An electronic apparatus connectable with a network, includes a communication interface configured to communicate with a first device and a second device; and a processor configured to store network connection setting information of the first device, determine, in response to receiving, from the second device, a signal requesting network connection setting information, whether the second device is capable of using the network connection setting information of the first device, and transmit the stored network connection setting information of the first device to the second device in accordance with a result of the determination.

The present disclosure provides a method for networking multi-protocol terminals, a method for communicating, a storage medium, and an electronic device. The method for networking multi-protocol terminals includes: acquiring a configuration file, configuring, based on the configuration file, a virtual management terminal, wherein the virtual management terminal is configured to perform conversion between an entity terminal protocol and a predetermined protocol; receiving a network access request from a first entity terminal, and creating, based on the network access request, a first virtual terminal corresponding to the first entity terminal, wherein the first virtual terminal is configured to perform conversion between a server protocol and the predetermined protocol; and implementing, based on the first virtual terminal, network access of the first entity terminal.

The described technology is generally directed towards an automation agent for network equipment configuration. The automation agent can be incorporated into a network automation platform. The network automation platform can include, inter alia, a communication channel, such as a data movement as a platform (DMaaP) communication channel, which is used by various components of the network automation platform. The disclosed automation agent can monitor the communication channel for network equipment configuration communications generated by other components of the network automation platform. In response to a network equipment configuration communication, the automation agent can create an interface update file comprising the updated interface configuration data, and send the interface update file to a network equipment configuration update service for deployment to the network equipment.

Provided is a method for configuring a gateway. The method may include a gateway monitoring current version data stored on at least one first server. The current version data may be associated with a current version of a configuration file. The first server may be remote from the gateway. The current version data may be modified at the first server. In response to the gateway determining that the current version data stored on the first server has been modified, a configuration service may be invoked to retrieve the current version of the configuration file from at least one repository based on the current version data. The repository may include at least one second server remote from the gateway and the first server. The gateway may store a copy of the current version of the configuration file retrieved by the configuration service. A system and computer program product are also disclosed.

Embodiments of this application disclose a FlexE information automatic configuration method, and the method may be implemented by a first communication apparatus. The first communication apparatus may receive first FlexE configuration information sent by a second communication apparatus. After receiving the first FlexE configuration information, the first communication apparatus may perform local FlexE configuration based on the first FlexE configuration information, so that FlexE configuration information of the first communication apparatus is consistent with FlexE configuration information of the second communication apparatus, to establish a FlexE connection. The second FlexE configuration information is used to perform FlexE configuration on a first physical interface on the first communication apparatus. The first communication apparatus may obtain the first FlexE configuration information, and implement the FlexE configuration on the first physical interface based on the first FlexE configuration information.

The present disclosure is directed to systems and methods of managing remote devices. The system can include a server with memory, a detection module, and a collection module. The memory can store a management information base (MIB) having a hierarchical tree of object identifiers and corresponding object values. The detection module can query devices and receive a first object identifier and its first object value, which can vary from those in the MIB; and use patterns to match the first object identifier and object value; and generate an identification of the device from the matches. The collection module can use the identification to select a collection template, which can indicate a subtree of the MIB and a collection pattern; traverse the subtree and identify a second object identifier that matches the collection pattern, and its second object value; and associate the second object value with the first object value.

Methods, systems, and apparatus, for automatically changing a network system. A method includes receiving a set of first intents that describe a state of a first switch fabric; receiving a set of second intents that describe a state of a second switch fabric; computing a set of network operations to perform on the first switch fabric to achieve the second switch fabric, the set of operations also defining an order in which the operations are to be executed, and the set of operations determined based on the set of first intents, the set of second intents, and migration logic that defines a ruleset for selecting the operations based on the set of first intents and the second intents; and executing the set of network operations according to the order, to apply changes to elements within the first switch fabric to achieve the state of the second switch fabric.

Aspects of the disclosure provide for mechanisms for managing containers across operating systems in a computer system. A method of the disclosure includes: causing a first container management agent in a first container to run a user interface in the first container, receiving a user request to create a copy of the first container, creating a second container in view of the first container, receiving, from the user interface running in the first container, a first command to switch from the first container to the second container, and responsive to receiving the first command to switch from the first container to the second container: configuring the second container in view of one or more configurations of the first container, causing a second container management agent in the second container to run the user interface in the second container, and causing execution of the first container to stop.

At a network-accessible service, a request is received from a client to enable access by a migration facilitator to a configuration record collection of the client. A response to a migration candidate identification query is generated using the configuration record collection and transmitted to the facilitator. An indication of a proposal associated with migrating at least a portion of the client's computing environment to a different computing environment with assistance from the facilitator is provided to the client.

Generating a core instance via a first access network device of a first access network, wherein the core instance facilitates operation of a second access network via a second access network device of the second access network is disclosed. Generally, implementing a core network can be highly resource intensive, e.g., high labor, equipment, and monetary costs. The level of resources that are conventionally committed in developing a core instance can be a significant barrier for many small or medium sized entities. The disclosed subject matter discloses a configuration component that can generate a core instance that can be performed at a remotely located access network. In an embodiment, a remotely implemented core instance can be updatable. Further, in response to a remotely implemented core instance failing to perform, a monitoring component can facilitate a failover operation.