WO1996018944A1 - Appareil de traitement de conception de logiciel du type a assemblage - Google Patents

Appareil de traitement de conception de logiciel du type a assemblage Download PDF

Info

Publication number
WO1996018944A1
WO1996018944A1 PCT/KR1995/000161 KR9500161W WO9618944A1 WO 1996018944 A1 WO1996018944 A1 WO 1996018944A1 KR 9500161 W KR9500161 W KR 9500161W WO 9618944 A1 WO9618944 A1 WO 9618944A1
Authority
WO
WIPO (PCT)
Prior art keywords
design
parts
software
processing
prefabricated
Prior art date
Application number
PCT/KR1995/000161
Other languages
English (en)
Japanese (ja)
Inventor
Hong Jun Yoo
Original Assignee
Hong Jun Yoo
Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)
Filing date
Publication date
Application filed by Hong Jun Yoo filed Critical Hong Jun Yoo
Priority to AU41903/96A priority Critical patent/AU4190396A/en
Publication of WO1996018944A1 publication Critical patent/WO1996018944A1/fr

Links

Classifications

    • GPHYSICS
    • G06COMPUTING; CALCULATING OR COUNTING
    • G06FELECTRIC DIGITAL DATA PROCESSING
    • G06F8/00Arrangements for software engineering
    • G06F8/20Software design
    • GPHYSICS
    • G06COMPUTING; CALCULATING OR COUNTING
    • G06FELECTRIC DIGITAL DATA PROCESSING
    • G06F9/00Arrangements for program control, e.g. control units

