JPH01175042A - High speed switching system for duplicated system - Google Patents

Abstract

PURPOSE:To switch at high speed a duplicated system by connecting a common memory between a master system and a slave system of the duplicated system and always inputting the contents of a main memory in the master system to a main memory in the slave system. CONSTITUTION:The master system of the duplicated system has a CPU 12 and the main memory 13, the slave system 14 has a CPU 15 and the main memory 16 and the common memory 20 is connected between the master and slave systems. Fixed time recovery information obtained from the master system 11 every fixed time and unfixed recovery information obtained during the unfixed time between the fixed periods are stored in the common memory 20 and the contents are always entered to the main memory 16 of the slave system 14. Even when the master system is switched to the slave system by a switching device 19 due to system down, the slave system 14 can immediately restart work.

Description

[Detailed Description of the Invention] [Summary] Concerning a high-speed switching method for a dual-vehicle system consisting of a master system and a slave system, the contents of the main memory of the master system are transferred to the main memory of the slave system by intervening a common memory. The purpose of this system is to provide a high-speed switching method for a duplex system that aims to speed up the switching of a dual-vehicle system by constantly reflecting the data. A communication control device that controls the main system and the slave system, a disk device connected to the main system and the slave system, respectively, and a switch that switches between the main system and the slave system. In the switching method of a duplex system equipped with a device, the main system stores regular recovery information J3 at regular intervals and non-scheduled recovery information during that time, and the contents are constantly transferred to the main system E by the slave system. A common memory to be read is provided so that if the main system is unable to continue the work due to system failure, the slave system can switch between pages by switching using the switching device.

[Industrial Application Field] The present invention relates to a high-speed switching method for a duplex system consisting of a main system and a slave system.

In banking systems that handle cash, C.
Same as the main system that has PU, main memory, etc.
The system consists of a redundant system consisting of 41 slave systems, including a main system.This redundant system is used because the main system cannot continue business due to a system failure.
: This is to enable work to be restarted on the subordinate system in order to avoid trouble if i becomes impossible.

In this case, it is necessary to perform system transition 8 from the main system to the slave system as quickly as possible.

[Prior Art] An example of a conventional switching system of this type of two-handed system is as shown in FIG. 5.

In the figure, 1 is the main system that resets the CPU, main memory, etc. to 0, and the main system 1 is used to edit constant n,' at intervals during business execution, and to store recovery information (scheduled recovery information). During the recovery information, there is raw information that is not edited every time an event occurs (non-scheduled recovery information).
, and then rape it onto Disc 2.

In this state, if the main system 1 becomes unable to continue operations due to system failure, the slave system 3, which has a CPU, main memory, etc., reads recovery information from disk 2 and continues operations.

However, in order to reproduce the contents of the main memory of the primary system 1 on the slave system 3 and continue the work, the disk 2 was inserted.

[Problem 1 to be solved by the invention However, 1,
In the 7J8 method, if the system of the main system 1 goes down just before the next periodic recovery information is saved by the main system 1 to the disk 2, the maximum amount of data to be imported from the disk 2 to the main memory of the slave system 3 is enormous. Therefore, it takes several minutes just to read the data from the disk 2.

Now, in Figure 4, IMB edited and recovery information is saved to disk 2 every 3 minutes, and during that time, 4KB of non-scheduled recovery information that has not been edited is saved to disk 2 in 1/10 pieces per minute. 11.1 If the main system 1 goes down just before the periodic recovery information is beeped and the next periodic 11.1 recovery information is saved, the recovery information will be saved to disk 2 and the recovery information will be saved to disk 2. J: I'm going to growl.

Recovery information = Fixed 1.1 Recovery information (non-standard)
Recovery information = IMB Do4 K B'X 140 x 180 seconds = I
MB + 100.8MB = 101.8MB So, the data transfer rate from disk 2 is 2M
B, it takes approximately 51 seconds to transfer 101.8 MB of information to the slave system 3.

