Abstract: A mobile computing device with a mobile operating system and desktop operating system running concurrently and independently on a shared kernel without virtualization. The mobile operating system provides a mobile user experience while the desktop operating system provides a full desktop user experience when the mobile computing device is docked to a secondary terminal environment. Applications of the desktop operating system communicate with applications and services of the mobile operating system through a cross-environment communication framework. The cross-environment communication framework may include application programming interfaces through which categories of applications can communicate across a multiple operating system computing environment through category-specific remote communication calls. The mobile computing device may be a smartphone running the Android mobile operating system and a full desktop Linux distribution on a modified Android kernel.

Abstract: A mobile computing device with a mobile operating system and desktop operating system running concurrently and independently on a shared kernel without virtualization. The mobile operating system provides a mobile user experience while the desktop operating system provides a full desktop user experience when the mobile computing device is docked to a secondary terminal environment. Applications of the desktop operating system communicate with applications and services of the mobile operating system through a cross-environment communication framework. The cross-environment communication framework may include application programming interfaces through which categories of applications can communicate across a multiple operating system computing environment through category-specific remote communication calls. The mobile computing device may be a smartphone running the Android mobile operating system and a full desktop Linux distribution on a modified Android kernel.

Abstract: A mobile computing device with a mobile operating system and desktop operating system running concurrently and independently on a shared kernel without virtualization. The mobile operating system provides a user experience for the mobile computing device that suits the mobile environment. The desktop operating system provides a full desktop user experience when the mobile computing device is docked to a secondary terminal environment. The desktop operating system may be suspended when the mobile computing device is not docked with a secondary terminal environment and resumed when the mobile computing device is docked with a secondary terminal environment that provides a desktop computing experience. The mobile computing device may be a smartphone running the Android mobile OS and a full desktop Linux OS distribution on a modified Android kernel.

Abstract: Cross-environment rendering and user interaction support provide a seamless computing experience in a multi-operating system computing environment. The multi-operating system computing environment may include a mobile operating system and a desktop operating system running concurrently and independently on a mobile computing device. The seamless computing experience includes mirroring the active user interaction space of the mobile operating system to a display of a user environment associated with the desktop operating system. The user interface is rendered by the desktop operating system by accessing surface information of the active user interaction space directly from shared memory. The mobile computing device may be a smartphone running the Android mobile operating system and a full desktop Linux distribution on a modified Android kernel.

Abstract: Cross-environment rendering and user interaction support provide a seamless computing experience in a multi-operating system computing environment. The multi-operating system computing environment may include a mobile operating system and a desktop operating system running concurrently and independently on a mobile computing device. The mobile operating system may be associated with a first user environment and the desktop operating system may be associated with a second user environment. Real-time display of applications running in the mobile operating system within the second user environment is provided by rendering the application through an extended graphics context of the mobile operating system. Application graphics for multiple applications are rendered into portions of a single graphics frame. The mobile computing device may be a smartphone running the Android mobile operating system and a full desktop Linux distribution on a modified Android kernel.

Abstract: A mobile computing device with a mobile operating system and desktop operating system running concurrently and independently on a shared kernel without virtualization. The mobile operating system provides a user experience for the mobile computing device that suits the mobile environment. The desktop operating system provides a full desktop user experience when the mobile computing device is docked to a secondary terminal environment. Applications of the desktop operating system communicate with applications and services of the mobile operating system through a cross-environment communication framework. The cross-environment communication framework may include interfaces to remotable objects allowing processes in the mobile operating system and processes in the desktop operating system to share memory in a thread-safe manner. The mobile computing device may be a smartphone running the Android mobile operating system and a full desktop Linux distribution on a modified Android kernel.

Abstract: A mobile computing device with a mobile operating system and desktop operating system running concurrently and independently on a shared kernel without virtualization. The mobile operating system provides a user experience for the mobile computing device that suits the mobile environment. The desktop operating system provides a full desktop user experience when the mobile computing device is docked to a second user environment. Cross-environment rendering and user interaction support provide a seamless computing experience in a multi-operating system computing environment. Real-time display of applications running in the mobile operating system within an environment of the desktop operating system is provided by rendering the application through an extended graphics context of the mobile operating system. Application graphics for multiple applications are rendered into separate graphics frames.

Abstract: Cross-environment rendering and user interaction support provide a seamless computing experience in a multi-operating system computing environment. Cross-environment rendering provides real-time display of applications running in a mobile operating system to be displayed within an environment of a desktop operating system. The mobile operating system and the desktop operating system may be running concurrently and independently on a shared kernel of a mobile computing device. A graphics server of the mobile operating system tears down and rebuilds the rendering context for each application as it composites the surface information. The rendering context may be established to match the resolution of the associated display, so that graphics will be appropriately rendered for that resolution. The mobile computing device may be a smartphone running the Android mobile operating system and a full desktop Linux distribution on a modified Android kernel.

Abstract: A mobile computing device with a mobile operating system and desktop operating system running concurrently and independently on a shared kernel without virtualization. The mobile operating system provides a mobile user while the desktop operating system provides a full desktop user experience when the mobile computing device is docked to a secondary terminal environment. Applications of the desktop operating system communicate with applications and services of the mobile operating system through a cross-environment communication framework. The cross-environment communication framework may include application programming interfaces through which categories of applications can communicate across a multiple operating system computing environment through category-specific remote communication calls. The mobile computing device may be a smartphone running the Android mobile operating system and a full desktop Linux distribution on a modified Android kernel.

Abstract: A mobile computing device with a mobile operating system and desktop operating system running concurrently and independently on a shared kernel without virtualization. The mobile operating system provides a user experience for the mobile computing device that suits the mobile environment. The desktop operating system provides a full desktop user experience when the mobile computing device is docked to a second user environment. Cross-environment rendering and user interaction support provide a seamless computing experience in a multi-operating system computing environment. The seamless computing experience includes mirroring the active user interaction space of the mobile operating system to a display of a user environment associated with the desktop operating system. The mobile computing device may be a smartphone running the Android mobile operating system and a full desktop Linux distribution on a modified Android kernel.

Abstract: Systems and methods for transfer of data including establishing two separate connections, the two separate connections including a high speed connection and a high integrity connection. Blocks of data are exchanged over the high speed connection while the high integrity connection facilitates communication of descriptor data regarding data received over the high speed connection. As such, the data transfer speed of the high speed connection is utilized while communication via the high integrity connection allows for data reliability features not provided by the high speed connection.

Abstract: Systems and methods for transfer of data including establishing two separate connections, the two separate connections including a high speed connection and a high integrity connection. Blocks of data are exchanged over the high speed connection while the high integrity connection facilitates communication of descriptor data regarding data received over the high speed connection. As such, the data transfer speed of the high speed connection is utilized while communication via the high integrity connection allows for data reliability features not provided by the high speed connection.

Abstract: Systems and methods for transfer of data including establishing two separate connections, the two separate connections including a high speed connection and a high integrity connection. Blocks of data are exchanged over the high speed connection while the high integrity connection facilitates communication of descriptor data regarding data received over the high speed connection. As such, the data transfer speed of the high speed connection is utilized while communication via the high integrity connection allows for data reliability features not provided by the high speed connection. The systems and methods may include receiver side data handling such that data received chronologically out of order may be ordered at the receiver.