Definitions

  • the present invention relates to a prefabricated software design component fi that handles assembly, abstraction, disassembly, handling, transmission, transformation, and the like of the prefabricated software design components, and software that is implemented using the fi device. I will discuss the method of design process.
  • a sequence design such as a sequence, a selection, or an eration, is performed by connecting or embodying the promised garden shapes for each control structure by bonding or wire. It can solve the problem of the recognition of the control structure of the program for the software I-design by S. Then, a number of structured field processing devices and methods appeared in various countries of the world, We were able to improve the productivity of wafer development.
  • the present invention which was devised to solve the above-mentioned problems of the conventional technology, is based on the software flow in the software design processing work using the assembly-type software I design processing device. Rather than connecting the design garden shapes one by one as in the case of the design processing method of Structuralization II, three types of pattern parts, basic parts, block parts, and structural parts, are used before the design of the software I / F.
  • the standardized and standardized assembling software pattern parts stored in the design parts storage section which is a separate storage means inside the assembling software design processing equipment e, are completely separated from the factory. Hardware by industrial robots!
  • the present invention is mainly divided into a central design control unit for controlling the overall design process of Soft Tu I and a design component storage unit for storing the assemblable Soft X X design components.
  • a design parts assembling section for assembling prefabricated software design parts, a design parts abstraction section to bind and abstract adjacent prefabricated software I design parts, and a A design parts disassembly section for disassembling and removing design parts, a design parts delivery management section that enables a large number of designers to cooperate on a network, and a multimedia software design processing section.
  • Multimedia design processing unit to enable software design processing
  • software design processing unit to enable software design processing in the real world environment, design stage and program code implementation stage.
  • the first section shows the block diagram of the prefabricated software I design processing device, which is the core device S of the present invention, and the central design control unit (101) that supervises the prefabricated software design process.
  • the central design control unit for controlling the prefabricated software design process comprehensively starts performing general design control work. And the second stage where the central design control unit loads the assembling software X design parts from the auxiliary storage device to the design parts storage unit.
  • the assembling type software where the design parts assembly unit is standardized and standardized The third stage of assembling work with tera design parts, and the abstraction work of design part abstraction part which binds and abstracts related software design parts among assembled software design parts.
  • the eighth stage which is the control of the realization of the realization of the design process
  • the ninth stage which is the conversion that supports the forward and reverse engineering between the design stage and the program code implementation stage. I have it.
  • the core device of the present invention is the assembling software:! : Software by design equipment If the method of the hardware design process is explained by function, the first function is to automatically assemble the design parts of the assemblable software into the storage device for image display and to have the effect of drawing the design on the image display »surface.
  • the second function to automatically recognize and specify the insertion position g of this part, and the The third function, which automatically inserts new software parts into the insertion position fi recognized by the second function in the second function and accurately assembles them, and the software design that simultaneously inserts new soft-to-I parts
  • the fourth function that automatically rearranges the entire design parts of the software and the software that attempts to abstract from the software design park are automatically recognized and specified by structure or function.
  • the first feature that allows you to When the main routine is designed so that it has lower modules such as supplemental channels in the design park, the calling point of the upper level design module is automatically recognized.
  • the twelfth function and the upper-level module automatically recognized by the twelfth function
  • the thirteenth function that automatically recognizes the starting part of the destination point of the module, and from the module of the upper layer to the design part of the lower layer that is automatically recognized by the thirteen function, the starting part of the module
