JPH01276229A - Management processing system for respective generation data - Google Patents

Abstract

PURPOSE:To present data at a high speed by dividing the referring of generation data and the reflection processing of real restoration data or change data. CONSTITUTION:A generation management difference information data base 19 is prepared to a user information storage area 18, and the data to be added, changed and deleted in respective generations are stored as difference information between an old generation and a new generation into it. A man machine interface part 13 displays the information necessary for a generation management related to the input of the change data or the input of a restoration generation immediately by referring to the user information storage area 18. A difference transmission processing part 15 reads the instructed difference information from the user information storage area 18 by a request from a data using component 16 and executes the processing of the transmission to the data using component 16. In such a way, since the referring processing and the real restoration processing are divided, a high-speed referring function can be offered.

Description

[Detailed description of the invention]

[1 already required] Regarding the management processing method for each generation data that manages two generations of data using differential information in a computer system that has a processing function to manage generations of data used by programs. The purpose is to provide a means to efficiently manage generation data and to speed up referencing of restored generations. A user information storage area that stores data added, changed, and deleted in each generation as difference information between the old and new generations, and 2.
Notify the specified change trigger or restore trigger to the man-machine interface unit that refers to the user information storage area and immediately displays the information necessary for generation management, and to the components that use the data related to the change or restore. with the management department. and a difference transmission processing section that extracts and transmits difference information from the user information storage area in response to a request from a component that uses data. [Industrial Application Field] The present invention relates to a computer system having a processing function for generation management of data used by a program. This invention relates to a management processing method for each generation data that manages generation data using differential information. [Prior Art] Data such as system generation parameters are managed for five generations. For operational reasons,
This is because it may be necessary to restore the operating environment of the system to a state several generations ago. Generally, two primary methods are used for data generation management. t81 A method of recording all information for each generation. Every time data has a generation, all information for each generation is displayed. Store it in a file, etc. and manage it. This method has the advantage that each generation data can be easily referenced, and restoration to the designated generation can be realized at high speed simply by translating the designated generation into 'XYS'. However, since the same data is duplicated every two generations for data that has not been changed, the storage space tends to be compressed. fbl A method for managing differences. One generation is formed by accumulating the difference between the old generation and the current generation (change data) when data is changed, and the trigger of the change, and one restoration is possible. Therefore. In order to restore data to the previous generation, it is necessary to perform the process in reverse order from when the data was actually changed, and if there is a large amount of changed data, there is a problem in that it takes a corresponding amount of time to restore. [Problem to be solved by the invention] As described above, conventionally, if all the information for each two generations was recorded independently, the storage space would be compressed. There was a problem in that the man-machine interface was poor because it took time to restore to the previous generation. SUMMARY OF THE INVENTION An object of the present invention is to solve the above-mentioned problems and to provide a means for efficiently managing two-generation data and speeding up reference to two restored generations. [Means for Solving the Problems] FIG. 1 shows a configuration example of the present invention. In FIG. 1, 10 is a processing 'At' consisting of a CPU and memory, 11 is a display, and 12 is a keyboard for inputting various data and instructions. Reference numeral 13 denotes a man-machine interface section that controls input/output with the display 11 and keyboard 12. 14 is a management unit that manages change/restoration triggers; 15 is a difference transmission processing unit that notifies the requester of difference information regarding generation data; 16 is a data usage component such as a user program or system component that uses the data;
7 is a control table used by each data usage component 16 when executing a program; 1st is a user information storage area in which generation data is stored; 19 is a generation management difference information data storage area that has generation data as difference information; 20 is a program and Represents various libraries that have data load modules, etc. A generation management difference information database 19 is created in the user information storage area 18, and data added, changed, or deleted in each generation is stored in this as difference information between the old generation and the new generation. The man-machine interface unit 13 refers to the user information storage area 18 and immediately displays information necessary for one-generation management in connection with input of change data or input of a restored generation. At this time, the search language for the first generation management difference information database 19 can be used. If there is an instruction for a change trigger or a restore trigger, the man-machine interface unit 1:H:t notifies the management unit 14 of the trigger. The management unit 14 monitors for one hour and notifies the data usage component 16 of the change or restoration when the notified change or restoration occurs. The data usage component 16 is a program that uses data in the control table 17 or various libraries 20, and upon receiving an instruction to change or restore the data, the data usage component 16 sends the data necessary for the change or restoration to the difference transmission processing unit 15. Inquire. The difference transmission processing unit 15 is a data usage component 16
In response to a request from the user information storage area 18, the specified difference information is read out from the data usage component 1.
6. Execute the process to be transmitted to 6. [Operation] Processing for inputting change data is as follows. (1) The user uses the man-machine interface section 13
By talking to the user, select input from the menu, and input the change data and change trigger. (2) The user information storage area 18 is provided with a generation management difference information data base 19 of a racial data base type, for example, and the man-machine interface unit 13 receives change data when it is input. Record it as a cupule with generation. (3) The changed data is transferred to the difference transmission processing unit 1 based on the specified change trigger, asynchronously with the input of the changed data.
5, the data usage component 16 is notified. The process for restoring generations is as follows. (1) The user uses the man-machine interface section 13
2 Select the reference menu and input the restoration generation. (2) The man-machine interface unit 13 searches the three-generation management difference information database 19 for generation data specified by the user and displays the search result. (3) In response to this display, the user instructs whether or not to enable the restored data and, if so, the trigger for restoration. (4) The restoration trigger is notified and managed by the management unit 14, and when the trigger occurs, a restoration instruction is given to the data usage component 16, and the data usage component 16 is instructed to restore the data usage component 16 via the difference transmission processing unit 15. Difference information for restoration is transmitted. As described above, since the reference processing and the actual restoration processing are separated, the man-machine interface unit 13 can provide the user with the same high-speed reference function for any generation. . Also, to manage the 1st generation data using differential information. The amount of data stored regarding generations can be minimized. Since the actual reflection is performed at a designated moment, the user does not need to be aware of the time required for restoration. [Example] In this example, five generations of data are managed using a relational data structure. First, according to the specific example, 3
Explain generation updates. [About generation update] The storage mechanism when data is added/changed/deleted is as follows. (1) Assume that the disk heath is currently configured as follows in the 1.1 generation state.

