Patent application number | Description | Published |
20120287926 | MULTI-ROLE DISTRIBUTED LINE CARD - A switch includes network ports and a network processor with a fabric interface that provides SerDes (Serializer/Deserializer) channels. The network processor divides each packet received over the network ports into cells and distributes the cells across the SerDes channels. Fabric ports of the switch communicate with the fabric interface to transmit cells to and receive cells from the fabric interface. The switch is selectively configurable as a standalone switch by connecting each fabric port of the switch to another of the fabric ports of the switch, as a member of a switch stack by connecting each fabric port of the switch to a different other switch through one fabric port of that other switch, or as a member of a distributed fabric system by connecting each fabric port of the switch to a different scaled-out fabric coupler (SFC) chassis by an SFC fabric port of that SFC chassis. | 11-15-2012 |
20130088971 | PARTIONING LARGE FLAT DATA CENTERS INTO MULTIPLE SWITCHING DOMAINS - A distributed fabric system includes multiple switches coupled to a cell-based switching fabric. A logical system port that is globally unique within the distributed fabric system is mapped to each physical network port in the distributed fabric system. To partition the system into multiple non-overlapping switching domains, each system port is associated with a look-up table having at least one table entry for each other system port to be allocated to the same switching domain as that system port. Each switch that receives a packet over a given system port is limited to switching the packet to only those other system ports for which the look-up table associated with the given system port has a table entry. | 04-11-2013 |
20130201873 | DISTRIBUTED FABRIC MANAGEMENT PROTOCOL - A distributed fabric system comprises a plurality of independent network elements interconnected by inter-switch links and assigned to a same group. Each network element includes a switching chip, a processor, and memory storing program code that is executed by the processor. The program code of each network element includes a device configuration (DC) stacking module and a switch discovery protocol (SDP) module. The SDP module of each network element, when executed, discovers each other network element in the group and elects one of the network elements as a master network element. The SDP module of the master network element, when executed, sends messages to the DC-stacking module of the master network element. Each sent message identifies one of the network elements in the group. The DC stacking module of the master network element, when executed, maintains a record of all network elements that are currently members in the group. | 08-08-2013 |
20130201875 | DISTRIBUTED FABRIC MANAGEMENT PROTOCOL - A distributed fabric system comprises a plurality of independent network elements interconnected by inter-switch links and assigned to a same group. Each network element includes a switching chip, a processor, and memory storing program code that is executed by the processor. The program code of each network element includes a device configuration (DC) stacking module and a switch discovery protocol (SDP) module. The SDP module of each network element, when executed, discovers each other network element in the group and elects one of the network elements as a master network element. The SDP module of the master network element, when executed, sends messages to the DC-stacking module of the master network element. Each sent message identifies one of the network elements in the group. The DC stacking module of the master network element, when executed, maintains a record of all network elements that are currently members in the group. | 08-08-2013 |
20130235735 | DIAGNOSTICS IN A DISTRIBUTED FABRIC SYSTEM - A distributed fabric system has distributed line card (DLC) chassis and scaled-out fabric coupler (SFC) chassis. Each DLC chassis includes a network processor and fabric ports. Each network processor of each DLC chassis includes a fabric interface in communication with the DLC fabric ports of that DLC chassis. Each SFC chassis includes a fabric element and fabric ports. A communication link connects each SFC fabric port to one DLC fabric port. Each communication link includes cell-carrying lanes. Each fabric element of each SFC chassis collects per-lane statistics for each SFC fabric port of that SFC chassis. Each SFC chassis includes program code that obtains the per-lane statistics collected by the fabric element chip of that SFC chassis. A network element includes program code that gathers the per-lane statistics collected by each fabric element of each SFC chassis and integrates the statistics into a topology of the entire distributed fabric system. | 09-12-2013 |
20130235762 | MANAGEMENT OF A DISTRIBUTED FABRIC SYSTEM - A distributed fabric system has distributed line card (DLC) chassis and scaled-out fabric coupler (SFC) chassis. Each DLC includes a network processor and fabric ports. Each network processor of each DLC includes a fabric interface in communication with the fabric ports of that DLC. Each SFC includes at least one fabric element and SFC fabric ports. A fabric communication link connects each SFC fabric port to one DLC fabric port. Each fabric communication link includes cell-carrying lanes. Each fabric element of each SFC detects connectivity between each SFC fabric port of that SFC and one DLC fabric port over a fabric communication link. Each SFC includes program code that reads connectivity matrix from fabric element chips and sends connection information corresponding to the detected connectivity from that SFC to a central agent. A network element includes the central agent, which, when executed, constructs a topology of the distributed fabric system from the connection information sent from each SFC. | 09-12-2013 |
