The subject matter of this specification can be implemented in, among other things, a method that includes accessing a plurality of target tasks for a computing system, the computing system comprising a plurality of resources, wherein the plurality of resources comprises a first server and a second server, accessing a plurality of configurations of the computing system, wherein each of the plurality of configurations identifies one or more resources of the plurality of resources to perform the respective target task of the plurality of target tasks, and performing, for each of the plurality of configurations, a simulation to determine a plurality of performance metrics, wherein each of the plurality of performance metrics predicts performance of at least one of the plurality of resources executing the plurality of target tasks on the computing system.

In one example of the disclosure, a graphic user interface is sent to a client system for display via a web browser. The graphic user interface is to enable receipt of a user instruction to commence recording of user actions made via the web browser upon a subject web application. Responsive to receipt of the user instruction, a key is caused to be sent via the web browser to a host system hosting the subject web application. The key and recording data indicative of user actions performed upon the subject web application via the web browser are received from the host system via the web browser. The key and the recording data are included within a web page or web pages of the subject web application. The key is utilized to access the recording data. The recording data is sent to the client system for display via the web browser.

A graphic session coordinator is established to enable remote virtualized graphics operations on behalf of a set of graphics request generators. A request generator submits a graphics session request to the session coordinator. A configuration operation is performed at one or more routing devices to enable graphics operation request packets from the request generator to be delivered to a first remote virtualized graphics device and to enable graphics operation response packets to be transmitted to a destination.

A method, computer system, and a computer program product for application sharing are provided. Setting information that includes a display preference of a receiver is received. Application content from a host computer is received. The application content includes at least one screen image. The at least one screen image is converted according to the setting information. The converted screen image is transmitted to a receiver computer for real-time screen sharing with the host computer. A host controller action signal is received. The host controller action signal represents a host controller action at the host computer. A content modification is transmitted to the receiver computer for the real-time screen sharing and for displaying with the converted at least one screen image. The content modification corresponds to the host controller action.

An Application Execution Server and a method for managing a Background Process which is associated with a Rich Internet Application which is accessible via a Web Browser of an Internet Enabled User Device. The Application Execution Server comprises a Background Process Manager which is adapted to create a Background Process, in response to receiving a request for such a process from the Rich Internet Application, the Background Process being adapted to recognize a triggered event associated with said associated rich Internet application and to invoke the Rich Internet Application, irrespective of whether the Web Browser and/or the Rich Internet Application is presently running or not.

Latency experienced by a user of a client device may be reduced by preloading virtual devices in anticipation of a connection request from the client device. For example, a plurality of virtual devices may be partially loaded prior to a connection request from a client device. In response to the connection request from the client device, a user associated with the client device may be identified and user profile information associated with the user may be retrieved. Based on the retrieved user profile information associated with the user, a virtual device, from among the plurality of preloaded virtual devices, may be loaded, such that the loading of the virtual device is complete and is specific to the user of the client device.

Embodiments of the present disclosure provide for improved interoperable data management between a user-accessed software application and an embedded software application. In some contexts, a user-accessed application provides both its own functionality as well as enabling access to functionality of an embedded application. The embedded application is accessed via a data-driven connection that provides several technical advantages and addresses various data interoperability and persistence problems. In some embodiments, a user-accessed application may be configured to provide functionality of multiple embedded applications consistent with the innovations herein described.

A desktop cloud system includes a desktop cloud server and a terminal. A virtual desktop instance is deployed on the desktop cloud server. The desktop cloud server is configured to obtain encoded data output by the virtual desktop instance, and send the encoded data to the terminal corresponding to the virtual desktop instance. The terminal is configured to decode the encoded data to obtain raw data, and present a virtual desktop based on the raw data.

According to at least one aspect, a system for remotely controlling an application installed on a device is provided. The system includes at least one processor and at least one computer-readable storage medium storing instructions which program the at least one processor to identify a task for the application installed on the device to perform, transmit a binary short message service (SMS) message to the device including a task code associated with the identified task, receive an information request from the device responsive to the binary SMS message, and transmit task information to the device responsive to receiving the information request.

Automation windows for robotic process automation (RPA) using multiple desktops are disclosed. One or more robot desktops are launched, and one or more RPA robots operate in the robot desktop(s). The robot desktops may not initially be the active desktop. When the robot(s) execute their automations, if an activity in the RPA robot workflow needs the robot desktop to be the active desktop, the active desktop is switched to the appropriate robot desktop when the appropriate robot desktop is not already active, and activit(ies) of the RPA workflow that require the robot desktop to be the active desktop are executed. In some embodiments, after RPA workflow execution finishes, the robot desktop, the RPA robot, or both, are automatically closed.