JPH0423120A - Method and device for automatic allocation of alternate block in array disk device - Google Patents

Abstract

PURPOSE:To improve the reliability of data at the time of detecting a data check error by storing an error area in an error list and then allocating an alternate block after the end of the due processing. CONSTITUTION:If an error occurred in the data check of a disk device 31c, for example, during the transfer of the read data, the read processing is started by a drive control part 32c. When a read error is confirmed, the position of the error block is added to an error list 34c. Then the restoring function of an array disk device 30 is started and the error data is restored by a disk device 31e. Thus the read processing is carried on. When this read processing is over, the control is shifted to an array control part 33 and the recovery processing is carried out. Then an alternate block is allocated and the data is restored to the alternate block by the device 31e. Thus the automatic recovery processing is attained at the time of generating a data check error and the reliability of data is improved.

Description

[Detailed Description of the Invention] [Summary] This invention relates to a method for automatically allocating alternate blocks for error processing in an array disk device and the device thereof, and the present invention relates to a method for automatically allocating alternate blocks for error processing in an array disk device, and a method for automatically allocating replacement blocks to perform error processing in an array disk device. The purpose is to increase the reliability of the system and improve the performance of the array disk device, and when an error is detected in the data check of the array disk, the error list 14i (i=a.

b, ..., n, or p) to store the error location,
The method and apparatus are configured to allocate a replacement block after processing is completed.

[Industrial application field]

The present invention relates to a method and apparatus for automatically allocating replacement blocks for error handling in an array disk device.

[Conventional technology]

As shown in FIG. 6, a device that uses a plurality of disk devices 1a to 1e to constitute one logical disk device is called an array disk device 1. One of the configurations of this array disk device 1 is a configuration using a parity disk device (#P) le that adds parity to data and guarantees data in other disk devices 1a to 1d.
Drive control units 2a to 2e are provided corresponding to each of these disk devices 18 to 1e to control their operations, and each drive control unit 2a to 2e is connected to the array control unit 3,
The array controller 3 collectively controls them as one disk device.

In the array disk device 1 having this conventional parity disk device (#P) 1e. When a data check occurs, the parity drive can be used to immediately modify the arrayed data without stopping data transfer.

[Problem to be solved by the invention]

In the conventional array disk device 1 described above, it is recognized that an error has occurred in a block for which a data check was performed for immediate processing, but the
Since CC (Error Checking and Correction) analysis and recovery are not performed, further data checks may be required on the same logical block of the array structure. At this time, if the error found by both data checks cannot be corrected, data will be lost. Furthermore, even if one error is correctable, the processing is temporarily stopped, the ECC is analyzed, the data is corrected, and then the processing is restarted, which significantly reduces the performance obtained by the array disk device 1. There was a point.

The present invention has been made in view of the above problems, and the technical problem set for solving the problem is to enable automatic recovery processing in the event of a data check error in the array disk device 1, and to recover data. An object of the present invention is to provide a method and apparatus for automatically allocating alternate blocks in an array disk device, which makes it possible to improve the reliability of the array disk and the performance of the array disk.

(Means for Solving the Problems) As a specific means for solving the above problems, the present invention provides a method for automatically allocating alternate blocks in an array disk device.As shown in FIG. When a disk device data check error is detected, an error list 14i (i=a, b, --..., n
, or p), and allocates a replacement block after the processing is completed.

In this method, as shown in FIG. 2, data is restored from another disk device and written into a replacement block corresponding to the data block in which the error occurs.

Further, in this method, the error list 14i (
The data block containing the error location stored in i=a, b, ---, n, or p) is replaced with a replacement block whose data has been restored.

As shown in FIG. 3, devices that execute this method include a plurality of disk devices 11i (i=a).

b, ..., nap) to configure one logical disk, the plurality of disk devices 11 i (i=a, b, ... n +
an array control unit 13 that allocates data to each disk device 11 i (i
An error list 14i (i=a, b, -) that controls the operation of the blocks (=a, b, ---, n, or p) and stores the position of the error block when a data error occurs.
--, n, or p)
(i=a, b, -, n.

p).

In the automatic allocation device for alternate drives in the array disk device, the drive control unit 12i (i=a
, b, ..., n, p) or error list 14i (i
=a, b, . . . , n, or p).

Further, in the automatic allocation device for alternate blocks in the array disk device, the array control unit 13 restores data from another disk device and writes it into the alternate block corresponding to the data block with the error location. desirable.

Further, in the automatic allocation device for replacement blocks in the array disk device, the array control unit 13 stores an error list 14i (i=a.

b, .

(Function) According to the above configuration, when an error is found in the data check, the present invention stores the name of the data block in which the error is located in the error list, so that the error can be identified even after the read process is completed. After processing is completed, an empty block is allocated as a replacement block to replace the data block with the error location. As a result, the replacement block can be used in place of the error block, and data restoration can be easily performed.

