A load distribution apparatus connected, via a network, to a plurality of relay apparatuses that relay communication performed by a terminal, and to the terminal, including: storage means configured to store relay apparatus identifiers that identify each of the plurality of relay apparatuses, installation site information that indicates installation sites of each of the plurality of relay apparatuses, and load information that indicates loads of each of the plurality of relay apparatuses; load management means configured to collect the load information from each of the plurality of relay apparatuses to store the load information in the storage means; selection means configured, when receiving a request from the terminal, to select a relay apparatus for relaying communication performed by the terminal from among the plurality of relay apparatuses based on the installation site information or the load information; and transmission means configured to transmit, to the terminal that transmits the request, a relay apparatus identifier of the relay apparatus selected by the selection means.

A data packet transmission method and a border routing bridge device, where the method includes receiving, by a first border routing bridge device of a first area, a first data packet sent by a border routing bridge device of a second area to the first area, determining, a device identifier group of the second area according to the first data packet, determining, from the device identifier group of the second area, according to the first data packet, a device identifier of a border routing bridge device used to forward a return data packet sent by the target device to the source device, and sending, by the first border routing bridge device, a second data packet carrying the determined device identifier to the target device, where the determined device identifier is used as a source routing bridge device identifier of the second data packet.

ECMP routing is carried out in fabric of network entities by representing valid destinations and invalid destinations in a group of the entities by a member vector. The order of the elements in the member vector is permuted and fanned out. A portion of the elements in the fanned out vector is pseudo-randomly masked. A flow of packets is transmitted to the first valid destination in the masked member vector.

Disclosed are systems, methods, and computer-readable storage media for guaranteeing symmetric bi-directional policy based redirect of traffic flows. A first switch connected to a first endpoint can receive a first data packet transmitted by the first endpoint to a second endpoint connected to a second switch. The first switch can enforce an ingress data policy to the first data packet by applying a hashing algorithm to a Source Internet Protocol (SIP) value and a Destination Internet Protocol (DIP) value of the first data packet, resulting in a hash value of the first data packet. The first switch can then route the first data packet to a first service node based on the hash value of the first data packet.

Technologies for distributed table lookup via a distributed router includes an ingress computing node, an intermediate computing node, and an egress computing node. Each computing node of the distributed router includes a forwarding table to store a different set of network routing entries obtained from a routing table of the distributed router. The ingress computing node generates a hash key based on the destination address included in a received network packet. The hash key identifies the intermediate computing node of the distributed router that stores the forwarding table that includes a network routing entry corresponding to the destination address. The ingress computing node forwards the received network packet to the intermediate computing node for routing. The intermediate computing node receives the forwarded network packet, determines a destination address of the network packet, and determines the egress computing node for transmission of the network packet from the distributed router.

One embodiment provides a system that indicates conditions associated with received content. During operation, the system generates, by a first computing device, an interest message which includes a name, wherein the interest message further includes a verification token which is a hash of a nonce. In response to transmitting the interest message to a second computing device, the system receives a content object message which includes a same name as the name for the interest message. In response to detecting a condition associated with the content object message, the system generates a content object return message which includes the nonce and a same name as the name for the content object message. The system forwards the content object return message to the second computing device, thereby facilitating the second computing device to process the content object return message.

Rather than using a large number of transceivers (transmitter/receiver pairs) operating in parallel, Access Points with multiple channels are used to aggregate, or stack, transmitted response communications, e.g., transmitting multiple acknowledgements (ACKs) in a single packet to one or more sources of received packets. The method includes sending on a plurality of channels, by each of a plurality of respective first nodes, a communication to a second node, receiving on the plurality of channels, by the second node, the communication from each of the plurality of first nodes and sending, by the second node, a transmission that contains a response to each communication that was successfully received from each of the plurality of first nodes. The response to each of the plurality of first nodes is part of a single message sent by the second node.

An example method is provided for a host to perform load balancing for multiple network interface controllers (NICs) configured as a team. The method may comprise the host detecting egress packets from a virtualized computing instance supported by the host for transmission to a destination via the team. The method may also comprise the host selecting one of the multiple NICs from the team based on load balancing weights associated with the respective multiple NICs. Each load balancing weight may be assigned based on a network speed supported by the associated NIC, and different load balancing weights are indicative of different network speeds among the multiple NICs in the team. The method may further comprise the host sending, via the selected one of the multiple NICs, the egress packets to the destination.

Described herein are various embodiments of a network element comprising a network port to receive a unit of network data and a data plane coupled to the network port. In one embodiment the data plane includes a ternary content addressable memory (TCAM) module to compare a first set of bits in the unit of network data with a second set of bits in a key associated with a TCAM rule. The second set of bits includes a first subset of bits and a second subset of bits and the TCAM module includes first logic to compare one or more bits in the first set of bits against the second set of bits, and second logic to select an action or a result using bits from either the second subset of bits, from the unit of network data, or from meta data associated with the unit of network data. Other embodiments are also described.

In one embodiment a method includes receiving a packet including a destination media access control (MAC) address field having a MAC address of a hypervisor and a destination Internet protocol (IP) address field having an IP address of a virtual machine (VM) coupled to the hypervisor. The method further determines a MAC address of the VM using the IP address of the VM and applies the VM MAC address to the destination MAC address field of the packet to forward the packet to the VM.