JP2010182031A - Software generation support device - Google Patents

Software generation support device Download PDF

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JP2010182031A
JP2010182031A JP2009024058A JP2009024058A JP2010182031A JP 2010182031 A JP2010182031 A JP 2010182031A JP 2009024058 A JP2009024058 A JP 2009024058A JP 2009024058 A JP2009024058 A JP 2009024058A JP 2010182031 A JP2010182031 A JP 2010182031A
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symbol
software
source code
selected
symbols
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JP2009024058A
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Japanese (ja)
Inventor
Yusuke Kanehashi
Michitomo Suzuki
祐輔 金橋
道奉 鈴木
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Hitachi Kokusai Electric Inc
株式会社日立国際電気
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Priority to JP2009024058A priority Critical patent/JP2010182031A/en
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Abstract

<P>PROBLEM TO BE SOLVED: To reduce design-production cost of software by facilitating reuse or use of a source code of a processing function in a software component of a software wireless machine. <P>SOLUTION: When a registration mode is selected and designated, the software generation support device displays a display screen for registration mode according to a symbol source code registration control program 132, stores the source code and an intermediate symbol selected and designated by an input device 16, in association with each other in a symbol source code association table 143. When a modeling-generation mode is selected and designated, the software generation support device displays a display screen for modeling-generation mode on a display device 17 according to a modeling-generation control program 133, generates a software model by dragging and dropping a connection symbol SB3 and the intermediate symbol SB2 using the input device 16, and embeds the source code into an interface file FF based on the generated model. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to a software generation support apparatus that supports generation of software used in, for example, a software defined radio.

  Conventionally, software radios are often used in the field of mobile communications. A software defined radio has, for example, a plurality of software for each function and corresponds to a desired radio system by selecting necessary software from the plurality of software. It is possible to change the function and performance by software (see, for example, Patent Document 1).

JP 2005-39557 A

  By the way, when developing a software defined radio, increasing the software design / manufacturing efficiency leads to a reduction in radio development / manufacturing costs, which is very important. Therefore, it has been proposed that the software interface can be reused and reused by unifying the software interface.

  As a means for unifying software interfaces, the current direction is to use software design and manufacturing support tools. For example, by using a tool that generates a software interface from a design drawing using a model language, the compatibility between the software designed by the same tool and the software designed by the same standard and the platform Ensures compatibility. However, this type of conventional support tool does not have the function to generate source code other than the interface, so the source code cannot be reused and diverted, and there is a limit in reducing software design and manufacturing costs. .

  The present invention has been made paying attention to the above circumstances, and its purpose is to make it easy to reuse or divert the processing function source code in the software component of the software defined radio. The object is to provide a software generation support apparatus that further reduces manufacturing costs.

In order to achieve the above object, one aspect of the present invention provides the following measures. That is, a source code registration control means is provided, and by this source code registration control means, a first symbol representing the category is generated for each of a plurality of software components constituting the software defined radio and stored in a memory. A second symbol representing the processing function is generated for each of a plurality of processing functions belonging to the category of the plurality of software components and stored in the memory. An input of a source code corresponding to each of the plurality of processing functions is received, and the source code is stored in the memory in association with the first and second symbols.
In addition, a software generation control unit is provided, and when the software generation control unit detects an operation of selecting one of the first symbols in a state where the first symbol is displayed as a list on the display device. A second symbol representing a processing function belonging to the category of the software component represented by the selected first symbol is selectively read from the memory and displayed on the display, and the second symbol is displayed. A plurality of connected symbols representing candidates for a connection relationship between symbols are displayed on the display. Then, in response to the selection operation for the displayed second symbol and connected symbol, a software model is generated by connecting the selected second symbols to each other by the selected connected symbol. The source code corresponding to the second symbol constituting the software model is read from the memory, and the read source code is inserted into the software interface file as a code representing the processing contents.

  Accordingly, when the first symbol corresponding to the software component to be generated is selected, the second symbol representing the function belonging to the category of the software component and the linked symbol are displayed, and the displayed second symbol The software model is generated by selecting and operating the connected symbols. Then, the source code corresponding to the second symbol constituting the software model is selectively read out, and the read out source code is inserted into the software interface file as a code representing processing contents and compiled. .

  That is, according to one aspect of the present invention, a new software component can be generated by reusing or diverting the source code of the processing function of the software component. Further, since the programmer only needs to perform the symbol selection operation, the software design / manufacturing cost can be further reduced.

