JP2011100369A - Method and apparatus for supporting generation of flow - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To solve such a problem that it is difficult detecting a definition in a dependency relationship with a corrected definition from another node and re-correcting or confirming it if a correction operation arises at a certain node in a flow, whereas it is easy to design a new definition in accordance with a preset flow. <P>SOLUTION: A system construction apparatus includes an interface, a processor connected to the interface, and a memory connected to the processor. A system construction database stores item definition information including items defined correspondingly to a pattern corresponding to the kind of a system to be constructed, and construction flow definition information defining the order of a process for inputting values to items and a previous process in a manner corresponding to the pattern. <P>COPYRIGHT: (C)2011,JPO&INPIT

Description

  The present invention relates to a technique for supporting system construction.

  When a system builder constructs a system, various definitions are set based on the system requirements from the customer for the system construction target server.

  As a support technology for newly constructing a system, a setting order of these definitions and a technology for ensuring consistency are disclosed. In particular, Patent Document 1 discloses a technique for displaying a procedure designed as a flow and an input field on a screen for system construction, and setting a system environment while checking consistency based on the input definition. It is disclosed.

JP 2006-72772 A

  With the technology disclosed in Patent Document 1, it is easy to newly perform definition input design in each node according to a procedure set in advance in the flow. However, if a definition modification work has occurred on a node that has already been set in the past, another definition that has a dependency relationship with the modified definition is found from another node, and re-correction or confirmation work is performed. It is not easy to do. For example, when a value of a certain definition is the basis for calculating a value of a definition of another item, if that value is corrected, there are many cases where another item needs to be confirmed or re-corrected. However, such a revision of the definition has not been taken into account, for example, dynamic changes in the flow.

  On the other hand, the above support system supports by providing design information as a flow only when a specific system set in advance is constructed. However, systems that are originally developed have various patterns according to customer needs, and existing flows are often customized based on the know-how possessed by system developers. In that case, the definition designed for each node of the flow is often changed, and it is assumed that the dependency relationship between the definitions often changes.

  In the present invention, in particular, in order to construct a large-scale system, the dependency relationship between the definitions by the customization of the technology for supporting the necessary items to be set efficiently can be dynamically acquired for each customization and designed once. The purpose is to provide information dynamically as a child flow of the dependency between definitions by modifying the definition.

In order to solve the above problem, in a navigation method in a navigation device provided with storage means,
The flow name, node information, key name, initial value setting definition, value match information, and equivalence prohibition information are associated with the definition list information and stored in the storage means.
In response to an input of a setting item definition change request, when another key is set in the initial value setting definition for the key, the search is performed from the value match information and equivalence prohibition information of the definition list information for the other key, When the relationship between the key searched from the searched definition list information and the other key is stored in the value matching information or the equivalence prohibition, it is realized by determining that there is dependence on the other key. .

  Furthermore, the present invention provides a system construction support method for supporting system construction in a computer system comprising a system construction device and a system construction database storing data accessed by the system construction device, wherein the system In the construction database, item definition information including items defined corresponding to patterns corresponding to the types of systems to be constructed, a process of inputting a value to the items, and the order of the processes correspond to the patterns. And the construction flow definition information defined by the method, the method accepts designation of a pattern of the constructed system, acquires item definition information corresponding to the designated pattern from the system construction database, and Specify the construction target server to be placed in the system to be constructed, and specify the specified Based on the construction flow corresponding to the process, the input of the value of the item corresponding to the process is accepted, and after the value of the item necessary for constructing the system is set, the environment of the construction target server is set Generating a construction script and system definition information to be executed, distributing an agent for executing the construction script to the construction target server, and executing the construction script based on the system definition information by the distributed agent. And instructing the construction target server.

  Even when a pattern stored in the system construction database is newly developed or modified, a construction script and system definition information can be generated. In addition, when a setting value is corrected in a midway node of a flow, a node with a definition having a dependency relationship can be displayed and provided as a child flow.