20130235763 | MANAGEMENT OF A DISTRIBUTED FABRIC SYSTEM - A distributed fabric system has distributed line card (DLC) chassis and scaled-out fabric coupler (SFC) chassis. Each DLC includes a network processor and fabric ports. Each network processor includes a fabric interface in communication with the fabric ports of that DLC. Each SFC includes at least one fabric element and SFC fabric ports. A fabric communication link connects each SFC fabric port to one DLC fabric port. Each fabric communication link includes cell-carrying lanes. Each fabric element detects connectivity between each SFC fabric port of that SFC and one DLC fabric port over a fabric communication link. Each SFC reads a connectivity matrix from fabric element chips and sends connection information corresponding to the detected connectivity from that SFC to a central agent. A network element includes the central agent, which, when executed, constructs a topology of the distributed fabric system from the connection information sent from each SFC. | 09-12-2013 |
20130238771 | SNMP request processing within distributed device architecture - A distributed device architecture includes a master device and one or more member devices. A simple network management protocol (SNMP) agent of a master device receives an SNMP request from a managing device. Where the SNMP request pertains to a given member device, and where the SNMP request requires involvement of the given member device to fulfill the SNMP request, the master device generates a non-SNMP request corresponding to the SNMP request and transmits the non-SNMP request to the given member device. A non-SNMP agent of the given member device processes the non-SNMP request and transmits processing results back to the master device. The master device generates an SNMP response corresponding to the processing results, and the SNMP agent of the master device transmits the SNMP response back to the managing device. | 09-12-2013 |
20130258899 | LAYER 2 PACKET SWITCHING WITHOUT LOOK-UP TABLE FOR ETHERNET SWITCHES - In one embodiment, a system includes at least one processor which includes logic configured for receiving a request to assign a media access control (MAC) address to a device on a port, logic configured for determining the MAC address to assign to the device based at least partially on the port, and logic configured for sending a response to the request with the MAC address. In another embodiment, a computer program product for assigning a MAC address includes a computer readable storage medium having computer readable program code embodied therewith, the computer readable program code including computer readable program code configured for determining, without using a look-up table, a MAC address to assign to a device and computer readable program code configured for sending the MAC address to the device. Other systems, methods, and computer program products are presented according to more embodiments. | 10-03-2013 |
20130259038 | COMMUNICATION TRANSPORT PROTOCOL FOR DISTRIBUTED INFORMATION TECHNOLOGY ARCHITECTURES - A communication protocol in a layer two (L2) network switch comprises, in response to a service request by a source node, registering the source node for packet communication service. The protocol further comprises forwarding one or more packets from the registered source node to one or more destination nodes. The protocol further comprises receiving packets from one or more destination nodes and forwarding each received packet to a corresponding registered node. | 10-03-2013 |
20130259040 | COMMUNICATION TRANSPORT PROTOCOL FOR DISTRIBUTED INFORMATION TECHNOLOGY ARCHITECTURES - A communication protocol in a layer two (L2) network switch comprises, in response to a service request by a source node, registering the source node for packet communication service. The protocol further comprises forwarding one or more packets from the registered source node to one or more destination nodes. The protocol further comprises receiving packets from one or more destination nodes and forwarding each received packet to a corresponding registered node. | 10-03-2013 |
20130259048 | LAYER 2 PACKET SWITCHING WITHOUT LOOK-UP TABLE FOR ETHERNET SWITCHES - In one embodiment, a method for assigning a media access control (MAC) address includes receiving a request from a device for a MAC address at a port of a switching device, determining a MAC address to assign to the device based at least partially on the port, and responding to the request with the MAC address. In another embodiment, a method for retrieving a media access control (MAC) address includes sending a request for a MAC address to a MAC allocation server (MAAS), waiting a predetermined amount of time to receive a response to the request, wherein the response comprises the MAC address, and using the MAC address when the response to the request is received within the predetermined amount of time. Other systems, methods, and computer program products are presented according to more embodiments. | 10-03-2013 |
