JPH07160432A - Duplex system for magnetic disk controller - Google Patents

Abstract

PURPOSE:To construct the duplex system for the magnetic disk controller which has an environment wherein the high reliability of a magnetic disk device having a write-back type disk cache is easily realized by copying cache data of a controller of one system to the other system at normal time. CONSTITUTION:The system is provided with a data transfer path 3 which copies the contents of the cache data and control information on the storage destination address, etc., of the data from the controller 10 that normally responds to a command from a host device to the controller 20 normally in a stand-by state, and, the same contents are made normally present in the caches 2 and 2 of the controllers of both the systems, but if the controller 10 gets out of order, the cache data are written to the magnetic disk device 5 from the controller 20.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention shares a magnetic disk device with a plurality of magnetic disk controllers, the data generated by the host device is received by the magnetic disk controller, and is sent to the host device. A magnetic disk controller duplexing method suitable for use in a disk cache system that adopts a write-back method in which a status indicating that processing is completed at that point is returned and then data is written to the magnetic disk device. .

[0002]

2. Description of the Related Art Magnetic disk devices are widely used as large-capacity external file devices not only in large-scale computers but also in the fields of distributed processing computers and recently personal computers, and are becoming smaller year by year. , The density has been increasing.

In order to ensure the reliability of this type of system, a system in which a magnetic disk controller for controlling a magnetic disk device is duplicated has been constructed. Conventionally, in a system in which such a magnetic disk controller is duplicated, an access path to a magnetic disk device is provided to both magnetic disk controllers, and one magnetic disk controller fails. In this case, a method has been adopted in which the access to the magnetic disk device from the magnetic disk controller of another system can be maintained.

In the recent magnetic disk controller, the magnetic disk controller first receives write data from the host (device on the host side), and the host receives a status indicating that the processing is completed at that time. A write-back type disk cache that reports and then writes data to a magnetic disk device is often used. This disk cache is an essential support item for high-speed access to the magnetic disk device.

When the above-mentioned write-back type disk cache is used, it is necessary to write the data remaining in the cache memory to the magnetic disk device after the failure of the magnetic disk controller. Therefore, simply replace the magnetic disk controller with cache memory with 2
In the conventional duplexing method, which is prepared individually, it is impossible to write end write data to the magnetic disk device.

Therefore, in order to avoid this inconvenience, there is a method in which the cache memory is separated from the magnetic disk controller so as to have access paths from both magnetic disk controllers, but when such a method is used. Has a problem in that a special cache device must be connected even when the magnetic disk controller is not duplicated, and the hardware structure of the system becomes complicated and expensive.

[0007]

As described above, when the write-back type disk cache is used,
It is necessary to write the data remaining in the cache memory to the magnetic disk device after the failure of the magnetic disk controller. Therefore, in the conventional duplex system in which two magnetic disk controllers having the cache memory are simply prepared,
It is impossible to write end write data to the magnetic disk device. Therefore, a method of separating the cache memory from the magnetic disk controller and providing an access path from both magnetic disk controllers was also considered, but this method is special even when the magnetic disk controllers are not duplicated. It is necessary to connect various cache devices, and the hardware structure of the system becomes complicated and expensive.

The present invention has been made in view of the above circumstances,
By copying the cache data of the one-sided magnetic disk controller to the other system during normal operation, it is possible to easily realize the high reliability of the magnetic disk device having the write-back type disk cache. It is an object of the present invention to provide a duplex system for a disk controller.

[0009]

SUMMARY OF THE INVENTION According to the present invention, a magnetic disk device is shared by a plurality of magnetic disk controllers, and the magnetic disk controller receives data generated by the host device, so that the host device can receive the data. In the disk cache system which returns a status indicating that the processing is completed at that time, and then writes data to the magnetic disk device, both magnetic disk controllers are controlled.
A path for communication between the two magnetic disks is provided as an access path to the shared magnetic disk device, and the cache data of one magnetic disk controller is copied to the other cache via this path and both magnetic disks are connected. The controller recognizes the data and writes the data to the magnetic disk device via the magnetic disk controller instructed by the host device. In addition, the magnetic disk controller in operation is
The cache data is always copied and sent to the magnetic disk controller in the standby state, and when the magnetic disk controller in the operating state fails, the cache data is transferred via the magnetic disk controller in the standby state. Writing data to a magnetic disk device.