  In the system construction navigation system that inputs the definition value to be designed to the server according to the navigation instructed at each node in the pre-designed flow, the definition value that was once designed was corrected later. Even in this case, another node in which another definition value related to the value is navigated is newly displayed as a child flow of the node. As a result, it is not necessary to check all the nodes in the order of the flow after correction, and only the directly related nodes need to be checked. Also, it is assumed that the flow is customized by the user in any way, and even when the flow is customized, the dependency relationship between each definition can be grasped in multiple stages. Therefore, in the customized flow, when the definition value is corrected in the same manner, a node that navigates the definition value having the dependency relationship is displayed as a child flow.

It is a block diagram which shows the system construction navigation system regarding this invention. It is a block diagram of the system construction navigation server which comprises a system construction navigation system. It is a block diagram of the system construction navigation database server which comprises a system construction navigation system. It is a block diagram of the construction object server which comprises a system construction navigation system. It is explanatory drawing which shows a process in case a user uses a system construction navigation server in the form which does not use an automatic child flow production | generation using a user terminal. It is explanatory drawing which shows the process performed by the input value check which is an internal process of a system construction navigation server. It is explanatory drawing which shows the process performed by the output value calculation which is an internal process of a system construction navigation server. It is a figure explaining the outline | summary of the procedure which inputs a value into the item of embodiment of this invention. It is a figure explaining the outline | summary of the procedure which develops the new flow of the developer in this invention. It is an example of the setting value with respect to the design item of each node defined simultaneously when a developer develops a flow. FIG. 14 is a flowchart for creating a table (FIG. 13) showing a dependency relationship between setting values from the setting item definition developed in FIG. 9. It is an example of the image figure showing the dependency of each design item which the system construction navigation process part of a system construction navigation server recognizes automatically in the procedure of FIG. 11 from the definition of the setting value which the developer developed in FIG. . 13 is an example of a definition value dependency relationship table stored by the system construction navigation database server from the image diagram of FIG. FIG. 9 shows a list of each design item automatically created by the system construction navigation processing unit of the system construction navigation server from the setting values defined by the developer and whether each design item has already been set by the user. It is an example of a figure. It is explanatory drawing which shows a process in case a user uses a system construction navigation server in the form of using automatic child flow generation using a user terminal. It is a figure which shows the procedure of the child flow generation in the system construction navigation system in the case of the form using automatic child flow generation. It is an example of the figure which showed the sizing flowchart of the Web system which a user can try using a utilization terminal. FIG. 18 is a diagram illustrating that a child node that appears when the setting item BBB is corrected in the sizing node 2 in the flowchart illustrated in FIG. 17 appears. After correcting the setting item BBB in the sizing node 2 in the flowchart shown in FIG. 17, it will be described that a new grandchild node appears when the sizing node 4 is corrected among the displayed child nodes. FIG. After correcting the setting item BBB in the sizing node 2 in the flowchart shown in FIG. 17, it will be explained that a new grandchild node appears when the sizing node 5 is corrected among the displayed child nodes. FIG.

  FIG. 1 shows a configuration diagram of a system construction navigation system. The system construction navigation system includes one or more system construction navigation servers 100, one or more developer terminals 700, one or more user terminals (801, 802), and one or more systems (900, 910). Are connected to the network 1000.

  The system construction navigation server is connected to the system construction navigation database server 200.

  The systems (900, 910) to be constructed are each composed of one or more servers (901, 902).

  Each server belonging to the system is connected to the network 1000, and the system construction navigation server 100 performs various settings over the network.

  The system construction navigation server 100 sets the definition of the system to be constructed based on the system requirements input from the user terminals 801 and 802. The configuration of the system construction navigation server 100 will be described later with reference to FIG.

  The system construction navigation database server 200 stores information necessary for constructing a system by the system construction navigation server 100. Details of the system construction navigation database server 200 will be described later with reference to FIG.

