A system, a method, and a computer program for generating a dynamically configurable resolution route for transmitting a request object to one or more nodes in a network, comprising receiving a trigger signal from a first node, determining one or more destination nodes based on a resolution process, schema or scenario, determining a pathway to the one or more destination nodes, generating a resolution route for transmitting the request object in the network, iteratively transmitting the request object to the one or more destination nodes based on the resolution route, receiving a request object resolution signal from a final destination node, and transmitting the request object resolution signal to the first node based on the request object resolution signal.

A system, a method, and a computer program for generating a dynamically configurable resolution route for transmitting a request object to one or more nodes in a network, comprising receiving a trigger signal from a first node, determining one or more destination nodes based on a resolution process, schema or scenario, determining a pathway to the one or more destination nodes, generating a resolution route for transmitting the request object in the network, iteratively transmitting the request object to the one or more destination nodes based on the resolution route, receiving a request object resolution signal from a final destination node, and transmitting the request object resolution signal to the first node based on the request object resolution signal.

Disclosed are embodiments for providing batch performance using a stream processor. In one embodiment, a method is disclosed comprising receiving, at a stream processor, an event, the stream processor including a plurality of processing stages; generating, by the stream processor, an augmented event based on the event, the augmented event including at least one additional field not appearing in the event, the additional field generated by an operation selected from the group consisting of a join or dimensional annotation operation; and emitting, by the stream processor, the augmented event to downstream consumer.

Disclosed are embodiments for providing batch performance using a stream processor. In one embodiment, a method is disclosed comprising receiving, at a stream processor, an event, the stream processor including a plurality of processing stages; generating, by the stream processor, an augmented event based on the event, the augmented event including at least one additional field not appearing in the event, the additional field generated by an operation selected from the group consisting of a join or dimensional annotation operation; and emitting, by the stream processor, the augmented event to downstream consumer.

The present disclosure relates to a communication method and system for converging a 5th-Generation (5G) communication system for supporting higher data rates beyond a 4th-Generation (4G) system with a technology for Internet of Things (IoT). The present disclosure may be applied to intelligent services based on the 5G communication technology and the IoT-related technology, such as smart home, smart building, smart city, smart car, connected car, health care, digital education, smart retail, security and safety services. Embodiments herein provide a method for performing a routing ID (RID) update in user equipment (UE) in a wireless communication network.

The present disclosure relates to a communication method and system for converging a 5th-Generation (5G) communication system for supporting higher data rates beyond a 4th-Generation (4G) system with a technology for Internet of Things (IoT). The present disclosure may be applied to intelligent services based on the 5G communication technology and the IoT-related technology, such as smart home, smart building, smart city, smart car, connected car, health care, digital education, smart retail, security and safety services. Embodiments herein provide a method for performing a routing ID (RID) update in user equipment (UE) in a wireless communication network.

Disclosed service discovery methods include responding, by a node, to detecting a new connection to a switch port by performing new connection operations that include determining, using link-layer discovery protocol (LLDP) advertisements, a switch port number and self-assigning an IP address in accordance with a predetermined addressing protocol in which the self-assigned IP address is indicative of the switch port number. The IP address assigned to the node may indicate the node's switch port number. Disclosed methods may further include initiating a unicast discovery procedure to determine, via unicast messages exchanged between nodes connected to the switch, a switch port roster that lists or otherwise indicates nodes connected to the switch as well as their corresponding port numbers and services available from each node. The switch port roster may be distributed to each of the connected nodes. The unicast discovery procedure may be periodically launched to refresh and re-distribute the roster.

Disclosed service discovery methods include responding, by a node, to detecting a new connection to a switch port by performing new connection operations that include determining, using link-layer discovery protocol (LLDP) advertisements, a switch port number and self-assigning an IP address in accordance with a predetermined addressing protocol in which the self-assigned IP address is indicative of the switch port number. The IP address assigned to the node may indicate the node's switch port number. Disclosed methods may further include initiating a unicast discovery procedure to determine, via unicast messages exchanged between nodes connected to the switch, a switch port roster that lists or otherwise indicates nodes connected to the switch as well as their corresponding port numbers and services available from each node. The switch port roster may be distributed to each of the connected nodes. The unicast discovery procedure may be periodically launched to refresh and re-distribute the roster.

Techniques are disclosed for management of communication sessions of network traffic between client devices and the use of an up-to-date session state to enable seamless failovers between routers. One example technique may prepare each backup router to resume sessions of the active router in event of a failover and cause a redirection of the network traffic to complete the failover to a backup router. In a hot-switchover example, a network device known as a session controller synchronizes the session state information to backup router prior to failure and then, causes the network traffic to be redirected to backup router in response to the active router failure. In a warm-switchover example, the same session controller selects a backup router dynamically after detecting failure to active router, synchronizes session state information to backup router, and trigger routing updates, causing the network traffic to be redirected to the backup router.

Techniques are disclosed for management of communication sessions of network traffic between client devices and the use of an up-to-date session state to enable seamless failovers between routers. One example technique may prepare each backup router to resume sessions of the active router in event of a failover and cause a redirection of the network traffic to complete the failover to a backup router. In a hot-switchover example, a network device known as a session controller synchronizes the session state information to backup router prior to failure and then, causes the network traffic to be redirected to backup router in response to the active router failure. In a warm-switchover example, the same session controller selects a backup router dynamically after detecting failure to active router, synchronizes session state information to backup router, and trigger routing updates, causing the network traffic to be redirected to the backup router.