20140052771 | REMOTE PROCEDURE CALL FOR A DISTRIBUTED SYSTEM - A distributed system includes first-tier entities, and a master entity in communication with each first-tier entity. The master entity provides a single access point through which an administrator can submit commands to manage all entities. The master entity maintains a table of virtual slots. Each virtual slot points to one of the first-tier entities, and each first-tier entity is pointed to by at least one virtual slot. The processor runs an RPC (remote procedure call) client to submit RPC requests to the first-tier entities, and determines a destination first-tier entity for a given RPC request in response to which virtual slot the administrator submits a command. The distributed system can include second-tier entities, each indirectly communicating with the master entity through a first-tier entity. The table has a virtual slot for each second-tier entity, which points to the first-tier entity acting as proxy for the second-tier entity. | 02-20-2014 |
20140064105 | DIAGNOSTICS IN A DISTRIBUTED FABRIC SYSTEM - A distributed fabric system has distributed line card (DLC) chassis and scaled-out fabric coupler (SFC) chassis. Each DLC chassis includes a network processor and fabric ports. Each network processor of each DLC chassis includes a fabric interface in communication with the DLC fabric ports of that DLC chassis. Each SFC chassis includes a fabric element and fabric ports. A communication link connects each SFC fabric port to one DLC fabric port. Each communication link includes cell-carrying lanes. Each fabric element of each SFC chassis collects per-lane statistics for each SFC fabric port of that SFC chassis. Each SFC chassis includes program code that obtains the per-lane statistics collected by the fabric element chip of that SFC chassis. A network element includes program code that gathers the per-lane statistics collected by each fabric element of each SFC chassis and integrates the statistics into a topology of the entire distributed fabric system. | 03-06-2014 |
20140067924 | REMOTE PROCEDURE CALL FOR A DISTRIBUTED SYSTEM - A distributed system includes first-tier entities, and a master entity in communication with each first-tier entity. The master entity provides a single access point through which an administrator can submit commands to manage all entities. The master entity maintains a table of virtual slots. Each virtual slot points to one of the first-tier entities, and each first-tier entity is pointed to by at least one virtual slot. The processor runs an RPC (remote procedure call) client to submit RPC requests to the first-tier entities, and determines a destination first-tier entity for a given RPC request in response to which virtual slot the administrator submits a command. The distributed system can include second-tier entities, each indirectly communicating with the master entity through a first-tier entity. The table has a virtual slot for each second-tier entity, which points to the first-tier entity acting as proxy for the second-tier entity. | 03-06-2014 |
20140098820 | CENTRALIZED CONTROL AND MANAGEMENT PLANES FOR DIFFERENT INDEPENDENT SWITCHING DOMAINS - A network includes a first switching domain having a distributed fabric comprised of interconnected standalone switches. The standalone switches communicate with each other in accordance with a packet-based distributed fabric protocol. A second switching domain has a plurality of cell-based switches in communication with a cell-based switch fabric. The cell-based switches communicate with each other through the cell-based switch fabric in accordance with a cell-based distributed fabric protocol. One of the cell-based switches is coupled by a communication link to one of the standalone switches of the first switching domain. The second switching domain includes a server device coupled to one of the cell-based switches. The server device is configured with logic to process control packets for the standalone switches in accordance with the packet-based distributed fabric protocol and control packets for the cell-based switches in accordance with a protocol that is different from the packet-based distributed fabric protocol. | 04-10-2014 |
20140201346 | APPLYING A CLIENT POLICY TO A GROUP OF CHANNELS - Management and provisioning of networking traffic may be provided by bundling virtual channels into a group. A global policy may be applied to the bundle so that virtual ports providing services to a client may be managed by referring to the global policy of the bundle. The channels comprising the bundle may span multiple physical ports and in some cases, multiple physical switches. Thus, policy management may be avoided at the port level and instead, be handled as groups of channels implementing a client service. | 07-17-2014 |
20140201348 | VIRTUAL APPLIANCE CHAINING AND MANAGEMENT - Management of virtual resources may be provided by interconnecting a plurality of virtual appliances with common executable software services. A data packet may be sent through multiple virtual appliances invoking services within each if rules stored within respective virtual appliances correspond to a request for service in the data packet. The data packet may be passed through multiple virtual appliances prior to being returned to a hypervisor. | 07-17-2014 |