  In the user terminals 801 and 802, a user who constructs a system (for example, a system engineer) inputs setting items such as system requirements and transmits them to the system construction navigation server 100. For example, a general-purpose web browser is used as an interface for setting items. By using a general-purpose web browser, a system can be constructed without requiring a dedicated application, and any terminals connected to the network can be used as user terminals 801 and 802.

  The construction target servers 900 and 990 are servers on which a system is constructed. Details of the construction target servers 900 and 990 will be described with reference to FIG.

  The users 803 and 804 use the user terminals 801 and 802 to access the system construction navigation server via the network 1000 to obtain information necessary for constructing the target system, and from the necessary information. Perform settings necessary for system construction. In addition, the system construction navigation server can be instructed to construct the system construction servers (901, 902) and (991, 992).

  The developer 701 has an authority to access the system construction navigation database via the network 1000 using the developer terminal 700 to add information and to update.

  FIG. 2 shows a configuration diagram of the system construction navigation server 100. The system construction navigation server 100 includes a main storage device 110, a CPU 120, an interface 130, and a disk drive 140, and is connected to each other via a bus. The main storage device 110 stores a system construction navigation processing unit 111 realized by a program executed by the CPU 120 and data necessary for the execution of the system construction navigation processing unit 111.

  The system construction navigation processing unit 111 can expand the function by adding program parts for each pattern. For example, by preparing a program part having a different calculation function for each business, it is possible to set a more suitable definition for each business. Definitions of definition settings by users 803 and 804, definitions for initial value calculation, definition of prohibition of equivalence with other definitions and value matching are defined by the developer 701 in the setting item information 540 of the system construction navigation database server 200. . Details of the setting item information 540 will be described later.

  Further, by configuring the system construction navigation processing unit 111 to include the function of the Web server, as described above, it is possible to construct a system without distributing dedicated applications to the user terminals 801 and 802. The system construction navigation server 100 may be separately provided with a Web server.

  The CPU 120 executes a system construction navigation processing unit stored in the main storage device 110 and realized by a program, and executes various processes. The interface 130 is an interface that accepts input from the user terminals 801 and 802 and connects to the network 1000 to access the system construction navigation database server 200 and the construction target servers 900 and 910.

  FIG. 3 is a diagram showing a configuration of the system construction navigation database server 200.

  The system construction navigation database server 200 includes a main storage device 210, a CPU 220, an interface 230, and a disk drive 240. The main storage device 210, CPU 220, interface 230, and disk drive 240 are connected to each other via a bus.

  The disk drive 240 stores data to be provided to the system construction navigation server 100. The stored data will be described later.

  The main storage device 210 stores a database processing unit realized by a program executed by the CPU 220 and data necessary for the execution of the database processing unit 211. Specifically, a database management system 211 for providing data to the system construction navigation server 100 is stored.

  The CPU 220 executes a database processing unit stored in the main storage device 210 and executes various processes. The interface 230 is an interface connected to the network 1000 in order to access the system construction navigation server 100 and the construction target servers 900 and 910.

  Next, data stored in the disk drive 240 will be described. The disk drive 240 stores the construction data 300, the construction target system tool 400, and the pattern specific data 500.

  The construction data 300 stores data necessary for constructing the system.

  The pattern specific data 500 stores information created based on know-how obtained by a system constructed in the past. The pattern specific data 500 includes a system definition file template 510, a construction script template 520, a construction flow definition 530, and setting item definition information 540. The pattern specific data 500 is defined for each pattern of the system to be constructed. Pattern specific data is defined or edited by the developer.

  The system definition file template 510 is a definition file template of the system to be constructed. A system definition file 410 is created based on the construction data 300 such as the input system requirements.

  The construction script template 520 is a script template for constructing a system by being executed on the construction target server. Similar to the system definition file, the construction script 420 is created based on the construction data 300 such as the input system requirements.

  In the construction flow definition 530, a construction flow including an order of inputting items set to construct a system is defined. The construction flow is configured by a process for setting a definition and an order of the processes. The construction flow defined here is expressed by the system construction navigation server and displayed by the user terminals 801 and 802. The user can efficiently construct a system by setting definitions according to the construction flow.

