The objective of the present invention is to prevent a conflict between variable names and unintended overwriting of data when a plurality of programs that define shared variables exist. A compiler device (12) includes: an identifier acquisition part (121a) for acquiring an identifier of a first user program; a shared variable name generation part (121b) for generating a shared variable name that includes a variable name of a shared variable and the identifier; a conversion part (121c) for converting the first user program to machine language; and an address determination part (122a) for determining an address of the shared variable. The address determination part (122a) associates the shared variable name and the address of the shared variable with each other and embeds these in the first user program that has been converted to machine language.

A mini program batch processing method and apparatus, an electronic device, and a readable storage medium are provided. A method includes: establishing a batch package submission creation event; creating, in response to the batch package submission creation event, a batch package submission task to generate a package submission work queue comprising a plurality of mini program package submission tasks; extracting a first quantity of mini program package submission tasks from the package submission work queue; creating a virtual mini program package for each of the first quantity of mini program package submission tasks; and updating the virtual mini program package to a mini program online package and automatically releasing the mini program online package.

A mini program batch processing method and apparatus, an electronic device, and a readable storage medium are provided. A method includes: establishing a batch package submission creation event; creating, in response to the batch package submission creation event, a batch package submission task to generate a package submission work queue comprising a plurality of mini program package submission tasks; extracting a first quantity of mini program package submission tasks from the package submission work queue; creating a virtual mini program package for each of the first quantity of mini program package submission tasks; and updating the virtual mini program package to a mini program online package and automatically releasing the mini program online package.

Generation of an executable file derived from a parent executable file having ranges of physical addresses referencing a binary code of at least one core feature (CR), a binary code of a set of native features (F), bytecodes of a set of java features (Pkg), by selecting at least one native feature from the set of native features to be removed, defining the range of physical addresses where the binary code of the selected native feature is stored, selecting at least one java feature from the set of java features to be relocated, and relocating the bytecodes of said at least one selected java feature in the defined range of physical addresses.

Embodiments disclosed herein provide for systems and methods of identifying package files in an application. The systems and methods include a static scan, a library-dependent archive scan, and a dynamic scan, where, at the conclusion of the scans, a list including each of the unused and/or potentially conflicting libraries in an application may be provided to a user.

Embodiments disclosed herein provide for systems and methods of identifying package files in an application. The systems and methods include a static scan, a library-dependent archive scan, and a dynamic scan, where, at the conclusion of the scans, a list including each of the unused and/or potentially conflicting libraries in an application may be provided to a user.

An engineering apparatus according to the present disclosure generates generating executable code, which causes target hardware to operate, from a control application. The engineering apparatus includes an algorithm converter that converts control logic included in the control application into control logic code, a type management unit that outputs a type definition code corresponding to a data block structure of data held by a function block included in the control application, an instance management unit that outputs a memory allocation code that allocates an instance of the function block to memory, and a build controller that generates the executable code based on the control logic code, the type definition code, and the memory allocation code. Executable code for execution by target hardware is debugged while the executable code is in the form of a control application before conversion to a high-level language.

An engineering apparatus according to the present disclosure generates generating executable code, which causes target hardware to operate, from a control application. The engineering apparatus includes an algorithm converter that converts control logic included in the control application into control logic code, a type management unit that outputs a type definition code corresponding to a data block structure of data held by a function block included in the control application, an instance management unit that outputs a memory allocation code that allocates an instance of the function block to memory, and a build controller that generates the executable code based on the control logic code, the type definition code, and the memory allocation code. Executable code for execution by target hardware is debugged while the executable code is in the form of a control application before conversion to a high-level language.

The present disclosure relates to a method for generating a binding between a C/C++ library and one or more interpreted high-level languages, in order to expose the functionalities of the C/C++ library to this or these high-level languages, involving the following steps: a step of writing a definition of the binding in the form of a high-level language, a step of processing this definition in order to produce binding elements, a step of grouping the binding elements around each of the high-level language(s) to produce a C++ binding code, and a step of compiling the C++ code and linking this to the C/C++ library. This can be used, in particular, to implement human-machine interfaces for terrestrial, aerial or maritime mobile equipment.

The present disclosure relates to a method for generating a binding between a C/C++ library and one or more interpreted high-level languages, in order to expose the functionalities of the C/C++ library to this or these high-level languages, involving the following steps: a step of writing a definition of the binding in the form of a high-level language, a step of processing this definition in order to produce binding elements, a step of grouping the binding elements around each of the high-level language(s) to produce a C++ binding code, and a step of compiling the C++ code and linking this to the C/C++ library. This can be used, in particular, to implement human-machine interfaces for terrestrial, aerial or maritime mobile equipment.