Techniques for automating the provisioning, configuring, and onboarding of network devices into a cloud management platform. The cloud management platform can be used to manage network devices that are provisioned in on-premise environments, cloud environments, and/or hybrid environments. However, it can be a cumbersome and error-prone process for a user to manually configure each of the network devices with connectivity settings needed to be managed by the cloud management platform. The techniques described herein provide an automated process to distribute connectivity information to the network devices to allow them to be managed by the cloud management platform. Once connected to the cloud management platform, the techniques described herein further include automating the process for attaching the network devices with the appropriate user account registered with the cloud management platform.

A method for obtaining a cross-domain link. The method includes: a control device sends a first message to a forwarding device in an internet protocol (IP) domain, where the first message is used to instruct the forwarding device to search for a device adjacent to the forwarding device in an optical domain; the control device receives a second message from an optical network element adjacent to the forwarding device in the optical domain, where the second message includes a first identifier identifying the optical network element, a second identifier identifying a port communicating with the forwarding device and being on the optical network element, and a media access control (MAC) address of the forwarding device; and obtains the cross-domain link between the forwarding device and the optical network element based on the first identifier, the second identifier, and the MAC address of the forwarding device.

According to various embodiments, an electronic device comprises a communication processor, an application processor operatively connected to the communication processor, and a memory, wherein the at least one memory may store instructions configured to, when executed, cause the application processor to identify a user identifier (UID) corresponding to at least one allowed application or at least one disallowed application when the electronic device enters a power saving state and to generate, on the basis of the user identifier, a first packet filter program which includes at least one condition for filtering a packet, and cause the communication processor to identify the first packet filter program generated from the application processor and to filter at least one packet associated with an application other than the at least one allowed application or at least one packet associated with the at least one disallowed application by using the first packet filter program, while the electronic device is in the power saving state. Various other embodiments are possible.

A port configuration migration system includes a primary I/O module connected to a server device via a secondary I/O module. A fabric manager system maps a virtual interface to a first downlink port on the primary I/O module that is connected to the secondary I/O module, with the virtual interface providing a virtual direct connection to the server device. The fabric manager system then configures the virtual interface with communication configuration information for the server device such that communications received via the first downlink port are transmitted using the virtual interface. The fabric manager system then receives a discovery communication from the server device via a second downlink port on the primary I/O module that is connected to the secondary I/O module, and remaps the virtual interface to the second downlink port such that communications received via the second downlink port are transmitted using the virtual interface.

A node interconnection apparatus includes a computing node, a resource control node, and a device interconnection interface connecting the computing node and the resource control node. Each of the computing node and the resource control node includes a processing unit and a storage unit, and the resource control node further includes a resource interface for connecting with a network storage device. The resource control node manages a storage resource of the network storage device, and when the computing node needs to start up, the resource control node obtains operating system startup information from the network storage device and provides the operating system startup information to the computing node. The computing node can start up without the need for storing startup information locally.

Techniques for automating the provisioning, configuring, and onboarding of network devices into a cloud management platform. The cloud management platform can be used to manage network devices that are provisioned in on-premise environments, cloud environments, and/or hybrid environments. However, it can be a cumbersome and error-prone process for a user to manually configure each of the network devices with connectivity settings needed to be managed by the cloud management platform. The techniques described herein provide an automated process to distribute connectivity information to the network devices to allow them to be managed by the cloud management platform. Once connected to the cloud management platform, the techniques described herein further include automating the process for attaching the network devices with the appropriate user account registered with the cloud management platform.

Systems and methods include receiving data from a network that includes a plurality of network elements that operate at a plurality levels that include any of network layers and encapsulations; displaying any of the plurality of network elements as a three-dimensional icon on a network map; illustrating a plinth in the three-dimensional icon for each of the plurality of levels for each network element of the any of the plurality of network elements, wherein a plinth at each level indicates a corresponding network element participates in that level; and illustrating horizontal connectivity as links between any of the network elements via associated plinths.

Examples include a computing system including a network input/output (I/O) device, the network I/O device including a microcontroller, a network controller, and a proxy mode monitor to enter a proxy mode by causing transfer of control of the network controller from a processor to the microcontroller without resetting the network controller, and to exit the proxy mode by causing transfer of control of the network controller from the microcontroller to the processor without resetting the network controller.

Methods and devices are discussed. A device configured to operate in a network comprises communication circuitry and a transceiver.

A network device may assign, to a port of a plurality of ports on the network device, a precision timing protocol (PTP) port priority for PTP communications between the network device and another network device. The network device and the other network device may be communicatively connected via a plurality of links in a link aggregation group (LAG). Each port, of the plurality of ports, may be associated with a respective link, of the plurality of links, in the LAG. The network device may generate a link layer discovery protocol (LLDP) frame that includes information identifying the PTP port priority assigned to the port. The network device may transmit the LLDP frame to the other network device to identify, to the other network device, the PTP port priority.