JP6926746B2 - Information processing equipment, information processing system and information processing program - Google Patents

Description

The present invention relates to an information processing device, an information processing system and an information processing program.

Today, there is known an information processing system that forms information that has undergone predetermined information processing by an information processing device and distributes the formed information to a device that is a designated delivery destination according to a predetermined rule. The information processing applied to the information by the information processing device is defined by the workflow. The information processing defined as a workflow can be defined by combining a plurality of desired information processes. The user defines the workflow by specifying the information processing according to the purpose. As a result, it is possible to obtain information that has been processed according to the purpose of the user.

In Patent Document 1 (Japanese Unexamined Patent Publication No. 2010-268604), among the functions provided by the other device, when the workflow is executed by using the function provided by the other device in the image processing device. An image processing system that makes it possible to select and use an appropriate function is disclosed.

However, the image processing system of Patent Document 1 requests an image processing device that provides a desired workflow processing for image processing. Therefore, for example, when the image processing device that provides the desired workflow processing has a high load, the workflow processing cannot be performed efficiently. Further, if the image processing device is not in the network environment desired by the user, the workflow processing cannot be executed in the network environment desired by the user. As described above, the image processing system of Patent Document 1 is not always able to efficiently perform workflow processing according to the user's wishes.

The present invention has been made in view of the above problems, and an object of the present invention is to provide an information processing device, an information processing system, and an information processing program capable of efficiently performing workflow processing according to a user's wishes. ..

In order to solve the above-mentioned problems and achieve the object, the present invention uses a processing status detection unit that detects the information processing status of a plurality of execution devices that perform predetermined information processing on the processing information, and the processing information. An execution flow generation unit that generates an execution flow definition in which processes to be executed for each execution device are assigned to each processing unit based on a workflow definition indicating the processing to be performed and the sequence of the processing, and each of the above in the execution flow definition. Among the processes assigned to the execution devices, the migration target process which is the process to be executed by the other execution device and the other execution device to execute the migration target process are performed based on the information processing status. An installation control unit that detects and controls the installation of an application program for executing the migration target process on the other execution device, and an execution device that executes the migration target process. Is generated by the change control unit that changes and controls the execution flow generation unit and the execution flow generation unit so that the application program generates the execution flow definition that is changed to the other execution device that is installed and controlled. The execution flow definition is transmitted to the execution device specified by the execution flow definition, and has a processing control unit that controls the processing of the processed information in the processing order of the execution flow definition, and is included in the workflow definition. Includes priority condition information indicating matters to be prioritized, and when the installation control unit performs installation control on the detected other execution device, it is transferred to the other execution device based on the priority condition information. Controls the installation of different application programs to execute processing .

According to the present invention, there is an effect that workflow processing can be efficiently performed according to the user's wishes.

FIG. 1 is a system configuration diagram of the information processing system of the embodiment. FIG. 2 is a block diagram showing a hardware configuration of each device provided in the information processing system of the embodiment. FIG. 3 is a functional block diagram of each device provided in the information processing system of the embodiment. FIG. 4 is a flowchart showing a flow of workflow processing operation of the information processing system of the embodiment. FIG. 5 is a diagram for explaining priority conditions that can be set when generating a workflow definition in the information processing system of the embodiment. FIG. 6 is a diagram for explaining detailed settings in the security priority setting. FIG. 7 is a diagram showing an example of a workflow definition generated by the information processing system of the embodiment. FIG. 8 is a diagram showing the workflow process of the workflow definition in a block diagram along the flow. FIG. 9 is a diagram for explaining a database of allocation determination information that is stored in the storage unit of the control server device and shows the execution server device assigned as the default for each process of the workflow process. FIG. 10 is a diagram for explaining processing status information showing the current processing status of each execution server device, which is collected from each execution server device. FIG. 11 is a diagram for explaining the current processing status in the main execution server device that mainly executes workflow processing. FIG. 12 is a diagram showing an example of an execution workflow definition to which an execution server device that executes each process of the workflow process is assigned based on the workflow definition generated by the information processing system of the embodiment. FIG. 13 is a diagram showing an example of an execution workflow definition generated so that a process that is mainly congested in the main execution server device that executes the workflow process is delegated by another execution server device.

(Overview)
In the information processing system of the embodiment, in a device that performs a series of workflow processes, if a problem such as congestion occurs in a part (or all) of the process, the process in which the problem occurs is performed by another device. Temporarily act on your behalf. As a result, a series of workflow processes can be efficiently executed with a configuration in which some processes are performed on behalf of another device. Further, in the information processing system of the embodiment, when a device that performs a series of workflow processes is in a cloud environment and the user wants to perform some processes in the on-premises environment, the processes are transferred to the on-premises environment. Temporarily substitute for a certain device. As a result, the workflow process can be executed in the network environment desired by the user. In this case, the application program for executing the process is installed on the device to be temporarily substituted when it is needed, and is uninstalled when the proxy process is completed and is no longer needed.

As a result, the device on which the processing is performed can be released, and the device can be made to perform the new processing on behalf of the device. In this way, the information processing system of the present embodiment temporarily installs and executes an application on a substitute device according to the processing status of the device and the network environment (processing execution location) desired by the user. Can be done. Therefore, it is possible to efficiently perform workflow processing according to the user's wishes. In addition, when necessary, the necessary application is installed on the device to be replaced, so that the device can substitute for various processes, and the number of devices used for workflow processing can be reduced. be able to. Therefore, it is possible to realize an information processing system with a small amount of resources. Further, for example, even in a cloud service in which a pay-as-you-go charge is made according to the resources (devices) to be used, the resources to be used can be suppressed, and an information processing system can be realized at low cost.

(System configuration)
FIG. 1 is a system configuration diagram of the information processing system of the embodiment. As shown in FIG. 1, the information processing system of the embodiment includes a scanner device 1, a control server device 2, an execution server device 3, a management server device 44, an application program server device (AP server device) 5, and a client terminal 6. have. The scanner device 1 to the client terminal 6 are connected to each other via a network 7 such as a LAN (Local Area Network) or a WAN (Wide Area Network) such as the Internet. The network 7 may be a wired communication network or a wireless communication network.

The scanner device 1 forms data to be processed by the workflow. Specifically, the scanner device 1 transmits the image data generated by scanning the document to the control server device 2 as input data for a series of workflow processes.

