JPH1021103A - System for communicating duplexing device control message - Google Patents

Abstract

PROBLEM TO BE SOLVED: To prevent the latent fault of a non-operational system in duplexing device control by permitting a control message transmission source to monitor the control states of both operational and non-operational systems. SOLUTION: In a low-order device 1 executing a synchronous operation, 0-system device 2 of the operational system is provided with a normal message and response message route 5 capable of transmitting a transmission message to a high-order device 7, and the 1-system device 3 of the non-operational system is provided with a response message route 6 capable of returning only a response message. When a control message is transmitted from the high-order device 7 to the low-order device 1, the response message is returned from both 0-system device 2 and the 1-system device 3 of the low-order device 1 executing the synchronous operation to the high-order device 7 so that it is recognized whether or not both 0-system device 2 and the 1-system device 3 of the low- order device 1 are controlled.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a duplexer control message communication system, and more particularly to a control message communication system for a duplexer in a synchronous operation. The present invention relates to an exchange having a function of transmitting a response from a system device to a transmission source and confirming a response regarding a control message.

[0002]

2. Description of the Related Art As this kind of prior art, for example, Japanese Patent Laid-Open Publication No. 1-4155 discloses a synchronous duplexer in which a working channel control device controls both channels. A communication channel synchronization control method has been proposed in which the operation of the communication channel is compared to detect the synchronization control failure of the duplexed communication channel at an early stage and the load on the central control device is reduced.

Further, Japanese Patent Publication No. 61-4128 (JP-A-57-101950) discloses that a fault occurring in a storage device occurs in the active storage device and the non-active storage device at the same probability. Therefore, in order to solve the problem that the failure cannot be detected when the non-operational storage device becomes faulty, the fault becomes latent, in a processing system having a duplicated storage device, the synchronous operation mode is separated. An operation mode, wherein the redundant storage devices are operated synchronously in the synchronous operation mode, and a display signal indicating the operation of each storage device is compared and collated between the two storage devices to detect an operational failure. A redundant storage device control method has been proposed in which a latent failure is detected early to prevent an inoperative state.

[0004]

However, in the above-mentioned conventional system, a control message is transmitted to the duplexer operating synchronously, but the operation of the duplexer operating synchronously is not performed. The system also has a problem that it is not possible to determine whether or not the system is properly controlled, and it is not possible to find a potential failure of the protection system.

[0005] The reason is that the same control message is transmitted to both systems of the duplexer performing the synchronous operation, but the operation of the duplexer performing the synchronous operation is performed in response to the control message. Because it is returned from the system side, it is not possible to determine whether the control message has been normally received in the protection system.

Therefore, the present invention has been made in view of the above circumstances, and has as its object to provide a non-synchronized non-synchronized operation only for a control message transmitted to a synchronously operated duplexer. It is an object of the present invention to provide a duplexer control message communication method for improving the reliability of duplexer control as a configuration in which a response message is sent back to the active system and the control state of both systems is monitored.

[0007]

In order to achieve the above object, in a duplexer control message communication system according to the present invention, an operation apparatus transmits a transmission message to an upper apparatus for a lower apparatus operating synchronously. And a message route for returning a response message even in the inactive device, and the lower device performing synchronous operation when transmitting a control message from the higher device to the lower device. By confirming that a response message to the control message is returned from both systems to the higher-level device, it is confirmed whether both systems of the lower-level device are controlled.

In the present invention, it is preferable that the normal message transmission queue, which cannot transmit a message only in the case of the protection system operating in the synchronous operation, and the duplexer be used in the synchronous operation / operation
A response message queue capable of transmitting a message in any state of asynchronous operation and operation / non-operation, and when performing message communication with a device in synchronous operation, a response message to a control message Is characterized by having functional means for transmitting from both the active and non-operating devices during the synchronous operation.

[0009]

Embodiments of the present invention will be described in detail below with reference to the drawings. FIG. 1 is a diagram showing a configuration of a preferred embodiment of the present invention.

Referring to FIG. 1, according to the embodiment of the present invention, the lower-level device 1 that is operating synchronously can transmit various transmission messages to the higher-level device 7 in the active 0-system device 2. It has a message and response message route 5 and, besides this route, has a response message route 6 that allows the protection first system device 3 to return only a response message.

Thus, when a control message is transmitted from the higher-level device 7 to the lower-level device 1, a response message is sent from both the 0-system device 2 and the 1-system device 3 of the lower device 1 performing the synchronous operation. Since it is returned to the higher-level device 7, it becomes possible to confirm whether or not both systems of the 0-system device 2 and the 1-system device 3 of the lower-level device 1 have been controlled.

As described above, in the preferred embodiment of the present invention, both systems are always controlled in the same state by confirming the response of both systems to the control messages of both systems in the synchronous duplex operation. It can be operated.

[0013]

DESCRIPTION OF THE PREFERRED EMBODIMENTS In order to more specifically describe the above-described embodiment of the present invention, an embodiment of the present invention will be described with reference to the drawings. FIG. 2 is a diagram illustrating a configuration of an embodiment of the present invention, and schematically illustrates a state in which a higher-level device 30 performing a synchronous operation transmits a control message to a lower-level device 8 performing a synchronous operation. FIG.

Referring to FIG. 2, a control message is sent from a CPU 28 mounted on the 0-system device 29 of the host device 30 and a CPU 36 mounted on the 1-system device 37 to each normal message transmission queue, that is, the CPU 28. Sends a stow message transmission request to the normal message transmission queue 24 and the CPU 36 issues a stow message transmission request to the normal message transmission queue 32.

At this time, since the normal message transmission queue 24 of the 0-system device 29 is the active system, the messages requested to be transmitted are synchronously operated. A control message is transmitted to both systems.

On the other hand, the control message requested to be transmitted to the normal message transmission queue 32 of the first device 37 mounted on the higher device 30 is such that the higher device 30 is operating synchronously and the first device 37 is not operating. Therefore, the transmission data stored in the normal message transmission queue 32 is discarded.

The 0-system device 9 mounted on the lower-level device 8
The CPU 3 of the first device 16 and the CPU 17 of the first device 16 receive the control message from the 0 device 29 of the higher-level device 30 by using the 0-system received message queue 11/2 in each device.
2 to receive.

The CPUs 10 and 1 of the 0-system device 9 of the lower-level device 8
The CPU 17 of the system device sends a response to the control message received together with the response message in the response message transmission queue 13/19 mounted on each device and makes a transmission request.

The response message transmission queue 13/19 has
Regardless of synchronous operation / asynchronous operation or operation / non-operation of the lower device 8, a message is transmitted in response to a transmission request, so that the 0 device 9 and the 1 device 16 of the lower device 8 are transmitted.
Accordingly, a response message is transmitted to the 0-system device 29 of the higher-level device 30.

The 0-system device 29 of the upper device 30 checks the response of the control message to the 0-system device 9 of the lower device 8,
This is performed by receiving a response message from the 0-system received message queue 27, and confirming the response of the control message of the lower-level device 8 to the 1-system device 16 by receiving the response message from the 1-system received message queue 26. .

As described above, in the present embodiment, the normal message transmission queue 24/32 is used, so that the 0-system device 9 and the 1-system device 16 of the lower device 8 are the active systems of the higher device 30. A message reception process from the system device 29 can be performed, and by using the response message transmission queue 13/19, the host device 30 that has transmitted the control message can be used.
The system 0 device 29 receives the response message from the lower device 8 independently from the system 0 reception queue 27 and the system 1 reception queue 26, and sends both the system 0 device 9 and the system 1 device 16 of the lower device 8. Is controlled.

[0022]

As described above, according to the present invention,
When a control message is transmitted to a device that is performing synchronous operation, a response message is returned from both devices and can be confirmed. Can be detected immediately.

[Brief description of the drawings]

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

FIG. 2 is a diagram schematically showing the operation of one embodiment of the present invention.

[Explanation of symbols]

 Reference Signs List 1 lower device 20 system device (active system) 13 1 system device (non-operating system) 4 transmission message route 5 communication message and response message route 6 response message route 8 lower device 90 system device 10, 17 CPU 11, 220 System reception message queue 12, 21 System 1 reception message queue 13, 19 Response message transmission queue 14, 18 Communication message transmission queue 15, 20 Transmission queue 16 System 1 device 23, 31 Transmission queue 24, 32 Communication message transmission queue 25, 33 Response message transmission queue 26, 34 1-system reception message queue 27, 350 0-system reception message queue 28, 36 CPU 290-system device 30 Host device 37 1-system device

Claims (3)

[Claims] 1. A low-level device that is operating synchronously includes a message route for an active device to transmit a transmission message to a high-level device, and a message route for returning a response message to a non-active device. When a control message is transmitted from the higher-level device to the lower-level device, by confirming that a response message to the control message is returned to the higher-level device from both systems of the lower-level device performing the synchronous operation. A duplex device control message communication method, comprising: checking whether both systems of the lower-level device are controlled. 2. In a duplexer control message communication system, a normal message transmission queue that cannot transmit a message only in the case of a protection system that is operating synchronously, and a duplexer that performs synchronous / asynchronous operation and operation. system/
In any state of the protection system, a response message queue capable of sending a message is provided.
A duplex device control message communication system, comprising: a function unit for transmitting a response message to a control message from both an active system device and a non-active system device during synchronous operation. 3. The transmitting side of the control message,
A message from the multiplexing device has an independent reception queue for each system, and a response message to a control message transmitted to a device operating in synchronization is received separately from both systems to confirm a response to the control message. 3. The apparatus according to claim 2, further comprising a function unit for performing
Duplexer control message communication method.