If the main system goes down, the slave system 3
The problem was that it took time for the company to resume operations.

The present invention has been made in view of these conventional problems, and it is possible to create a redundant system by constantly reflecting the contents of the main memory of the master system in the main memory of the slave system through a common memory. The purpose of this research is to provide a high-speed switching method for a duplex system that speeds up switching.

[Means for solving problems] FIG. 1 is a diagram explaining the principle of the present invention.

In Fig. 1, 11 is CI) U12, main memory 1
14 is a slave system that has a CPU 15, a main system 16, etc., 17 is a communication control device that controls the main system 11a3 and the slave system 14, and 18 is a communication control device that controls the main system 11 and the slave system. 14, a switching device 19 for switching between the main system 11 and the slave system 14; 20, a constant (i-recovery information and non-scheduled recovery information for each period in which the main system 11 is fixed); This is a common memory for storing the data and always importing the contents into the main memory 16 of the slave system 14.

[Operation] In the present invention, the main system 11
The contents of the main menu 13 of the main menu 14 of the slave system 1
6, so if the main system 11 is unable to continue operations due to a system failure, the switch is set to 8 and 19, and the secondary system 14 is updated. can resume operations immediately.

In other words, while conventional methods using disks required time on the order of minutes to switch between systems, with this method switching takes only a few seconds, making it possible to speed up the switching of redundant systems. .

[Example] Hereinafter, embodiments of the present invention will be described based on the drawings.

FIG. 2d3 and FIG. 3 are diagrams showing a duplex system for implementing the present invention.

First, to explain the redundant system 31, in FIG. 2, 11 indicates a main system, and the main system 11 is composed of a CPU 12, a main memory 13, and the like.

14 is a slave system, and the slave system 14 also includes a CPU 15, a main memory 16, and the like.

17 is a communication control device, and this communication control device 17 controls the main system 11 and the slave system 14, respectively.

18 is a disk interposed between the main system 11 and the slave system 14, and during normal operation, this disk 1B is connected to the 13 system u.
ll Data from the device 17 is stored via the main system 13 of the main system 11.

In other words, this system is configured as a banking system that handles cash, etc. When the main system 11 is operating, the slave system 14 is idle, and when the main system 11 is operating, the accounts etc. on the disk 18 are Personal payments such as cash are stored.

Reference numeral 19 denotes a switching device interposed between the main system 11 and the slave system 14. When the main system 11 goes down, this switching device @19 detects this and switches to the slave system 14. In the banking system, it is necessary to reliably prevent troubles that would cause the main system 11 to go down.
A slave system 14 is provided as a backup.

Here, ゛, 20 are the main memory 13 of the master system 11 and the slave system 1
The main system 11 imports periodic recovery information every 3 minutes into this common memory 20, and events occur during the 3 minute intervals. Every time, non-electronic 1. 'I import recovery information. On the other hand, the slave system 11 always imports the contents of this common memory 20 into its own main memory 16 in order to make it compatible with the main memory 13 of the master system 11.

As shown in FIG. 3, the common system 20 includes a main buffer 21 of 11 [;', 1 for constant nji recovery information + If, and n sub-buffers 722 for non-scheduled recovery information.
It is composed of respective synchronization flags 23.

The reason why n sub-buffers 22 for recovery information are provided is because of some processing delay in the slave system 14. When the recovery information *]J is written in the calculation from the main system 11, it is 1,! This is to prevent you from being exposed.

+i1 period flag 23 When the system 11 outputs recovery information to the common memory 20, it writes "1", and when the slave system 14 imports the contents into its own main memory 16, rO
The main system 11 sequentially writes non-scheduled recovery information from buffer 22-1 to buffer 22-n, and then writes the non-scheduled recovery information to buffer 22-n and then to buffer 22-n.
1, and the slave system 14 takes in the non-scheduled recovery information into its main memory 16 in this order. In addition, in FIG. 4, the non-scheduled recovery information in the buffer 22-2 is transferred to the slave system 14.
This indicates that the state should be captured.