[0010]

The present invention relates to a magnetic disk controller system in a normal standby state which is activated when a failure occurs in the magnetic disk controller system which normally responds to a command from the host device. A data transfer path and a processing procedure for copying the control contents such as the contents of the cache data and the storage destination address of the data are provided, and normally, it is the same in the caches of the magnetic disk controllers of both systems. The write-back method by operating the system so that the contents of the above exist and when the failure of the one-sided magnetic disk controller takes the method of writing the cache data from the remaining another-sided magnetic disk controller to the magnetic disk. It realizes the duplication of the magnetic disk controller having the disk cache of.

Therefore, in order to realize the above-mentioned processing, each magnetic disk controller has a built-in CPU and
2, the command including the write address is issued to the other magnetic disk controller, and the data obtained from the host device is written into the cache of its own system, and at the same time, the access path is deleted. After writing the data to the cache of the other system provided in the other magnetic disk controller via the command and returning the status to the host device, the command is received from the other magnetic disk controller and the other magnetic disk controller is received. -The directory information of the data written in the magnetic disk device by the scanner is obtained, and the self-system directory update is prepared.

As a result, similar to the duplication of the conventional magnetic disk controller which does not use the write-back type disk cache, the magnetic disk controller is not duplicated when high reliability is not required, and high reliability is achieved. If high reliability is required, a high reliability system can be easily constructed by adding only a magnetic disk controller.

[0013]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS An embodiment of the present invention will be described below with reference to the drawings. FIG. 1 is a block diagram showing an embodiment of the present invention. In the figure, reference numeral 1 is a host bus used to connect to a host device (not shown), and the host device transfers data to and from the disk cache 2 in the magnetic disk controller via this bus 1. To do.

Reference numeral 2 is a disk cache in the magnetic disk controller, which performs data transfer with the host bus 1 and a disk bus 3 described later. Reference numeral 3 is a disk bus, and a command data to the magnetic disk device 5
In addition to transmitting / receiving data, communication between magnetic disk controllers can be performed, for example, via the SCSI bus.

Reference numeral 4 is a microprocessor (CPU) in the magnetic disk controller, which controls the entire processing of the magnetic disk controller. Reference numeral 5 denotes a magnetic disk device, which is shared by a plurality of magnetic disk controllers 10 and 20 via the disk bus 3. Here, the magnetic disk controller 10 is a magnetic disk controller on the master side, and the magnetic disk controller 2
0 is called a magnetic disk controller on the slave side.

FIG. 2 is a flow chart showing the operation of the embodiment of the present invention. 2A shows an operation procedure of write command processing of the microprocessor 4 in the magnetic disk controller 10 as a master, and FIG.
3 shows an operation procedure of write command processing of the microprocessor 4 in the magnetic disk controller 20 which becomes a block.

In FIG. 2, reference character Sa is a magnetic disk controller 20 in which the magnetic disk controller 10 is another system.
Is a step of issuing a command to the magnetic disk controller 20 of the other system to notify the control information including the data storage destination address to prepare for the data transfer.

Reference numeral Sb is a magnetic disk controller 10.
Is a step of performing data transfer, in which the data obtained via the host bus 1 is written into the disk cache 2 of its own system (having the magnetic disk controller 10), and at the same time, via the disk bus 3. Write to the disk cache 2 of another system (which the magnetic disk controller 20 has).

Reference symbol Sc is the magnetic disk controller 10.
Is a step of receiving a command issued from the magnetic disk controller 20 of the other system, the magnetic disk controller 20 of the other system receives the directory information of the data written to the magnetic disk device 5, and the magnetic field of the own system is received. Prepare for the directory update by the disk controller 10.

Reference numeral Sd is a magnetic disk controller 20.
Is a step of writing a disk, and normally, the magnetic disk controller 20 in the standby state takes charge of processing in the sense of load distribution. Reference numeral Sf is a step in which the magnetic disk controller 20 issues a directory update request, and the directory ejected from the disk cache 2 is used as a magnetic disk controller 1 of another system.
0 is notified and the disk cache contents of both systems are matched.