  The setting item definition information 540 is a definition for checking the input items to be set defined in the construction flow. For each input item, define the initial value and dependencies with other definitions. Details will be described later with reference to FIG.

  The construction target system tool 400 includes definition files and construction scripts necessary for system construction distributed to the construction target servers 901, 902, 911, and 912.

  The system definition file 410 is a system definition file generated based on the input system requirements, the construction data 300 corresponding to the system requirements, the system definition file template 510, and the like.

  The construction script 420 is a construction script generated based on the input system requirements, the construction data 300 corresponding to the system requirements, the construction script template 520, and the like.

  FIG. 4 is a diagram illustrating a configuration of the construction target server 901.

  The construction target server 901 includes a main storage device 910, a CPU 920, an interface 930, and a disk drive 940. The main storage device 910, CPU 920, interface 930, and disk drive 940 are connected to one another via a bus.

  The disk drive 940 stores a system definition file 941 and a construction script 942 that are necessary for the operation of the construction target server 901.

  The main storage device 910 stores a system construction navigation agent 911, a pattern-specific logic processing unit 912 implemented by a program executed by the CPU 920, and data necessary for the execution. Specifically, the system construction navigation agent 911 that manages the system construction definition file 941 and the construction script 942 distributed from the system construction navigation server 100 is stored.

  The CPU 920 executes the system construction navigation agent 911 and the pattern-specific logic processing unit 912 stored in the main storage device 910, and executes various processes. The interface 930 is an interface connected to the network 1000 in order to access the system construction navigation server 100.

  FIG. 5 is a flowchart illustrating a procedure for setting the environment of the construction target servers 901, 902, 911, and 912 according to the embodiment of this invention. This flowchart is used particularly when the environment of the construction target servers 901, 902, 911, and 912 is newly set.

  The procedure for setting the environment of the construction target servers 901, 902, 911, and 912 is as follows. The user 803 who sets the environment accesses the system construction navigation server 100 via the network 1000 using the user terminals 801 and 802. This is implemented by inputting a value on the screen according to the procedure indicated by the flow displayed on the user terminal by the system construction navigation processing unit 111. The value input on the screen is transmitted to the system construction navigation server via the network 1000 as well. It is assumed that the flow transitions in units of nodes and various design procedures related to the construction target server are shown in units of nodes. An example of the flow displayed on the user terminal will be described later with reference to FIG.

  First, the user 803 selects which type of system is to be constructed from the various system patterns stored in the system construction navigation database server (S3001).

  The procedure indicated by each node of the flow includes a process of inputting a value into an item and a process of checking the input value (S3002, S3007). The input value check process will be described later with reference to FIG.

  The user 803 repeats the setting by inputting necessary values to the construction target server on the screen according to the navigation instruction of the node displayed on the screen (S3005, S3006). .

  The determination process of whether or not the return value of the input value check is assumed is always performed after the input value check process (S3003, S3008). If the determination process is OK, the process proceeds to the next process, and if it is NG, an error notification is given and the process returns to the original node (S3004, S3009).

  Input value check processing is performed on the input values at each node by the user 803, but there are values that need to be saved and values that are not required to be stored in the construction data 300 of the system construction navigation database server 200. To do. When the system construction navigation database server 200 needs to store the data, if the determination result of the input value check processing is OK, the system construction navigation database server 200 stores the data (S3010).

  Depending on the item displayed in the node, a recommended value (default value) of a value input in the subsequent process may be set based on the value input in the previous process. In that case, the calculation process is performed using the value input in the previous step (S3011). The recommended value may be calculated on the basis of the value registered in advance in the system construction navigation database server 300 or based on the input value and the calculation formula set in the setting item definition information 540. Details will be described later in the initial value definition T2006 of FIG.