It is a block diagram which shows the hardware of the software production | generation assistance apparatus concerning one Embodiment of this invention, and the structure of software. It is a figure which shows an example of the information regarding the category of software air conditioner components among the symbol information memorize | stored in the data memory of the software generation assistance apparatus shown in FIG. It is a figure which shows an example of the information regarding the preset middle symbol among the symbol information memorize | stored in the data memory of the software generation assistance apparatus shown in FIG. It is a flowchart which shows the procedure and content of the symbol source code registration control by the software generation assistance apparatus shown in FIG. 5 is a flowchart showing a procedure and contents of a middle symbol registration process in the symbol / source code registration control procedure shown in FIG. It is a flowchart which shows the procedure and content of modeling and the production | generation control by the software production | generation assistance apparatus shown in FIG. It is a figure which shows an example of the registration mode screen displayed by the symbol and source code registration control shown in FIG.4 and FIG.6. It is a figure which shows an example of the registration mode screen displayed by the modeling and production | generation control shown in FIG.4 and FIG.6. It is a figure for demonstrating the copy process of the source code with respect to the software interface file by the modeling and generation control shown in FIG.

Embodiments according to the present invention will be described below with reference to the drawings.
FIG. 1 is a block diagram showing the hardware and software configuration of a software generation support apparatus according to an embodiment of the present invention.
A software generation support apparatus 1 according to this embodiment includes, for example, a personal computer or a workstation, and includes a central processing unit (CPU) 11 including a microprocessor. A program memory 13 and a data memory 14 are connected to the CPU 11 via a bus 12, and an input / output interface 15 and an external storage interface 18 are further connected.

  An input device 16 and a display device 17 are connected to the input / output interface 15. The input device 16 includes a keyboard and a mouse. The display device 17 is configured by a liquid crystal display, for example. The input / output interface 15 has a function of transmitting operation information from the input device 16 to the CPU 11 and displaying a display screen for source code registration, a display screen for modeling / generation, and the like on the display device 17 under the control of the CPU 11. Have.

  The external storage interface 18 reads symbol information and a source code file from the external storage medium 2 and stores them in the data memory 14 under the control of the CPU 11 and stores the software model and software generated by the software generation support apparatus 1. A function of storing the wear interface file in the external recording medium 2.

  The data memory 14 includes a symbol information storage area 141, a source code information storage area 142, a symbol / source code table 143, a software model storage area 144, as storage areas necessary for carrying out the present invention. A software file storage area 145 is provided.

  The symbol information storage area 141 stores information for managing categories of a plurality of software components for software radios and information for managing processing functions belonging to any of the above categories. The information for managing the category of the software component defines, for each category, a category name, a first symbol representing the category (hereinafter referred to as a large symbol), and a description of the category. An example is shown in FIG. On the other hand, the information for managing the processing function defines, for each processing function, a second symbol representing the processing function (hereinafter referred to as a middle symbol), a large symbol name of the registration source, and a description of the middle symbol. It is. An example is shown in FIG.

In the source code information storage area 142, a source code file generated in advance or read from the external storage medium 2 is stored. The source code is used to express a processing function belonging to the category of the software component.
The symbol / source code table 143 stores information representing a correspondence relationship between the middle symbol and the source code registered in accordance with a symbol / source code registration control program described later.

  The software model storage area 144 is used for storing a software model generated according to a modeling / generation control program described later. The software file storage area 145 is used to store a software interface file generated according to a modeling / generation control program described later.

The program memory 13 stores a design / manufacturing support control program 131, a symbol / source code registration control program 132, and a modeling / generation control program 133 as application programs necessary for carrying out the present invention. .
The design / manufacturing support control program 131 causes the CPU 11 to execute processing for automatically generating a software interface file. The generated software interface file includes a software interface interposed between the middleware layer of the software defined radio and software constituting each software component, and software constituting each software component. There is a software interface interposed between them.

  The symbol / source code registration control program 132 displays a display screen for symbol / source code registration on the display device 17 when the registration mode is selected and specified, and the intermediate symbol selected and specified by the registration operation by the input device 16. The CPU 11 is caused to execute processing for storing the source code and the source code in the symbol / source code correspondence table 143 in association with each other.

  When the modeling / generation mode is selected and designated, the modeling / generation control program 133 displays a modeling / generation display screen on the display device 17, and software is generated according to the modeling operation and the file generation operation by the input device 16. The CPU 11 is caused to execute a wear model generation process and a source code embedding process in the software interface file.