[1.1 generation data] (2) Next, in the 1.2 generation, data 1-“C” is changed to “X”
If you change it to , the above table will be . It will look like this:

[1.2 generation data] (3) Next, in the 1.3 generation, data l-“Y”. When data 2="10" is added,
It will look like this:

[1.3 generation data] (4) Next, in the 11.4 generation, data 1-“Y”. If the data with data 2="10" is deleted, the result will be as follows.

[1.4-generation data] Storage using the above mechanism is based on differential management, and it can be said that 9-generation management is managed with the minimum amount of data necessary for 5 generations. The data hese reference logic when referring to the 1st generation from the information in the 1.4th generation will be explained first. An existing data search language can be used as a search language. [Regarding generation references] (1) When acquiring the latest information When a user wants to refer to information that is valid in the latest generations (1st and 4th generations), a search is performed using the following primary conditions. -Condition Valid end generation = NIJLL This extracts the primary valid data and displays it twice.

[1.4 generation valid data] +211.If you want to restore to the 3rd generation If you want to restore to the 1st and 3rd generations, check out the data created in the 1.4th generation by specifying the following. , it is possible to refer to it. Condition: Valid start generation ≦1.3 AND (Valid end generation > 1.3 OR Valid end generation = NULL)

[1.3 generation valid data] Also, what is the difference when 5 is restored? Rumor Condition Valid starting generation -1,3