  After all the navigation design for the system pattern to be designed is completed, the system construction navigation server 100 creates the system definition file 410 and the construction based on the set information based on the system definition file template 510 and the construction script template 520. The construction target system tool 400 including the script 420 is generated and stored in the system construction navigation database server 200 (S3013).

  FIG. 6 is a flowchart of internal processing performed by the system construction navigation processing unit 111 of the system construction navigation server 100 related to the input value check shown in FIG.

  When the users 803 and 804 input to the use terminals 801 and 802, the values input at the nodes are acquired for each input value (S3101).

  The system construction navigation processing unit 111 acquires the setting item definition information 540 from the corresponding pattern specific data 500 stored in the disk drive of the system construction navigation database server for each input value (S3102).

  In the table defined in the setting item definition information 540, if a check definition corresponding to the input value, a value match, and a column for which equivalence is prohibited are not defined, the next processing for the value is not executed and the next The process is continued (S3103). The meanings of check definition, value matching, equivalence prohibition, etc. will be described later with reference to FIG.

  When confirmation items (check definition, value match, equivalence prohibition) are defined, the input value is checked according to the definitions of these confirmation items (S3104).

  After checking the input value, if the input value satisfies the definition of the confirmation item, the next value confirmation process is performed, or if all the input values have been checked, the process repeats (S3105). If the input value does not satisfy the definition of the confirmation item, the output of the warning dialog is instructed and the repetition process is exited (S3106).

  After confirming all the input values input to the node by the user or outputting a warning dialog, the check result is returned and the input value check processing is terminated (S3107).

  FIG. 7 is a flowchart of internal processing performed by the system construction navigation processing unit of the system construction navigation server 100 related to the output value calculation shown in FIG.

  The user transitions to the next node after designing the value according to the navigation described in the node, but the system construction navigation processing unit 111 displays information on whether there is a value to be designed in the transition destination node. It can be grasped from the construction flow definition 530 in the pattern specific data 500 (S3201).

  When there is a value output to the screen as a value to be set in the transition destination node, the system construction navigation processing unit 111 performs the processing repeatedly for the number of output values. The contents of the iteration process are shown below.

  First, it is confirmed whether or not the initial value definition column T2006 is defined from the setting item definition information 540 of the acquired pattern specific data 500 (S3202).

  When the initial value definition column T2006 is defined, an output value calculation formula is acquired (S3203). Information necessary for the calculation formula of the output value is acquired from the construction data 300 of the system construction navigation server 200 (S3204). An output value is calculated based on necessary information and a calculation formula (S3205). After finishing the calculation of output values for all design values displayed at the transition destination node, the calculation result is returned (S3206).

  FIG. 8 is a diagram illustrating an outline of a procedure for inputting a value to an item according to the embodiment of this invention.

  In the embodiment of the present invention, a value can be set in the input field, and a value can be set in another definition based on the value set in the input field when transitioning to the next screen. For example, as shown in FIG. 8, the user enters values in the input fields inputA and inputB displayed on the browsers of the user terminals 801 and 802 and operates “ActionButton” to shift to the next screen. At this time, on the next screen, OutputC is output based on the input values (inputA and inputB).

  OutputC is a value searched based on inputA and inputB, or a value calculated by applying inputA and inputB to a calculation formula.

  The procedure for outputting other definition values based on the input values has already been described with reference to FIG.

  FIG. 9 shows a flowchart of work in the case where a system pattern designed by the developer 701 is newly developed or an existing pattern is modified. The system construction navigation 100 can be newly developed and modified flexibly so that the system construction navigation processing unit 9111 can automatically provide usability to the documenter simply by creating some definitions and navigation by the developer 701. It has such a function.

  The developer 701 first sets a flow to be newly added or modified for the developer terminal 700 (S3301). The following processing is repeated for the number of nodes in the flow to be newly added or modified. First, navigation is developed for each node (S3302). This is normal text data or image data. Next, a setting value to be set at the node is developed as a setting item (S3303). Finally, a definition for the setting value developed at the node is developed as a setting item definition (S3304). Details of the setting item definition defined here will be described later with reference to FIG.