20140201349 | APPLYING A CLIENT POLICY TO A GROUP OF CHANNELS - Management and provisioning of networking traffic may be provided by bundling virtual channels into a group. A global policy may be applied to the bundle so that virtual ports providing services to a client may be managed by referring to the global policy of the bundle. The channels comprising the bundle may span multiple physical ports and in some cases, multiple physical switches. Thus, policy management may be avoided at the port level and instead, be handled as groups of channels implementing a client service. | 07-17-2014 |
20140201845 | SECURE CLOUD IMPLEMENTATION - Implementation of a secure network may be provided by analyzing packet traffic for sensitive information. Network processing elements found to be processing sensitive information may be classified as needing higher security. The classified network processing elements may be moved into a group of secure network processing elements. | 07-17-2014 |
20140201846 | SECURE CLOUD IMPLEMENTATION - Implementation of a secure network may be provided by analyzing packet traffic for sensitive information. Network processing elements found to be processing sensitive information may be classified as needing higher security. The classified network processing elements may be moved into a group of secure network processing elements. | 07-17-2014 |
20140219286 | MULTI-ROLE DISTRIBUTED LINE CARD - A switch includes network ports and a network processor with a fabric interface that provides SerDes (Serializer/Deserializer) channels. The network processor divides each packet received over the network ports into cells and distributes the cells across the SerDes channels. Fabric ports of the switch communicate with the fabric interface to transmit cells to and receive cells from the fabric interface. The switch is selectively configurable as a standalone switch by connecting each fabric port of the switch to another of the fabric ports of the switch, as a member of a switch stack by connecting each fabric port of the switch to a different other switch through one fabric port of that other switch, or as a member of a distributed fabric system by connecting each fabric port of the switch to a different scaled-out fabric coupler (SFC) chassis by an SFC fabric port of that SFC chassis. | 08-07-2014 |
20140254607 | CENTRALIZED CONTROL AND MANAGEMENT PLANES FOR DIFFERENT INDEPENDENT SWITCHING DOMAINS - A network includes a first switching domain having a distributed fabric comprised of interconnected standalone switches. The standalone switches communicate with each other in accordance with a packet-based distributed fabric protocol. A second switching domain has a plurality of cell-based switches in communication with a cell-based switch fabric. The cell-based switches communicate with each other through the cell-based switch fabric in accordance with a cell-based distributed fabric protocol. One of the cell-based switches is coupled by a communication link to one of the standalone switches of the first switching domain. The second switching domain includes a server device coupled to one of the cell-based switches. The server device is configured with logic to process control packets for the standalone switches in accordance with the packet-based distributed fabric protocol and control packets for the cell-based switches in accordance with a protocol that is different from the packet-based distributed fabric protocol. | 09-11-2014 |
20140279885 | DATA REPLICATION FOR A VIRTUAL NETWORKING SYSTEM - Embodiments of the invention provide a method for data replication in a networking system comprising multiple computing nodes. The method comprises maintaining a data set on at least two computing nodes of the system. The method further comprises receiving a data update request for the data set, wherein the data update request includes a data update for the data set. The data set on the at least two computing nodes is updated based on the data update request received. | 09-18-2014 |
20140280949 | LOAD BALANCING FOR A VIRTUAL NETWORKING SYSTEM - Embodiments of the invention provide a method for load balancing a networking system comprising multiple computing nodes. The method comprises maintaining one or more data sets on at least one computing node. The method further comprises receiving, from each computing node, a load information unit for the computing node, wherein the load information unit relates to resource usage on the computing node. For each computing node, the method determines whether the load information for the computing node exceeds a corresponding load threshold for the computing node. A data set on at least one computing node is transferred to another computing node when the load information for the at least one computing node exceeds a corresponding load threshold for the at least one computing node. | 09-18-2014 |
20140334498 | LAYER 2 PACKET SWITCHING WITHOUT LOOK-UP TABLE FOR ETHERNET SWITCHES - In one embodiment, a system includes at least one processor and logic integrated with and/or executable by the at least one processor, the logic being configured to receive, by the at least one processor, a request to assign a media access control (MAC) address to a device on a port, determine, by the at least one processor, the MAC address to assign to the device based at least partially on the port, and send, by the at least one processor, a response to the request with the MAC address. According to a further embodiment, the logic may be configured to create a MAC address allocation table that includes a plurality of hash values, each hash value being associated with one port and a plurality of MAC addresses, wherein the assigned MAC address is one of the MAC addresses associated with the port in the MAC address allocation table. | 11-13-2014 |