  • the 14th function automatically searches the lower level design park module regardless of whether it is in the same file as the upper level module, and the 514th function allows the lower level module to move from the lower level module to the lower level module.
  • the upper module calling point When searching for a module, the upper module calling point is memorized, and after the processing of the upper module is completed, the upper layer design location of the upper module is called the lower module and the lower layer is called. Fifteenth function that can be traced back regardless of whether it is in the same file as the other module, and returns to the calling point of the upper module after the processing of the lower module is completed. Sometimes, do not take steps, At the point of calling the upper module called at the end, the design module of the upper layer can be traced back regardless of whether it is in the same file as the module of the lower layer. 16 functions and software of desired form and standard in assemblable soft-to-designer parts:!:
  • the 15 17 Recognize the functions and the names and shapes of the modules on the design park, and explain the functions and usage of the modules with multimedia such as video and audio, without having to go directly to the modules.
  • the 18th function which allows the user to easily learn the functions and usage of the module, and the operation of the control structure in the design diagram can be observed in an animation-like manner on a module-by-module basis. If you try to do so, through the power, unit test, etc.
  • the 19th function to enable the module to be tested in a multimedia manner, such as sound and visual notification of the conditions of errors and the like that occur, has been developed. Input and output of multimedia data such as audio and video so that it can be created in a multimedia format instead of being created by the text user as in the past.
  • the real real environment was formed, and in the three-dimensional vertical K environment of the real world, the designed parts were touched directly in a contemplative manner while looking at the B parts.
  • the core function of the present invention is the assembling type software: the function of realizing each function held by the r design processing device e is performed by the central design control unit embedded in the assembling type software design processing device, The other parts of the internal organs are controlled as necessary.
  • Fields 2-1 and 2-2 are the cores of the present invention, each of which is owned by the assembling type Softu Xa design processing equipment. This is an example of a design that shows how to implement a function using the method of the present invention.
  • Chapters 3-1 ⁇ and 3-2 show examples of basic parts for designing the assembling software I according to the present invention.
  • each half-width basic part has been created and registered as a half-width basic part from Al_l part to Al_16, which means a space.
  • the blank half-width basic parts for Al-1 in Garden No. 3-1 are the half-width basic parts for filling in the white space and maintaining the overall balance of the design diagram when the software design garden is assembled by assembly.
  • the half-width basic parts of Al_2 to Al_14 are used for building a kind of building. »The parts corresponding to the streaks are assembled with these line-shaped parts to create the frame of the overall design of the software I.
  • the 3-1 solid Al_15 is an albet half-width basic part corresponding to the English capital letter 'T' and functions as a signboard when the road splits on the way along the highway.
  • the branching display half-width basic parts that are used when assembling a branch when it is performed.
  • the M_16 in Section 3-1 ⁇ is an 'n' meaning number 0 to 9
  • This half-width basic part indicates the stage of abort when the design flow is aborted when the corresponding abort occurs in a kind of program goto statement or break statement due to exception handling (exception handling). This is the basic part of the half-cut to be used for cutting.
  • the 3rd side means full-width basic parts corresponding to the size of one kanji on the S-plane.
  • Each full-width basic part is used by the garden in the design area in order from the parts used for the abstraction of processing.
  • the full-width basic part number is always added and the new full-width basic part is registered continuously.
  • Blocks 1 to B3_4 are processed according to certain conditions when the structural parts of Design II are used. If the structural parts have conditions such as then and for ⁇ do, the same conditions can be displayed. Bock parts for B4_l to B4-9 in the 4th and 4th circles are the software parts.
  • the parts are processing block parts that enable the description of the specific processing of each structural part of Soft Tu Ika Oka.
  • Block parts B 6_1 through B6_12 in Figure 4-6 are the parts of the software design park.
  • Blocks B7_l to B7_6 require materials to be maintained when building or disassembling the building in a prefabricated manner. Or being abstracted Understood Block maintenance parts to complement and maintain parts that become loose depending on the type of structure in the process.
  • the block parts of the above-mentioned 4-1 garden to 4-7 solid blocks can be added with the part number whenever necessary, and new parts can be added. It is possible to add additional registrations and prepare for future expansion.
  • Fig. 5-1 -A to Fig. 5-4-1 show the assembled parts of Fig. 4-1 to Fig. 4-7 on each other and they are abstracted with new structure. Examples of the structural components are shown below, and the 5-th Affl and 5-B surfaces indicate whether the software design to be created is a main module or a sub-module.
  • the - ⁇ of the fifth garden A means the software design to be created, which means the basic structural parts used to form the design foundation corresponding to the foundation work of the building.
  • the 5-1 -BH Cl_2 forms the basis when the software design ⁇ to be made is a sub-module, meaning the main module substructure components used to form the basis when Means a sub-module substructure part used for.
  • 5-2- ⁇ through 5-2-Mffl mean single processing structural parts used to indicate single processing, one processing at a time
  • C2_l of 5-2-AK means a sequential structue part that abstracts the processing when the processing is processed sequentially and sequentially and sequentially.
  • the flow of C2_2 in Garden No. 5-2-B is divided and Taki selection structure showing a structure that will allow another processing
  • C2_3 of 5-2-C which means a part, also refers to a part, so that the condition can be inspected in two, and the other processing can be performed according to the twin technique selection structure (if ⁇ therTelse structure).
  • C2_4 of Garden No. 5-2-D inspects the condition with three or more conditions, and thereby performs other processing, so that a multi-skill selection structure (case)
  • C2-5 of the 5-2-Effl means a part, which means that it is an iterative structure that iterates and processes at the front part of the structure.
  • C2_6 in Fig. 5-2-F is a repetitive structure that is processed and processed in a middle part of the structure.
  • the C2--7 of the 5-2-G solid is a repetition-processed repetition structure that emerges from the structure.
  • C2_9 in the 5-2-1 field is the part where the abnormality occurred when the system abnormality occurred.
  • C2_10 of the 5-2-2 Jffl inspects the condition by one kind and inputs the keyboard incorrectly.
  • 5-2-K ⁇ C2_ll means an if-then exception handling structure, which indicates a structure for performing an emergency treatment such as a special condition treatment, etc. Inspects the condition in two parts, thereby showing a structure for performing other emergency processing.
  • g structure means a part
  • C2_12 of the 5-5-2 L ⁇ has three or more conditions
  • C2_13 of the 5-2-M field refers to the function of the material, which means a case excaption handling structure, which indicates the structure for performing other emergency processing. Abstraction structure (data) that indicates a structure for performing processing such as binding and abstraction declaration such as
  • Fields 5-3-A through 5-3-R are multi-processing structures used to indicate multiple processing (uiu iprocessing) that simultaneously processes two or more tasks at a time.
  • C3_l of the fifth garden abstracts the two sequential processings when they are processed at the same time and shows a double sequential structure ( C3_2 in 5-3-B garden means a part of a double sequential structure, and when three or more loose processings are processed at the same time, this is abstracted to show a multiple sequential structure (mujtipje sequential structure).
  • C3_3 of 5-3-Cffl detects two conditions at the same time, so that the flow that is matched to the conditions is divided at the same time, and the special processing is performed in a complex way.
  • C3_4 in 5-3-D ⁇ means three or more conditions, meaning a double if-then structure part showing the structure Sometimes it is a multiple i rthen structure part that shows a structure where the flow is divided at the same time as the processing that matches the conditions to make a special processing complex.
  • the C3_5 of the 5-3-E ⁇ is an iteratively processed iterative structure (iteration structure), which is a pre-decision iterative structure (while ⁇ do structure) that indicates the structure in which the inspection coming out of the structure is performed at the front part of the structure ) Means a double while ⁇ do structure part that indicates that two are processed simultaneously and simultaneously, and C3_6 in Fig.
  • 5-3-F is a repeated processing Inspection from the structure with the structure (Knuth-Zahn-Haberman structure) showing the structure where two are processed in the middle part of the structure (double nuth-Zahn-Haberman structure) Meaning of parts
  • C3_7 in the 5-3-G garden is a repetitive structure that is processed and processed, and a post-judgment repetition structure (ckTuil structure) that indicates a structure in which a check out of the relevant structure is performed at the end of the structure.
  • C3_8 in 5-3-H ⁇ means a repetition-processed structure, which means a double do ⁇ until structure component indicating that two are processed simultaneously and simultaneously.
  • (Eration structure) A pre-determination repetition structure (while ⁇ do structure) showing the structure that the inspection that comes out of the structure is performed at the front part of the structure.