  After the development of the nodes defined in the flow is completed, a system definition file template (510) and a construction script template (520) relating to the system pattern to be developed are developed (S3305).

  After all the related nodes have been developed, whether or not to continue the flow development is reviewed, and if necessary, the process returns to the repetition. However, if it is determined that the flow development has ended, the process ends as it is (S3306). These pieces of information set in the flow development are stored in the construction flow definition 530 and the setting item definition information 540 of the system construction navigation database server.

  FIG. 10 shows definitions for each setting item developed by the developer 701 shown in FIG. A pattern T2001 indicates the name of a system pattern defined by the developer. The flow name T2002 indicates the name of the flow in the system pattern defined by the developer. A node T2003 indicates each node name in the flow defined by the developer. Key name T2004 indicates the name of a setting item set in each node.

  A check definition T2005 indicates a definition that the system construction navigation processing unit 111 should check in the input value check process when the user inputs the setting item indicated by each key name. For example, the input type such as whether the input value is a character string or a numerical value, or the range if the numerical value is a numerical value.

  The initial value definition T2006 defines a calculation formula to be displayed in the input field at the transition destination node used in the output value calculation (S3011) shown in FIG.

  Value match T2007 is defined so as to confirm that the value matches another defined value. The values defined in this field are input values that are assumed to match each other.

  The equivalence prohibition T2008 is defined to confirm that the value is not the same as other defined values. The values defined in this field must be different from each other.

  T2009 is an example of the initial value definition T2009. The value defined as the key name GGG is defined to be displayed by adding a character string% to the key name FFF as an initial value at the time of transition of the transition destination node. T2010 is an example of a value match T2007. If defined as "-", it indicates that the value is not instructed to match other definitions.

  T2011 is an example of the equivalence prohibition T2008. The key name FFF indicates that the same value as the key name BBB must not be input.

  FIG. 11 is a flowchart in which the system construction navigation processing unit 111 extracts the presence / absence of the dependency between the definitions and the dependency itself based on the setting item definition created by the developer.

  First, the developer checks whether the setting item definition has been developed (S3401). If not yet developed, exit from this flowchart.

  If development of the setting item definition has been completed, the following processing is repeated for the number of keys defined in the setting item definition.

  First, it is confirmed whether or not a calculation formula using another key is defined in the initial value definition of the setting item definition (S3402). If it exists, there is a dependency between its definition and the other key defined. If it does not exist, transition to the next confirmation item.

  If a calculation formula using another key is defined in the initial value definition, the other key is set as a parent and the target key is set as a child (S3403). These dependency relationships will be described later with reference to FIG.

  A check is made in the presence / absence of dependency of setting value list information (see FIG. 14) created from the setting item definition (S3404). The next confirmation item confirms whether or not another key is defined to match the value of the setting item definition and prohibit the same value (S3405). If not defined, the process proceeds to the next iteration as it is. If defined, transition to the following process. If there is another key that is defined as value match and equivalence prohibition, both keys are defined as strongly connected (S3406).

  Finally, a check is made as to whether there is a dependency in the definition list information (S3407).

  FIG. 12 is an image diagram showing the dependency relationship of each key from the setting item definition example of FIG.

  610, 611, 612, 613, 614, 615, and 616 in the figure indicate the names of keys defined in the setting item definition example of FIG.

  A set 600 means a set of keys having a dependency relationship with each other, and a set 601 indicates a set of keys having no dependency relationship.

  An arrow line 620 indicates that there is a dependency from the source of the arrow to the destination. This is displayed when the key parent-child relationship is defined (S3403) when it is "Yes" in the confirmation of whether or not another key exists in the initial value definition of FIG. 11 (S3402). .

  A line 621 is defined as a strong connection, and is displayed when another key is defined for value matching and forbidden equivalence in FIG. 11 (S3406).