In this example, the scanner device 1 is used as a device for generating or acquiring data for workflow processing, but any electronic device is used as long as it is a device for generating or acquiring data for workflow processing. You may. For example, instead of the scanner device 1, a copy device may be used, or a read device that reads data from the storage medium may be used. Further, a receiving device that receives data transmitted by wire or wirelessly from the outside may be used. Further, the data received by e-mail may be used. Further, data may be acquired from a predetermined file server device or storage device in a cloud environment or the like.

The execution server device 3 performs workflow processing on the image data (job data: an example of processed information) generated by the scanner device 1 according to the workflow definition received from the control server device 2. Workflow processing refers to a processing flow (processing flow) formed by any combination of one or more processing units (tasks) that realize functions that are completed independently or independently, for example. As the "processing unit", "activity" in the general workflow concept may be used.

As each process included in the workflow process, there are various processes such as an image correction process applied to the image data, a process of adding metadata to the data, and a process of delivering the data to the delivery destination. The execution server device 3 is an example of an execution device, which performs a process based on workflow processing on job data and transmits the process to a predetermined device such as a client terminal 6. It is not necessary to perform all the workflow processing in one execution server device 3. In the case of the information processing system of the embodiment, of a series of workflow processes, a partial process (transition target process) that is hindered by congestion or the like is temporarily performed by one or a plurality of other execution server devices 3. A series of workflow processes can be efficiently executed by sharing the processes.

Further, the application program for each process of the workflow process may be stored in advance in a storage unit such as ROM 12 or HDD 14 of the execution server device 3, or may be downloaded to the execution server device 3 via the network 7 at a predetermined timing. You may install it.

The control server device 2 monitors the processing status executed by the execution server device 3 and optimizes the workflow processing. For example, in the execution server device 3, when there is a congested process among each process of the workflow process, the control server device 2 corresponds to the process that is congested with respect to the other execution server device 3. Instruct the installation of the application program. The other execution server device 3 to which this instruction is given acquires an application program corresponding to the congested process from the AP server device 5 and installs it. As a result, the congested process can be substituted by another execution server device 3, and a series of workflow processes can be executed without delay (efficiently).

Further, the control server device 2 instructs to uninstall the application program installed in the other execution server device 3 when the application program corresponding to the congested process is no longer needed. The other execution server device 3 to which the uninstall instruction is given uninstalls the application program installed at the time of the above-mentioned congestion. As a result, the other execution server device 3 for which processing has been temporarily requested can be opened (standby state) for installation of an application program for other processing or other information processing, and can be set in the information processing system. Effective use of resources can be achieved.

The AP server device 5 is a server device that stores various application programs executed by the execution server device 3. One AP server device 5 may be provided on the network 7, or a plurality of AP server devices 5 may be provided. The application program stored in each AP server device 5 may be the same type of application program, or may store different types of application programs. The AP server device 5 transmits an application program to the execution server device or the like instructed to install by the control server device 2.

The management server device 4 has a database in which definition data of each process forming the workflow process is stored in a storage unit such as an HDD 14. The management server device 4 generates a workflow definition corresponding to a series of workflow processes specified by the user based on the definition data stored in the database. Then, the generated workflow definition is transmitted to the control server device 2 via the network 7. A database in which definition data is stored may be provided in the scanner device 1, a workflow definition may be generated by the scanner device 1, and may be transmitted to the control server device 2.

Further, in FIG. 1, the control server device 2, the execution server device 3, the management server device 4, and the AP server device 5 are shown as physically different server devices, but one server device is used as a control server device. 2. Each function of the AP server device 5 may be realized, or each function of the control server device 2 to the AP server device 5 may be shared by a plurality of server devices 1. Further, the control server device 2 to the AP server device 5 shown in FIG. 1 may be provided in either the on-premises environment or the cloud environment, or may be distributed in the on-premises environment and the cloud environment. ..

The client terminal 6 accesses the management server device 4 via a web browser or the like, and creates a workflow definition. In the management server device 4, various settings can be changed via the client terminal 6, and various settings can be changed by directly operating the management server device 4.

(Hardware configuration)
FIG. 2 is a diagram showing a main hardware configuration included in the scanner device 1 to the client terminal 6. As shown in FIG. 2, the scanner device 1 to the client terminal 6 include a CPU (Central Processing Unit) 11, a ROM (Read Only Memory) 12, a RAM (Random Access Memory) 13, an HDD (Hard Disk Drive) 14, and operations. It has a unit 15 and a communication unit 16. The CPUs 11 to 16 are connected to each other via a bus line 17.

The scanner device 1 has a document reading mechanism and the like in addition to the CPU 11 to the communication unit 16. The client terminal 6 has a display unit such as a monitor device or a liquid crystal display unit in addition to the CPU 11 to the communication unit 16.

An information processing program corresponding to each device such as a scanner device, a control server device, an execution server device, a management server device, an AP server device, or a client terminal is stored in a storage unit such as the ROM 12, RAM 13, or HDD 14. Is remembered. The CPU 11 of the scanner device 1 to the client terminal 6 realizes each of the functions described below by executing the information processing program for each device stored in the storage unit.

(Functional configuration)
FIG. 3 is a functional block diagram of each function realized by the CPU 11 of the scanner device 1 to the client terminal 6 executing an information processing program.

(Function of execution server device)
First, as shown in FIG. 3, the execution server device 3 includes a remote communication control unit 21, a flow processing execution unit 22, a flow processing status notification unit 23, an execution flow definition holding control unit 24, and a flow processing function management unit 25. Have.

The flow processing function management unit 25 includes a flow processing function acquisition unit 26, a flow processing function application unit 27, and a flow processing function deletion unit 28. The flow processing function management unit 25 manages various flow processing functions stored in the execution server device 3, such as the flow processing function A and the flow processing function B.

The flow processing execution unit 22 is included in a series of workflow processing based on the application program such as the flow processing function A or the flow processing function B described above according to the workflow definition held in the storage unit by the execution flow definition holding control unit 24. , Executes the process assigned to the control server device 2. Further, the flow processing execution unit 22 is a flow processing function (application program) installed by being designated by the control server device 2, and substitutes a part (or all) of the workflow processing.

The execution flow definition holding control unit 24 stores and controls the workflow definition created by the management server device 4 or the like in a storage unit such as the HDD 14. The flow processing status notification unit 23 notifies the control server device 2 of the current processing status of the execution server device 3 when it receives a notification request from the control server device 2 periodically or irregularly.