Normally, in a two-meter system, communication is performed to confirm that the other system is operating, but in this system, the synchronization flag 23 can also serve as a function to confirm that the other system is operating. I'm trying to make it possible. In addition,
This duplex system can access the common memory 20 from both the main system 11 and the slave system 14, and is a highly independent device with its own power supply. : Never redownloaded.

Next, the switching method of this system will be explained.

In FIG. 4, in J3, the main system 11 stores periodic recovery information every 3 minutes during business execution in the main buffer 2 of the common memory 20.
1, the calculated recovery information for three minutes is stored in the secondary buffer 22 of the common memory 20, respectively.

On the other hand, the slave system 14 has the contents in the common mail 20, 1,
[setting]], 1 recovery information, and non-electronic 11.1 recovery information are always 1) imported into the main memory 16,
Main system 11 main system 13Q] synchronized with the contents J><.

In this state 83, if the main system 11 goes down and it becomes impossible to continue the business, the disconnection device 19 detects the system down of the main system 11 and switches to the slave system 14. In this case, since the recovery information of the main system 13 of the primary system 11 is taken into the main system 16 of the secondary system 14 via the common system 20, the secondary system 14 is , '1 (approximately 4 seconds), business can be resumed immediately.

Therefore, in the conventional method using the disk 2, the system time H takes on the order of minutes, but with this switching method, the switching time can be shortened to on the order of several seconds.

In other words, by interposing the common memory 20, the contents of the main memory 13 of the primary system 11 are constantly reflected in the main memory 16 of the secondary system 14, thereby making it possible to speed up switching of the duplex system.

In addition, in the hydraulic system, there is an advantage that the main system 11 and the slave system 14 can be communicated through the synchronization flag 23 as an intermediary, and that it can also serve as a function of so-called diagnosis of other systems.

[Efficacy of invention! ! ] As explained above, according to the present invention, a common memory is interposed between the main system and the slave system, and the main system [
By constantly loading the contents of the secondary system into the main memory of the secondary system, it is possible to speed up the switching of the duplex system.

Furthermore, since the main system and the slave system can communicate via the synchronization flag in the common memory, it can also serve as a function for diagnosing other systems.

[Brief explanation of the drawing]

Figure 1 is the basis of the present invention! Fig. 2 is a diagram of a redundant system for implementing the present invention, Fig. 3 is a configuration diagram of a common system, Fig. 4 is an explanatory diagram explaining a system switching method, and Fig. 5 is a diagram of a conventional system. It is an explanatory diagram of an example. In the figure, 11...Main system, 12...CPU, 13...Main system, 14...Slave system, 15...C'PU. 16... Main menu, 17... Communication control device, 18... Disk, 1... 1 sword? ! equipment, 20...common memory, 21...main buffer, 22.22-1.22-n...sub-buffer 1.23...
・Synchronization flag.

Claims (2)

[Claims] (1) A main system (11) that includes a CPU (12), main memory (13), etc.;
16) and the like, and the main system (11).
and a communication control device (17) that controls the slave system (14).
), a disk device (18) connected to the main system (11) and the slave system (14), respectively, and the main system (1
a switching device (19) for switching between 1) and the slave system (14);
In the switching method of a redundant system, the main system (11) stores scheduled recovery information at regular intervals and non-scheduled recovery information during that period, and the contents are constantly stored in the secondary system (14). A common memory (20) is provided that is taken into the main memory (16), and when the main system (11) is unable to continue business due to system down, the switching device (19) switches to the slave system (14). ) is used to resume operations. (2) The common memory (20) includes one buffer (21) for storing the scheduled recovery information and a plurality of buffers (22) for storing the non-scheduled recovery information.
) and a synchronization flag (23) which writes "1" when the main system (11) writes the recovery information and writes "0" when the slave system (14) imports the contents into its own main memory (16). ) A high-speed switching system for a duplex system according to claim 1, characterized in that the system comprises: