Lightweight, dynamic mechanisms are provided to support service layer interworking and resource extensibility. For example, one mechanism disclosed herein comprises defining a new service layer (SL) resource definition registration procedure that allows for specifying custom attributes of service layer resources to represent third party technology resources. A second mechanism disclosed herein comprises defining a new SL data model mapping registration procedure to map service layer resources to third party data models and to provide a new interworked retargeting indicator to the service layer. Further, a third mechanism disclosed herein comprises defining a SL generic interworking procedure to intelligently retarget requests toward interworked resources based on the interworked retargeting indicator provided by the data model mapping.

A message associated with a subscription topic hosted by a publish/subscribe message tracking device is sent by the publish/subscribe message tracking device to at least one subscriber device that is registered to the subscription topic and configured to report action completion processing based upon content of the message. The action completion processing based upon content of the message by the at least one subscriber device is monitored.

In accordance with an embodiment, described herein is a system and method for integrating a cloud platform with an application server or other environment, for example, a WebLogic environment. A cloud platform runtime including a cloud server can be embedded within an application server container, so that the cloud server domain can execute within the application server domain. An integration bridge and integration components support integration between the cloud server and the application server. Cloud server components can be used as part of the application server domain, including for example, administration, logging and diagnostics, security, and configuration management.

A method for providing individualized communication service includes (1) recognizing a first client being communicatively coupled to a first local communication network, (2) determining an identity of the first client, (3) transporting first data between the first client and a first operator communication network, using the first local communication network in accordance with a first service profile associated with the first client, and (4) transporting the first data using the first operator communication network in accordance with the first service profile.

A method for providing individualized communication service includes (1) recognizing a first client being communicatively coupled to a first local communication network, (2) determining an identity of the first client, (3) transporting first data between the first client and a first operator communication network, using the first local communication network in accordance with a first service profile associated with the first client, and (4) transporting the first data using the first operator communication network in accordance with the first service profile.

A Yet Another Next Generation (YANG) module management method includes that a first network device determines a target YANG package in a second network device. The target YANG package includes at least two service-related YANG modules. The first network device generates a processing instruction for the target YANG package, and sends the processing instruction to the second network device. The processing instruction includes an identifier of the target YANG package. The identifier of the target YANG package includes a name of the target YANG package or the name and version information of the target YANG package.

A system for integration and interoperability between disparate distributed server technologies is provided. In particular, the system may provide communications functionality between heterogenous distributed register technology networks. In this regard, the system may establish an interoperability layer between the disparate networks to allow cross-network process flows to be executed. The interoperability layer may comprise one or more network services nodes for each distributed register technology to be integrated by the system. Each network services nodes may act as an event handler for internal processes executed within a given distributed register network and be configured to send and receive data from other network services nodes regarding the execution of such processes. The respective network services may then use the data obtained regarding such internal processes to in turn execute its own processes. In this way, the system may efficiently integrate networks using disparate distributed register technologies.

A system for integration and interoperability between disparate distributed server technologies is provided. In particular, the system may provide communications functionality between heterogenous distributed register technology networks. In this regard, the system may establish an interoperability layer between the disparate networks to allow cross-network process flows to be executed. The interoperability layer may comprise one or more network services nodes for each distributed register technology to be integrated by the system. Each network services nodes may act as an event handler for internal processes executed within a given distributed register network and be configured to send and receive data from other network services nodes regarding the execution of such processes. The respective network services may then use the data obtained regarding such internal processes to in turn execute its own processes. In this way, the system may efficiently integrate networks using disparate distributed register technologies.

A computer program product, system, and method for accessing an application from different locations to gather geo-location specific data via pre-provisioned network endpoints in the different locations, the method includes receiving a request from a client application to access an application via a particular geographical location to collect geo-location specific data via a pre-provisioned network endpoint in the particular location, selecting a route to send traffic via the particular geographical location using the pre-provisioned network endpoint, establishing a virtual circuit to route the request via a network endpoint, sending the request for execution to the network endpoint, collecting responses received from the network endpoint from accessing the application, and sending the responses to the client application.

The present disclosure relates to operation, administration and maintenance (OAM) data transmission methods and apparatus. One example method includes obtaining a first data flow of a client, inserting an OAM data block in the first data flow of the client to obtain a second data flow of the client, where the OAM data block is a 64B/66B code block that carries OAM data, and distributing the second data flow of the client to at least one slot of a channel corresponding to the client.