The flow processing function acquisition unit 26 of the flow processing function management unit 25 receives an instruction from the control server device 2 when there is a process that causes a problem such as congestion in the execution server device 3 that mainly performs workflow processing. The application program corresponding to the processing in which the trouble occurs is acquired from the AP server device 5 via the network 7. The flow processing function application unit 27 installs and processes the application program corresponding to the flow processing function acquired from the AP server device 5 on the execution server device 3 by the flow processing function acquisition unit 26. As a result, when the execution server device 3 that mainly performs the workflow process has a process that causes a problem such as congestion, the process that causes the problem is temporarily substituted by the instruction from the control server device 2. The execution server device 3 is formed. When the above-mentioned trouble in the execution server device 3 that mainly performs workflow processing is resolved, the flow processing function deletion unit 28 is installed in the execution server device 3 that has been acting for the processing, and the above-mentioned trouble has occurred. Uninstall the application program corresponding to the process.

(Function of control server device)
Next, as shown in FIG. 3, the control server device 2 has a flow definition holding control unit 31, an application information holding control unit 32, a flow execution control unit 33, and a remote communication unit 34. The flow execution control unit 33 is an example of a processing control unit, and has a flow processing status monitoring unit 35, a flow processing function application instruction unit 36, a flow processing function deletion instruction unit 37, and an execution flow definition generation unit 38. There is.

The flow definition holding control unit 31 stores and controls the workflow definition created by the management server device 4 or the like in a storage unit such as the HDD 14 of the control server device 2. The application information holding control unit 32 stores and controls possible processing information indicating the processing that can be executed by each execution server device 3 in a storage unit such as HDD 14 of the control server device 2. The flow processing status monitoring unit 35 of the flow execution control unit 33 is an example of the processing status detection unit, and periodically or irregularly makes an inquiry to each execution server device 3 on the network 7, and the flow processing status monitoring unit 35 of each execution server device 3 Monitor the current processing status (information processing status).

The flow processing function application instruction unit 36 is an example of an installation control unit, and instructs each execution server device 3 to acquire (install) the flow processing function (application program). As a result, it is possible to form an execution server device 3 (sub-execution server device 3) that temporarily substitutes for processing that causes problems such as congestion on the execution server device 3 that mainly executes workflow processing. The flow processing function deletion instruction unit 37 is an example of an uninstall processing unit, and is a sub-execution that temporarily substitutes for processing when problems such as congestion in the execution server device 3 that mainly executes workflow processing are resolved. Instructs to uninstall (delete) the application program installed on the server device 3. The execution flow definition generation unit 38 is an example of the execution flow generation unit and the change control unit, and each process of this workflow process is processed as a processing unit by using the workflow definition stored in the storage unit by the flow definition holding control unit 31. Generates an execution flow definition (specified) to which the execution server device 3 to be executed in is assigned.

The remote communication unit 34 transmits the execution flow definition to the execution server device 3 to which the process is assigned in the execution flow definition generated by the execution flow definition generation unit 38. In addition, the remote communication unit 34 communicates with each execution server device 3 and acquires processing status information indicating the current processing status of each execution server device 3.

(Function of AP server device)
The AP server device 5 has a flow processing function providing unit 41 and a remote communication unit 42. The flow processing function providing unit 41 is a process designated by the control server device 2 among the flow processing function A, the flow processing function B, and the like, which are various application programs stored in the storage unit such as the HDD 14 of the AP server device 5. The flow processing function corresponding to is transmitted to the execution server device 3 via the remote communication unit 42.

(Function of management server device)
The management server device 4 has a remote communication unit 45 and a flow definition generation unit 46. Further, the management server device 4 has a database in a storage unit such as the HDD 14 that stores definition data corresponding to each process of the workflow process. The remote communication unit 45 communicates with the scanner device 1, the control server device 2, the execution server device 3, the AP server device 5, and the client terminal 6 via the network 7. The flow definition generation unit 46 generates a workflow definition corresponding to a series of workflow processes specified by the user.

(Client terminal function)
The client terminal 6 has a display control unit 50 that controls display on the input reception unit 47, the remote communication unit 49, and the display unit 48. The user specifies a desired workflow process by operating the operation unit. The remote communication unit 49 transmits the workflow information indicating the designated workflow process to the management server device 4. As a result, in the management server device 4, the workflow definition corresponding to the workflow process specified by the user is generated.

(Function of scanner device)
The scanner device 1 controls the scanner engine 53 by the CPU 11 executing a scanner application program (scanner application) 51, which is an example of an information processing program stored in a storage unit such as an HDD 14, and mounts the scanner engine 53 on a document mounting table. Controls the reading of characters and figures written on the placed manuscript.

Further, the CPU 11 of the scanner device 1 functions as a remote communication unit 54, a display control unit 55, and an input control unit 56 by executing the scanner application. The display control unit 55 controls the display of the preview image of the original, the scanning setting, and the like on the display unit 58 of the operation panel 57. The input control unit 56 performs input processing such as a set value input via the operation unit 59 of the operation panel 57. The remote communication unit 54 transmits the document data (job data) read by the scanner engine 53 to the control server device 2. The control server device 2 transmits job data to the execution server device 3 based on the workflow process. As a result, the execution server device 3 performs a predetermined workflow process on the manuscript data.

The functions of the scanner device 1, the control server device 2, the execution server device 3, the management server device 4, the AP server device 5, and the client terminal 6 shown in FIG. 3 are stored in storage units such as the HDD 14 of each device. It is realized by software when the CPU 11 executes the information processing program being executed. However, some or all of these functions may be realized by hardware such as an IC (Integrated Circuit).

In addition, the information processing program that realizes each function is provided by recording a file in an installable format or an executable format on a recording medium that can be read by a computer device such as a CD-ROM or a flexible disk (FD). May be good. Further, it may be recorded and provided on a recording medium readable by a computer device such as a CD-R, a DVD (Digital Versatile Disk), a Blu-ray disc (registered trademark), or a semiconductor memory. Further, the information processing program may be provided in the form of being installed via a network such as the Internet. Further, the information processing program may be provided by incorporating it into a ROM or the like in the mobile terminal in advance.

(System operation)
The flowchart of FIG. 4 shows the flow of system operation of the information processing system of the embodiment. In the flowchart of FIG. 4, when the execution server device 3 (main execution server device 3) that mainly executes the workflow processing is congested, for example, a part (or all) of the workflow processing is executed by another execution. This is an example of substituting the server device 3 (sub-execution server device 3). In addition, for example, when the response to the inquiry about the current data processing status to the main execution server device 3 cannot be obtained, the sub-execution server device 3 may perform a predetermined process on behalf of the user. Further, a predetermined process may be performed on behalf of the sub-execution server device 3 on a desired network environment (process execution location) such as an on-premises environment or a cloud environment designated by a user or the like.

