includes a first NID connected to a peer NID; a second NID connected to the peer NID and communicatively coupled to the first NID, wherein the first NID and the second NID are each connected to a network element for redundant communication to the peer NID, and wherein the first NID actively operates an active maintenance endpoint in an Operations, Administration, and Maintenance (OAM) session with the peer NID, and wherein the active maintenance endpoint synchronizes OAM session data with a dormant maintenance endpoint at the second NID. The dormant maintenance endpoint becomes the active maintenance endpoint responsive to a protection switch, and the dormant maintenance endpoint has the OAM session data in a database based on synchronization with the first NID.

An embodiment is directed to switchover operations with a virtualized network device in a cloud or remote infrastructure. The virtualized hardware switchover operations may be used to selectively and temporarily provide virtualized control-plane operations to the data-plane of a non-redundant network device undergoing an upgrade or a reboot of its control plane. A non-redundant network device may operate hitless, or near hitless, operation even when its control plane is unavailable.

A multi-logical port data traffic stream preservation system includes a networking device coupled to a computing device via its physical port, a first networking fabric via a first uplink, and a second networking fabric via a second uplink. The networking device receives communications from the computing device that identify first and second logical ports provided using the physical port on the computing device, a first data traffic type associated with the first networking fabric and transmitted on the first logical port, and a second data traffic type associated with the second networking fabric and transmitted on the second logical port. If the first uplink becomes unavailable, the networking device transmits a communication to the computing device that causes the computing device to stop transmitting the first data traffic type via the first logical port while continuing to transmit the second data traffic type via the second logical port.

Technology is described for receiving a request for data packets at a server from a device. The server may determine a predicted number of data packets that are expected to be lost during fulfillment of the request based in part on a device profile. The server may send, in response to the request, the requested data packets and parity packets to the device. The number of parity packets may be based on the predicted number of data packets. The parity packets may enable the device to rebuild requested data packets that are lost during fulfillment of the request.

An embodiment is directed to switchover operations with a mobile virtualized network device in a mobile device. The mobile virtualized hardware switchover operations may be used to selectively and temporarily provide virtualized control-plane operations to the data-plane of a non-redundant network device undergoing an upgrade or a reboot of its control plane. A non-redundant network device may operate hitless, or near hitless, operation even when its control plane is unavailable.