  • C3_9 in the 5-3-1 field is repeatedly processed to indicate a part of the judgment repeated structure (multiple while ⁇ do structure).
  • C3-10 in Fig. 5-3-J is a repetitive structure that is processed by repetition, which means the part that has a repetitive structure (iple Knuth-Zahn-Haberman structure).
  • KTuntil structure which indicates the structure to be performed in (kTuntil structure), which means a multiple post-determination iterative structure ⁇ mu iple do ⁇ unti 1 structure) part that indicates that three or more are simultaneously processed in a complex manner.
  • C3_l 1 in Fig. 5-3-K indicates the structure that can control the number of repetitions and enter the structure by knowing the point before exiting from the structure. A double for ⁇ do structure part that is processed in a complex manner. Therefore, C3-12 on the 5-3-L plane controls the number of repetitions and knows when to exit the structure before entering the structure.
  • a limited for-do structure indicating a structure that can be processed is a multiple limited for-do structure part that indicates that three or more can be processed simultaneously and in a complex manner.
  • C3_13 in the garden shows a structure that automatically displays information on the part where an abnormality has occurred when a system abnormality occurs. It shows that two sequential illness handling structures are processed simultaneously and simultaneously.
  • C3_14 in Section 5-3-N ⁇ has a structure that automatically displays information etc. on the part where an error occurred when the system error occurred.
  • Illness handling structure (mu) indicates that more than one is simultaneously and simultaneously processed (mu) tip means a part of the sequential illness handling structure.
  • C3_15 checks condition to one kind and keyboard input error
  • a single-selection emergency structure that shows a structure for performing an emergency treatment such as a treatment, etc. (if ⁇ then exception handling structure) Meaning of the structure (mu iple i fthen exception handling structure) part.
  • C3_17 of 5-3-Qffl is a processing such as binding and abstracting the data by function or type, etc.
  • a data abstraction structure that indicates the structure to be performed. It refers to the abstract ⁇ spoon structure (double data abstraction structure) parts C3_18 in Fig. 5-3-R is a data abstraction structure (data abstraction) that shows a structure for performing processing such as binding and abstracting the data according to function or type. structure) means multiple data abstraction structure parts that indicate that three or more are processed simultaneously and simultaneously. 5-1-A ⁇ through 5-3 above -When a new structural part is made in the future, a new number will be added to the structural parts of the -R garden so that it can be registered as a structural part.
  • Sections 5-4-A ⁇ to 5-4-1 ⁇ support the extension and maintenance when structural parts are expanded as described above in Sections 5-1-Affl to 5-3-R. In detail, this means the structural maintenance parts that have been created.
  • C4-1 in field 5-4-A is more than C2-4 in field 5-2-D.
  • C4_2 in field 5-4-B is the same as that in field 5-2-Lffl.
  • C4_3 in Figure 5-4-C Is a multiple sequential structure component of C3_2 in 5-3-B® and a multiple sequential structure component of C3-14 in 5-3- ⁇ ⁇ , mul tiple sequential illness handling structure
  • the 5-3-R specific C3_18 multiple data abstraction structure multipl e data abstraction structure
  • a C4_4 in Fig. 5-4-D is a multiplex of C3_4 in Fig. 5-3-D, meaning a multiple sequential structure maintenance component used when trying to increase the number of parts sequentially.
  • 5-4-E refers to the emergency maintenance part for multiple if-then structure, which is used when trying to expand the number of operations with multiple if-then structure parts.
  • C C3_8 multiple while ⁇ do structure part C4_6 of 5-4_Fffl refers to the repetition of the C3-9 multiplexing process shown in Fig. 5-3-1.
  • Intermediate Judgment Repetition with Structure Multiple Knuth-Zahn-Haberman Structure
  • the C4_7 of 5-4-G ⁇ means the maintenance part of multiple middle judgment repetition structure used when trying to expand the number of structures.
  • the multi-post judgment repeated structure maintenance part that is used when trying to expand the number of post-judgment repeated structures with the multiple do-until structure parts of C3_10 in the 3-J field.
  • C-4-8 of -4-H garden is a multiple-limited repeated structure of C3_12 of 5-3-Lffl. Multiple-limited repeated structure used when trying to expand the number of limited repeated structures.
  • C4_9 in Section 5-4-1 ⁇ is a multiple-single-segment emergency structure of C3_16 in Section 5-3-P (multiple if ⁇ then exception ha (ndling structure) means a multi-unit selection emergency structural maintenance part used when trying to expand the selection number with parts.
  • a maintenance (structure maintenance) part is also required, a new structural maintenance part for the structure to be added can be newly added by adding a number.
  • the Bl_l of the 4-1 garden is one A-two part of the 3-1 garden and one A-two part.
  • one Al_2 part and one Al_l part and seven Al_l parts are assembled in a row, and are expressed as ⁇ 1_2 ⁇ ⁇ 1_8 ⁇ Al_2 ⁇ (Al_l) * 7, where the ' ⁇ ' The symbol means that the two parts were soldered together, and the symbol means that the symbol was repeated and joined by the number harmed by the symbol.