In the flowchart of FIG. 4, the user first selects a desired workflow process on the client terminal 6 (step S1). As an example, the display control unit 50 of the client terminal 6 is formed by combining a plurality of processes when a workflow process selection item is selected from the general menu, and is formed by combining a plurality of workflow processes having different processing contents. The list is displayed on the display unit 48. In step S1, the user selects and operates a desired workflow process from this list.

Alternatively, when the selection item of the workflow process is selected from the general menu, the display control unit 50 of the client terminal 6 displays the selection screen of each process forming the workflow process. From this selection screen, the user selects and operates a desired process in order from the first process to be executed.

Further, in the information processing system of the embodiment, when selecting or setting such a workflow, it is possible to set "priority condition information" indicating items to be prioritized when executing the workflow process. Specifically, when a desired workflow is selected by the user, the display control unit 50 of the client terminal 6 displays the priority condition setting screen of the selected workflow on the display unit 48.

FIG. 5 is a diagram showing an example of a screen for setting priority conditions for such a workflow. The example of FIG. 5 shows an example in which "security" is selected by the user as the highest priority condition and "processing speed" is selected by the user as the second priority condition. Further, the example of FIG. 5 shows an example in which the condition of "cost" is not selected by the user.

In addition, each priority condition can be set in detail. As an example, FIG. 6 is a detailed setting screen for the priority condition of "security". When the display control unit 50 of the client terminal 6 detects the operation of the detailed setting button 100 for the "security" priority condition shown in FIG. 5, the display control unit 50 displays the detailed setting screen for the "security" priority condition shown in FIG. 6 on the display unit 48. Display control.

As an example, in the case of the example of FIG. 6, the display control unit 50 sets the "workflow execution location", "security level", and "application" for the detailed setting screen for the priority condition of "security". Display each selection item of "Presence / absence of signature". In addition, the display control unit 50 selects "on-premises only" as a selection item of "workflow execution location" when designating only on-premises as the execution location, and in addition to on-premises, the cloud is also the execution location. Display the selection item of "Allow cloud" to be selected when specifying.

Further, the display control unit 50 selects "high" selection items when a high security level is desired, and "medium" selection items when a medium security level is desired, as selection items of the "security level". Display the selection items and the "low" selection items to be selected when a low security level is desired. Further, the display control unit 50 selects "only with signature" as the selection item of "presence or absence of signature of the application" when permitting the use of only the application with the signature, and the selection item without the signature. Display the selection item of "Allow unsigned" to be selected when the use of the application is also permitted.

In the case of the examples of FIGS. 5 and 6, the workflow process is executed safely and at high speed without considering the cost aspect. By making it possible to set priority conditions for workflow processing in this way, it is possible to execute workflow processing that is more in line with the user's wishes.

The workflow information indicating the workflow processing and the priority conditions selected by the user in this way is transmitted to the management server device 4 via the remote communication unit 49 of the client terminal 6.

Next, when the user selects such a workflow process, the user performs an operation of forming input data. As an example, the user operates the client terminal 6 to instruct the scanner device 1 to scan a desired document. The input reception unit 47 of the client terminal 6 acquires the scan instruction information and transfers it to the remote communication unit 49. The remote communication unit 49 instructs the scanner device 1 to scan the document via the network 7. The control unit 52 (corresponding to the CPU 11 in FIG. 2) of the scanner device 1 controls the scanner engine 53 so as to scan the document placed on the document mounting table (step S2). The remote communication unit 54 of the scanner device 1 transmits the image data (job data) generated by the scanning process of the scanner engine 53 to the control server device 2 via the network 7 (steps S3 and S4). In this example, the job data generated by the scanner device 1 is transmitted to the control server device 2, but the job data is transmitted to the management server device 4, and the management server device 4 will be described below together with the job data. The workflow definition may be transmitted to the control server device 2.

The flow definition generation unit 46 of the management server device 4 acquires the definition information of each process indicated by the workflow information received from the client terminal 6 from the storage unit 14, and obtains the workflow definition corresponding to the workflow process specified by the user. Generate.

FIG. 7 is an example of the workflow definition formed by each process selected in this way. The example of FIG. 7 is an example in which each of the first to sixth processes is selected as a series of workflow processes by the user. The first process is an image correction process, the second process is a conditional branch process, the third process is a format conversion process, the fourth process is a mail delivery process, and the fifth process is. The high compression format conversion process is selected, and the folder distribution process is selected as the sixth process.

Further, in the case of the example of FIG. 7, the condition of "data size <10MB" is attached to the conditional branching processing which is the second processing, and when the data size is less than 10MB, the third processing and the fifth processing It is set as a supplement to branch to the processing of. Further, in the case of the example of FIG. 7, when the data size is determined to be less than 10 MB in the second process, the transition of the third process is set as a supplement. Further, in the case of the example of FIG. 7, when the data size is determined to be 10 MB or more in the second process, it is set as a supplement to shift to the fifth process.

FIG. 8 is a block diagram showing the workflow process illustrated in FIG. 7. When the workflow process of FIG. 7 is executed, as shown in FIG. 8, a predetermined image correction process is performed on the input image data, for example, and in the conditional branching process, the image data after the image correction process is executed. The data size of is determined. When the data size is less than 10 MB, the image data is converted into image data in a predetermined format without changing the data size, attached to an e-mail, and sent to a predetermined e-mail address. On the other hand, when the data size is 10 MB or more, the data size is reduced by high-efficiency compression coding processing (high compression processing), converted into image data in a predetermined format, and distributed in a folder. ..

Next, the remote communication unit 45 of the management server device 4 transmits the workflow definition generated by the flow definition generation unit 46 to the control server device 2. The flow definition holding control unit 31 of the control server device 2 stores and controls the workflow definition received from the management server device 4 and the job data received from the scanner device 1 in a storage unit such as the HDD 14. The flow execution control unit 33 analyzes the workflow definition received from the management server device 4 and detects the execution server device 3 capable of executing each process of the workflow definition (step S5).

Specifically, the storage unit such as the HDD 14 of the control server device 2 stores a database of allocation determination information for determining the execution server device 3 to which each process of the workflow process is assigned. As shown in FIG. 9, the database contains the process name of each process included in the series of workflow processes, the server identification information (server ID) of the execution server device 3 capable of executing each process, and each process. The average time required for processing image data corresponding to one page (average processing time per page) is stored in association with each other. As the server ID, the server ID of the execution server device 3 set as the default is stored as the execution server device 3 capable of executing each process.

