The disclosure provides a method for managing multiple operating systems in a terminal. The terminal includes multiple operating systems and a management system. The management system is configured to manage the multiple operating systems. The management system includes a cross-system application database. The method includes: when a first operating system in the multiple operating systems runs in a foreground, and a second operating system in the multiple operating systems runs in a background, if the second operating system receives a first message of a first application in the second operating system, sending, by the second operating system, a notification message to the management system; storing, by the management system, the notification message into the cross-system application database; and listening, by the first operating system, on the cross-system application database, and outputting a prompt of the first message when listening and obtaining the notification message.

The present disclosure generally relates to controlling access to resources by selectively processing requests stored in a task queue to prioritize certain requests over others, thereby preventing automated scripts from accessing the resources. More specifically, the present disclosure relates to a normalization and prioritization system for controlling access to resources by queuing resource requests based on a client-defined normalization process that uses one or more data sources.

Methods and apparatus are disclosed for controlling distributed software applications implementing asynchronous replication of shared data objects. Each shared data object has a distinct token. A token has respective states (active or inactive) at each computing system sharing the data object. At most one computing system can have the token active at any time; possessing an active token allows a computing system to update the shared data object. Counters maintain state across the computing systems, and semantic checks specific to a class of data objects (or, a single object) ensure consistency of updates across computing systems. Token activation requests and update replication requests are supported. Participating computing systems can have asymmetric or symmetric roles. Token management can be provided by a framework offering superior performance compared to conventional locking systems, co-existence with local conventional locking systems, and a single uniform interface for streamlined integration with existing software applications.

A system and method for network traffic management between multiple nodes are described. A computing system includes multiple nodes connected to one another. When a home node determines a number of nodes requesting read access for a given data block assigned to the home node exceeds a threshold and a copy of the given data block is already stored at a first node of the multiple nodes in the system, the home node sends a command to the first node. The command directs the first node to forward a copy of the given data block to the home node. The home node then maintains a copy of the given data block and forwards copies of the given data block to other requesting nodes until the home node detects a write request or a lock release request for the given data block.

A method for executing atomic commands may include receiving, by an interface of an atomic command execution unit and from a plurality of requestors, a plurality of memory mapped atomic commands. The method may also include executing the plurality of memory mapped atomic commands to provide output values. The method may further include storing, in a first memory unit of the atomic command execution unit, requestor specific information. Different entries of a plurality of entries of the first memory unit may be allocated to different requestors of the plurality of requestors. The method may also include storing, in a second memory unit of the atomic command execution unit, the output values of the plurality of memory mapped atomic commands, and outputting, by the interface and to at least one of the plurality of requestors, at least one indication indicating a completion of at least one of the atomic commands.

Controlling a software process by causing the execution of a first software process on a computer, where the first software process is configured to exclusively access a resource on the computer, causing the execution of a second software process on the computer when the first software process has exclusive access to the resource, where the second software process is configured to perform a first predefined action that is independent of the second software process accessing the resource, attempt to access the resource, and perform a second predefined action that is dependent on the second software process accessing resource, and causing the first software process to terminate its exclusive access to the resource, thereby causing the second software process to access the resource and perform the second predefined action.

The present disclosure generally relates to controlling access to resources by selectively processing requests stored in a task queue to prioritize certain requests over others, thereby preventing automated scripts from accessing the resources. More specifically, the present disclosure relates to a normalization and prioritization system for controlling access to resources by queuing resource requests based on a client-defined normalization process that uses one or more data sources.

A synchronization manager interface determines a first state of execution of an application task executing on a first controller at defined synchronization points and further determines a second state of execution of the application task executing on a second controller at the defined synchronization points. The synchronization manager interface, when executed, configures the first controller to transmit the first state from the first controller to the second controller via a communications channel established between the controllers for verifying a successful synchronization of the application task on the controllers based on a comparison of the first state with the second state.

Computer devices and management methods are provided. In an implementation, a computer device includes a subrack common component and a plurality of service nodes, wherein each of the plurality of service nodes comprises a baseboard management controller (BMC connected to the subrack common component and configured to manage the subrack common component when being in a primary status.

A method for generating and updating a live dashboard of a building management system for a building includes generating a dashboard designer interface and causing the dashboard designer interface to be displayed on a user device of a user, receiving a graphic element from the user, wherein the graphic file supports animation and user interaction, generating a widget by binding the graphic element received from the user to a widget of the live dashboard, binding a data point to the widget based on a user selection via the dashboard designer interface, wherein the data point being a data point of building equipment of the building, receiving a value for the data point from the building equipment, and displaying the widget in the live dashboard, the widget including an indication of the value for the data point.