JPH09305558A - Data base server for duplex system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To unnecessitate the usage of a cross call disk and the synchronization or transmission of transaction data, for example, for the data base system of a duplex system. SOLUTION: System monitor processes 1-6 and 2-6 of an active server device 1 and a stand-by system server device 2 perform the monitor of the counter server system 1 or 2 by communicating each other. When the system monitor process 2-6 of the stand-by system server device 2 detects any abnormality at the active system server device 1, operating system update data reflection process 2-4 is stopped and a job application 2-3 is turned into active state so that its own system is switched to an active system.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a database server of a duplex system, and more particularly to a database server of a duplex system of a line center system in a broadcasting station.

[0002]

2. Description of the Related Art Conventionally, for example, Japanese Patent Laid-Open No. 7-18 shown in FIG.
In the network system including a plurality of server devices 1 and 2 described in Japanese Patent No. 2297, which communicate with each other and execute processing of the same information on the same network 4, the server device 1 having the network operation right is currently used. The server device is used, and the other server device 2 is used as the standby system server device 2. When the standby server device 2 detects an abnormality in the active server device 1, the backup server device 2 acquires the network operation right and takes over the processing being executed until then.

In this case, only the active server device 1 has the network operating right, and the clients 3-1 to n send and receive processing information, for example, only transaction processing information, and the active server device 1 Performs process control for network resources based on network operating rights. At this time, the standby system server device 2 communicates with the active system server device 1 and always possesses the same process processing information, but since it does not have the network operation right, it does not execute the process processing using network resources. .

The standby system server device 2 also requests the active system server device 1 for operating status information at any time and waits for a response. When there is no response regarding the operating status information, or when the operating status information is incomplete, it is judged as abnormal and the network operation right is taken over, and, for example, transaction processing that the active server device 1 was executing until the abnormality was detected continues Run.

At this time, when there are a plurality of spare server devices 2 and the priorities are set, the server device with the second priority takes over the network operation right and becomes a new active server device. As a result, from the client's point of view, for example, transaction processing can be continuously executed without any trouble, and the situation of network operation interruption can be avoided.

However, the standby server device 2 requests the operating status information from the active server device 1, and the active server device 1
In the mode in which the operating state of the active server device 1 is monitored based on the operating state information from, there is a disadvantage that there is no means for detecting an abnormality in the standby server device 2.

Further, for synchronization of transaction data between the active server device 1 and the standby server device 2, for example,
In the mode in which data is transmitted from the active server device 1 to the standby server device 2, the active server device 1 needs to perform transaction processing of the system, for example, and at the same time transmit transaction data to the standby server device 2, for example. Therefore, the load on the active server device 1 increases.

Further, in order to complete the synchronization of transaction data between the active server device 1 and the standby server device 2, for example, the active server device 1 sends the backup server device 2 to the standby server device 2, for example. It is necessary to monitor the completion of transaction data reflection processing. Therefore, for example, the transaction processing becomes complicated, and the response of the transaction processing also deteriorates.

One of the methods for solving the above problems is to use the cross-call disk 5 shown in FIG. In FIG. 5, a cross call disk (including a cross call disk device or a cross call disk array device, hereinafter referred to as a cross call disk) 5 is provided between the active server device 1 and the standby server device 2, for example, The business data such as transaction processing is stored in the cross-call disk 5 and shared by the active server device 1 and the standby server device 2.

When the standby server device 2 takes over transaction processing from the active server device 1, for example, the business data stored in the cross-call disk 5 can be read out and the processing can be immediately continued.
It is not necessary to consider, for example, the synchronization of transaction data between the backup server device 2 and the standby system server device 2, and therefore it is not necessary to transmit, for example, transaction data from the active server device 1 to the standby server device 2.

In FIG. 5, 1-1 and 1-2 are magnetic disk devices, 1-2 and 2-2 are database engines, 1-3 and 2-3 are business applications, and 1-6 and 1-6.
Reference numerals 2-6 indicate system monitoring processes, respectively.

