The present disclosure provides computing systems and methods that optimize the execution of workflows that include computational tasks (e.g., which may take the form of functions or containers). In general, the proposed systems and methods can be referred as to or embodied within a serverless workflow enablement and execution platform (also referred to herein as a workflow management system). The serverless workflow platform can facilitate performance of a large-scale computational workflow. In particular, the serverless workflow platform can facilitate performance of serverless workflows that are executed on serverless execution platforms.

In one embodiment, a device receives application experience metrics for a software-as-a-service application. The device generates, based on the application experience metrics, a predictive model that predicts application experience scores for a plurality of network service providers that provide connectivity to the software-as-a-service application. The device selects a particular network service provider for use by a location, based on an application experience score predicted by the predictive model. The device sends an indication of the particular network service provider to the location.

A data processing system is described herein that includes two or more software-driven host components. The two or more host components collectively provide a software plane. The data processing system also includes two or more hardware acceleration components (such as FPGA devices) that collectively provide a hardware acceleration plane. A common physical network allows the host components to communicate with each other, and which also allows the hardware acceleration components to communicate with each other. Further, the hardware acceleration components in the hardware acceleration plane include functionality that enables them to communicate with each other in a transparent manner without assistance from the software plane.

A system for finding and identifying computer nodes in a network includes a network having multiple computer nodes and a planning module. The computer nodes are connected to one another by communication connections and are configured to perform a workload of one or more software application(s). The planning module includes at least one probe having a test code and is configured to send the probe with the test code to the computer nodes to test the properties of the computer nodes with respect of their ability to perform a specific workload of at least one software application. The planning module is configured to take the test results as a basis for selecting one or more computer nodes for performing the workload of at least one software application, and to start the performance of the workload of the at least one software application on the selected computer node.

In an example, there is disclosed a system and method for providing a service-oriented architecture, including request/response, over a publish/subscribe framework. In one embodiment, a system is disclosed for adding layers upon a publish/subscribe messaging framework for sophisticated messaging such as point-to-point (request/response) and the ability to query for available services, in a reliable, scalable manner.

Techniques for providing a distributed standards registry are provided. A DSR system may include a plurality of distributed standards registry participants that are collectively configured to provide control logic for the distributed standards registry using a consensus voting mechanism to make control decisions. The DSR system includes include a distributed ontology model library maintained on the plurality of distributed standards registry participants and storing a plurality of ontology models, and a distributed federation broker registry maintained across the plurality of distributed standards registry participants. A first distributed standards registry participant of the plurality of distributed standards registry participants includes a discovery processor operable to receive and process federation participant queries and a registry processor operable to receive and process registration requests to register the federation broker as providing brokerage services related to a federation service described by one of the plurality of ontology models.

Among other things, a node is enabled to participate, with other nodes, in forming and using transport layer features in a communication network, the transport layer features being extensible to support ten million or more simultaneous reliable conversations between or among applications running on respective participant nodes.

Methods, apparatuses, or computer program products are disclosed providing for the dynamic generation and traversal of object dependency data structures. Examples enable generation of service dependency work graph structures for service dependencies associated with one or more services and dynamic replacement of service instances based upon traversal of the service dependency work graph data structures.

A virtual delivery appliance may include a memory and a processor configured to cooperate with the memory to connect client computing devices with virtual computing sessions provided by a host computing device(s) based upon respective connection leases each including an ordered list of virtual delivery appliances, with at least some of the client computing devices having different ordered lists of virtual delivery appliances. Each client computing device may be configured to request a new session from the virtual delivery appliances in the ordered list in descending order until receiving a connection with a new virtual computing session. The processor may be further configured to re-direct new session requests received from the client computing devices to lower virtual delivery appliances in the ordered list when existing virtual computing sessions for the client computing devices are already active with the host computing device(s) associated with the lower virtual delivery appliances.

A system and method of dynamically controlling a reservation of resources within a cluster environment to maximize a response time are disclosed. The method embodiment of the invention comprises receiving from a requestor a request for a reservation of resources in the cluster environment, reserving a first group of resources, evaluating resources within the cluster environment to determine if the response time can be improved and if the response time can be improved, then canceling the reservation for the first group of resources and reserving a second group of resources to process the request at the improved response time.