Patent application number | Description | Published |
20130223277 | DISJOINT MULTI-PATHING FOR A DATA CENTER NETWORK - A method for determining disjoint multi-paths in a data center fabric network system, according to one embodiment, includes creating a topology of a data center fabric network system, wherein the system comprises a plurality of switches; determining paths between the plurality of switches; calculating one or more disjoint multi-paths from a source device to a destination device in the system; and writing the one or more disjoint multi-paths into a forwarding table of at least one of the source device and a nearest shared switch to the source device. | 08-29-2013 |
20130223440 | DISJOINT MULTI-PATHING FOR A DATA CENTER NETWORK - According to one embodiment, a data center fabric network system includes a controller, a plurality of switches connected to the controller via a plurality of communication links, a source device connected to at least a first switch of the plurality of switches, a destination device connected to at least a second switch of the plurality of switches, and wherein the controller is adapted for: creating a topology of the data center fabric network system, determining paths between the plurality of switches, calculating one or more disjoint multi-paths from the source device to the destination device based on the topology, and writing the one or more disjoint multi-paths into a forwarding table of at least one of: the source device, the first switch, and a nearest shared switch to the source device. | 08-29-2013 |
20130266007 | SWITCH ROUTING TABLE UTILIZING SOFTWARE DEFINED NETWORK (SDN) CONTROLLER PROGRAMMED ROUTE SEGREGATION AND PRIORITIZATION - In one embodiment, a system includes a network having a plurality of switches and one or more devices connected to one or more of the plurality of switches, a software defined network (SDN) controller connected to one or more of the plurality of switches in the network, the SDN controller having logic integrated with and/or executable by a processor, the logic being adapted to determine SDN routes through the network between the one or more devices and each of the plurality of switches and send one or more SDN routes to each switch in the network capable of communicating with the SDN controller. In other embodiments, methods and computer program products are also described for providing SDN routes through a network. | 10-10-2013 |
20130311637 | OVERLAY TUNNEL INFORMATION EXCHANGE PROTOCOL - In one embodiment, a system includes logic adapted for receiving, at a first end point station, an information exchange packet from each end point station in a virtual network having a specified virtual network identifier (VNID) and logic adapted for processing each received information exchange packet to retrieve information about connections at each end point station in the virtual network having the specified VNID, wherein each end point station either terminates or originates a tunnel shared by the first end point station in an overlay network. In this way, the information may be used to respond to address resolution protocol (ARP) requests sent locally in lieu of flooding the ARP request. Other systems, methods, and computer program products are also presented regarding the overlay tunnel information exchange protocol, according to various embodiments. | 11-21-2013 |
20130311663 | OVERLAY TUNNEL INFORMATION EXCHANGE PROTOCOL - In one embodiment, a method for exchanging overlay tunnel information includes receiving an information exchange packet, at a first end point station, from each end point station in a virtual network having a specified virtual network identifier (VNID); and processing each received information exchange packet to retrieve information about connections at each end point station in the virtual network having the specified VNID, wherein each end point station either terminates or originates a tunnel shared by the first end point station in an overlay network. In this way, the information may be used to respond to address resolution protocol (ARP) requests sent locally in lieu of flooding the ARP request. Other systems, methods, and computer program products are also presented regarding the overlay tunnel information exchange protocol, according to various embodiments. | 11-21-2013 |
20130322292 | Multipath effectuation within singly contiguous network fabric via switching device routing logic programming - Each of a network fabric controller device and a network fabric forwarder devices includes network connecting hardware and network managing logic. The network connecting hardware of the devices connects them to a singly contiguous network fabric including switching devices that route data between initiator nodes and target nodes and that have routing logic programmable by the controller device. The controller device does not directly route the data themselves. The network managing logic of the devices effects multipaths for transmission of the data through the singly contiguous network fabric from the initiator node to the target nodes via programming of the routing logic of the switching devices. | 12-05-2013 |
20130322447 | End-to-end multipathing through network having switching devices compatible with different protocols - A first cluster includes first switching devices that are compatible with a software-defined networking (SDN) protocol. A second cluster includes second switching devices within or partially overlapping the first cluster. Each second switching device is compatible with a protocol for an open systems interconnection (OSI) model layer. The first switching devices include one or more border switching devices located at a boundary between the first cluster and the second cluster. Each border switching device is also compatible with the protocol for the OSI model layer. The first switching devices effect first multipathing through the network except through the second cluster, and the second switching devices effect second multipathing just through the second cluster of the network. As such, the first switching devices and the second switching devices together effect end-to-end multipathing through both the first cluster and the second cluster of the network. | 12-05-2013 |
20130322454 | Multipath effectuation within singly contiguous network fabric via switching device routing logic programming - Each of a network fabric controller device and a network fabric forwarder devices includes network connecting hardware and network managing logic. The network connecting hardware of the devices connects them to a singly contiguous network fabric including switching devices that route data between initiator nodes and target nodes and that have routing logic programmable by the controller device. The controller device does not directly route the data themselves. The network managing logic of the devices effects multipaths for transmission of the data through the singly contiguous network fabric from the initiator node to the target nodes via programming of the routing logic of the switching devices. | 12-05-2013 |