[0012]

However, in the case of the conventional example shown in FIG. 5, the work is completely stopped when the cross call disk 5 fails or is maintained. Further, since the cross call disk 5 is directly connected to the active server device 1 and the spare server device 2 at the same time, if the spare server device 2 mistakenly accesses the cross call disk 5, the business data is destroyed. May be When the standby server device 2 monitors the failure of the active server device 1 and detects an error in the active server device 1, when the active server device 1 is updating data to the cross call disk 5, for example. In principle, it is impossible to prohibit access to the standby server device 2.

Further, normally, the business data update to the cross-call disk 5 is written after being cached in the memory, but before the actual writing on the cross-call disk 5, a failure occurs and the system is switched. If done, lost update data, or worst case,
The file itself may be destroyed. Further, when the standby server device 2 takes over the job due to a failure of the active server device 1, the state of the cross-call disk 5 in which the job data is written is unknown, so the file system is checked and the database table area Since it is necessary to perform a check, it takes time to switch the active / standby system of the server device, and there is a problem that work is stopped during this period.

It is an object of the present invention to use cross-call disks, eg transaction data synchronization,
It is to provide a database server of a duplicated system that does not require transmission.

[0015]

According to the present invention, a database server of a duplex system, which constitutes a system with a plurality of server devices as an active system and a standby system, receives an update request for business data from the outside and stores it as update data. Data storage means, update data reflecting means for reflecting the update data of the active system on the work data of the standby system, and mutual monitoring of the partner system while communicating between the active system and the standby system. The present invention is characterized by including system monitoring means for performing the operation, and active / standby system switching means for newly switching the standby system to the active system when the system monitoring means detects an abnormality in the active system.

[0016]

DESCRIPTION OF THE PREFERRED EMBODIMENTS The operation of the present invention is as follows.
The backup server constantly monitors the update of the job data of the active server, and when there is an update, the job data of the backup server is updated in the same manner so as to reflect each other's job data.

For example, as shown in the principle system diagram of the present invention in FIG. 2, a disk device or a disk array device 1-1 or 2-1 is connected to two server devices 1 and 2, respectively. The business data of each server device 1 or 2 is stored independently. Further, the two server devices 1 and 2 are connected by a communication line for monitoring the operation system (system operation of the active server device 1) and a LAN line 4 for connecting a database network.

One of the two server devices 1 and 2 is, for example, the active server device 1 that executes a task (for example, transaction processing), and the other is a standby server device as a substitute server device when a failure occurs. It becomes 2.

As shown in the block diagram of the embodiment of FIG.
The operation system update data reflection process 2-4 of the standby server device 2 uses the active server device 1 via the database network connection software 2-5 and 1-5.
The database engine 1-2 is connected as a database client, and the database engine 2-2 of the standby server device 2 is also connected as a database client.

The operation system update data reflection process 2-4 monitors the update of the business data of the active server device 1 and reflects the updated business data in the business data of the standby server device 2. Further, the system monitoring processes 1-6 and 2-of the active server device 1 and the standby server device 2 are performed.
6 monitors the partner server device 1 or 2 by communicating with each other.

When the system monitoring process 2-6 of the standby server device 2 detects an abnormality in the active server device 1,
The operation system update data reflection process 2-4 is stopped and the business application 2-3 is put into an operating state, thereby switching its own system to the active system.

The operation of the embodiment of the present invention will be described below with reference to the drawings. In FIG. 1, in the server devices 1 and 2, the database engine 1-2 or 2-2 is a database client (client devices 3-1 to 3-1).
(n, etc.), reference / update business data.
The database network connection software 1-5 or 2-5 connects the database engine 1-2 or 2-2 and the database client via the network.

The business applications 1-3 and 2-3 refer to / update the business data by the database engine 1-2 or 2-in response to a request from the database client.
Request 2 Operation system update data reflection process 1
-4 or 2-4 is in a dormant state in the active server device 1, and the standby server device 2 reflects the update data of the active server device 1 in its own system. The system monitoring process 1-6 or 2-6 performs communication for system monitoring.

