A method of and a node device for determining location addresses of node devices (21, 22 . . . 26) of a network (10). The node devices (21, 22 . . . 26) are arranged along an elongated track (12) and geographically distanced from each other by an inter-node distance “d”. Each node device (21, 22 . . . 26) comprises a short range communication interface (20). A node device (22) receives a message (27) from an immediate neighbouring node device (21) having a known location address comprised in the message (27). The receiving node device (21) determines its own location address based on the location address received in the message (27). The receiving node device (22) then may transmit a further message (28) comprising its determined location address to a further node device (23), allowing the further node device (23) to determine its location address as well.

A method of and a node device for determining location addresses of node devices (21, 22 . . . 26) of a network (10). The node devices (21, 22 . . . 26) are arranged along an elongated track (12) and geographically distanced from each other by an inter-node distance “d”. Each node device (21, 22 . . . 26) comprises a short range communication interface (20). A node device (22) receives a message (27) from an immediate neighbouring node device (21) having a known location address comprised in the message (27). The receiving node device (21) determines its own location address based on the location address received in the message (27). The receiving node device (22) then may transmit a further message (28) comprising its determined location address to a further node device (23), allowing the further node device (23) to determine its location address as well.

A control apparatus includes a setting unit configured to perform a setting for forwarding a packet destined for first software to a second computer on a switch on a communication path from a first computer to the second computer during a migration of the first software from the first computer to the second computer, the first computer being a computer in which the first software and second software configured to communicate with the first software run, and a deletion unit configured to delete the setting from the switch when the migration of the first software is completed. Thus, the control apparatus shortens the time during which the setting of data forwarding remains at the switch.

A control apparatus includes a setting unit configured to perform a setting for forwarding a packet destined for first software to a second computer on a switch on a communication path from a first computer to the second computer during a migration of the first software from the first computer to the second computer, the first computer being a computer in which the first software and second software configured to communicate with the first software run, and a deletion unit configured to delete the setting from the switch when the migration of the first software is completed. Thus, the control apparatus shortens the time during which the setting of data forwarding remains at the switch.

Presented herein are techniques for dynamic optical network programming using Segment Routing (SR) using an Optical Provisioning SR Label (OPSL). In one form, a method is provided that is performed by a network element that has received an OPSL from another network element to create an optical circuit. In another form, a method is provided that is performed by a network element that sends an OPSL to another network element to cause that other network element to create an optical circuit.

Presented herein are techniques for dynamic optical network programming using Segment Routing (SR) using an Optical Provisioning SR Label (OPSL). In one form, a method is provided that is performed by a network element that has received an OPSL from another network element to create an optical circuit. In another form, a method is provided that is performed by a network element that sends an OPSL to another network element to cause that other network element to create an optical circuit.

In one embodiment, a method includes establishing, by an identity agent installed on a device, a connection to a browser installed on the device and generating, by the identity agent, first device information, a public key, and a private key. The method also includes communicating, by the identity agent, the first device information and the public key to an authentication service and receiving, by the identity agent, a unique identifier from the authentication service. The method further includes generating, by the identity agent, a first signature of the first device information and communicating, by the identity agent, the first signature, the first device information, and the unique identifier to the browser.

In one embodiment, a method includes establishing, by an identity agent installed on a device, a connection to a browser installed on the device and generating, by the identity agent, first device information, a public key, and a private key. The method also includes communicating, by the identity agent, the first device information and the public key to an authentication service and receiving, by the identity agent, a unique identifier from the authentication service. The method further includes generating, by the identity agent, a first signature of the first device information and communicating, by the identity agent, the first signature, the first device information, and the unique identifier to the browser.

Some embodiments provide policy-driven methods for deploying edge forwarding elements in a public or private SDDC for tenants or applications. For instance, the method of some embodiments allows administrators to create different traffic groups for different applications and/or tenants, deploys edge forwarding elements for the different traffic groups, and configures forwarding elements in the SDDC to direct data message flows of the applications and/or tenants through the edge forwarding elements deployed for them. The policy-driven method of some embodiments also dynamically deploys edge forwarding elements in the SDDC for applications and/or tenants after detecting the need for the edge forwarding elements based on monitored traffic flow conditions.

Some embodiments of the invention provide a method of facilitating routing through a software-defined wide area network (SD-WAN) defined for an entity. A first edge forwarding node located at a first multi-machine site of the entity, the first multi-machine site at a first physical location and including a first set of machines, serves as an edge forwarding node for the first set of machines by forwarding packets between the first set of machines and other machines associated with the entity via other forwarding nodes in the SD-WAN. The first edge forwarding node receives configuration data specifying for the first edge forwarding node to serve as a hub forwarding node for forwarding a set of packets from a second set of machines associated with the entity and operating at a second multi-machine site at a second physical location to a third set of machines associated with the entity and operating at a third multi-machine site at a third physical location. The first edge forwarding node serves as a hub forwarding node to forward the set of packets from the second set of machines to the third set of machines.