20130322460 | End-to-end multipathing through network having switching devices compatible with different protocols - A first cluster includes first switching devices that are compatible with a software-defined networking (SDN) protocol. A second cluster includes second switching devices within or partially overlapping the first cluster. Each second switching device is compatible with a protocol for an open systems interconnection (OSI) model layer. The first switching devices include one or more border switching devices located at a boundary between the first cluster and the second cluster. Each border switching device is also compatible with the protocol for the OSI model layer. The first switching devices effect first multipathing through the network except through the second cluster, and the second switching devices effect second multipathing just through the second cluster of the network. As such, the first switching devices and the second switching devices together effect end-to-end multipathing through both the first cluster and the second cluster of the network. | 12-05-2013 |
20140044130 | AVOIDING UNKNOWN UNICAST FLOODS RESULTING FROM MAC ADDRESS TABLE OVERFLOWS - In one embodiment, a system includes a processor adapted for running a switch controller application, logic configured for detecting a switch in a network, logic configured for determining that the switch is capable of communicating via the switch controller application, and logic configured for overwriting a default rule for handling unknown unicast packets in the switch such that the switch sends any unknown unicast packet received by the switch to the system instead of flooding when an unknown unicast packet is received. In another embodiment, a method includes detecting a switch in a network, determining that the switch is capable of communicating via a switch controller application, and overwriting a default rule for handling unknown unicast packets in the switch such that the switch sends any unknown unicast packet received by the switch to the switch controller instead of flooding when an unknown unicast packet is received. | 02-13-2014 |
20140086065 | DISJOINT MULTI-PATHS WITH SERVICE GUARANTEE EXTENSION - In one embodiment, a system includes a network manager including logic configured for determining at least one pair of disjoint paths between an ingress node and an egress node from the plurality of nodes in the network, each disjoint path having an ingress node, an egress node, and a number of nodes and connecting links therebetween, wherein each pair of disjoint paths shares no common nodes or links except for the ingress node and the egress node, and logic configured for determining characteristics of each of the at least one pair of disjoint paths based on an assigned cost of each link in the at least one pair of disjoint paths. In other embodiments, methods are described for providing disjoint multi-paths in a network. | 03-27-2014 |
20140096183 | PROVIDING SERVICES TO VIRTUAL OVERLAY NETWORK TRAFFIC - In one embodiment, a method for applying security policy in an overlay network includes receiving a request, including a packet, for a communication path through an overlay network, determining whether a security policy is to be applied to the packet based on at least one of: contents of the packet, first information, and second information, selecting a communication path between a source physical switch and a destination physical switch, wherein the selected communication path directly connects the source physical switch to the destination physical switch when it is determined to not apply the security policy to the packet, and the selected communication path connects the source physical switch to the destination physical switch via a security appliance when it is determined to apply the security policy to the packet, and sending the selected communication path to the source physical switch. | 04-03-2014 |
20140198649 | EXTENDED LINK AGGREGATION (LAG) FOR USE IN MULTIPLE SWITCHES - In one embodiment, a method for providing link aggregation (LAG) to heterogeneous switches includes receiving, at a switch controller, LAG requests forwarded by switches and determining that multiple LAG requests corresponding to a server have been received, grouping the multiple LAG requests into LAG groups according to a switch from which they were received and correlating all the LAG groups with the server, instructing each of the switches to setup a LAG group with the server according to the LAG groups determined by the switch controller, and creating alternate flows that correspond to flows through each of the switches to the server through direction from the switch controller. The switches may rely upon OpenFlow to communicate with the switch controller, in some approaches. In addition, other methods for providing LAG to heterogeneous switches are also described, along with systems and computer program products which provide LAG to heterogeneous switches. | 07-17-2014 |
20140286340 | Multipath effectuation within singly contiguous network fabric via switching device routing logic programming - Each of a network fabric controller device and a network fabric forwarder devices includes network connecting hardware and network managing logic. The network connecting hardware of the devices connects them to a singly contiguous network fabric including switching devices that route data between initiator nodes and target nodes and that have routing logic programmable by the controller device. The controller device does not directly route the data themselves. The network managing logic of the devices effects multipaths for transmission of the data through the singly contiguous network fabric from the initiator node to the target nodes via programming of the routing logic of the switching devices. | 09-25-2014 |
20150043576 | SOFTWARE DEFINED NETWORK (SDN) SWITCH CLUSTERS HAVING LAYER-3 DISTRIBUTED ROUTER FUNCTIONALITY - According to one embodiment, Layer-3 (L3) distributed router functionality is provided to a switch cluster by receiving an address resolution protocol (ARP) request packet from a first host at an entry switch in a switch cluster, a switch controller being in communication with the entry switch, and the ARP request packet including a virtual router IP address of the switch controller as a target, forwarding the ARP request packet to the switch controller after adding a header that adheres to a communication protocol used by the switch controller, receiving an ARP response packet from the switch controller indicating: a source IP address corresponding to a virtual router of the switch controller and a SMAC corresponding to the switch controller, forwarding the ARP response packet to the first host after stripping the communication protocol header, and setting the virtual router as a default gateway for traffic received from the first host. | 02-12-2015 |