20140337453 | SNMP request processing within distributed device architecture - A distributed device architecture includes a master device and one or more member devices. A simple network management protocol (SNMP) agent of a master device receives an SNMP request from a managing device. Where the SNMP request pertains to a given member device, and where the SNMP request requires involvement of the given member device to fulfill the SNMP request, the master device generates a non-SNMP request corresponding to the SNMP request and transmits the non-SNMP request to the given member device. A non-SNMP agent of the given member device processes the non-SNMP request and transmits processing results back to the master device. The master device generates an SNMP response corresponding to the processing results, and the SNMP agent of the master device transmits the SNMP response back to the managing device. | 11-13-2014 |
20150026102 | DIRECTORY SERVICE DISCOVERY AND/OR LEARNING - In the context of a client sub-system that requires the use of directory services on behalf of a tenant (such as an overlay tenant), learning an identity of a server node, that can provide such directory services by: (i) sending, by the client sub-system to a first server node, a first directory service request for directory service for a first tenant; (ii) receiving, by the client sub-system, a first acknowledgement from a second server node; and (iii) learning, by the client sub-system, that the second server node can provide directory service for the first tenant based upon the first acknowledgement. | 01-22-2015 |
20150100670 | TRANSPORTING MULTI-DESTINATION NETWORKING TRAFFIC BY SENDING REPETITIVE UNICAST - In a distributed network environment, a first virtual machine sends a first virtual machine control information to a first network system. The first network system sends a first control information to a first network control system in response to receiving the first virtual machine control information. The first network control system sends a portion of the first control information to a number of network systems. The first network control system sends a second control information to the first network system. The first virtual machine sends a first packet to the first network system which generates a unicast packet using a portion of the first packet and a portion of the second control information. A second network system receives and processes the unicast packet. The second network system sends a copy of the processed unicast packet to a second virtual machine associated with a second tenant. | 04-09-2015 |
20150112955 | MECHANISM FOR COMMUNICATION IN A DISTRIBUTED DATABASE - In a method for providing communication integrity within a distributed database computer system, a first node of a plurality of nodes transmits a change notification to a second node of the plurality of nodes. The second node is a neighbor of the first node. The first node receives at least one change confirmation from the second node. The change confirmation confirms acknowledgment of the change notification by the second node and by a third node of the plurality of nodes. The third node is not a neighbor of the first node. Responsive to receiving the at least one change confirmation, the first node determines that all the plurality of nodes have acknowledged the change notification. | 04-23-2015 |
20150180718 | PARTITIONING A NETWORK SWITCH INTO MULTIPLE SWITCHING DOMAINS - To partition a distributed fabric system, at least one system port is allocated to each switching domain of multiple non-overlapping switching domains in a distributed fabric system. Multiple different look-up tables are produced, wherein each look-up table corresponds to a different switching domain of the multiple non-overlapping switching domains in the distributed fabric system. Each system port is associated with the look-up table of the multiple look-up tables that corresponds to the switching domain to which that system port is allocated. The look-up table associated with each system port has at least one table entry for each other system port allocated to the same switching domain as that system port. | 06-25-2015 |
20150381412 | TRANSPORTING MULTI-DESTINATION NETWORKING TRAFFIC BY SENDING REPETITIVE UNICAST - In a distributed network environment, a first virtual machine sends a first virtual machine control information to a first network system. The first network system sends a first control information to a first network control system in response to receiving the first virtual machine control information. The first network control system sends a portion of the first control information to a number of network systems. The first network control system sends a second control information to the first network system. The first virtual machine sends a first packet to the first network system which generates a unicast packet using a portion of the first packet and a portion of the second control information. A second network system receives and processes the unicast packet. The second network system sends a copy of the processed unicast packet to a second virtual machine associated with a second tenant. | 12-31-2015 |