  FIG. 13 is a graph of the image diagram of FIG. 12 based on the flowchart of FIG. In the horizontal row and vertical column of the graph, all setting items defined in the setting item definition are set (T2101, T2102).

  Each row indicates whether the setting item affects other setting items, in other words, each column indicates whether the setting item depends on other setting items. For example, T2103 indicates that the setting item DDD affects the setting item BBB, and the setting of the setting item BBB is dependent on the setting item DDD.

  On the other hand, the setting item BBB and the setting item FFF have a strongly connected relationship that depends on each other in setting. In the case of such a setting item, a check is written in both columns as in T2104 and T2105.

  Among the setting items, there are setting items that have no dependency at all. Such setting items are indicated by “-” as shown in T2105.

  FIG. 14 is an example of a table that the system construction navigation processing unit has as the setting value dependency relationship table 320 in the construction data 300 of the system construction navigation database server 200 from the setting item definition.

  T2201 indicates the type of pattern. T2202 indicates a flow name. T2203 indicates the name of the node. T2204 indicates a key name that is a setting item name. T2205 indicates whether or not there is a dependency relationship with other setting items. T2206 indicates a value set by the user using the user terminal. T2207 indicates whether or not the user has already designed the user terminal once using the user terminal.

  FIG. 15 shows a flowchart of the processing of the user and the system construction navigation processing unit 111 in the system construction after applying the present technology. The basics are the same as in FIG. 5, but if the user corrects a setting item that has been designed once focusing on the dependency of the setting item, the setting item having a dependency relationship with the corrected setting item is navigated. Node is displayed as a child flow.

First, when a user sets a value for a setting item according to navigation on the screen, it is stored in the system construction navigation database server after being checked by the system construction navigation processing unit (S3010).
When a setting item that has already been set has been corrected, the setting item is saved in the system construction navigation database server, and the setting item is checked for dependency with other setting items (S3501).

  If there is a dependency and the setting item has been designed, a child flow is created (S3502). However, if the setting item has no dependency relationship with other setting items, the output value is calculated as in FIG. 5 and the process proceeds to the next screen (S3011, S3012).

  After creating the child flow, the user is made to determine whether or not to transition to the child flow as the next processing (S3503). If there is no transition to the child flow, the output value of the next node is calculated in order to transition to the next node of this flow as it is.

  If transition is made to a child flow node, the value displayed on the node is confirmed by the number of nodes of the child flow having a dependency relationship with the setting item (S3504).

  FIG. 16 shows the creation of a child flow.

  First, the presence / absence of a setting item that affects the target setting item is checked using a dependency table (S3601).

  If there is a setting item that affects the target setting item, it is checked whether or not the setting item has already been set (S3602).

  If the searched setting item has already been set, a node for setting the searched setting item is newly set with an arrow pointing to the node for setting the target setting item (S3603).

  Subsequently, the presence / absence of a setting item affected by the target setting item is searched (S3604).

  If there is a setting item that affects the target setting item, it is checked whether the setting item has already been set (S3605).

  If the setting item has already been set, the node that is navigating the searched setting item is newly set with the arrow pointing from the node that is navigating the target setting item (S3606).

  Finally, the presence / absence of another setting item value defined as value matching or prohibition of equivalence to the target setting item is searched (S3607).

  If there is another setting item value defined as a value match and prohibition of equivalence, it is investigated whether or not the retrieved setting item has already been set (S3608).

  If the retrieved setting item has already been set, the node that is navigating the setting item is set by connecting with a line from the node that sets the target setting item (S3609).

  This is repeated for the number of setting items set for the node.

  FIG. 17 is an example of a flow of a certain pattern that the user sees on the user terminal.

  This flow shows a sizing flow of the Web system, and sizing node 1 (navigation and setting of setting item AAA) is performed at some transition from the start node (1101).

  Subsequently, sizing node 2 (navigation and setting of setting item BBB) is performed (1102).

  Further, it is assumed that sizing node 3 (navigation and setting of setting item CCC) is performed (1103).