  • Nos. 4-1 ⁇ through 4 -The other parts of the block 7 can be constructed by combining the basic parts of No. 3-1 in the same way as the Bl_l block of Fig. 4-1.
  • Related parts should be constructed by connecting the block parts shown in Figures 4-1 to 4-7ffl up and down.
  • Garden No. 1 is a block plot of a prefabricated software design processing device, which is the core device of the present invention.
  • 101 Central design control unit
  • 102 Design parts storage unit
  • 103 Design parts assembly unit
  • 104 Design parts abstraction unit
  • 105 Design parts disassembly unit
  • 106 Design parts transmission management unit
  • 107 Multimedia design processing section
  • 108 Korean current design processing section
  • 109 Design implementation mutual conversion section.
  • Fig. 2-1 to Fig. 2-2 show how to implement each function possessed by the prefabricated software I-design processing equipment, which is the core device of the present invention, by drawing the prefabricated method using the method of the present invention. This is an example of the design aspect.
  • Fig. 3-lffl to Fig. 3-2 show examples of basic components for the assembly type soft- ware design process according to the present invention.
  • Figures 4-1 to 4-7 are examples of block components assembled from basic components for the assembly type software X-processor design processing according to the present invention. .
  • No. 4-1 ⁇ Example of basic block parts
  • No. 4-2 field Example of target block parts
  • No. 4-3 ⁇ Example of condition block parts
  • Example 4-6 Circle Example of post-processing block part
  • No.4-7 Example of block maintenance part.
  • Fig. 5-1 -A ⁇ through Fig. 5-4-1 show assembled software according to the present invention
  • a design process This is an example of structural components constructed by assembling packing components for use.
  • Fields 5-1-A through 5-1-B are examples of basic structure components, and 5-2-A ⁇ through 5-2-Mffl are uniprocessing structure components. 5-3-Affl to 5-3-R circles are examples of multiprocessing structure components). Is an example of structure maintenance components.
  • Sections 6-1-A ⁇ through 6-3-A ⁇ show examples of how to assemble, abstract, and disassemble at the time of S with the prefabricated software used in the present invention: Fields 6-1-A through 6-1-D ⁇ are examples of assembling structural parts in design parts, and Section 6-2-A ⁇ is a method of assembling structural parts in design parts. Figure 6-3-A is an example of a method of disassembling and removing structural components from design components.
  • Sections 6-1-A ⁇ through 6-3-A describe how to actually assemble, abstract, and disassemble with the prefabricated software design components used in the present invention. It is.
  • Sections 6-1-Affl to 6-1-D show actual assembly examples of how to actually assemble and assemble with the prefabricated software I-designer used in the present invention.
  • Fig. 6-1-A shows the Cl_l structural part of the 5-5-1A solid in the basic structure of the main module.
  • -1-A shows an example of assembling C2_l sequential structural parts of the 5-2-A painting into the Oka. This is an example of assembling the single-segmentation structural parts of C2_2 in -B garden.
  • the 6-1-D solid is in the 6-C garden before the C2--5 of 5-2-Effl. Judgment It represented an example of assembling return structural parts.
  • the structure of software design W can be completed in a prefabricated manner by continuing assembly as described above.
  • Section 6-2-A ⁇ describes a method of assembling with a new structure and abstracting by associating those related to the actually assembled contents with the prefabricated software design parts used in the present invention. It actually expressed an example of assembly.
  • Garden No. 6-2-A includes the structural components for selective selection of C2_2 in the solids of Nos. 6-1 -D ⁇ to No. 5-2-B and the pre-judgment return structural components for C2_5 in No. 5-2-E ⁇ .
  • the necessary structure can be tied to anything and abstracted with a new structure that we hope for, so that we can increase the readability of the software (readabi lity).
  • Chapter 6-3-Affl is an actual disassembly example of a method of disassembling and removing unnecessary parts from the contents assembled especially when using the pre-assembled software I-design parts used in the present invention. It was shown.
  • the 6-3-ABB is the C2_8 of the 5-2-H ⁇ , which was judged to be troublesome to abstract again from the example represented in the An example is shown in which the limited repetitive structural parts are disassembled and deleted to recover the condition as shown in Fig. 6-1-D.
  • the present invention is based on automated software and software.
  • various software such as assembly, abstraction, disassembly, handling, delivery, and conversion of software to Xer design parts.
  • the design process and maintenance can be easily performed, and the development productivity and maintenance and maintenance in the soft-to-I field can be improved. Can be used to reduce the general economic situation and strengthen the power of complications ⁇

