A device, system and method controlling operation of a client device via an intermediation server are provided. The server maintains indications of predefined data descriptions, associated with respective provider systems, comprising a subset of given predefined data descriptions to be provided at a client device during implementation of a computing-process flow in conjunction with communicating with the respective provider systems. The server: provides, to the respective provider systems, a communication from the client device received in conjunction with implementing a given step of the computing-process flow; and receives, from a given provider system, a response to the communication. The server provides, to the client device: the response; and a predefined data description associated with the given provider system in the indications, the predefined data description provided at the client device in conjunction with the response causing the client device to implement the predefined data description, according to the computing-process flow.

A device, system and method controlling operation of a client device via an intermediation server are provided. The server maintains indications of predefined data descriptions, associated with respective provider systems, comprising a subset of given predefined data descriptions to be provided at a client device during implementation of a computing-process flow in conjunction with communicating with the respective provider systems. The server: provides, to the respective provider systems, a communication from the client device received in conjunction with implementing a given step of the computing-process flow; and receives, from a given provider system, a response to the communication. The server provides, to the client device: the response; and a predefined data description associated with the given provider system in the indications, the predefined data description provided at the client device in conjunction with the response causing the client device to implement the predefined data description, according to the computing-process flow.

A method, system and apparatus are disclosed. A network node is configured to communicate with a wireless device, WD, where the network node configured to, and/or comprising a radio interface and/or comprising processing circuitry configured to: receive an indication whether the WD is to cache at least one file based on spatial statistics of a cache-enabled device-to-device, D2D, network collected by the WD, and perform spectrum allocation based on the received indication.

Disclosed are various approaches for remote working experience optimization. In some examples, a management service receives task execution data and corresponding user data for multiple client devices. The management service inputs target user context data along with the task execution data and the corresponding user data into a prediction model to identify a task and a task schedule that indicates a time to download and cache task content. Instructions are transmitted for a management agent to download and cache the task content according to the task schedule.

Described embodiments provide systems and methods for providing data loss prevention via an embedded browser. An interprocess communication (IPC) manager may interface with an embedded browser to control the transfer of data from a first application to a second application in accordance with a policy. The IPC manager may detect a command to store data accessed on the first application via the embedded browser and store the data onto a secure container. The secure container may be dedicated to the embedded browser. The IPC manager may subsequently detect a command to retrieve data from the secure container and to replicate the data onto the second application. The IPC manager may determine a policy to apply to the data. The policy may specify whether the data from the first application is permitted to be replicated onto the second application. The IPC manager may subsequently replicate the data on the second application.

Described embodiments provide systems and methods for providing data loss prevention via an embedded browser. An interprocess communication (IPC) manager may interface with an embedded browser to control the transfer of data from a first application to a second application in accordance with a policy. The IPC manager may detect a command to store data accessed on the first application via the embedded browser and store the data onto a secure container. The secure container may be dedicated to the embedded browser. The IPC manager may subsequently detect a command to retrieve data from the secure container and to replicate the data onto the second application. The IPC manager may determine a policy to apply to the data. The policy may specify whether the data from the first application is permitted to be replicated onto the second application. The IPC manager may subsequently replicate the data on the second application.

In one disclosed method, a computing system receives a first request to download a first file to a client device. The computing system further sends, based at least in part on the first request, a first digest of the first file to the client device to enable the client device to compare the first digest with at least a second digest of a second file stored locally at the client device. The computing system further receives, after sending the first digest to the client device, a second request to refrain from downloading the first file to the client device.

In one disclosed method, a computing system receives a first request to download a first file to a client device. The computing system further sends, based at least in part on the first request, a first digest of the first file to the client device to enable the client device to compare the first digest with at least a second digest of a second file stored locally at the client device. The computing system further receives, after sending the first digest to the client device, a second request to refrain from downloading the first file to the client device.

Techniques are disclosed for the sharing and transferring of user data in online network systems operating in multiple jurisdictions. The different jurisdictions may be, for example, different geo-partitions in an online network system. Various techniques are disclosed for providing cross-partition operational functionalities (e.g., cross-geo transactions) between geo-partitioned server systems through the sharing and transferring of data between the geo-partitions. The geo-partitions may have established permissions for data that can be shared between the geo-partitions. A server system in one geo-partition may generate an auxiliary account from a subset of data shared across the geo-partitions that complies with the data permissions. Complying with the established data permissions may inhibit overlapping between the different laws or regulations of the geo-partitions.

Techniques are disclosed for the sharing and transferring of user data in online network systems operating in multiple jurisdictions. The different jurisdictions may be, for example, different geo-partitions in an online network system. Various techniques are disclosed for providing cross-partition operational functionalities (e.g., cross-geo transactions) between geo-partitioned server systems through the sharing and transferring of data between the geo-partitions. The geo-partitions may have established permissions for data that can be shared between the geo-partitions. A server system in one geo-partition may generate an auxiliary account from a subset of data shared across the geo-partitions that complies with the data permissions. Complying with the established data permissions may inhibit overlapping between the different laws or regulations of the geo-partitions.