Embodiments of the present disclosure relate to the field of communication technology, and disclose a resource acquisition method, including: receiving a user input event from a first browser on a client; acquiring an event result triggered at a second browser by the user input event, where the second browser runs on the server for the WebVPN; acquiring, using the second browser, resources from a source station according to the event result; and feeding back the resources to the client, to present the resources at the first browser. Embodiments of the present disclosure further disclose a proxy server for a WebVPN, a resource acquisition system, and a server.

Disclosed are techniques and apparatuses that are configured to receive an indication that a web browsing session executing on an enterprise server needs additional information based on a request for additional information being sent to a client device. The request may include an identifier of the web browsing session and an identifier of an enterprise server that initiated the web browsing session. A globally unique identifier related to the web browsing session and an identifier of the enterprise server is stored in a common data store. The web browsing session may be paused when the web browsing session requests additional information from a client device. The client device may respond with the additional information. The system may provide the identifier of the enterprise server to a load balancing component so the identified web browsing session executing on the enterprise server may continue to be used.

Methods and systems for delivering data for cluster computing are described herein. A worker device may receive a dataset and store the dataset in a local storage media. This may prevent the need for the dataset to be sent over a network each time the applications are used to perform a task. Each application may be able to access the dataset in the local storage area. This may prevent the need to copy the dataset to memory associated with each application. A worker device may store a dataset, for example, if it determines that the frequency of updates to the dataset satisfy a threshold. The worker device may receive updates to the dataset via a messaging system and may store the updated data in the local storage media.

Methods and systems for delivering data for cluster computing are described herein. A worker device may receive a dataset and store the dataset in a local storage media. This may prevent the need for the dataset to be sent over a network each time the applications are used to perform a task. Each application may be able to access the dataset in the local storage area. This may prevent the need to copy the dataset to memory associated with each application. A worker device may store a dataset, for example, if it determines that the frequency of updates to the dataset satisfy a threshold. The worker device may receive updates to the dataset via a messaging system and may store the updated data in the local storage media.

Profile based services and content can assist with the backward and forward compatibility of conventional service layers or the like. Using a profile to manage content and access to services offered may reduce the overhead or processing associated with providing those value added services by service layers.

A method is provided, including the following operations: executing a cloud video game in a data center; streaming video generated by the executing cloud video game over a network to a client device; deploying a cloud gaming proxy to an edge compute that is proximate to the client device; wherein the cloud gaming proxy buffers the video and retransmits lost packets of the video to the client device.

A graphical user interface is configured to guide a user through a method of creating an OData-compliant URL, without requiring that the user be familiar with syntax of OData-compliant URLs. The graphical user interface includes a set of graphical input devices to solicit and receive from the user input specifying a set of query options, which user input is used to define the OData-compliant URL. The graphical user interface is automatically customized to solicit and receive from the user input only for options available from a specific OData service.

A graphical user interface is configured to guide a user through a method of creating an OData-compliant URL, without requiring that the user be familiar with syntax of OData-compliant URLs. The graphical user interface includes a set of graphical input devices to solicit and receive from the user input specifying a set of query options, which user input is used to define the OData-compliant URL. The graphical user interface is automatically customized to solicit and receive from the user input only for options available from a specific OData service.

Distributed network address discovery in non-uniform node networks can be performed. Regarding a client request for a service, network management component (NMC) can determine a network address space associated with a client based on a network identifier associated with the client or a node identifier. NMC can determine a group of candidate nodes (CN group) from a group of nodes based on network addresses associated with nodes of the node group and the network address space. NMC can determine a group of available candidate nodes (ACN group), from the CN group, available and able to process the request and perform the service based on operational statuses associated with the nodes of the CN group or services associated with those nodes. From the ACN group, NMC can determine a ranked list of network addresses associated with available nodes that can process the request based on defined service performance criteria.

Distributed network address discovery in non-uniform node networks can be performed. Regarding a client request for a service, network management component (NMC) can determine a network address space associated with a client based on a network identifier associated with the client or a node identifier. NMC can determine a group of candidate nodes (CN group) from a group of nodes based on network addresses associated with nodes of the node group and the network address space. NMC can determine a group of available candidate nodes (ACN group), from the CN group, available and able to process the request and perform the service based on operational statuses associated with the nodes of the CN group or services associated with those nodes. From the ACN group, NMC can determine a ranked list of network addresses associated with available nodes that can process the request based on defined service performance criteria.