In addition, the flow processing function application instruction unit 36 of the control server device 2 has a problem such as congestion in a part of the main execution server device 3 that mainly executes the workflow process, and the process in which the problem occurs. Is temporarily substituted by another execution server device 3 (sub-server device 3), the server ID of the sub-execution server device 3 to be substituted is written in the above-mentioned database as the sub-server ID.

In the example of FIG. 9, the execution server device 3 that executes the high compression format conversion process and the folder distribution process is set to the execution server device 3 with the server ID of "002" by default, but the server ID of "002" is set. The execution server device 3 with the server ID (sub server ID) of "003" acts on behalf of the high compression format conversion process and the folder distribution process due to the congestion of the high compression format conversion process in the execution server device 3 of the above. This is an example selected as.

That is, in the case of the example of FIG. 9, the execution server device 3 having the server ID “001” is assigned to the image correction process and the conditional branch process. The time required for the image correction processing of the image data corresponding to one page in the execution server device 3 having the server ID "001" is 20 ms, and the time required for the conditional branch processing is 1 ms. Further, an execution server device 3 having a server ID of "002" is assigned to the format conversion process, the mail delivery process, the high compression format conversion process, and the folder delivery process. The time required for the format conversion process corresponding to one page in the execution server device 3 with the server ID "002" is 50 ms, the time required for the mail delivery process is 5 ms, the time required for the high compression format conversion process is 100 ms, and the folder distribution. The time required for processing is 10 ms. Further, for the high compression format conversion process and the folder distribution process, the execution server device 3 having the server ID "003" is assigned as a spare execution server device for executing the high compression format conversion process and the folder distribution process. There is.

A database of such allocation determination information may be created in advance by an administrator or the like and stored in the HDD 14 of the control server device 2. Alternatively, the flow processing function application instruction unit 36 of the control server device 2 acquires information indicating the executable processing and the processing time from each execution server device 3 at a predetermined timing, and processes as shown in FIG. It may be associated with each and stored in the storage unit as a database.

In addition, in the execution server device 3 of the server ID of "002" in which the high compression format conversion processing is set as the default, when it is no longer necessary to substitute the processing due to the elimination of congestion of the high compression format conversion processing or the like. The flow processing function deletion instruction unit 37 instructs the sub-execution server device 3 requesting the proxy processing to uninstall the application program of the proxy processing, and also instructs the sub-server of the database shown in FIG. 9 to uninstall. Delete the ID.

Next, in step S5 described above, when the execution server device 3 capable of executing each process of the workflow definition is detected, the flow processing status monitoring unit 35 of the control server device 2 sends the detected execution server device 3 to each of the detected execution server devices 3. In response to this, a notification request for the current data processing status is made. The flow processing status notification unit 22 of each execution server device 3 that has received the notification request transmits the processing status information indicating the current data processing status to the control server device 2 via the remote communication control unit 21 (step S6). ..

FIG. 10 is a diagram showing an example of processing status information acquired from each execution server device 3. As shown in FIG. 10, the execution server device 3 includes a server ID, a current data processing status (status), an area (location) where the execution server device 3 is provided, and a network where the execution server device 3 is provided. The environment (cloud or on-premises), the transmission speed of the execution server device 3, and the like are transmitted to the control server device 2 as processing status information.

The processing status information shown in FIG. 10 shows that the execution server device 3 with the server ID of 001 is a server device having a transmission speed of 50 MB / s provided on a cloud network in Japan, and serves as a server device for executing processing. It has been selected, but indicates that it is currently in an uncrowded "in use" situation. Further, in the processing status information shown in FIG. 10, the execution server device 3 of the server ID of 002 is a server device having a transmission speed of 10 MB / s provided on a cloud network in the United States of America, and is a server device that executes processing. It is selected as, indicating that it is currently in a "crowded" situation. Further, in the processing status information shown in FIG. 10, the execution server device 3 of the server ID of 003 is a server device having a transmission speed of 100 MB / s provided on the network of the on-premises environment in Japan, and executes the process. Indicates that the status is "unused", which is not selected as the server device to be used.

Further, each execution server device 3 includes the processing status information and transmits the breakdown information indicating the breakdown of the status for each process to the control server device 2. FIG. 11 shows the breakdown information of the execution server device 3 of the server ID of 002 shown in FIG. As described with reference to FIG. 10, the execution server device 3 with the server ID of 002 is currently in a “congested” state. The breakdown information shown in FIG. 11 shows the breakdown of "congestion" in each process executed by the execution server device 3 of the server ID of 002.

That is, in the execution server device 3 with the server ID of 002, the number of jobs waiting to be executed for the format conversion process is "5", which is a "normal" state that cannot be said to be congested, and the number of jobs waiting to be executed for the mail delivery process. Is "0", which is a "normal" state that is not congested, and the number of jobs waiting to be executed for folder distribution processing is "5", which means that it is a "normal" state that cannot be said to be congested. Shown. However, in the execution server device 3 of the server ID of 002, the number of jobs waiting to be executed for the high compression format conversion process is "100", indicating that the high compression format conversion process is the cause of the current "congestion". ing.

Next, in step S7 of the flowchart of FIG. 4, the flow processing status monitoring unit 35 determines the presence or absence of congested processing. When it is determined in step S7 that a congested process exists (step S7: Yes), the process proceeds to step S13, and when it is determined that there is no congested process (step S7: No). The process proceeds to step S8.

The example shown in FIG. 11 is an example in which the high compression format conversion process is currently congested in the main execution server device 3. In this case, the process proceeds to step S13. In step S13, the flow processing function application instruction unit 36 substitutes the main execution server device 3 for the high compression format conversion process based on the above-mentioned allocation determination information and the processing status information. To select.

That is, in the example of FIG. 10, processing congestion has occurred in the execution server device 3 having the server ID of "002", and the breakdown of this congestion is due to the high compression format conversion processing as shown in FIG. be. As a result of searching for the sub-execution server device 3 that substitutes for the high compression format conversion process, as shown in FIG. 10, the execution server device 3 having the server ID "003" is currently used as the "unused" execution server device 3. Suppose it is searched. In this case, the flow processing function application instruction unit 36 selects the execution server device 3 whose server ID is "003", which is "unused", as the sub-execution server device 3 that performs the high compression format conversion processing on behalf of the execution server device 3. Then, the flow processing function application instruction unit 36 instructs the sub-execution server device 3 to install the flow processing function (application program) for performing the high compression format conversion process (step S14).

Upon receiving the installation instruction, the flow processing function acquisition unit 26 of the sub-execution server device 3 downloads the application program corresponding to the instructed high compression format conversion process from the AP server device 5. Then, the flow processing function application unit 27 of the sub-execution server device 3 installs and processes the downloaded application program for high compression format conversion processing on the sub-execution server device 3. As a result, the high compression format conversion process can be performed on behalf of the sub-execution server device 3 having the server ID "003" instead of the main execution server device 3.

Here, in the case of the information processing system of the embodiment, as described with reference to FIG. 5, it is possible to set a "priority condition" for the workflow process. The flow processing function application instruction unit 36 is suitable when it is determined that it is preferable to substitute the processing other than the processing in which congestion occurs in order to satisfy the priority condition attached to the workflow processing. The execution server device 3 is selected, and the application program of the process to be substituted is installed.

Specifically, in the case of the workflow process shown in FIG. 7, "folder distribution process" is specified as the next process of the high compression format conversion process in which congestion occurs. When the priority condition of "processing speed priority" shown in FIG. 5 is attached to the workflow processing by the user, it is possible to contribute to the improvement of the processing speed by not transmitting and receiving data via the network 7 as much as possible. Therefore, when the flow processing function application instruction unit 36 gives an instruction to install the congested application program for the high compression format conversion processing on the execution server device 3 having the server ID of "003", the flow processing function application instruction unit 36 is instructed to install the application program. It also instructs the execution server device 3 whose server ID is "003" to install the application program for folder distribution processing. As a result, the sub-execution server device 3 can substitute the processing so as to satisfy the priority condition.

Next, in step S8 of the flowchart of FIG. 4, the execution flow definition generation unit 38 of the control server device 2 is each of the workflow processes based on the workflow definition stored and controlled in the storage unit by the flow definition holding control unit 31. Generates an "execution flow definition" that specifies the execution server device 3 that executes processing in processing units.

Specifically, in step S7, when processing congestion is not detected based on the processing status information indicating the current data processing status acquired from each execution server device 3 (step S7: No), the execution flow definition As shown in FIG. 9, the generation unit 38 uses the execution server device 3 designated by default for each process as the execution server device 3 that executes each process of a series of workflow processes specified by the user. Generates the specified execution flow definition.

That is, for example, as shown in FIG. 9, for the image correction processing and the conditional branching processing, the execution server device 3 of "001" is specified by default, respectively, and the format conversion processing, the mail delivery processing, and the high compression are performed. It is assumed that the execution server device 3 of "002" is specified by default for the conversion process and the folder distribution process, respectively. When the processing congestion is not detected based on the processing status information (step S7: No), the execution flow definition generation unit 38 performs the image correction processing and the conditional branching processing as shown in FIG. For each of the execution server devices 3 of "001", and for the format conversion process, the mail delivery process, the high compression conversion process, and the folder delivery process, the execution flow definition in which the execution server device 3 of "002" is specified is defined. Generate.

On the other hand, when the application program for the congested process is installed in the sub-execution server device 3 that substitutes for the congested process (step S13, step S14), the execution flow definition generation unit. 38 generates an execution flow definition in which the sub-execution server device 3 is designated as the execution server device 3 that executes the processing in which congestion occurs.

That is, in the examples of FIGS. 10 and 11, the execution server device 3 whose server ID is "003", which is currently "unused", is used as a sub-execution server that performs high-compression format conversion processing that is congested. This is an example selected as the device 3. In this case, as shown in FIG. 13, the execution flow definition generation unit 38 designates the execution server device 3 of "001" for the image correction processing and the conditional branching processing, respectively, and performs the format conversion processing and the mail delivery processing. For each, the execution server device 3 of "002" was specified, and for the high compression conversion process, the execution server device 3 having the server ID of "003", which is the sub-execution server device 3 described above, was designated. Generate an execution flow definition.

When the "priority condition" is set for the workflow process as described above, the execution flow definition generation unit 38 performs the process to be substituted and the execution server device 3 to be delegated so as to satisfy this priority condition. Select and control the installation of the specified flow processing function (application program).

The flow execution control unit 33 of the control server device 2 transmits the execution flow definition thus generated to the execution server device 3 that executes the processing of the execution flow definition. The execution flow definition holding control unit 24 of the execution server device 3 stores the execution flow definition received from the control server device 2 in a storage unit such as the HDD 14.

Next, the remote communication unit 34 of the control server device 2 transmits the job data (for example, the image data generated by scanning) received from the scanner device 1 to the execution server device 3 that executes the workflow process, and at the same time. Instruct the execution of the process (step S9). Further, the flow execution control unit 33 of the control server device 2 sends the job data to the execution server device 3 that executes the workflow process, and the network address of the execution server device 3 that is the transfer destination of the processed job data ( (IP address of another execution server device 3) is transmitted. Further, the flow execution control unit 33 of the control server device 2 provides information for specifying the last process such as the process name of the last process to the execution server device 3 to which the last process of the workflow process is assigned. Notify end data including information indicating that it is the last process.

In step S10, the flow processing execution unit 22 of the execution server device 3 performs the instructed processing on the job data. In step S11, whether or not the process executed by the flow execution control unit 33 of the control server device 2 based on the presence or absence of notification of the end data from the control server device 2 described above is the final process of the workflow process. To determine. When the end data from the control server device 2 is notified, the flow process execution unit 22 of the execution server device 3 determines that the executed process is the final process of the workflow process (step S11: Yes). In this case, the process proceeds to step S15.

On the other hand, when the end data from the control server device 2 is not notified, the flow processing execution unit 22 of the execution server device 3 determines that the executed process is not the final process of the workflow process (step S11). : No). In this case, the process proceeds to step S12. In step S12, the flow processing execution unit 22 of the execution server device 3 is next based on the presence or absence of the network address of the execution server device 3 which is the transfer destination of the processed job data received from the control server device 2. It is determined whether or not the process of is executed by another execution server device 3. When the flow processing execution unit 22 of the execution server device 3 determines that the next processing is to be executed by itself (step S12: No), the processing is returned to step S10, and the specified processing is subsequently executed. On the other hand, when it is determined that the next process is executed by another execution server device 3 (step S12: Yes), the process returns to step S9, and the remote communication control unit 21 of the execution server device 3 determines. The processed job data is transmitted from the control server device 2 to the execution server device 3 which is the transfer destination designated.

Such operations of steps S9 to S12 will be described with reference to specific examples. In the case of the example shown in FIG. 13, the image correction process, which is the first process, and the conditional branch process, which is the second process, are processed by the execution server device 3 whose server ID is "001" according to the above-mentioned execution flow definition. Assigned. Further, in the case of the example of FIG. 13, the format conversion process which is the third process and the mail delivery process which is the fourth process are processed by the execution server device 3 whose server ID is "002" according to the above-mentioned execution flow definition. Is assigned. Further, in the case of the example of FIG. 13, in the high compression format conversion process which is the fifth process and the folder distribution process which is the sixth process, the execution server device 3 whose server ID is "003" according to the above-mentioned execution flow definition. Processing is assigned to.

The format conversion process, which is a process after the conditional branching process executed by the execution server device 3 having the server ID "001", is executed by the execution server device 3 having the server ID "002". Therefore, the flow execution control unit 33 of the control server device 2 sends the job data after the conditional branch processing to the execution server device 3 having the server ID "001", and the execution server device 3 having the server ID "002". The network address of the execution server device 3 having the server ID "002" is notified to the execution server device 3 having the server ID "001" together with the instruction information to be transmitted to the server.

Similarly, the high compression format conversion process, which is a process after the mail delivery process executed by the execution server device 3 having the server ID "002", is executed by the execution server device 3 having the server ID "003". Therefore, the flow execution control unit 33 of the control server device 2 sends the job data after the mail delivery process to the execution server device 3 having the server ID "002", and the execution server device 3 having the server ID "003". The network address of the execution server device 3 having the server ID "003" is notified to the execution server device 3 having the server ID "002" together with the instruction information to be transmitted to the server.

Further, the folder distribution process executed by the execution server device 3 whose server ID is "003" is the final process of a series of workflow processes. Therefore, the flow execution control unit 33 of the control server device 2 notifies the execution server device 3 having the server ID “003” of the above-mentioned end data indicating that the folder distribution process is the final process.

In such a state, when the image correction process is executed by the execution server device 3 whose server ID is "001" in steps S9 and S10, the image correction process is executed again via steps S11 (No) and S12 (No). In step S10, the conditional branching process is executed by the execution server device 3 whose server ID is "001". Since the format conversion process after the conditional branching process is executed by the execution server device 3 having the server ID "002" (step S11: No, step S12: Yes), the execution server device 3 having the server ID "001" Sends the job data after the conditional branch processing to the execution server device 3 whose server ID is "002" (step S9).

The execution server device 3 having the server ID of "002" executes the format conversion process and the mail delivery process assigned to itself in steps S9 to S12, and outputs the job data after the mail delivery process to the server ID ". 003 ”is transmitted to the execution server device 3.

The execution server device 3 having the server ID of "003" executes the high compression format conversion process and the folder distribution process assigned to itself in steps S9 to S12. The control server device 2 notifies the execution server device 3 whose server ID is "003" by the above-mentioned end data that the final process of the series of workflow processes in this example is the folder distribution process. Therefore, when the folder distribution process, which is the final process of the workflow process, is completed, the remote communication control unit 21 of the execution server device 3 having the server ID “003” uses the job data after the folder distribution process, for example, as a client terminal. It is transmitted to a device specified by the user in advance, such as 6. As a result, the client terminal 6 can acquire the job data after the workflow processing of the example.

Next, when the final process of the series of workflow processes is completed, the process of the flowchart of FIG. 4 proceeds to step S16 via step S15. In step S16, the flow function deletion instruction unit 37 of the control server device 2 determines, for example, whether or not there is a sub-execution server device 3 on behalf of the processing in which congestion has occurred. In other words, in step S16, the flow function deletion instruction unit 37 determines whether or not there is a sub-execution server device 3 in which, for example, an application program for processing that is congested is installed. If the sub-execution server device 3 on which the predetermined application program is installed does not exist (step S16: No), all the processing of the flowchart of FIG. 4 ends.

On the other hand, when there is a sub-execution server device 3 in which an application program for processing that is congested is installed, such as the execution server device 3 whose server ID is "003" (step S16: Yes). The process proceeds to step S17.

In step S17, the flow processing status monitoring unit 35 receives processing status information indicating the current processing status of the execution server device 3 that is congested in the processing performed by the sub-execution server device 3 described above. Make a notification request. That is, in the case of the above example, since the high compression format conversion process of the execution server device 3 having the server ID "002" is congested, the high compression format conversion process is performed on the execution server device 3 having the server ID "003". I let you act on your behalf. Therefore, the flow processing status monitoring unit 35 of the control server device 2 requests the execution server device 3 whose server ID is "002" to notify the processing status information indicating the current processing status. The flow processing status notification unit 23 of the execution server device 3 having the server ID “002” transmits the processing status information indicating the current processing status of the own machine to the control server device 2.

The flow processing status monitoring unit 35 of the control server device 2 performs processing corresponding to the application program installed in the sub-execution server device 3 based on the processing status information received from the sub-execution server device 3. It is determined whether or not it is no longer necessary to substitute for the server (step S17). That is, in the above example, the flow processing status monitoring unit 35 of the control server device 2 determines whether or not the congestion of the high compression format conversion process of the execution server device 3 whose server ID is "002" has been resolved by the server ID. Determines based on the processing status information received from the execution server device 3 of "002".

The flow processing status monitoring unit 35 determines that the congestion of the high compression format conversion processing of the execution server device 3 whose server ID is "002" has not been resolved, and that the sub-execution server device 3 needs to continue the proxy processing. If this is done (step S17: Yes), all the processing of the flowchart of FIG. 4 is completed, and the proxy processing is continued.

On the other hand, when the flow processing status monitoring unit 35 determines that it is not necessary for the sub-execution server device 3 to substitute the processing corresponding to the application program installed in the sub-execution server device 3 (step S17: No), the process proceeds to step S18. That is, as described in the above example, when the flow processing status monitoring unit 35 determines that the congestion of the high compression format conversion processing in the execution server device 3 having the server ID “002” has been eliminated based on the processing status information. , The process proceeds to step S18.

In step S18, the flow processing function deletion instruction unit 37 of the control server device 2 instructs the sub-execution server device 3 to delete the application program installed to act for the processing of the other execution server device 3. The entire process of the flowchart of FIG. 4 is completed. That is, in the case of the above example, the flow processing function deletion instruction unit 37 of the control server device 2 is higher than the execution server device 3 whose server ID is "002" with respect to the execution server device 3 whose server ID is "003". Instructs to delete the application program installed to act for the compression format conversion process. When the flow processing function deletion unit 28 of the execution server device 3 having the server ID "003" receives the deletion instruction from the control server device 2, the application program for high compression format conversion processing stored in the storage unit such as the HDD 14 or the like. To delete. As a result, the processing function of the workflow processing that is no longer needed can be deleted from the sub-execution server device 3, and the sub-execution server device 3 can be released.

(Effect of embodiment)
As is clear from the above description, in the information processing system of the embodiment, in the execution server device 3 that performs a series of workflow processes, for example, when a problem such as congestion occurs in a part (or all) of the processes. In addition, the sub-execution server device 3 temporarily substitutes for the processing in which this problem occurs. Alternatively, when a network environment (on-premises environment, cloud environment, etc.) for executing some (or all) processing is specified by the user or the like, the sub-server device 3 on the specified network environment is temporarily used. Let the process act on your behalf. As a result, the workflow process can be executed while changing the execution server device 3 that performs each process in the "substitute configuration of the process unit" in which a part of the process is delegated by another device. Therefore, it is possible to efficiently perform workflow processing according to the user's wishes.

Further, the application program of the proxy processing is deleted from the proxy sub-execution server device 3 after the processing is completed. As a result, the sub-execution server device 3 on behalf of the processing can be released, so that the network resources can be effectively utilized.

Finally, the embodiments described above are presented as an example and are not intended to limit the scope of the invention. This novel embodiment can be implemented in various other embodiments. In addition, various omissions, replacements, and changes to the embodiments can be made without departing from the gist of the invention.

The CPU 11 described above includes a processor programmed to execute each function by software, an ASIC (Application Specific Integrated Circuit), an IC (Integrated Circuit), a circuit module, etc. designed to execute each function. Hardware shall be included.

Further, the above-described embodiment is carried out by an ASIC (Application Specific Integrated Circuits) and a device configured by connecting conventional circuit modules if the engineer has ordinary knowledge in the information processing technology field. Is possible.

In addition, each of the functions described in the above-described embodiment can be realized by one or a plurality of processing circuits (Circuit), respectively. The "processing circuit" includes hardware such as a processor programmed to execute each function by software, an ASIC designed to execute each function, and a circuit module.

Such embodiments and modifications of the embodiments are included in the scope and gist of the invention, and are included in the invention described in the claims and the equivalent scope thereof.

1 Scanner device 2 Control server device 3 Execution server device 4 Management server device 5 Application program server device (AP server device)
6 Client terminal 11 CPU
12 ROM
13 RAM
14 HDD
15 Operation unit 16 Communication unit 17 Bus line 21 Remote communication control unit 22 Flow processing execution unit 23 Flow processing status notification unit 24 Execution flow definition holding control unit 25 Flow processing function management unit 26 Flow processing function acquisition unit 27 Flow processing function application unit 28 Flow processing function deletion unit 31 Flow definition retention control unit 32 Application information retention control unit 33 Flow execution control unit 34 Remote communication unit 35 Flow processing status monitoring unit 36 Flow processing function application instruction unit 37 Flow processing function deletion instruction unit 38 Execution flow Definition generation unit 41 Flow processing function providing unit 42 Remote communication unit 45 Remote communication unit 46 Flow definition generation unit 47 Input reception unit 48 Display unit 49 Remote communication unit 50 Display control unit 51 Scanner application program (scanner application)
52 Control unit 53 Scanner engine 54 Remote communication unit 55 Display control unit 56 Input control unit 57 Operation panel 58 Display unit 59 Operation unit

Japanese Unexamined Patent Publication No. 2010-268604

Claims (7)

A processing status detection unit that detects the information processing status of a plurality of execution devices that perform predetermined information processing on the information to be processed, and
An execution flow generation unit that generates an execution flow definition in which processes to be executed for each execution device are assigned to each processing unit based on a workflow definition indicating the processing to be performed on the processing information and the order of the processing.
Among the processes assigned to each execution device in the execution flow definition, the migration target process, which is a process to be executed by another execution device, and the other execution device, which executes the migration target process , are An installation control unit that detects based on the information processing status and controls the installation of an application program for executing the migration target process on the other execution device that has been detected.
A change control unit that changes and controls the execution flow generation unit so as to generate the execution flow definition in which the execution device that executes the migration target process is changed to the other execution device whose application program is installed and controlled. ,
A processing control unit that transmits the execution flow definition generated by the execution flow generation unit to the execution device specified by the execution flow definition and controls the processing of the processed information in the processing order of the execution flow definition. Have,
The workflow definition includes priority condition information indicating priority matters.
When the installation control unit performs installation control on the detected other execution device, the installation control unit controls the installation of different application programs for executing the migration target process on the other execution device based on the priority condition information. the information processing apparatus according to claim <br/> that. After completion of a series of workflow processing based on the execution flow definition, the installed in other execution device, to have a uninstallation unit which uninstalls processing an application program for executing the migration target process The information processing apparatus according to claim 1. The installation control unit to the other execution devices on the specified network environment in claim 1 or claim 2, characterized in that the installation control an application program for executing the migration target process The information processing device described. A workflow definition generation device that generates a workflow definition indicating the processing to be performed on the information to be processed and the order of the processing, and
A plurality of execution devices that perform predetermined processing on the information to be processed, and
An information processing system including the information processing device according to any one of claims 1 to 3. Computer,
A processing status detection unit that detects the information processing status of a plurality of execution devices that perform predetermined information processing on the information to be processed, and
An execution flow generation unit that generates an execution flow definition in which processes to be executed for each execution device are assigned to each processing unit based on a workflow definition indicating the processing to be performed on the processing information and the order of the processing.
Among the processes assigned to each execution device in the execution flow definition, the migration target process, which is a process to be executed by another execution device, and the other execution device, which executes the migration target process , are An installation control unit that detects based on the information processing status and controls the installation of an application program for executing the migration target process on the other execution device that has been detected.
A change control unit that changes and controls the execution flow generation unit so as to generate the execution flow definition in which the execution device that executes the migration target process is changed to the other execution device whose application program is installed and controlled. ,
The execution flow generator the execution flow definition generated by unit, and transmitted to the execution device designated by the execution flow definition, a processing control unit for controlling the processing of the object to be processed information to the processing order of the execution flow definition Have,
The workflow definition includes priority condition information indicating priority matters.
When the installation control unit performs installation control on the detected other execution device, the installation control unit controls the installation of different application programs for executing the migration target process on the other execution device based on the priority condition information. the information processing program characterized <br/> that. The computer
After completion of a series of workflow processing based on the execution flow definition, the installed in other execution device, an application program for executing the migration target process for uninstallation processing unit for uninstall process, to further features The information processing program according to claim 5 , wherein the information processing program is characterized by the above. The fifth or sixth aspect of the present invention, wherein the installation control unit installs and controls an application program for executing the migration target process on the other execution device on the designated network environment. The information processing program described.

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