CN106933567B - GUI system of graphic user interface - Google Patents

Abstract

The embodiment of the invention provides a Graphical User Interface (GUI) system, which relates to the technical field of nuclear power safety level, and comprises: the graphic library module is used for analyzing graphic data in the configuration file; the icon library module is used for analyzing the icon data in the configuration file; the graphic display module is used for drawing a GUI (graphical user interface) graphic according to the data obtained by the analysis of the graphic library module and the data obtained by the analysis of the icon library module; wherein the configuration file is used to indicate the basic settings and basic files loaded by the GUI system. The GUI system provided by the embodiment of the invention is a platform product, the whole GUI system does not need to be redesigned aiming at different nuclear power projects, and only configuration files need to be compiled, so that the workload and the V & V review are reduced.

Description

GUI system of graphic user interface

Technical Field

The embodiment of the invention relates to the technical field of nuclear power, in particular to a Graphical User Interface (GUI) system.

Background

There are many GUI systems on the market today, for example: WinCE's GWES (graphical User Interface of microsoft embedded operating system, including Graphics, windows, and event subsystem), which is composed of Application Programming Interface (API), User Interface (UI), and Graphics Device Interface (GDI), and includes message mechanism), MiniGUI (embedded Linux system-based middleware, supporting multiple threads and multiple processes), and UC/GUI (GUI supporting multiple environments, which can be operated in single-task, multiple-task, or foreground-background mode). The patent CN103729587A provides a chip integrating a fingerprint interface, a fingerprint algorithm, a security algorithm and a related accelerator, which relates to designing Ram and Flash storage related contents; the patent CN1758581A discloses a "method and system for protecting integrity of data transmitted between an input/output bus and a network" relating to network data redundancy check, "the patent CN105095039A discloses a" method and device for power-on self-test of I/O plug-in "relating to hardware self-test content, and the patent CN105446739A provides a" method and device for setting UI interface "relating to functions such as parsing configuration file corresponding to UI interface.

Although the GUI systems have rich functions, none of the GUI systems can meet the requirements of the nuclear power safety level standard (I EC60880), and the IEC60880 requirements are software requirements of instruments and control systems that perform a class a safety function in a nuclear power plant, and are a development process of a full life cycle of software, such as software requirement specification, software verification, software tools for software development, software design and implementation, software-aspect system integration, software-aspect system validation, and software maintenance.

Disclosure of Invention

The embodiment of the invention provides a Graphical User Interface (GUI) system, which is applied to the field of nuclear power safety level.

According to an aspect of an embodiment of the present invention, there is provided a GUI system, including:

the graphic library module is used for analyzing graphic data in the configuration file;

the icon library module is used for analyzing the icon data in the configuration file;

the graphic display module is used for drawing a GUI (graphical user interface) graphic according to the data obtained by the analysis of the graphic library module and the data obtained by the analysis of the icon library module;

wherein the configuration file is used to indicate the basic settings and basic files loaded by the GUI system.

The GUI system provided by the embodiment of the invention is applied to the technical field of nuclear power safety level, and meets the requirements of different nuclear power projects by compiling configuration files, and comprises the following components: the graphic library module is used for analyzing graphic data in the configuration file; the icon library module is used for analyzing the icon data in the configuration file; the graphic display module is used for drawing a GUI (graphical user interface) graphic according to the data obtained by the analysis of the graphic library module and the data obtained by the analysis of the icon library module; the configuration file is used for indicating basic settings and basic files loaded by the GUI system, and is a plurality of engineering project application files generated by configuration and compiling through an EAST development environment, so that under the condition that GUI system codes are not changed, engineering applications of different nuclear power projects are realized through EAST configuration, and the method comprises the following steps: graphical data, icon data, algorithm data, and network configuration data. The safety-level GUI system provided by the embodiment of the invention is a platform product, the whole GUI system does not need to be redesigned aiming at different nuclear power projects, and only a configuration file needs to be compiled, so that the workload and verification (V & V) review are reduced.

Drawings

FIG. 1 is a schematic structural diagram of a GUI system according to a first embodiment of the present invention;

FIG. 2 is a schematic structural diagram of a GUI system according to a second embodiment of the present invention;

FIG. 3 is a schematic structural diagram of a GUI system according to a third embodiment of the present invention;

FIG. 4 is a schematic diagram of a storage structure of a GUI system according to a fourth embodiment of the present invention;

fig. 5 is a data flow diagram of a GUI system according to a fifth embodiment of the present invention.

Detailed Description

The following detailed description of embodiments of the invention is provided in conjunction with the accompanying drawings (like numerals indicate like elements throughout the several views) and examples. The following examples are given for illustration.

It will be understood by those within the art that the terms "first", etc. in the embodiments of the present invention are used only for distinguishing between different steps, devices or modules, etc., and do not denote any particular technical meaning or necessarily order therebetween.

Example one

Fig. 1 is a schematic structural diagram of a GUI system according to a first embodiment of the present invention.

Referring to fig. 1, a GUI system of a graphical user interface provided in this embodiment includes: the graphic library module 100 is used for parsing graphic data in the configuration file, for example, parsing information such as graphic coordinates, length, width and the like in the configuration file. The graphic data in this embodiment includes: points, lines, faces, and buttons, text, and hand operator controls, among others.

The icon library module 102 is configured to parse icon data in the configuration file, where the icon data in this embodiment includes a length of an icon, a width of the icon, picture content of the icon, and the like.

And the graphic display module 104 is used for providing a graphic drawing interface for the application layer program and drawing the GUI graphics according to the data obtained by the analysis of the graphic library module 100 and the data obtained by the analysis of the icon library module 102. The graphic rendering interface in this embodiment includes: drawing points, drawing line segments, drawing circles, drawing rectangles, and drawing other polygons, filling backgrounds, filling circles, filling ellipses, filling rectangles, displaying images, displaying text, etc.

The configuration file in this embodiment is used to indicate the basic settings and basic files loaded by the GUI system. The GUI system provided by the embodiment can adapt to different nuclear power projects by compiling the configuration file.

The method aims to solve the problem that no independent product exists in the domestic nuclear power safety level GUI system at present, and is applied to the GUI system in the field of nuclear power safety levels. The embodiment of the invention provides a Graphical User Interface (GUI) system, which is applied to the technical field of nuclear power safety level and meets the requirements of different nuclear power projects by compiling configuration files, and the GUI system comprises: the graphic library module is used for analyzing graphic data in the configuration file; the icon library module is used for analyzing the icon data in the configuration file; the graphic display module is used for drawing a GUI (graphical user interface) graphic according to the data obtained by the analysis of the graphic library module and the data obtained by the analysis of the icon library module; wherein the configuration file is used to indicate the basic settings and basic files loaded by the GUI system. The GUI system provided by the embodiment of the invention is a platform product, the whole GUI system does not need to be redesigned aiming at different nuclear power projects, and only configuration files need to be compiled, so that the workload and the V & V review are reduced.

Example two

Fig. 2 is a schematic structural diagram of a GUI system according to a second embodiment of the present invention.

Referring to fig. 2, the GUI system of the present embodiment includes: the graphic library module 200 is used for parsing the graphic data in the configuration file, for example, parsing the information such as the coordinates, length, width, etc. of the graphic in the configuration file. The graphic data in this embodiment includes: points, lines, faces, and buttons, text, and hand operator controls, among others.

Optionally, the configuration file in this embodiment may include algorithm data, network configuration data, field device configuration data, and the like, in addition to the graphic data.

Optionally, the graphic library module 200 in this embodiment is further configured to display status information of the field devices, and/or receive control field device operations input through the manipulator panel, and run logic algorithms associated with the manipulator panel in the algorithm data. Wherein, the field device can include: valves (opening degree and closing degree), sensors, switching value equipment and the like. The manipulator panel is a set of predefined controls comprising: point controls, line controls, face controls, text controls, icon controls, and the like. Each control is associated with a variable, and the GUI system in this embodiment displays the state of each control according to the state of the variable associated with the control. The logic algorithm is stored in the algorithm data, and the logic relations between the control and the face changing and between the control and the control in the manipulator panel are processed by the logic algorithm.

Optionally, the GUI system in this embodiment may further include a plurality of templates of the manipulator panel, where the templates are used to indicate use cases of the manipulator panel.

The icon library module 202 is configured to parse icon data in the configuration file, where the icon data in this embodiment includes a length of an icon, a width of the icon, picture content of the icon, and the like.

And the graphic display module 204 is configured to provide a graphic drawing interface for the application layer program, and draw a GUI graphic according to the data obtained through analysis by the graphic library module 200 and the data obtained through analysis by the icon library module 202. The graphic rendering interface in this embodiment includes: drawing points, drawing line segments, drawing circles, drawing rectangles, and drawing other polygons, filling backgrounds, filling circles, filling ellipses, filling rectangles, displaying images, displaying text, etc.

Optionally, the GUI system provided in this embodiment further includes: and a self-diagnosis module 206 for performing fault diagnosis on the RAM and the ROM of the GUI system and monitoring a program execution sequence of the GUI system. The RAM and ROM in this embodiment are two-part areas divided from the memory of the GUI system. The ROM is a read-only area for storing icon data, graphic data, and a word stock. Wherein the word stock stored in the ROM is copied to the ROM by the FLASH of the GUI system. And the self-diagnosis module 206 is used for performing ROM fault diagnosis by judging whether the cyclic redundancy check value of the ROM is the same as the cyclic redundancy check value of the GUI system in the initialization stage when the GUI system is in the periodic operation stage. The RAM is a readable and writable area and is used for storing dynamic page parameter data and algorithm data. The graphics data in this embodiment are associated with memory addresses in the RAM where the dynamic page parameter data is stored. During the periodic operation phase of the GUI system, the data stored in the RAM can be changed at any time. After the GUI system initialization stage, the periodic operation stage of the condition cycle is entered, and the functions of hardware monitoring, network communication, algorithm operation, graphic display, hardware interface data reading and the like are sequentially executed.

The configuration file in this embodiment is used to indicate the basic settings and basic files loaded by the GUI system. The GUI system provided by the embodiment can adapt to different nuclear power projects by compiling the configuration file.

The method aims to solve the problem that no independent product exists in the domestic nuclear power safety level GUI system at present, and is applied to the GUI system in the field of nuclear power safety levels. The embodiment of the invention provides a Graphical User Interface (GUI) system, which is applied to the technical field of nuclear power safety level and meets the requirements of different nuclear power projects by compiling configuration files, and the GUI system comprises: the graphic library module is used for analyzing graphic data in the configuration file; the icon library module is used for analyzing the icon data in the configuration file; the graphic display module is used for drawing a GUI (graphical user interface) graphic according to the data obtained by the analysis of the graphic library module and the data obtained by the analysis of the icon library module; wherein the configuration file is used to indicate the basic settings and basic files loaded by the GUI system. The GUI system provided by the embodiment of the invention is a platform product, the whole GUI system does not need to be redesigned aiming at different nuclear power projects, and only configuration files need to be compiled, so that the workload and the V & V review are reduced.

The GUI system in the embodiment provides a plurality of templates of the manipulator panel, and improves the convenience of designing the manipulator panel.

The self-diagnosis module carries out fault diagnosis on the RAM and the ROM and monitors the program execution sequence of the GUI system, so that the safety and the stability of the GUI system are improved.

EXAMPLE III

Fig. 3 is a schematic structural diagram of a GUI system according to a third embodiment of the present invention.

Referring to fig. 3, the GUI system of the present embodiment includes: the system comprises a graphic display module 300, a graphic library module 302, an icon library module 304, an operation panel 306, a cyclic redundancy check value checking module 308, a self-diagnosis module 310, a word library 312, a character string processing module 314, a data conversion module 316, a hardware driving module 318, algorithm data 320 and a coordinate input interface 322.

The graphic display module 300 provides a graphic drawing interface to the application layer program, and the graphic drawing interface in this embodiment includes: drawing points, drawing line segments, drawing circles, drawing rectangles, and drawing other polygons, filling backgrounds, filling circles, filling ellipses, filling rectangles, displaying images, displaying text, etc.

The graphic library module 302 analyzes information such as graphic coordinates, length, width and the like in the configuration file, and specifically can analyze points, lines, faces, buttons, texts, manual operator controls and the like. The graphics library module 302 has two functions in the GUI system, one is to display status information of the field devices; the other function is to allow the user to operate the manipulator panel to realize the control of the field device, and simultaneously run the logic algorithm related to the manipulator panel in the algorithm data 320, so as to realize the functions of operation feedback, data transmission speed and the like.

The icon library module 304 stores icon information including length information of the icons, width information of the icons, and picture contents in the icons.

The operator panel 306 is a manipulator panel, and includes panel logic (logic algorithms) that is configured by a configuration program and downloaded to the GUI system.

The crc value check module 308 mainly handles the calculation, check, and appending functions of the crc value.

The self-diagnosis module 310 is mainly responsible for fault diagnosis of the ROM and the RAM, and monitoring the execution sequence of the program.

The font library 312 provides a font library for screen display that meets the human factor criterion NUREG 0700.

The string processing module 314 is used to obtain the length of the string, copy the string, compare the string and search the string.

The data conversion module 316 is used for converting characters into floating-point numbers and interconversion between integer data, wherein interconversion between integer data includes conversion of unsigned short integer data into signed long integer data.

The hardware driver module 318 provides Serial Peripheral Interface (SPI) bus driver, FLASH driver, Universal Asynchronous Receiver/Transmitter (UART) driver, Liquid Crystal Display (LCD) driver, dot matrix driver, and touch screen driver. The hardware driver module 318 does not use an interrupt function and does not use a Direct Memory Access (DMA) function.

Algorithm data 320 is a logical algorithm generated for user configuration, written in standard C language.

The coordinate input interface 322 reads coordinate information of the display screen, for example, reads coordinate information of the touch display screen, and feeds back the coordinate information to the GUI system.

The method aims to solve the problem that no independent product exists in the domestic nuclear power safety level GUI system at present, and is applied to the GUI system in the field of nuclear power safety levels. The embodiment of the invention provides a Graphical User Interface (GUI) system, which is applied to the technical field of nuclear power safety level and meets the requirements of different nuclear power projects by compiling configuration files, and the GUI system comprises: the graphic library module is used for analyzing graphic data in the configuration file; the icon library module is used for analyzing the icon data in the configuration file; the graphic display module is used for drawing a GUI (graphical user interface) graphic according to the data obtained by the analysis of the graphic library module and the data obtained by the analysis of the icon library module; wherein the configuration file is used to indicate the basic settings and basic files loaded by the GUI system. The GUI system provided by the embodiment of the invention is a platform product, the whole GUI system does not need to be redesigned aiming at different nuclear power projects, and only configuration files need to be compiled, so that the workload and the V & V review are reduced.

The self-diagnosis module carries out fault diagnosis on the RAM and the ROM and monitors the program execution sequence of the GUI system, so that the safety and the stability of the GUI system are improved.

Example four

Fig. 4 is a schematic diagram of a storage structure of a GUI system according to a fourth embodiment of the present invention.

Referring to fig. 4, the GUI system of the present embodiment includes: RAM, ROM, SPI-FLASH and FLASH. The RAM is a readable and writable area divided by the memory and used for storing dynamic page parameter data and algorithm data. The dynamic page parameter data is associated according to a dynamic data area address pointed by each static graphic data (such as a text box, a button, a manipulator panel and the like) in the GUI system initialization stage. During the periodic operation phase of the GUI system, the data in the RAM changes at any time. The ROM is a read-only area divided by the memory and used for storing icon data, graphic data and a word stock, and the ROM is checked regularly in the periodic operation stage of the GUI system. Specifically, in the GUI system initialization stage, the cyclic redundancy check value may be calculated for the ROM according to a preset capacity, for example, 1KB, and stored in a preset location. And in the periodic operation stage of the GUI system, checking the content in the ROM according to a preset capacity sequence, and judging whether the content in the ROM is rewritten. The SPI-FLASH is used for storing human-computer interface data and comprises the following steps: configuration files and log files, the configuration files including algorithm data, graphic data and icon data. And writing the configuration file into the SPI-FLASH of the GUI system when the GUI system is in a downloading mode. The FLASH stores program codes, and the program codes comprise Boot codes, GUI codes and word stock.

The method aims to solve the problem that no independent product exists in the domestic nuclear power safety level GUI system at present, and is applied to the GUI system in the field of nuclear power safety levels. The embodiment of the invention provides a Graphical User Interface (GUI) system, which is applied to the technical field of nuclear power safety level.

And the log file is stored in the SPI-FLASH which cannot be erased, the log file cannot be damaged or lost, the GUI system works in a running mode and is forbidden to erase the configuration file, and the configuration file can be modified in a downloading mode. The run/download mode is switched by a hardware key switch and the device needs to be powered up again, the run/download is two independent executable bin codes, and meets the I EC-60880 core security standard.

EXAMPLE five

Fig. 5 is a data flow diagram of a GUI system according to a fifth embodiment of the present invention.

Referring to fig. 5, in the GUI system of the GUI in the present embodiment, the graphic display module is a basic module for drawing the GUI system, and the graphic display module directly calls hardware drivers of the SPI-FLASH, the UART, the LCD, and the like downward through the hardware driver module and connects various functional units upward.

Wherein, various functional units include: the system comprises a graphic library module, an icon library module, an operation panel, a cyclic redundancy check value checking module, a self-diagnosis module, a word library, a character string processing module, a data conversion module, algorithm data, a coordinate input interface and an exception handling module.

And the coordinate input interface is used for calling UART hardware drive to read the coordinate information of the touch screen and transmitting the coordinate information to the operation panel.

And the operation panel is used for dynamically displaying the operation feedback information of the field equipment by executing the corresponding logic algorithm in the algorithm data. The logic algorithm has a secondary operation (confirmation or cancellation) function, prevents misoperation of a user, meets human factor standards, and improves the safety and reliability of the GUI system.

And the data conversion module is used for converting the received parameter data into character strings, and the character string processing module is used for normalizing the character strings obtained by conversion and loading a character library. And the word stock is verified by a cyclic redundancy check value verification module in the initialization stage of the GUI system.

And the self-diagnosis module is used for periodically carrying out fault diagnosis on the ROM, the RAM and the hardware equipment.

And the exception handling module is used for displaying fault codes in a designated area of a screen and recording fault logs when the GUI system has serious faults caused by software and hardware, meanwhile, the GUI codes run to a fault mode, and log files are stored in the SPI-FLASH during the fault mode, so that the I EC-60880 core safety standard is met.

And the graphic library module is used for analyzing the graphic data in the configuration file to obtain graphic files such as basic graphics, buttons, texts and the like in the operation panel.

And the icon library module is used for analyzing the icon data in the configuration file to obtain the icon file in the operation panel.

The image display module is used for displaying the character string processed by the character string processing module; the display device is also used for displaying graphic files such as basic graphics, buttons and texts in the operation panel and icon files in the operation panel; the system is also used for displaying the diagnosis results of the memory, the hardware and the like; and also for displaying exception handling status and results, etc.

The method aims to solve the problem that no independent product exists in the domestic nuclear power safety level GUI system at present, and is applied to the GUI system in the field of nuclear power safety levels. The embodiment of the invention provides a Graphical User Interface (GUI) system, which is applied to the technical field of nuclear power safety level, the requirements of different nuclear power projects are met by compiling configuration files, a logic algorithm has a secondary operation (confirmation or cancellation) function, misoperation of a user is prevented, human factor standards are met, and the safety and the reliability of the GUI system are improved.

The self-diagnosis module carries out fault diagnosis on the RAM and the ROM and monitors the program execution sequence of the GUI system, so that the safety and the stability of the GUI system are improved.

The log file is stored in the SPI-FLASH which cannot be erased, the log file cannot be damaged or lost, and the IEC-60880 nuclear safety standard is met.

It should be noted that, according to the implementation requirement, each component/step described in the embodiment of the present invention may be divided into more components/steps, and two or more components/steps or partial operations of the components/steps may also be combined into a new component/step to achieve the purpose of the embodiment of the present invention.

The above-described method according to an embodiment of the present invention may be implemented in hardware, firmware, or as software or computer code storable in a recording medium such as a CD ROM, a RAM, a floppy disk, a hard disk, or a magneto-optical disk, or as computer code originally stored in a remote recording medium or a non-transitory machine-readable medium downloaded through a network and to be stored in a local recording medium, so that the method described herein may be stored in such software processing on a recording medium using a general-purpose computer, a dedicated processor, or programmable or dedicated hardware such as an ASIC or FPGA. It will be appreciated that the computer, processor, microprocessor controller or programmable hardware includes memory components (e.g., RAM, ROM, flash memory, etc.) that can store or receive software or computer code that, when accessed and executed by the computer, processor or hardware, implements the GUI system described herein. Further, when a general-purpose computer accesses code for implementing the GUI system shown herein, execution of the code transforms the general-purpose computer into a special-purpose computer for executing the GUI system shown herein.

Those of ordinary skill in the art will appreciate that the various illustrative elements and method steps described in connection with the embodiments disclosed herein may be implemented as electronic hardware, or combinations of computer software and electronic hardware. Whether such functionality is implemented as hardware or software depends upon the particular application and design constraints imposed on the implementation. Skilled artisans may implement the described functionality in varying ways for each particular application, but such implementation decisions should not be interpreted as causing a departure from the scope of the present embodiments.

The above embodiments are only for illustrating the embodiments of the present invention and not for limiting the embodiments of the present invention, and those skilled in the art can make various changes and modifications without departing from the spirit and scope of the embodiments of the present invention, so that all equivalent technical solutions also belong to the scope of the embodiments of the present invention, and the scope of patent protection of the embodiments of the present invention should be defined by the claims.

Claims (11)

1. A graphical user interface, GUI, system, the GUI system being a security-level platformized product, the GUI system comprising:

the graphic library module is used for analyzing graphic data in the configuration file;

the icon library module is used for analyzing the icon data in the configuration file;

the graphic display module is used for drawing a GUI (graphical user interface) graphic according to the data obtained by the analysis of the graphic library module and the data obtained by the analysis of the icon library module;

wherein the configuration file comprises: the GUI system comprises graphic data, icon data, algorithm data and network configuration data, wherein the configuration files are used for indicating basic settings and basic files loaded by the GUI system and are a plurality of engineering project application files generated by configuration and compiling through an EAST development environment; under the condition that GUI system codes are not changed, engineering application of different nuclear power projects is achieved through EAST configuration, the whole GUI system does not need to be redesigned for the different nuclear power projects, and only configuration files need to be compiled.

2. The GUI system of claim 1, wherein said graphics library module is further configured to display status information of field devices and/or to receive input from a manipulator panel to control operation of said field devices and to run logical algorithms associated with said manipulator panel in said algorithm data.

3. The GUI system of claim 2, wherein said GUI system further comprises: a plurality of templates of the manipulator panel, the templates for indicating use cases of the manipulator panel.

4. The GUI system of claim 1, wherein said GUI system further comprises:

and the self-diagnosis module is used for carrying out fault diagnosis on the RAM and the ROM of the GUI system and monitoring the program execution sequence of the GUI system.

5. The GUI system of claim 4, wherein said self-diagnostic module is configured to perform a ROM fault diagnosis by determining whether a cyclic redundancy check value of said ROM is the same as a cyclic redundancy check value of said GUI system in an initialization phase when said GUI system is in a periodic operation phase.

6. The GUI system of claim 4, wherein said RAM stores dynamic page parameter data and said algorithm data.

7. The GUI system of claim 6, wherein the graphics data is associated with a memory address in the RAM where the dynamic page parameter data is stored.

8. The GUI system of claim 4, wherein said ROM stores a word stock, said icon data, and said graphic data.

9. The GUI system of claim 8, wherein said word stock is copied to said ROM by a FLASH of said GUI system, said FLASH storing program code, said program code comprising Boot code, GUI code and word stock.

10. The GUI system of claim 9, wherein said configuration file is written to an SPI-FLASH of said GUI system when said GUI system is in a download mode, said SPI-FLASH further storing a log file.

11. The GUI system of claim 10, wherein said FLASH and said SPI-FLASH are physically isolated.

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