JPS58163052A - Fault processing system for decentralized data base system - Google Patents

Abstract

PURPOSE:To improve the operation processing speed of a decentralized data base system, by matching a replacement state between nodes at restarting time when a fault, etc. are recovered by a recording means provided separately from a data base history information recording means. CONSTITUTION:A node 1-i consists of a data base 2-i, a history information recorder 3-i, a telegram processing part 4-i, a decentralized processing part 5-i, a data base processing part 6-i and a stack processing part 7-i incorporating stacks like a semiconductor memory, etc. A node 1-j has the same constitution as the node 1-i. For the data base matching process in a restart mode to a fault of the node 1-j, the information of a history information recorder 3-j is read out by a data base processing part 6-j when the fault of the node 1-j is recovered. Then the unfinished data base process is informed to the part 5-i, and the recorder 3-j receives the end information of the corresponding data base process from the part 5-i.

Description

DETAILED DESCRIPTION OF THE INVENTION The present invention provides a distributed database system that can perform high-speed and easy consistency processing between nodes when restarting when a failure occurs in a communication path or a node. The present invention relates to a failure handling method.

FIG. 1 shows a block diagram implementing a conventional failure handling method for a distributed database system. In FIG. 1, l-i and 1-'' are nodes, which are connected by a communication path. The node l-i includes a database 2-1, a history information recording device 3-i, an 'i4 statement processing section 4-i, and a distributed processing section 5.
-i, database processing unit (composed of 1-i, etc.).

The configuration of node 1-J is also similar. In the distributed database system shown in Figure 1, an overview of the process of acquiring essential information to the history information recording device when restarting the distributed database and the matching process when restarting is distributed in the message processing at node l-i. A case where processing becomes necessary will be explained with reference to FIG.

In FIG. 2, when the message processing unit 4-■ of node l-i issues a database start command, the distributed processing unit 5-i sends a start processing command to the database processing units 6-j of node ]-J, and starts processing automatically. The database processing unit 6-1 acquires run start information from the history information recording device 3-1 of node ]-1.

When the message processing unit 4-1 of the node 1-i issues a database normal termination command, the distributed processing unit 5 to summer are transferred to the node ■-
The update guarantee processing command is sent to the database processing unit 6-j of node j, and the response from the database processing unit 6-j is acquired in the history information recording device 3-1 of the own node 1-1. Next, the distributed processing unit 5-1 sends a termination processing command to the database processing unit 6-j of the node ■-J based on the above processing result, and sends the response from the database processing unit 6- to its own node l-i. The history information recording device 3-1 acquires the information. Further, when the message processing unit 4-i of the node 1-i issues a database abnormal termination command, the distributed processing unit 5-1 sends a termination processing command to the database processing unit 6- of the node l-j, and the database processing The response from node 6-j is acquired by own node 1-summer history information recording device 3-i.

On the other hand, in node l-j, based on the command sent from distributed processing unit 5-i of node 1-i, database processing unit 6-j converts information on start processing, update guarantee processing, and termination processing into own history information. The data is acquired by the recording device 3-j, and each processing result is sent to the distributed processing unit 5-i of the node l-i.

In this way, if a failure occurs in the processor or the communication path, database matching processing is performed based on the information acquired by the history information recording devices 3-i and 8-j of nodes l-i and 1-J through the above processing. . In this database matching process, node 1-! .

1-J history information recording device 3-1.8-j reading,
Information is transferred from the failed node to the normal node, and processing is performed to match the database of the failed node with the database of the normal node based on the information of the normal node.

By the way, in the above-mentioned conventional fault handling method of the distributed database system, each node needs to acquire information to the history information recording device three times, which has the disadvantage that it takes time to process a message during normal operation. Furthermore, in the matching process between nodes when restarting, even a normal node takes time to read information from the history information recording device, which slows down the matching process and interferes with the history information writing process of other message processing. There was a drawback.