Landscapes

  • Engineering & Computer Science (AREA)
  • Theoretical Computer Science (AREA)
  • Software Systems (AREA)
  • General Engineering & Computer Science (AREA)
  • Physics & Mathematics (AREA)
  • General Physics & Mathematics (AREA)
  • Stored Programmes (AREA)

Abstract

Elément de conception de logiciel du type à assemblage, appareil de traitement de conception de logiciel du type à assemblage et procédé de traitement de conception de logiciel utilisant l'appareil. Le traitement de conception de logiciel englobe l'abstraction, le désassemblage, la manipulation, la transmission, la conversion ainsi que d'autres traitements d'assemblage d'éléments normalisés, ainsi que le développement de logiciel, leur maintenance et inspection pouvant être effectuées facilement.
PCT/KR1995/000161 1994-12-13 1995-12-13 Appareil de traitement de conception de logiciel du type a assemblage WO1996018944A1 (fr)

Priority Applications (1)

Application Number Priority Date Filing Date Title
AU41903/96A AU4190396A (en) 1994-12-13 1995-12-13 Assembly type software design processing apparatus

Applications Claiming Priority (2)

Application Number Priority Date Filing Date Title
KR1994/34014 1994-12-13
KR1019940034014A KR100367134B1 (ko) 1994-12-13 1994-12-13 조립식소프트웨어설계부품과그조립및분해방법

Publications (1)

Publication Number Publication Date
WO1996018944A1 true WO1996018944A1 (fr) 1996-06-20

Family

ID=19401328

Family Applications (1)

Application Number Title Priority Date Filing Date
PCT/KR1995/000161 WO1996018944A1 (fr) 1994-12-13 1995-12-13 Appareil de traitement de conception de logiciel du type a assemblage

Country Status (3)

Country Link
KR (1) KR100367134B1 (fr)
AU (1) AU4190396A (fr)
WO (1) WO1996018944A1 (fr)

Families Citing this family (2)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
KR20160084026A (ko) 2015-01-05 2016-07-13 유홍준 조립식 패턴진화 통합 모델링 기반 컴퓨터적사고 증진 방법 및 시스템
KR102170740B1 (ko) 2019-03-05 2020-10-27 국방과학연구소 도메인 에셋 정보 제공 방법 및 장치

Citations (8)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
JPS6289137A (ja) * 1985-10-16 1987-04-23 Hitachi Ltd プログラム対話方式
JPS6373475A (ja) * 1986-09-17 1988-04-04 Fujitsu Ltd 二次元プログラム言語構造解析処理方式
JPS63197229A (ja) * 1987-02-12 1988-08-16 Fujitsu Ltd モジユ−ル構造自動生成方式
JPH01142828A (ja) * 1987-11-30 1989-06-05 Nec Corp ソフトウェア開発ステーション
JPH01173131A (ja) * 1987-12-28 1989-07-07 Toshiba Corp 構造エディタ
JPH0334021A (ja) * 1989-06-30 1991-02-14 Yokogawa Electric Corp プログラム言語変換方法
JPH04235630A (ja) * 1990-07-30 1992-08-24 Ronald L Colier 可聴コマンドでコンピュータのプログラミングを行うための方法及び装置
JPH04344932A (ja) * 1991-05-22 1992-12-01 Hitachi Ltd 分散プログラミング方法

Family Cites Families (5)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
JPS58169244A (ja) * 1982-03-31 1983-10-05 Fujitsu Ltd プログラム開発方式
JPH02128234A (ja) * 1988-11-09 1990-05-16 Nec Corp 試験プログラム作成管理方式
JPH02207325A (ja) * 1989-02-08 1990-08-17 Hitachi Software Eng Co Ltd ソースプログラム自動生成方式
US5325533A (en) * 1993-06-28 1994-06-28 Taligent, Inc. Engineering system for modeling computer programs
JPH101994A (ja) * 1996-06-17 1998-01-06 Naoya Suzuki 腰掛便器での男子用排尿介助器

Patent Citations (8)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
JPS6289137A (ja) * 1985-10-16 1987-04-23 Hitachi Ltd プログラム対話方式
JPS6373475A (ja) * 1986-09-17 1988-04-04 Fujitsu Ltd 二次元プログラム言語構造解析処理方式
JPS63197229A (ja) * 1987-02-12 1988-08-16 Fujitsu Ltd モジユ−ル構造自動生成方式
JPH01142828A (ja) * 1987-11-30 1989-06-05 Nec Corp ソフトウェア開発ステーション
JPH01173131A (ja) * 1987-12-28 1989-07-07 Toshiba Corp 構造エディタ
JPH0334021A (ja) * 1989-06-30 1991-02-14 Yokogawa Electric Corp プログラム言語変換方法
JPH04235630A (ja) * 1990-07-30 1992-08-24 Ronald L Colier 可聴コマンドでコンピュータのプログラミングを行うための方法及び装置
JPH04344932A (ja) * 1991-05-22 1992-12-01 Hitachi Ltd 分散プログラミング方法

