An electronic device including an application processor and a communication processor. The communication processor, for managing a resource memory, configured to monitor an occupancy rate of the resource memory for detecting a memory leakage, release a network connection when the electronic device is in an idle state, in response to the detecting of the memory leakage, initialize the resource memory after the network connection is released, and reconnect the network connection, wherein the idle state indicates a state when the electronic device is not occupied or used by a user, and wherein the initialization is performed at a non-flag area from among the resource memory.

Provided are a service transfer method and an electronic device. In the method, a first device stores, through a first data management module, persistent data and temporary data of a target application produced during running of the target application as stored data, and sends the stored data to a second device through the first data management module. The second device receives the stored data through a second data management module, and runs the target application based on the stored data upon completion of backing up the stored data.

Technologies for providing attestation for function as a service flavors include a compute device including circuitry configured to obtain function definition data indicative of a set of operations to be performed in a function and a set of hardware resources to be utilized by the function, execute a benchmark operation to produce benchmark data indicative of a measured performance of the function, and sign the function definition data and the benchmark data to produce function flavor data. The circuitry is also configured to provide the function flavor data to one or more other compute devices for validation that the function, when executed on the hardware resources, provides the measured performance and write, to a distributed ledger, the function flavor data.

Migrating application from on premise HPC cluster to serverless platform is tedious task and involves significant amount of human efforts as cloud infrastructure needs to be created, data along with libraries and application code need to be copied from on-premise to cloud, and application need to be made compliant for execution on cloud. Present disclosure provides method and system for performing automated migration of high performance computing application to serverless platform. The system first check cloud readiness of application based on operation qualification parameters of application. In case application is found to be cloud ready, the system determines whether application can be executed on serverless platform based on execution time of the application and permissible limits defined for application in service level agreements. Once the application is found to be executable on the serverless platform, the system performs automatic migration of the application to serverless platform using infrastructure automation engine.

A task handoff method includes: displaying a target task, where the target task is a task that is running in a foreground and can be handed off on a first device; and in response to detection that a device at which a target user is gazing is switched from the first device to a second device, handing off the target task from the first device to the second device, so as to display the target task on the second device; where the first device is associated with at least one third device, and the second device is any one of the at least one third device.

Disclosed herein are examples of systems and methods that may provide multiple virtual mobile phones for a user. For example, a back-end enterprise computer network architecture may interact with an application installed on a client device. Using the application, the user may generate multiple virtual mobile phones for different purposes, e.g., a work phone and a personal phone. The computer network architecture may further allow the user to label data to correspond to the different virtual mobile phones for an efficient storage and retrieval of the data. A back-end session manager may allow the user to seamlessly switch between the different virtual mobiles within a single client device or across multiple client devices.

A data processing system comprising: a first information processing device and a second information processing device, the second information processing device including: a second memory; and a second processor coupled to the second memory and the second processor configured to: convert a first identifier included in a first processing request from the first information processing device into a reversibly convertible first conversion identifier in response to receiving the first processing request; transmit the first processing request including the converted first conversion identifier to another information processing system; reconvert, in response to receiving a first execution result of a process corresponding to the first processing request, the first conversion identifier included in the first execution result into the first identifier; and transmit the first execution result including the reconverted first identifier and the first conversion identifier to the first information processing device.

In one embodiment, a method includes receiving, at a client system, an audio input, where the audio input comprises a coreference to a target object, accessing visual data from one or more camera associated with the client system, where the visual data comprises images portraying one or more objects, resolving the coreference to the target object from among the one or more objects, resoling the target object to a specific entity, and providing, at the client system, a response to the audio input, where the response comprises information about the specific entity.

Systems and methods are described for implementing a distributed unit in a radio access network that executes code on behalf of mobile devices. A distributed unit may be implemented on an edge server that is in close physical proximity to a radio unit, with few or no intervening devices. The edge server may thus provide services to mobile devices, such as executing code on behalf of a mobile device in an execution environment on the edge server, at significantly lower latency than more distant cloud-based servers. The edge server may preload computing environments with code for which a mobile device is likely to request execution (e.g., because a particular application is executing on the mobile device), and may determine whether to execute code on the edge server or on a cloud provider network.

In one embodiment, a method includes receiving, at a client system, an audio input, where the audio input comprises a coreference to a target object, accessing visual data from one or more camera associated with the client system, where the visual data comprises images portraying one or more objects, resolving the coreference to the target object from among the one or more objects, resoling the target object to a specific entity, and providing, at the client system, a response to the audio input, where the response comprises information about the specific entity.