The operation of the embodiment of the present invention will be described below. As shown in FIG. 1, according to the present invention, a disk bus capable of communication between magnetic disk controllers is used.
A magnetic disk controller of the system is connected. Normally, the magnetic disk controller 10, which is shown as a master, receives a command from a host device (not shown) and performs processing according to an instruction from the host device. However, the operation shown by the flow chart in FIG. 2 is executed only for a data write request to the disk device 5. That is, the processing is terminated at the time when the data is written in the disk cache built in the magnetic disk controller serving as the self system and the slave, and the write operation itself to the disk device 5 is left to the slave.

The magnetic disk controller 20 shown as a slave is a standby magnetic disk controller in case of failure of the master magnetic disk controller 10, but as shown in FIG. At times, the cache data operates as a write-back cache controller for writing data to the magnetic disk device 5.

When the magnetic disk controller 10 shown as a master fails, the magnetic disk controller 20 shown as a slave receives a command from the host device and executes the command processing to the magnetic disk device 5 in general. become.

At this time, since the write data already processed by the master magnetic disk controller 10 exists in the own disk cache 2, the contents can be written to the magnetic disk device 5 without any problem.

On the other hand, when the magnetic disk controller 20 shown as a slave fails, the master magnetic disk controller 10 performs the writing process to the magnetic disk device 5 instead of the slave.

At this time, since the necessary data is still in the own system disk cache 2, the operation can be continued without any problem. When one of the magnetic disk controllers fails, a report to that effect is sent to the host device. At this time, it is left to the judgment of the host device whether or not the line-back cache operation is performed only by the one-sided magnetic disk controller. Even if the magnetic disk controller is not duplicated, the magnetic disk controller shown in FIG. 1 can perform write buffer cache operation by itself, and in a system that does not require high reliability, the magnetic disk controller can be used. -The write-back cache operation is performed by the laser unit alone, and the reliability can be improved only by adding the magnetic disk controller when necessary.

[0027]

As described above, according to the present invention, the cache data of the one-sided magnetic disk controller is normally used.
By duplicating the data in the disk cache of another system's magnetic disk controller, it is possible to easily duplicate the control, and to duplicate the conventional magnetic disk controller without using the write-back type disk cache. Similarly, by not duplicating the magnetic disk controller when reliability is not required so much, by adding the magnetic disk controller only when reliability is required,
A highly reliable system can be built easily.

[Brief description of drawings]

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

FIG. 2 is a flow chart showing the operation of the embodiment of the present invention.

[Explanation of symbols]

1 ... Host bus, 2 ... Disk cache, 3 ... Disk bus (SCSI bus), 4 ... Microprocessor (C
PU), 5 ... Magnetic disk device, 10, 20 ... Magnetic disk controller.

Claims (3)

[Claims] 1. A plurality of magnetic disk controllers having a cache share a magnetic disk device, and when the magnetic disk controller receives data generated by a host device, the host device is notified at that time. The status indicating the end of processing is returned, and then the data is sent to the magnetic disk unit.
In a disk cache system for writing data, a path for communicating between the magnetic disk controllers is provided as an access path for a shared magnetic disk device, and one magnetic disk controller is connected via this path. Copy the cache data held by the other to the other cache, recognize the data by both magnetic disk controllers, and send it to the magnetic disk device via the magnetic disk controller instructed by the host device. A dual system of a magnetic disk controller characterized by writing data. 2. A magnetic disk controller in an operating state.
Always sends a copy of the cache data to the magnetic disk controller in the standby state and sends it to the magnetic disk device via the magnetic disk controller in the standby state when a failure occurs. 2. The duplex system of a magnetic disk controller according to claim 1, wherein writing is performed to the magnetic disk controller. 3. A plurality of magnetic disk controllers each have a built-in CPU, and the CPU issues a command including a write address to the other magnetic disk controller and obtains data from a host device. Data to the cache of its own system at the same time as writing to the cache of the other system via the access path, and after returning the status to the host device, it receives the command from the other magnetic disk controller and 2. The duplex system for a magnetic disk controller according to claim 1, wherein the disk controller obtains directory information of data written in the magnetic disk device and prepares for updating the directory of its own system.