A configuration of a service of a cloud computing system is rendered in a user interface of an electronic display, according to a discovery chain generated by a networking tool using a service discovery function to establish the configuration. The configuration includes one or more of a router, a splitter, and/or a resolver, each having one or more configuration files that are represented as a graphical element within a graphical representation of the one or more of the router, the splitter, and/or the resolver. The configuration further includes data traffic routes between pairs of the configuration files, each being represented in the UI as a line between each pair of configuration files, where each line is rendered in the UI so as to avoid crossing over any graphical element that represents a configuration file.

A distributed cloud computing system is disclosed that includes a controller configured to deploy a first gateway in a first cloud computing network and a second gateway in a second cloud computing network and logic. The logic, upon execution by one or more processors, causes performance of operations including generating a topology mapping visualization illustrating a plurality of constructs and communication paths therebetween, wherein a first subset of the plurality of constructs are deployed in the first cloud computing network and a second subset of the plurality of constructs are deployed in the second cloud computing network, receiving user input corresponding to (i) a selection of one or more constructs and (ii) an identifier for the selection, generating a filtered topology mapping visualization of the selection of the one or more constructs and any connections therebetween, and causing rendering of the filtered topology mapping visualization on a display screen.

A distributed cloud computing system is disclosed that includes a controller configured to deploy a first gateway in a first cloud computing network and a second gateway in a second cloud computing network and logic. The logic, upon execution by one or more processors, causes performance of operations including generating a topology mapping visualization illustrating a plurality of constructs and communication paths therebetween, wherein a first subset of the plurality of constructs are deployed in the first cloud computing network and a second subset of the plurality of constructs are deployed in the second cloud computing network, receiving user input corresponding to (i) a selection of one or more constructs and (ii) an identifier for the selection, generating a filtered topology mapping visualization of the selection of the one or more constructs and any connections therebetween, and causing rendering of the filtered topology mapping visualization on a display screen.

The present disclosure is generally related to edge computing technologies (ECTs), communications networking, network slicing, and in particular, to techniques and technologies for providing flow-specific network slices. In particular, the present disclosure describes mechanisms that expand existing end-to-end architectures in order to include quality of service and monitoring mechanisms that connect network slicing technologies with infrastructure and/or network data center quality of service provider domains. The described mechanisms provide data center bridging to enable network, edge computing, and cloud computing domains.

The present disclosure is generally related to edge computing technologies (ECTs), communications networking, network slicing, and in particular, to techniques and technologies for providing flow-specific network slices. In particular, the present disclosure describes mechanisms that expand existing end-to-end architectures in order to include quality of service and monitoring mechanisms that connect network slicing technologies with infrastructure and/or network data center quality of service provider domains. The described mechanisms provide data center bridging to enable network, edge computing, and cloud computing domains.

Systems, apparatuses, and methods are provided herein for network incident management. A method for network incident management comprises aggregating network metrics associated with a monitored network in a historical network data database, identifying incidents based on the network metrics, generating a training data set based on the network metrics and the incidents, wherein the training data set comprises time series of network metrics as training input and incidents as labels, training an incident model using the training data set, receiving real-time network metrics from the network via the network interface, determining an incident prediction based on the incident model using the real-time network metrics as input, and causing a user interface device to provide an alert to a user based on the incident prediction.

Systems, apparatuses, and methods are provided herein for network incident management. A method for network incident management comprises aggregating network metrics associated with a monitored network in a historical network data database, identifying incidents based on the network metrics, generating a training data set based on the network metrics and the incidents, wherein the training data set comprises time series of network metrics as training input and incidents as labels, training an incident model using the training data set, receiving real-time network metrics from the network via the network interface, determining an incident prediction based on the incident model using the real-time network metrics as input, and causing a user interface device to provide an alert to a user based on the incident prediction.

Some embodiments provide a method for presenting a visualization of a topology for a logical network. In response to receiving a selection of a particular user interface (UI) item representing a particular group of logical elements, the method presents one or more filter UI items for the particular group of logical elements. Each filter UI item corresponds to a different attribute associated with the logical elements. Upon receiving selection of one or more attribute states for each attribute for which a filter UI item is presented, the method identifies logical elements in the group of logical elements that match the selected attribute states. The method presents, in the UI, an expanded version of the particular group of logical elements that emphasizes the identified logical elements that match the selected attribute states.

A mechanism is disclosed operating a transport network function (TNF) as part of a fifth generation wireless (5G) virtualized control plane. The mechanism includes receiving a request to compute a traffic engineering (TE) path in a 5G transport network for a packet data unit (PDU) session, the request received from a 5G virtualized control plane function via a service based interface (SBI) bus. Network topology information for the 5G transport network is obtained via a northbound interface (Nn). A TE path across the 5G transport network is computed for the PDU session based on the network topology information. A TE path identifier for the TE path computed for the PDU session is returned via the SBI bus.

An example first device may include a processor to establish a plurality of links associating between the first network device and a second network device, the plurality of links corresponding to a plurality of virtual local area networks (VLANs) that a plurality of client devices associated with the first network device belong to; create a mapping between the plurality of links and the plurality of VLANs; and forward data received from a particular client device among the plurality of client devices in a particular VLAN of the plurality of VLANs to the second network device via a particular link corresponding to the particular VLAN based on the mapping.