  It is assumed that the user has already designed the flow shown in this example and has corrected the value of the sizing node 2 (setting item BBB) at a certain time.

  FIG. 18 shows a flow form that the user can see when the sizing node 2 is modified in the flow of FIG.

  When the sizing node 2 is modified, a node connected by an arrow is newly output from the node (sizing node 4) that is set to navigate and set the setting item DDD that affects the setting item BBB (1104). ).

  Similarly, a node obtained by connecting a node (sizing node 5) that performs navigation and setting of the setting item FFF that is strongly connected to the setting item BBB by connecting with the sizing node 2 by a line is newly output (1105). ).

  In this manner, when the setting item BBB is corrected in the sizing node 2, the setting item directly related to the setting item BBB can be displayed in a form in which the node to be navigated and set can be changed.

  FIG. 19 shows the form of a flow displayed when transitioning to sizing node 4 in FIG.

  When transitioning to sizing node 4 and modifying setting item DDD, environment definition design node 1 that is navigating and setting other setting item EEE affected by setting item DDD is newly displayed as a child flow. (1106).

  FIG. 20 shows the form of the flow displayed when transitioning to the sizing node 5 in FIG.

  When transitioning to sizing node 5 and modifying setting item FFF, environment definition design node 2 that is navigating and setting other setting item GGG affected by setting item FFF is newly displayed as a child flow. (1107).

100 System Construction Navigation Server 110 Main Memory 111 System Construction Navigation Processing Unit 120 CPU
130 Interface 140 Disk Drive 200 System Construction Navigation Database Server 210 Main Memory 211 Database Management System 220 CPU
230 Interface 240 Disk drive 300 Construction data 310 Setting value 320 Setting value dependency table 400 Construction target system tool 410 System definition file 420 Construction script 500 Pattern specific data 510 System definition file template 520 Construction script template 530 Construction flow definition 540 Setting item Definition information 700 Developer terminal 701 Developer 801 User terminal # 1
802 User terminal #N
803 User 804 User 900 System #A
901 Construction target server # 1
902 Construction target server #L
910 Main storage device 911 System construction navigation agent 912 Logical system by pattern 920 CPU
930 Interface 940 Disk drive 941 System definition file 942 Construction script 990 System #B
991 Construction target server # 1
992 Construction target server #M

Claims (5)

In the flow generation support method in the flow generation support apparatus provided with the storage means,
The flow name, node information, key name, initial value setting definition, value match information, and equivalence prohibition information are associated with the definition list information and stored in the storage means.
In response to an input of a setting item definition change request, when another key is set in the initial value setting definition for the key, the search is performed from the value match information and equivalence prohibition information of the definition list information for the other key, When the relationship between the key searched from the searched definition list information and the other key is stored in the value matching information or the equivalence prohibition, it is determined that there is dependence on the other key. Flow generation support method.   2. The flow according to claim 1, wherein the key stored in the value matching information or the equivalence prohibition is stored as dependency information when the other key is stored in the value matching information or the equivalency prohibition. Generation support method.   3. The flow generation support method according to claim 2, wherein a sizing having a key stored in the value matching information or the equivalence prohibition is displayed adjacent to a sizing related to the other key. The node information includes environmental parameter design information and displays the environmental parameter information and an initial value setting definition of the environmental parameter information in the vicinity of a sizing node having the same initial value setting as the treatment setting intention definition. Item 3. The flow generation support method according to Item 2. In a navigation method in a navigation device provided with storage means,
Storage means for storing the flow name, node information, key name, initial value setting definition, value match information, and equivalence prohibition information in association with each other as definition list information;
In response to an input of a setting item definition change request, when another key is set in the initial value setting definition for the key, the search is performed from the value match information and equivalence prohibition information of the definition list information for the other key, Means for determining that there is dependence on the other key when the relationship between the key searched from the searched definition list information and the other key is stored as value matching information or equivalence prohibition. A flow generation support apparatus characterized by that.

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