FIG. 3 is a conceptual diagram of data flow in the block of FIG. FIG. 3 shows a data flow when a client device, for example, 3-N requests a business application 1-3 to update business data. The operation data of the active server device 1 and the standby server device 2 are updated as follows.

A: The client device 3-N requests the business application 1-3 of the active server device 1 to update the business data.

B: The business application 1-3 of the active server device 1 requests the database engine 1-2 to update the business data.

C: The database engine 1-2 of the active server device 1 writes the business data in the disk device 1-1.

D: Operation system update data reflection process 2 of the standby server device 2 connected to the database engine 1-2 of the active server device 1 via the database network connection software 1-5 and 2-5 −
4 is a database engine 1 of the active server device 1
Request to reference the updated business data to 2.

E: The database engine 1-2 of the active server device 1 reads the business data from the disk device 1-1.

F: The database engine 1-2 of the active server device 1 delivers the business data read in the process (e) to the operational system update data reflection process 2-4 of the standby server device 2.

G: The operation system update data reflection process 2-4 of the spare server device 2 updates the business data in the database engine 2-2 of the spare server device 2 based on the business data received in (f). Request.

H: The database engine 2-2 of the standby server device 2 writes business data to the disk device 2-2.

As shown in FIG. 1, the system monitoring processes 1-6 and 2 of the active server device 1 and the standby server device 2 are performed.
-6 monitors the other server device 1 or 2 by communicating with each other. When the system monitoring process 2-6 of the standby server device 2 detects an error in the active server device 1, the operation system update data reflection process 2-4
Is stopped and the business application 2-3 is put into an operating state, thereby switching its own system to the active system.

At that time, the fact that an abnormality has occurred in the active server device 1 and that the active server device has been switched are simultaneously displayed on the system display board (not shown). Conversely, the system monitoring process 1-6 of the active server device 1
However, when an abnormality of the standby server device 2 is detected, the abnormality of the standby server device 2 is displayed on the system display board (not shown).

[0035]

As described above, the present invention is applicable to the current system /
Since a system monitoring process is provided in each of the standby server devices and the other server device is constantly monitored by communicating with each other, the standby server device can also be monitored. Since the standby system server device mainly synchronizes the business data of the active / standby system server device, there is an effect that the load on the active system server device is not increased. Since the cross-call disc is not used, there is an effect that the trouble of the cross-call disc is released.

[Brief description of drawings]

FIG. 1 is a software configuration diagram of an embodiment of the present invention.

FIG. 2 is a system configuration diagram of an embodiment of the present invention.

FIG. 3 is an explanatory diagram of a data flow according to the embodiment of this invention.

FIG. 4 is a system configuration diagram of an example of a database server of a conventional duplex system.

FIG. 5 is a system configuration diagram of another example of the database server of the conventional duplex system.

[Explanation of symbols]

1, 2 Server device 1-1, 2-1 Disk device 1-2, 2-2 Database engine 1-3, 2-3 Business application 1-4, 2-4 Operation system update data reflection process 1-5, 2 -5 Database network connection software 1-6, 2-6 System monitoring process 3-1 to n Client device 4 LAN line

Claims (2)

[Claims] 1. A database server of a duplex system, which comprises a plurality of server devices as an active system and a standby system, and an update data storage means for receiving an update request for business data from the outside and storing it as update data. Update data reflecting means for reflecting the update data of the active system on the business data of the standby system, and system monitoring means for mutually monitoring the partner system while communicating between the active system and the standby system. A database server for a duplicated system, comprising: an active system / spare system switching unit that switches the standby system to a new active system when the system monitoring unit detects an abnormality in the active system. 2. The database server of the duplex system according to claim 1, wherein when the system monitoring means detects an abnormality in the standby system, it displays an abnormality.