Non-Patent Citations (5)

* Cited by examiner, † Cited by third party
Title
INFORMATION PROCESSING, Vol. 22, No. 5, (Tokyo), May 1981, TADAMASA SATO, "Programming Documentation". *
IPS, "Lecture Transactions (I) of the 32nd (The First Term of 1986) Nationwide Convention", Received by JAPAN PATENT OFFICE LIBRARY, 15 April 1986, pages 637-638. *
IPS, "Lecture Transactions of the 20th Nationwide Convention in 1979", Received by JAPAN PATENT OFFICE, 27 May 1982, pages 285-286. *
KENICHI HARADA, "Structure Editor", KYORITSU SHUPPAN K.K., (TOKYO), 01 June 1988, pages 121-146. *
NIKKEI COMPUTER, No. 60, (Tokyo), 09 January 1984, HIDEYUKI HAYASHI, "A New Presentation of Program Control Structure: A Tree Structure Chart is Widespread". *

Also Published As

Publication number Publication date
KR960024909A (ko) 1996-07-20
KR100367134B1 (ko) 2003-03-12
AU4190396A (en) 1996-07-03

Similar Documents

Publication Publication Date Title
Groote et al. Modeling and analysis of communicating systems
Koskimies et al. Automated support for modeling OO software
Kerbrat et al. Automated test generation from SDL specifications
CN100571167C (zh) Web服务业务流程的单元测试的方法和设备
Clarke Automated test generation from a behavioral model
WO1996018944A1 (fr) Appareil de traitement de conception de logiciel du type a assemblage
Abdallah et al. Models transformation to implement a Project-Based Collaborative Learning (PBCL) scenario: Moodle case study
Bourhfir et al. Test cases selection from SDL specifications
Combes et al. Modeling and verification of a telecommunication application using live sequence charts and the play-engine tool
Bordeleau A systematic and traceable progression from scenario models to communicating hierarchical state machines.
JP5113779B2 (ja) 情報処理装置、情報処理方法、プログラム、およびデータ構造
Ghazi et al. ImitGraphs: Towards faster usability tests of graphical model manipulation techniques
Sung et al. Layered approach to development of OO war game models using DEVS framework
Barrett et al. Merging of use case models: Semantic foundations
JP2585460B2 (ja) テストデータ作成方法
Dean Object-oriented design using message flow decomposition
Alyami et al. Enhancing and consolidating requirements specification in teaching system design by aligning concepts from heterogeneous diagrams
Mani et al. Exploring SOA pattern performance using coupled transformations and performance models
JP4713788B2 (ja) シナリオ編集装置、シナリオ表示装置、ならびにそのプログラムを記録した記録媒体
EP0738964B1 (fr) Dispositif pour l'animation du comportement composite de scénarios
Hahn et al. Micro and nano product engineering using data management for silicon-based fabrication process development
Kanjilal et al. CAG: A Component Architecture Graph
Akkøk Refining Compositional Structure Using the N 2 Chart for Identifying Components and Design Patterns in Component-Based Systems
JP2002132323A (ja) 生産工程の設計方法およびその装置
Favre Metamodel-Driven Architecture Recovery

Legal Events

Date Code Title Description
AK Designated states

Kind code of ref document: A1

Designated state(s): AU CA CN JP US

AL Designated countries for regional patents

Kind code of ref document: A1

Designated state(s): AT BE CH DE DK ES FR GB GR IE IT LU MC NL PT SE

121 Ep: the epo has been informed by wipo that ep was designated in this application
122 Ep: pct application non-entry in european phase
NENP Non-entry into the national phase

Ref country code: CA