Next, the operation of the software generation support apparatus configured as described above will be described.
In the standby state, the CPU 11 generates display data for the menu screen, for example, and supplies the display data to the input / output interface 15 to display the menu screen on the display device 17. On the menu screen, selection buttons for a symbol / source code registration mode and a modeling / generation mode are displayed.

(1) Symbol / source code registration mode
It is assumed that the programmer operates the input device 16 and selects and selects the selection button for the symbol / source code registration mode while the menu screen is displayed. Then, the CPU 11 activates the symbol / source code registration control program 132 and executes the symbol / source code registration control process as follows according to the registration control program 132. FIG. 4 is a flowchart showing the processing procedure and processing contents of this symbol / source code registration control.

  That is, the CPU 11 first generates display data for the symbol / source code registration mode screen, and supplies the display data to the input / output interface 15 to display the symbol / source code registration mode screen on the display device 17. For example, as shown in FIG. 7, a file reading button B11, a registration button B12, and an end button B13 are displayed on the symbol / source code registration mode screen, and a source code window W11, a large symbol selection window W12, and a medium symbol are displayed. A selection window W13, a definition display window W14, and a related module window W15 are displayed. Further, a new symbol registration button B14 and a symbol deletion button B15 are displayed at positions close to the middle symbol selection window W13.

  In this state, it is assumed that the programmer operates the input device 16 to select and specify the file reading button B11. Then, the CPU 11 detects the operation of the file reading button B11 in step S41 and proceeds to step S42. First, a dialog for reading the source code is generated and displayed on the display device 17. This dialog displays a list of source code files.

  Subsequently, when the programmer operates the input device 16 to select and specify one of the source code files displayed in the dialog, the CPU 11 detects this selection / designation operation in step S43, and proceeds to step S44. The selected and designated source code file is read from the source code information storage area 142 in the data memory 14 and displayed in the source code window W11 of the symbol / source code registration mode screen.

  At the same time, the CPU 11 extracts definition information from the source code described in the source code file in step S45, and displays the definition information on the definition display window W14 of the symbol / source code registration mode screen. The definition information includes a variable definition section, a user type declaration section, and a preprocessor. Further, in step S46, the CPU 11 reads information (FIG. 2) for managing the category of the software component from the symbol information storage area 141 in the data memory 14, and generates large symbol list display data based on the category management information. Then, the large symbol list is displayed on the large symbol selection window W12 of the symbol / source code registration mode screen.

Next, the programmer operates the input device 16 to select a large symbol corresponding to the category of the software component to be registered from the displayed list of large symbols. FIG. 7 illustrates a case where “MOD / DEM” is selected. Then, the CPU 11 proceeds from step S47 to step S48, and reads processing function management information (illustrated in FIG. 3) from the symbol information storage area 141 in the data memory 14. Then, based on the management information, the middle symbol of the processing function belonging to the category represented by the selected large symbol is selected, and the list display data of the selected middle symbol is displayed in the middle symbol selection window W13. Let
In step S48, every time a different large symbol is selected in step S47, the list display data of the middle symbols belonging to the category represented by the selected large symbol is regenerated and displayed.

  In this state, it is assumed that the programmer operates the input device 16 and selects one of the medium symbols displayed in the list. FIG. 7 illustrates the case where “FFT” is selected. Then, in step S49, the CPU 11 executes a process for associating the selected middle symbol with the source code as follows. FIG. 5 is a flowchart showing the processing procedure and processing contents.

  That is, when the CPU 11 detects the selection of the middle symbol in step S61, the process proceeds to step S62, and the work area in the data memory 14 is selected as a candidate to associate the selected middle symbol with the source code displayed in the source window W11. Hold on. Further, in order to associate a plurality of source codes with the same middle symbol, it is assumed that the programmer operates the input device 16 in a state where one of the middle symbols is selected and inputs the changed notation character. In this case, the CPU 11 proceeds from step S63 to step S64, edits the notation character of the selected middle symbol so as to be the inputted notation character, and generates a duplicate of the middle symbol. For example, when a duplicate of a symbol in “AGC” is generated, a suffix is added to “AGC.UHF (fast only)”.

