Some embodiments provide a method for an edge computing device in a first datacenter that implements a logical network gateway for processing data traffic for a particular LFE between the first datacenter and multiple other datacenters. For each particular other datacenter, the method stores a record that maps logical network addresses for DCNs connected to the particular LFE and operating in the particular datacenter to a group of TEP addresses corresponding to logical network gateways that handle data traffic for the particular LFE between the particular datacenter and the other datacenters, including the first datacenter. Upon receiving a data message for the particular LFE from a host computer in the first datacenter, the method uses a destination address of the data message to identify one of the groups of TEP addresses. The method encapsulates the data message with one of the TEP addresses from the identified group of TEP addresses.

Some embodiments provide a method for configuring an edge computing device to implement a logical router belonging to a logical network. The method configures a datapath executing on the edge computing device to use a first routing table associated with the logical router for processing data messages routed to the logical router. The method configures a routing protocol application executing on the edge computing device to (i) use the first routing table for exchanging routes with a network external to the logical network and (ii) use a second routing table for exchanging routes with other edge computing devices that implement the logical router.

Some embodiments provide a method for a first edge device in a first datacenter that implements a centralized routing component of a logical router that spans multiple datacenters and handles data traffic between a logical network implemented across the multiple datacenters and external networks. From a second edge device in a second datacenter, the method receives via routing protocol a route having a particular routing protocol tag. When the first datacenter is a primary datacenter for the logical router such that all data traffic between the logical network and the external networks is handled by one or more centralized routing components implemented at the first datacenter, the method uses the routing protocol tag to determine whether to advertise the received route to the external networks.

Some embodiments provide a method for implementing a logical network across multiple datacenters. The method receives a configuration for a logical router that handles data traffic between the logical network implemented in the plurality of datacenters and networks external to the logical network. The method, for each datacenter defines (i) an active centralized routing component of the logical router in the datacenter and (ii) a standby centralized routing component of the logical router in the datacenter. The centralized routing components for a particular datacenter handle the data traffic between the logical network in the particular datacenter and the external networks. The active and standby centralized routing components are each assigned to edge computing devices in the datacenter that implement the centralized routing components.

Some embodiments provide a method for implementing a logical router that spans multiple datacenters. The method receives a configuration for a set of logical switches and a logical router (LR) that (i) handles data traffic between data compute nodes (DCNs) connected to the logical switches and endpoints not connected to the set of logical switches and (ii) performs stateful services on the traffic. The DCNs include at least one DCN operating in each datacenter. For each datacenter, the method defines a centralized routing component (SR) for the LR for handling the traffic between the DCNs in the datacenter and the endpoints not connected to the set of logical switches. The method designates one of the SRs as a primary SR and the other SRs as secondary SRs. The secondary SRs forward traffic, received from DCNs in their respective datacenters and for which stateful services are required, to the primary SR.

Some embodiments provide a method for an MFE, in a first datacenter, to implement an LN spanning the first datacenter and a set of additional datacenters. The method stores records that each map one or more LN addresses for DCNs belonging to the LN and operating in the first datacenter to a different TEP address. The method stores an additional record that maps addresses for DCNs connected to a particular LFE of the LN and operating in the additional datacenters to a group of TEP addresses corresponding to LN gateways that handle data traffic for the particular LFE between the first datacenter and the additional datacenters. Upon receiving a data message with a destination address corresponding to a DCN connected to the particular LFE and operating in one of the additional datacenters, the method uses the additional record to identify a TEP address for encapsulating the data message.

Some embodiments provide a method for a computing device that implements a first logical network gateway in a first datacenter to process data messages between data compute nodes (DCNs) belonging to the logical network and operating in the first datacenter and DCNs belonging to the logical network and operating in a second datacenter. From a host computer in the first datacenter, the method receives a logical network data message encapsulated with a first tunnel header including a first virtual network identifier corresponding to a logical forwarding element of the logical network. The method removes the first tunnel header and encapsulates the logical network data message with a second tunnel header include a second virtual network identifier corresponding to the logical forwarding element. The method transmits the logical network data message encapsulated with the second tunnel header to a second logical network gateway in the second datacenter.

The present disclosure relates to a 5G or pre-5G communication system to be provided for supporting a data rate higher than that of a 4G communication system such as LTE. A dynamic resource allocation method of an intelligent orchestrator in a software-defined network (SDN) according to the present invention includes acquiring operation data related to resource allocation in the SDN, adjusting at least one of virtual switch and host parameters based on the operation data and a preconfigured scheduling policy, and allocating resources dynamically according to the adjustment result.

[Problem] Connection between a centralized control apparatus and a group of transfer apparatuses can be prevented from having a single point of failure. Traffic can be distributed among a plurality of paths. A bypass path is selected when a failure occurs in a switch cluster.

[Solution] Transfer apparatuses 61a to 61d perform communications for path control with a centralized control apparatus 73 that performs centralized control from the outside of a switch cluster including the group of transfer apparatuses, through a path similar to D-plane (main signal). A packet flow controller 87 serving as a separation unit that separates a packet for the inside of the cluster 61 and a packet for the outside of the cluster transmitted through the similar path from each other, and an internal route engine 85 that performs path control of obtaining a path for freely passing through a plurality of paths in the cluster are provided. The packet flow controller 87 separates a path control packet for the inside of the cluster, and the engine 85 performs, when a failure to communicate the path control packet for the inside thus separated occurs, path control of generating a path that bypasses a path with the failure.

Systems and methods for dynamically assigning membership in a data partition to an end-port of a requesting host channel adapter. An exemplary embodiment can provide a subnet manager configured to operate within a subnet of a network fabric. The subnet can include a plurality of nodes, and the plurality of nodes can include at least one switch and a plurality of end-nodes, where the subnet manager executes on one of the plurality of nodes. A host channel adapter of a node in the subnet can request membership for an end-port of the host channel adapter. In response to the request, the subnet manager can request data from the data store to confirm that the end-port is a member of an admin partition and that the admin partition is associated with the data partition in which membership was requested.