An edge computing system configured to dynamically offload tasks from a user device to an edge device. The edge device may receive a request to download or run a software application suitable processing a sensory feed collected by the user device. The edge device may determine operating requirements of the software application, determine the internal capabilities of the edge device, and compare the determined operating requirements of the software application to the determined capabilities of the edge device to determine whether the edge device is capable of running the entire software application. The edge device may also determine whether the edge device is capable of running a portion of the software application in response to determining that the edge device is not capable of running the entire software application. The edge device may send a message identifying portions that could be run on the edge device.

An edge computing system configured to dynamically offload tasks from a user device to an edge device. The edge computing system may receive a processed sensory feed from the user device, analyze the received processed sensory feed, and generate mapper output results. The edge computing system may compare the generated mapper output results to information received from a datastore, identify a correlation between a feature included in the received processed sensory feed and a feature included in the received information, and determine whether a confidence value associated with the identified correlation exceeds a threshold value. The edge computing system may further process the received processed sensory feed locally in the edge computing system or send the received processed sensory feed to a cloud component for further processing based on whether the confidence value exceeds the threshold value.

A first communicating entity determines session state parameters of a security protocol session between itself and a second communicating entity. The first entity uses the session state parameters to transmit a first set of messages of the session to the second entity via a first communication mechanism. The first entity also uses the session state parameters to transmit a second set of messages of the session to the second entity via a second communication mechanism.

Short term wagers can be made on predicted outcomes of performances in events such as the performance of a specific player in a sports event or the performance of a company stock in a given time frame. A user can select a plurality of challenge parameters, including a time duration of a challenge; a subject matter of the challenge; a type of wager for the challenge; a specific player for the challenge; and a wager amount for the challenge. The plurality of challenge parameters can be transmitted to a matching engine in order to match the challenge to one or more target users based upon a comparison of the challenge parameters to a plurality of historical challenge parameters for each of the target users to find common parameters. A casino or sports bookmaker can also accept the challenge as a house player.

Short term wagers can be made on predicted outcomes of performances in events such as the performance of a specific player in a sports event or the performance of a company stock in a given time frame. A user can select a plurality of challenge parameters, including a time duration of a challenge; a subject matter of the challenge; a type of wager for the challenge; a specific player for the challenge; and a wager amount for the challenge. The plurality of challenge parameters can be transmitted to a matching engine in order to match the challenge to one or more target users based upon a comparison of the challenge parameters to a plurality of historical challenge parameters for each of the target users to find common parameters. A casino or sports bookmaker can also accept the challenge as a house player.

A distributed policy management (PM) system (e.g., system for authentication, authorization, and accounting (AAA) activities on a network) is provided. Nodes of the PM system may share information of the PM system using a distributed data store (e.g., a multi-master cache). Each node of the distributed PM system may further share information from the distributed data store with other nodes of a corporate infrastructure network by augmenting information in a remote authentication dial-in user service (RADIUS) protocol message. Nodes that are involved in policy management (e.g., network authentication server (NAS) or firewall) without access to the distributed data store may receive information via augmented RADIUS messages. In this manner, devices may be interfaced to the distributed PM system without having access to the distributed data store. High availability and load balancing implementations may be provided by leveraging the distributed data store across nodes of the PM system.

An interface obtains basic page information from another interface. The basic page information includes N bits, the N bits include an FEC function indicator bit sequence including an FEC ability indicator bit and an FEC requested indicator bit. The interface determines, based on values of a plurality of bits in the N bits, an operation mode supported by the another interface. The FEC function indicator bit sequence includes a first FEC function indicator bit corresponding to m FEC abilities; or the FEC function indicator bit sequence includes a first FEC ability indicator bit corresponding to n FEC abilities, where both m and n are greater than or equal to 1. Because one FEC function indicator bit indicates more FEC abilities, N bits in a basic page can carry more information, so that a process of increasing auto-negotiation pages is slowed down, thereby avoiding impact on auto-negotiation efficiency.

An interface obtains basic page information from another interface. The basic page information includes N bits, the N bits include an FEC function indicator bit sequence including an FEC ability indicator bit and an FEC requested indicator bit. The interface determines, based on values of a plurality of bits in the N bits, an operation mode supported by the another interface. The FEC function indicator bit sequence includes a first FEC function indicator bit corresponding to m FEC abilities; or the FEC function indicator bit sequence includes a first FEC ability indicator bit corresponding to n FEC abilities, where both m and n are greater than or equal to 1. Because one FEC function indicator bit indicates more FEC abilities, N bits in a basic page can carry more information, so that a process of increasing auto-negotiation pages is slowed down, thereby avoiding impact on auto-negotiation efficiency.

A method, computer program, and computer system is provided for determining 3rd Generation Partnership Project (3GPP) Framework for Live Uplink Streaming (FLUS) sink capabilities. A capability description is signaled using at least a first attribute and a second attribute. The first attribute comprises a location from which the capability description can be retrieved. The second attribute comprises a descriptor that determines a FLUS sink capability. Signaling the descriptor and a scheme identifier of the descriptor enables interoperability between a FLUS sink and a source from a plurality of vendors.

Code may be dynamically routed to computing resources for execution. Code may be received for execution on behalf of a client. Execution criteria for the code may be determined and computing resources that satisfy the execution criteria may be identified. The identified computing resources may then be procured for executing the code and then the code may be routed to the procured computing resources for execution. Permissions or authorization to execute the code may be shared to ensure that computing resources executing the code have the same permissions or authorization when executing the code.