In view of the above-mentioned drawbacks of the conventional method, an object of the present invention is to reduce the number of times history information is acquired to a history information recording device in a distributed database system, and to speed up and easily perform database matching processing when restarting. The objective is to provide a fault handling method that

Therefore, the present invention provides a database system in a distributed database system in which a group of nodes each having an independent database and its processor are connected by a communication path, and message processing by one node requires processing by the databases of multiple nodes. In addition to the means for recording history information of start, update, and end processing, means for separately recording history information of start and end processing is provided, and at the time of restart, the update status between nodes is recorded by this separately provided recording means. It is characterized by consistency. A detailed explanation will be given below with reference to the drawings.

FIG. 3 shows an embodiment of a failure handling method for a distributed database system to which the present invention is applied. In the case of FIG. 3, node 1-! are database 2-1, history information recording device 3-
In addition to a message processing section 4-i, a distributed processing section 5-i, and a database processing section 6-i, the stack processing section 7-1 has a built-in stack such as a semiconductor memory. The configuration of node 1-J is also similar. The operation when distributed processing becomes necessary in message processing at node l-i will be described below with reference to FIGS. 4 to 6.

FIG. 4 is a diagram illustrating the operation of the history information acquisition process in FIG. 3. When the message processing unit 4-1 of node l-i issues a database start command, the distributed processing unit 5-i sends start information to the stack processing unit 7-i. When the stack processing unit 7-i receives the start information, it picks up the oldest information in its own stack and stacks the start information. Next, a start processing command is sent to the database processing unit 6-j of the distributed processing unit 5-iid node i-j. Then node l
When the message processing unit 4-i of -i issues a database termination command, the distributed processing unit 5-natsu performs the following processing.

If the database termination command is a normal termination request, it sends an update guarantee processing command to the database processing unit 6-1 of node l-J and waits for the processing result. As a result, if all responses are normal, normal completion information is acquired in the history information recording device 3-1, and the same information is sent to the stack processing section 7-i to stack the information. Then node l
-J sends a normal termination processing command to the database processing unit 6-j, and when the result is received, the message processing unit 4-1
The process returns a normal completion response to . On the other hand, if the database termination command is an abnormal termination request, or if one of the results is an abnormal response to the sending of the update guarantee processing instruction to node 1-J, the abnormal termination information is stored in the history information. The same information is acquired by the recording device 8-1 and sent to the stack processing unit 7-1, so that the information is stacked. Then, it sends an abnormal termination processing command to the database processing unit 6-j of the node 1-J, and when the result is received, an abnormal termination response is returned to the message processing unit 4-Natsu, and the process ends.

In contrast to the above processing on the node l-i side, at node ■-J,
Based on the command from the distributed processing unit 5-i of node l-i,
The following processing is performed in response to the case where the instruction is a start processing instruction, an update guarantee processing instruction, (7) a normal termination processing instruction, or an abnormal termination processing instruction.

If the command from the node 1-summer distributed processing unit 5-i is a start processing command, the database processing unit 6-'' sends start information to the stack processing unit q-J, and in response, the stack processing unit q -J discards the oldest information in its own stack and stacks the start information. Thereafter, the database processing unit 6-j returns the processing result to the distributed processing unit 5-i of node l-i. Next, in the case of an update guarantee processing command, the database processing units 6-, i(d) store the database update information and all the information stacked in the stack processing unit q-J in the history information recording device s-J as update guarantee processing. and node 1-
The processing result is returned to the distributed processing unit 5-i of No.1. Next, in the case of a normal termination processing instruction, the database processing unit 6-j transfers the normal termination information to the stack processing unit 7 as part of the normal termination processing.
-j, and the stack processing unit 7-jH stacks the information. After that, the database processing unit 6-J
The processing result is returned to the distributed processing unit 5-i of No.1.

The command sent from the distributed processing unit 5-i of the node 1-1 (
8) If the command is an abnormal termination processing command, the database processing unit 6-j performs processing before and after update guarantee processing as follows. That is, before the update guarantee process, the database processing unit 6-'' sends the abnormal termination information and all information stacked in the stack processing unit 7-'' to the history information acquisition device 3-'' as part of the abnormal termination process. Get node l-
The processing result is returned to the distributed processing unit 5-i of i. On the other hand, if the update guarantee processing is not yet performed, the database processing section 6-'' sends the abnormal termination information to the stack processing section q-J as part of the abnormal termination processing, and the stack processing section 7-J stacks the information. .

Thereafter, the database processing unit 6-J returns the processing result to the distributed processing unit 5-1 of the node 1-1.

FIG. 5 is a diagram illustrating the operation of database matching processing at the time of restarting in response to a failure of node -j in FIG. 3. When the failure of the node 1- is recovered, the database processing unit 6-j reads out the information in the history information recording device 8-j acquired by the history information acquisition process described in FIG. 4 above. Next, when the database processing unit 6-j finds unfinished database processing from the information, it notifies the distributed processing unit 5-i of the node 1-1 of the unfinished database processing. In response to the notification, the distributed processing unit 5-1 of the node l-i sends the completion information of the corresponding database process to the stack processing unit 7-i.
The database processing unit 6 of node 1-J
−Notify j. The database processing unit 6-j acquires the notification information from the distributed processing unit 5-i of the node 1-1 into the history information recording device 8-J. Thereafter, the same process is repeated until there are no incomplete database processes, and the database processing unit 6-j restores the database 2-J by the conventional restoration process based on the information from the history information recording device 3-J.

FIG. 6 11'lj is a diagram illustrating the operation of database matching processing at the time of restart in response to a failure of node l-i in FIG. 3.

When the failure of node l-i is recovered, the distributed processing unit 5-Sumi reads the information of the history information recording device 3-i acquired by the above-mentioned history information acquisition process, and finds the last recorded end information. Next, the distributed processing unit 5-i transmits the termination information to node 1.
-J's database processing unit 6-J. When the database processing unit 6-J determines that the corresponding database processing is incomplete based on the termination information and the information from the stack processing unit 7-J, the database processing unit 6-J executes the termination processing indicated in the history information acquisition process based on the termination information. I do. Even after the termination process, node 1-”
If there is an incomplete database process, the database processing unit 6-'' performs an abnormal termination process as indicated in the history information acquisition process.

As is clear from the above explanation, the present invention reduces the number of times database start, update, and end information is acquired to the history information recording device to one time in each node compared to the conventional method, and also stacks data in the stack processing unit. Since the database matching process at the time of restart is performed quickly and easily based on the database start and end information that has been updated, there is an advantage that the operational processing speed of the distributed database system is improved.

[Brief explanation of the drawing]

FIG. 1 is a block diagram for implementing a failure handling method of a conventional distributed database system, FIG. 2 is a diagram for explaining the history information acquisition process of FIG. 1, and FIG. 3 is an implementation of the failure handling method of the present invention. FIG. 4 is a block diagram of an example, and FIG. 4 is a diagram for explaining the history information acquisition process in FIG. 3, and FIGS. 5 and 6 are diagrams for explaining the database matching process in FIG. 8. ■... Node, 2... Database, 3... History information recording device, 4... Message processing unit, 5... Distributed processing unit, 6... Database processing unit, 7... Stack processing section.

Claims (1)

[Claims] (1) Database start, update, and termination processing in a distributed database system in which a group of nodes each having an independent database and its processor are connected by a communication path, and message processing of one node requires processing of databases of multiple nodes. In addition to the means for recording history information, the node is further provided with means for separately recording history information of start and end processing, and when restarting due to failure recovery, etc., the separately provided recording means records updated status between nodes. A failure handling method for a distributed database system characterized by consistency.