The present application discloses an environment isolation method. First, a pre-configured full address in a routing address pool in a Remote Procedure Call (RPC) client terminal is automatically refreshed according to a preset cycle. The RPC client terminal stops automatic refresh in the routing address pool after receiving an environment isolation instruction sent by an environment isolation device, and replaces a current address in the routing address pool with a combined address. When subsequently receiving a service call request sent by a user, the RPC client terminal generates a valid target address based on the combined address in the routing address pool, sends the service call request to an RPC server terminal corresponding to the target address, and returns to the user a service processing result returned by the RPC server terminal.

Disclosed herein are method, system, and computer product embodiments for generating a graphical user interface (GUI) to visually represent a programmatic process with various process objects. This may also include interacting with interfaces of the GUI to update the programmatic process. Process objects may contain a hierarchy of functions. Through interaction with the GUI registration interface a process object may be modified such that the hierarchy of functions is changed. Additional process objects may be defined based on a hierarchy of functions. The GUI may also include an analysis interface which may display timing data associated with execution of the programmatic process.

Disclosed herein are method, system, and computer product embodiments for generating a graphical user interface (GUI) to visually represent a programmatic process with various process objects. This may also include interacting with interfaces of the GUI to update the programmatic process. Process objects may contain a hierarchy of functions. Through interaction with the GUI registration interface a process object may be modified such that the hierarchy of functions is changed. Additional process objects may be defined based on a hierarchy of functions. The GUI may also include an analysis interface which may display timing data associated with execution of the programmatic process.

A system generates a customized application data structure for modeling physical systems. The system includes a processor, an input device, optionally a display device, and a memory device. The processor is adapted to embed a multiphysics model data structure in the application data structure. The multiphysics model data structure comprises a representation of models of physical systems. Geometry data representing geometry subroutines and call data representing geometry subroutine calls are added to the embedded multiphysics model data structure. Data representing application features are added to the application data structure. Each application feature comprises one or more of (i) first data representing a form feature, or (ii) second data representing an action feature. A customized application data structure is generated providing a customized modeling of the physical systems using a modeling operation, a geometry of the one or more models of physical systems, an application feature, and a geometry subroutine. The customized application data structure is configured for distribution to end users as an application executed by an application runtime engine.

A system generates a customized application data structure for modeling physical systems. The system includes a processor, an input device, optionally a display device, and a memory device. The processor is adapted to embed a multiphysics model data structure in the application data structure. The multiphysics model data structure comprises a representation of models of physical systems. Geometry data representing geometry subroutines and call data representing geometry subroutine calls are added to the embedded multiphysics model data structure. Data representing application features are added to the application data structure. Each application feature comprises one or more of (i) first data representing a form feature, or (ii) second data representing an action feature. A customized application data structure is generated providing a customized modeling of the physical systems using a modeling operation, a geometry of the one or more models of physical systems, an application feature, and a geometry subroutine. The customized application data structure is configured for distribution to end users as an application executed by an application runtime engine.

Exemplary embodiments may provide an automated approach for processing an input data sample to yield a set of object classes, a parser and one or more unit tests for input data that is to be integrated into a data lake. The objects may be readily queried and, in some instances, may be Plain Old Java Objects (POJO's). The exemplary embodiments may process an input data sample to better understand the format of the input data. The input sample may be processed to identify entities, such as records, objects or the like, in the input data sample. The input data sample may be processed on a line by line basis to identify fields in the entities. Once the format of the input data is determined from the input data sample, a parser may be generated to parse the input data.

A method for permitting a program to be analyzed and tuned includes the steps of receiving a program which itself includes a plurality of stages, where execution of the program follows a plurality of distinct paths, each of the distinct paths including one or more of the stages. The method further includes determining unique paths of the program and determining execution boundaries of the program. In addition, the method includes persisting the unique paths and the execution boundaries in a database, and changing an execution of the program based on the persisted unique paths and execution boundaries.

A method for permitting a program to be analyzed and tuned includes the steps of receiving a program which itself includes a plurality of stages, where execution of the program follows a plurality of distinct paths, each of the distinct paths including one or more of the stages. The method further includes determining unique paths of the program and determining execution boundaries of the program. In addition, the method includes persisting the unique paths and the execution boundaries in a database, and changing an execution of the program based on the persisted unique paths and execution boundaries.

The technology disclosed offers a declarative and visualization framework that implements a state machine for multi-step progression of interaction with an entity. The declarative framework is usable over and over for a broad range of applications because it provides a simple rule-based authoring tool that can be used for specifying different elements and components of a complex state machine, including state definitions, state transition triggers, state transition conditions and state transition actions. Once defined, the state machine is automatically generated and visually implemented based on the declarative input provided by a non-technical user.

The technology disclosed offers a declarative and visualization framework that implements a state machine for multi-step progression of interaction with an entity. The declarative framework is usable over and over for a broad range of applications because it provides a simple rule-based authoring tool that can be used for specifying different elements and components of a complex state machine, including state definitions, state transition triggers, state transition conditions and state transition actions. Once defined, the state machine is automatically generated and visually implemented based on the declarative input provided by a non-technical user.