  Also, assume that the programmer presses the new symbol registration button B14. In this case, the CPU 11 proceeds from step S65 to step S66, reads the management information of the processing function from the symbol information storage area 141, generates list display data of the middle symbols, and supplies this display data to the input / output interface 15. Thus, the list of the middle symbols is displayed on the display device 17. When the programmer selects and designates a desired medium symbol from the displayed list of medium symbols, the CPU 11 additionally displays the selected medium symbol in the medium symbol selection window W13, and the medium symbol is being selected. Are stored in the work storage area in the data memory 14 as candidates for processing functions newly belonging to the category represented by the large symbol.

  On the other hand, it is assumed that the programmer presses the delete symbol button B15 while selecting one of the middle symbols. In this case, the CPU 11 proceeds from step S67 to step S68, erases the display of the selected middle symbol from the middle symbol selection window W13, and performs the processing function represented by the middle symbol by the selected large symbol. As a candidate to be deleted from the list belonging to the represented category, it is held in the work storage area in the data memory 14.

  Definition information displayed in the definition display window W14 can be edited. For example, when adding definition information that could not be extracted from the source code file, the programmer inputs desired definition information at the input device 16. When detecting the input operation of the definition information in step S50, the CPU 11 additionally displays the input definition information in step S51 in the definition display window W14 and holds it in the work storage area in the data memory 14.

  Since the related module cannot be extracted from the source code file, the programmer inputs it. For example, when information representing a program module or class method called by the programmer from the source code is input to the input device 1, the CPU 11 sends the information representing the input program module or class method via the input / output interface 15 in step S52. It is received and displayed in the related module window W15, and held in the work storage area in the data memory 14.

  Now, it is assumed that the above-described selection selection, duplication, addition, deletion, definition information editing, and related module input reception processing of the middle symbol are completed, and the programmer presses the registration button B12 in the input device 16. Then, the CPU 11 detects the operation of the registration button B12 in step S53 and proceeds to step S54, where the middle symbol held as the association candidate in the work storage area in the data memory 14 is displayed in the source code window. The symbol / source code correspondence table 143 in the data memory 14 is stored in association with the source code being displayed in W11. At this time, the definition information after editing held in the working storage area in the data memory 14 and the information representing the related modules such as program modules and class methods are associated with the above source code together with the symbol source. It is stored in the code correspondence table 143.

  If the programmer selects the file read button B11 or the large symbol after the operation of the registration button B12, the CPU 11 returns to step S41 or step S47 again, and uses the above described middle symbol and source code. A series of processing for registering in association is repeated.

Finally, when the programmer operates the input device 16 and presses the end button B13, the CPU 11 detects this operation in step S55, erases the display of the symbol / source code registration mode screen, and controls symbol / source code registration. Exit.
The information stored in the symbol / source code correspondence table 143 and the source code file stored in the source code information storage area 142 may be stored as a library in the external storage medium 2 via the external storage interface 18. Is possible. In addition, when the support apparatus 1 includes a communication interface, it is possible to transfer to another support apparatus via this communication interface.

(2) Modeling / generation control mode
Assume that the programmer operates the input device 16 and selects the modeling / generation control mode selection button while the menu screen is displayed. Then, the CPU 11 activates the modeling / generation control program 133 and executes the modeling / generation control process as follows according to the modeling / generation control program 133. FIG. 6 is a flowchart showing the processing procedure and processing contents of this modeling / generation control.

  That is, the CPU 11 first generates display data for the modeling / generation mode screen, and supplies the display data to the input / output interface 15 to display the modeling / generation mode screen on the display device 17. For example, as shown in FIG. 8, a file reading button B21, a save button B22, and an end button B23 are displayed on the modeling / generation mode screen, and a modeling window W21, a large symbol selection window W22, and a medium symbol selection window W23 are displayed. The definition display window W24 and the related module window W25 are displayed. The middle symbol selection window W23 is used to display the middle symbol group SB2 and the linked symbol group SB3.

  When the modeling / generation mode screen is displayed, the CPU 11 first reads out information for managing the category of the software component (illustrated in FIG. 2) from the symbol information storage area 141 in the data memory 14 in step S71. The large symbol list display data is generated based on the information for managing the large symbol, and the large symbol list SB1 is displayed on the large symbol selection window W22.

In this state, it is assumed that the programmer operates the input device 16 and selects a large symbol corresponding to the category of the software component to be modeled from the displayed large symbol list SB1. FIG. 8 illustrates a case where “MAC” is selected. Then, the CPU 11 proceeds from step S72 to step S73, and reads processing function management information (illustrated in FIG. 3) from the symbol information storage area 141 in the data memory 14. Then, based on the management information, a middle symbol of the processing function belonging to the category represented by the selected large symbol is selected, and the list display data of the selected middle symbol is supplied to the input / output interface 15. As a result, a list SB2 of medium symbols belonging to the selected large symbol is displayed in the medium symbol selection window W23. At the same time, in step S74, the CPU 11 generates a plurality of linked symbols SB3 representing a linkage method for linking the middle symbols and displays them on the middle symbol selection window W23.
Each time a different large symbol is selected in step S72, the list display data SB2 of the middle symbol belonging to the category represented by the selected large symbol is regenerated and displayed in step S73.

  In this state, it is assumed that the programmer operates the input device 16 and selects one of the medium symbols displayed in the list. FIG. 8 illustrates the case where “AGC” is selected. Then, in step S75, the CPU 11 refers to the symbol / source code correspondence table 143 for the definition information such as the variable definition part, the user type declaration part, and the preprocessor registered in association with the selected middle symbol. The data is read from the storage area 142 and displayed on the definition display window W24.

  At the same time, in step S76, the CPU 11 refers to the symbol / source code correspondence table 143 for the related module information such as the program module and the class method registered in association with the selected middle symbol in the same manner as the definition information. Then, it is read from the source code information storage area 142 and displayed on the related module window W25.

  The software modeling process is performed by dragging and dropping the middle symbol SB2 and the linked symbol SB3 displayed in the middle symbol selection window W23. That is, when the programmer operates the mouse of the input device 16 to select the middle symbol and the connected symbol, the CPU 11 detects this operation in step S77 and proceeds to step S78. Then, when the programmer performs a drag and drop operation on the selected middle symbol and linked symbol, the selected middle symbol and linked symbol are moved to the modeling window W21 in accordance with the manipulation and pasted. . Thereafter, every time the programmer drags and drops the middle symbol and the linked symbol, the modeling process is performed on the modeling window W21. FIG. 8 shows an example of a model in the middle of modeling.

  In parallel with the modeling process, the definition information can be edited as necessary. For example, when changing the definition name and initial value, the programmer inputs a new definition name and initial value for the definition information to be changed in the input device 16. When the CPU 11 detects the definition information change input operation in step S79, the CPU 11 changes the definition information displayed in the definition display window W24 in step S80 to the input definition information, and the change result is displayed in the data memory 14. In the working storage area.

  Now, it is assumed that the modeling process is finished and the programmer presses the save button B22 on the input device 16. Then, the CPU 11 detects the operation of the save button B22 in step S81, proceeds to step S82, and stores the model generated in the modeling window W21 in the software model storage unit 144 in the data memory 14. At this time, the definition information after editing held in the work storage area in the data memory 14 and information representing the related modules such as program modules and class methods are also associated with the model and the software model storage unit 144. Remember me.

  Subsequently, it is assumed that the programmer presses the file generation button B21. If it does so, CPU11 will detect this operation by step S83, will transfer to step S84, and will first display a dialog on the display device 17. FIG. In this dialog, a list of software files to be generated is displayed.

  In this state, when the programmer operates the input device 16 to select and specify a desired file from the list of software files displayed in the dialog, the CPU 11 detects this operation in step S85 and proceeds to step S86. Transition. Based on the software model stored in the software model storage area 144, the source code is read from the source code storage area 142 with reference to the symbol / source code correspondence table 143, and the read source code is stored in the above-described source code. Copy to the specified software file and compile. Then, the CPU 11 stores the software component in which the source code is embedded in the software file storage area 145 in the data memory 14.

FIG. 9 shows how the source code is copied, and the source code representing the processing function is copied to the software interface file FF generated in advance by the design / manufacturing support control program 131.
Finally, when the programmer operates the input device 16 and presses the end button B23, the CPU 11 detects this operation in step S87, deletes the display of the modeling / generation mode screen, and ends the modeling / generation control.

  The software model stored in the software model storage area 144 and the software file stored in the software file storage area 145 can be stored in the external storage medium 2 via the external storage interface 18. Is possible. In addition, when the support apparatus 1 includes a communication interface, it can be transferred to another support apparatus via the communication interface.

