Embodiments of this application disclose an information reporting method, an information processing method, an apparatus, and a device. The method in embodiments of this application includes the network device obtains a routing prefix included in local routing information, and information about a neighboring peer set corresponding to the routing prefix, and sends a local route monitoring message including the routing prefix and the information about the neighboring peer set to a first device. The neighboring peer set includes a source peer set and/or a destination peer set, the source peer set includes one or more source peers, the source peer is a peer that advertises original routing information including the routing prefix to the network device, the destination peer set includes one or more destination peers, and the destination peer is a peer to which the network device advertises destination routing information including the routing prefix.

Systems, apparatuses, and methods may provide for robust and autonomous provisioning of routing nodes and/or server stacks within a network. For instance, each routing node and/or server stack may perform self-discovery (e.g., determines its own identity and where it has been placed in the network), and determine its role (e.g., how to route packets) within the network.

Technologies for multi-cloud routing and policy interconnectivity are provided. An example method can include assigning different sets of data plane routers to data plane traffic associated with different address spaces in a cloud site of a multi-cloud fabric to yield a distributed mapping of data plane traffic and data plane routers. The method can further include providing, to an on-premises site in the multi-cloud fabric, routing entries from a control plane router on the cloud site, the routing entries reflecting the distributed mapping and identifying, for each address space, which data plane router handles data plane traffic for that address space; and when a data plane router is deployed at the cloud site, providing, to the on-premises site, updated routing information from the control plane router, the updated routing information identifying the data plane router as a next hop for data plane traffic associated with a respective address space.

Various methods are provided for facilitating the assignment of a DNS name to load balancers in a dynamically partitioned cluster environment. One example method may comprise receiving cluster configuration information from a cluster configuration observer, the cluster configuration information comprising information indicative of each of a plurality of instances of running application and one or more servers and associated ports to which at least one of the plurality of instances is bound, receiving a request from a first level load balancer requiring a call to the first application, determining, based on the cluster configuration information, to which port the instance of the first application is bound, and transmitting the request to the port to which the instance of the first application is bound.

Some embodiments of the invention provide a method of facilitating routing through a software-defined wide area network (SD-WAN) defined for an entity. A first edge forwarding node located at a first multi-machine site of the entity, the first multi-machine site at a first physical location and including a first set of machines, serves as an edge forwarding node for the first set of machines by forwarding packets between the first set of machines and other machines associated with the entity via other forwarding nodes in the SD-WAN. The first edge forwarding node receives configuration data specifying for the first edge forwarding node to serve as a hub forwarding node for forwarding a set of packets from a second set of machines associated with the entity and operating at a second multi-machine site at a second physical location to a third set of machines associated with the entity and operating at a third multi-machine site at a third physical location. The first edge forwarding node serves as a hub forwarding node to forward the set of packets from the second set of machines to the third set of machines.

To improve the efficiency and reliability of communication, such as for control commands distribution and data collection, in a large and high density wireless control system (100), each one of a plurality of nodes in the system is assigned one out of three roles, a router node (200), a non-router node (300), or a data collector node (400). A node (200, 300, 400) in the wireless control system (100) is capable to operate according to at least one of two communication protocols. A first communication protocol is capable to support mesh or tree network with multi-hop routing, while a second communication protocol is capable to support a star network with point-to-point connection. The router nodes build up a sparse multi-hop network to guarantee the connectivity of the large-scale network. Around each router node within one-hop direct link, a local star network is built up with at least one non-router node and at least one data collector node.

A method implemented by a first node in a segment routing (SR) network domain includes receiving, from a second node of another network domain, a packet configured to pass through the SR network domain in accordance with segment identifiers (SIDs). The method also includes obtaining compressed SIDs corresponding to some of the SIDs. The method includes generating a segment routing header (SRH) having a list of segments. The method further includes adding the SRH to the packet and forwarding the packet with the SRH to a third node in the SR network domain.

Provided are a BIER packet forwarding method and apparatus, a device and a storage medium. The BIER packet forwarding method is applied to a packet sending node and includes: setting node information of a BIER forwarding neighboring node in a BIFT forwarding entry; in a case of determining according to the node information that the BIER forwarding neighboring node has a capability of processing a target packet format, encapsulating a BIER packet according to the target packet format; and sending an encapsulated BIER packet to the BIER forwarding neighboring node.

The present application relates to egressing traffic from a public cloud network. An egress traffic manager configures routing at hosts and edge routers within the public cloud network. The egress traffic manager determines, for an edge router, a plurality of current border gateway protocol (BGP) sessions with external networks. The egress traffic manager configures a virtual router hosted on the edge router to route a portion of egress traffic to a selected one of the external networks via one of the BGP sessions. A host is configured to route the portion of egress traffic within the public cloud network to the edge router. An edge router configured to route, by the virtual router, the portion of egress traffic from the edge router to the selected one of the external networks.

The present technology provides a system and method for implementing targeted collection of in-situ Operation, Administration and Maintenance data from select nodes in a Segment Routing Domain. The selection is programmable and is implemented by setting an iOAM bit in the function arguments field of a Segment Identifier. In this way only the nodes associated with local Segment Identifiers (Function field of a Segment Identifier) with an iOAM argument bit are directed to generate iOAM data. The iOAM data generated by target nodes may be stored in TLV field of the segment routing header. The Segment Routing packet is then decapsulated at a Segment Routing egress node and the Header information with the collected iOAM data is sent to a controller entity for further processing, analysis and/or monitoring.