[1.3 generation difference data] can be obtained, so if there is a restoration request. The difference transmission processing unit can asynchronously transmit the difference data for restoration to a component that uses the difference data when requested. The same process can be used to transmit the difference to the 1.2 generation/1.1 generation and restore the data. As you can see from the above example, by one conditional statement. All the information necessary for managing the latest generation to the second generation can be searched instantly. As a result, from the user information storage area 18 shown in FIG.
All data of the specified generation, the difference transmission processing unit 15, changes/
Difference data at the time of restoration. It is possible to acquire different information, and asynchronous processing between the man-machine interface section 13 and the differential transmission processing section 15 can be realized. FIG. 2 shows an example of generation restoration processing according to an embodiment of the present invention. Below, according to the process shown in Figure 2, 1
The flow of processing during generation restoration will be explained. Note that the process for inputting change data is also similar. 1 when restoring
While each generation moves in a negative direction, it can be considered that five generations move in a positive direction at the time of change. ■ When the man-machine interface unit 13 is instructed to restore one generation from a menu or the like. Identifier X of the generation to be restored and reflection contract J indicating when to restore
Enter RY. (2) By inputting the identifier X and the reflection trigger Y, the generation data corresponding to the identifier X is extracted and acquired from the user information storage area by using a data search language or the like. ■ Edit the extracted restored data and immediately display it on the display screen and present it to the user. (2) Notify the management unit 14 of the reflection trigger Y, etc., and terminate the processing of the man-machine interface unit 13. (2) The W management department 14 stores the reflection trigger Y notified from the man-machine interface section 13 and monitors it for two hours. ■ Check whether or not the reflection trigger has become Y. If the reflection trigger has become Y, execute the first process (■). ■ Notify the generation identifier X to the data usage component 16 that uses the data to be restored. (2) The data usage component 16 requests the data of the generation identifier X from the difference transmission processing unit 15. (2) The difference transmission processing unit 15 determines whether the request is for restored data or changed data. That is 3
Determine whether generation identifier X is specified. If generation identifier [Phase] The data corresponding to the generation identifier X, its size, data type, etc. are extracted from the user information storage area and transmitted to the requesting data usage component 16. ■ If generation identifier X is not specified, other processing such as notification of changed data is executed. (2) When the data usage component 16 receives the restored data corresponding to the first generation identifier X, it acquires and analyzes the change table name etc. that should reflect it. 0 Determine whether there are any tables to restore. When processing for all target tables is completed, move to processing [phase]. ■ Data usage component 16 for each target table.
Find the identifier of the data record that has. It is compared with the identifier of the record transmitted from the difference transmission processing unit 15. ■ Determine whether the record identifiers match, and if they do not match, skip the secondary processing [phase]. [Phase] Replace the data record with the record transmitted from the difference transmission processing unit 15 and restore it to the previous generation. ■ Determine whether or not the record has finished; if it has finished, go to process 0; if it has not finished yet. Transfer control to processing ■. [Phase] When processing for all target data is completed, processing for changing the operating environment of each data usage component 16 is performed. That is, processes such as synchronization with the currently executing task and reflection on the memory are executed as necessary, and the restoration process is ended. [Effects of the Invention] As explained above, according to the present invention, the reference to the two-generation data and the process of reflecting the actual restored data or changed data are divided, so that the user is not informed about which generation. Similarly, data can be presented at high speed. Furthermore, since the first generation data is managed using differential information, the amount of data stored regarding the first generation can be reduced. The user only needs to specify the reflection trigger, and there is no need to know the time required for restoration.

[Brief explanation of the drawing]

FIG. 1 shows a configuration example of the present invention. FIG. 2 shows an example of generation restoration processing according to an embodiment of the present invention. In the figure, 10 is a processing device, and 11 is a display. 12 is a keyboard, 13 is a man-machine ink face section, 14 is a management section, and 15 is a differential transmission processing section. Reference numeral 16 represents a data usage component, 17 a control table, 18 a user information storage area, 19 a generation management difference information data storage area, and 20 various libraries.

Claims (1)

[Claims] In a computer system that has a processing function to manage generations of data used by a program, additions, changes, and
A user information storage area (18) that stores deleted data as differential information between the old generation and the new generation; a man-machine interface unit (13) that refers to the information storage area and immediately displays it; a management unit (14) that notifies a specified change trigger or restore trigger to a component that uses data related to the change or restore; A management processing method for each generation of data, comprising: a difference transmission processing unit (15) that extracts and transmits difference information from the user information storage area in response to a request from a component that uses the data.