  As described above, in this embodiment, when the symbol / source code registration mode is selected, the display screen for symbol / source code registration is displayed on the display device 17 in accordance with the symbol / source code registration control program 132, The intermediate symbol and the source code selected and designated by the registration operation by the input device 16 are stored in the symbol / source code correspondence table 143 in the data memory 14 in association with each other. When the modeling / generation mode is selected and specified, a display screen for modeling / generation is displayed on the display device 17 in accordance with the modeling / generation control program 133, and the intermediate symbol SB2 and the linked symbol SB3 are dragged by the input device 16. The software model is generated by the drop operation, and the source code is embedded in the interface file FF based on the generated model.

  Therefore, a new software component can be generated by reusing or diverting the source code of the processing function of the software component. In addition, when registering source code, the programmer can perform association with the source code simply by selecting the middle symbol, and dragging and dropping the middle symbol and connected symbol for modeling and generation. Since software can be modeled simply by doing, software design and manufacturing costs can be further reduced. Furthermore, since it is difficult for individual differences to occur in the completion of the source code file, it is possible to provide the minimum processing uniformity by the model. Further, by using a common library, it is possible to provide uniformity at the processing level.

  The present invention is not limited to the above embodiment. For example, although the large symbol and the medium symbol are defined in the above embodiment, the partial function belonging to the processing function represented by the medium symbol is represented by the small symbol, and the source code is registered in association with the small symbol and used for modeling. You may make it do.

  Other software component categories, types of processing functions represented by medium symbols, display modes for registration mode and modeling / generation mode, processing procedures and processing for symbol / source code registration control and modeling / generation control The contents, the hardware configuration of the apparatus, and the like can be variously modified and implemented without departing from the gist of the present invention.

  In short, the present invention is not limited to the above-described embodiment as it is, and can be embodied by modifying the constituent elements without departing from the scope of the invention in the implementation stage. Further, various inventions can be formed by appropriately combining a plurality of constituent elements disclosed in the embodiment. For example, some components may be deleted from all the components shown in the embodiment. Furthermore, you may combine suitably the component covering different embodiment.

  DESCRIPTION OF SYMBOLS 1 ... Software generation assistance apparatus, 2 ... Recording medium, 11 ... Central processing unit (CPU), 12 ... Bus, 13 ... Program memory, 14 ... Data memory, 15 ... Input / output interface, 16 ... Input device, 17 ... Display Device 18 ... External storage interface 131 ... Design / manufacturing support control program 132 ... Symbol / source code registration control program 133 ... Modeling / generation control program 141 ... Symbol information storage area 142 ... Source code information storage area 143... Symbol / source code correspondence table, 144... Software model storage area, 145.

Claims (1)

  1. Source code registration control means that operates when the source code registration mode is designated;
    Software generation control means that operates when a software generation mode is designated,
    The source code registration control means includes:
    Means for generating a first symbol representing a category of each of a plurality of software components constituting the software defined radio and storing the first symbol in a memory;
    Means for generating a second symbol representing each of a plurality of processing functions belonging to a category of the plurality of software components and storing the second symbol in the memory;
    Means for receiving an input of a source code corresponding to each of the plurality of processing functions and storing the source code in the memory in association with the first and second symbols;
    The software generation control means includes:
    A software component represented by the selected first symbol when an operation of selecting one of the first symbols is detected in a state where the plurality of first symbols are displayed as a list on the display Means for selectively reading out a second symbol representing a processing function belonging to the category of the category from the memory and displaying it on the display;
    Means for causing a display to display a plurality of connected symbols representing candidates for a connection relationship between the second symbols;
    Means for generating a software model in which the selected second symbols are linked by the selected linked symbols in response to a selection operation on the displayed second symbol and linked symbol candidates;
    Means for reading a source code corresponding to a second symbol constituting the generated software model from the memory and inserting the read source code into a software interface file as a code representing processing contents; A software generation support method characterized by the above.
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JPN6013005623; 白須光雄ほか5名: 'ソフトウェア無線機の製品化' 電子情報通信学会技術研究報告 Vol.106  No.188, 20060720, pp.101-107, 社団法人電子情報通信学会 *

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US9224288B2 (en) 2011-03-30 2015-12-29 Sony Corporation Control apparatus, control method, program and system
US10437206B2 (en) 2011-03-30 2019-10-08 Sony Corporation Control apparatus, control method, program and system
JP2014182746A (en) * 2013-03-21 2014-09-29 Japan Radio Co Ltd Radio equipment software model generator and radio communication device

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