Systems and methods for supporting efficient virtualization in a lossless interconnection network. An exemplary method can provide, one or more switches, including at least a leaf switch, a plurality of host channel adapters, wherein each of the host channel adapters comprise at least one virtual function, at least one virtual switch, and at least one physical function, a plurality of hypervisors, and a plurality of virtual machines, wherein each of the plurality of virtual machines are associated with at least one virtual function. The method can arrange the plurality of host channel adapters with one or more of a virtual switch with prepopulated local identifiers (LIDs) architecture or a virtual switch with dynamic LID assignment architecture. The method can assign each of the virtual switches a pLID and each of the plurality of virtual machines a vLID.

In one illustrative example, a network node connected in a network fabric may identify that it is established as part of a multicast distribution tree for forwarding multicast traffic from a source node to one or more host receiver devices of a multicast group. In response, the network node may propagate in the network fabric a message for advertising the network node as a candidate local source node at which to join the multicast group. The message for advertising may include data such as a reachability metric. The propagation of the message may be part of a flooding of such messages in the network fabric. The network node serving as the candidate local source node may thereafter locally join a host receiver device in the multicast group at the network node so that the device may receive the multicast traffic from the source node via the network node.

The disclosure provides Internet of Things (IoT) systems organized as tree hierarchies in which rule processing can occur at each level of the tree hierarchies. In the IoT system according to one embodiment, formulas are defined and centrally managed at a cloud hub that is a root of a tree hierarchy. Each formula defined at the cloud hub is further percolated down to a hub, which may be the cloud hub itself or a local hub, in the tree hierarchy that is logically closest to devices specified in the formula. Each of the cloud and local hubs in the IoT system may utilize the same core IoT platform image, providing ease of management. In addition, formulas may be defined with basic stimuli and responses, as well as with higher-order stimuli and responses that combine one or more other stimuli and responses, respectively.

The subject technology addresses a need for improving utilization of network bandwidth in a multicast network environment. More specifically, the disclosed technology provides solutions for extending multipathing to tenant multicast traffic in an overlay network, which enables greater bandwidth utilization for multicast traffic. In some aspects, nodes in the overlay network can be connected by virtual or logical links, each of which corresponds to a path, perhaps through many physical links, in the underlying network.

A method of forwarding a multicast packet by a physical forwarding element is provided. The method receives a multicast packet that identifies a multicast group. The method scans a multicast tree associated with the multicast group to identify an ECMP group for forwarding the multicast packet to a member of the multicast group. The method calculates a group of hash values on several fields of the packet and uses a first hash value in the group of hash values to identify a first path in the ECMP. The method determines that the identified path has failed. The method uses a second hash value to identify a second path in the ECMP. The method forwards the multicast packet to the multicast member through the second path.

In one embodiment, a device receives data regarding usage of access points in a network by a plurality of clients in the network. The device maintains an access point graph that represents the access points in the network as vertices of the access point graph. The device generates, for each of the plurality of clients, client trajectories as trajectory subgraphs of the access point graph. A particular client trajectory for a particular client comprises a set of edges between a subset of the vertices of the access point graph and represents transitions between access points in the network performed by the particular client. The device identifies a transition pattern from the client trajectories by deconstructing the trajectory subgraphs. The device uses the identified transition pattern to effect a configuration change in the network.

A method in a virtual, augmented, or mixed reality system includes a GPU determining/detecting an absence of image data. The method also includes shutting down a portion/component/function of the GPU. The method further includes shutting down a communication link between the GPU and a DB. Moreover, the method includes shutting down a portion/component/function of the DB. In addition, the method includes shutting down a communication link between the DB and a display panel. The further also includes shutting down a portion/component/function of the display panel.

An STP link selection system includes a first and second designated switch devices providing different paths to a root switch device. A non-designated switch device receives a first communication from the first designated switch device identifying a first root path cost for a first link to the first designated switch device and a first designated switch device identifier, and designates the first link as an active link for communications to the root switch device. The non-designated switch device subsequently receives a second communication from the second designated switch device identifying a second root path cost for a second link to the second designated switch device that is equal to the first root path cost, and a second designated switch device identifier that is lower than the first designated switch device identifier. In response, the non-designated switch device designates the second link as a non-active link upon which communications are blocked.

Some examples relate to determining routing decisions in a SD-WAN overlay. In an example, a controller in a SD-WAN overlay comprising a plurality of network nodes may receive respective routing and link information from a respective routing agent present on each network node of the plurality of network nodes. The controller may generate a Prefix tree based on the respective routing and link information received from the respective routing agent. The prefix tree may store prefixes along with respective prefix information. The controller may determine, for each prefix in the Prefix tree, a respective routing decision for each network node in the plurality of network nodes. The controller may distribute the respective routing decision to each network node in the plurality of network nodes in the SD-WAN overlay.

An example device at a gateway node in a mesh network comprising: a processor to negotiate with other gateway node in the mesh network to obtain a common network identifier wherein the mesh network includes at least two gateway nodes uniquely identified by at least two node identifiers; report the common network identifier to a route generator for establishing a source routing tree for gateway nodes in the mesh network, wherein the source routing tree includes the gateway node as a root and a plurality of non-root nodes each comprising a non-gateway node including the device.