Furthermore, when restoring data, the data is transferred from another disk device such as a parity disk and written to a replacement block, and the internal processing of the array disk device is repaired to facilitate the restoration process.

Furthermore, by using a replacement block in place of a data block with an error location, it is possible to easily perform processing using restored data.

Then, the drive control unit 12i (i=a.

b,...+n+P) stores the data block containing the error in the error list 14i (i=a, b,...n, or P), so that it can be quickly processed without affecting subsequent processing. to create a record of error blocks.

Then, the array control unit 13 writes the restored data to the replacement program, causing the array disk device to execute the restoration process as an internal process.
The processing of No. 3 is made to perform restoration processing using free time, and the utilization efficiency of an array control section 13 can be improved.

Furthermore, by causing the array control unit 13 to replace the data block whose data has been restored with the data block containing the error, block replacement is executed as an internal process of the array disk device, thereby freeing up the processing time of the array control unit 13. Array controller 13
to further increase the efficiency of use.

〔Example 〕

Hereinafter, a case where five disk devices are used as an embodiment of the present invention will be illustrated and explained.

In the array disk device 30, as shown in FIG.
disk devices 31a, 31b.

An array disk 31 is constructed in which four of 31c, 31d, and 31e are used as data disks, and the remaining one is used as a parity disk.

Each disk device 31a, 31b, 31c.

Drive control units 32a and 32 that control 31d and 31e
Error lists (memories) 34a, 34b, 34c, 34b, 32c, 32d, 32e store error locations.
4d and 34e are provided.

Each drive control section 32a, 32b, 32c.

32d and 32e are connected to an array control unit 33 that controls the entire array disk, and are connected to an interface of a host device (not shown) via the array control unit 33.

In this configuration, the disk device (#2)
Assume that an error occurs in the data check of 31c. As shown in FIG. 5, the drive control unit 32c starts the read process (step 41), checks whether or not there is a read error (step 42), and if there is a read error, the position (of the error block) is determined. Error list 3
In addition to step 4c, step 43), array disk device 3
Activate the restore function of 0 and restore the disk device (#p) 31e.
is used to instantly restore the error data and continue the read process without stopping the process.
If there is no read error in the check, the operations up to restoration (steps 43 and 44) are omitted.

It is checked whether all the reading processing has been completed. If not, the process returns to step 42, and if it has been completed, the process advances to the next step (step 45).

Next, check whether there is any other processing request from the host device, and if there is any other processing request, proceed to that processing step 46).
If not, the error list 34c is checked to see if there was an error during the read operation, and if there is no error block, the process is terminated.
If there is an error block, control is transferred to the array control unit 33 and the following recovery process is executed (step 47).
.

First, after confirming that there is no access from the host side, the status of the error block is confirmed and an available replacement block is allocated (step 48). Next, data is restored from the disk device 31e to the alternate block (step 49). Further, the error block whose data has been restored is deleted from the error list 34b (step 50).

Then, it is checked whether there is another error block in the error list 34c, and if not, the process is terminated, and if there is, step 48
Return to continue processing.

In this embodiment, in order to prevent the recovery operation from being performed during the read process, the array disk device 3
0 can be transferred at high speed without interruption even when an error occurs, and the drive control unit 32i (i=a, b,
c, d, or e) can now automatically re-examine error blocks and allocate replacement blocks, and all data recovery can be performed using processing idle time without intervention from higher-level devices. It is possible to perform error recovery functions without increasing the load on the host device. Also, the drive control unit 32i (i=a
, b, C, ci, or e) and the array control unit 33, blocks in which data errors occur during data check are successively assigned to alternate blocks, and the array structure is kept the same. This further reduces the possibility of data errors occurring on the ring block,
It is possible to increase the probability that recovery can be performed using the disk device (parity disk) 31e and maintain high data reliability.

〔Effect of the invention 〕

As described above, in the present invention, when an error is found in a data check, the name of the data block in which the error location is located is stored in the error list, so that the error location can be identified even after the read processing is completed, and the error location is detected after the processing is completed. By allocating an empty block to replace a data block with an error part as a replacement block, the replacement block can be used in place of a data block with an error part, and data restoration can be easily performed.

Additionally, when restoring data, the data can be transferred from another disk device, such as a parity disk, and written to an alternate block, making it possible to restore the data within the scope of the array disk device's internal processing. This makes the restoration process easier.

Furthermore, by using a replacement block in place of a data block with an error location, processing using the restored data can be easily executed within the scope of the array disk device's internal processing, and the array disk device You can use free time to efficiently repair data with data check errors.

Then, the drive control unit 12 i (i = a, b.

...+n+P) is the data block with the error location in the error list 14i (i=a, b, -, n,
or p), it is possible to quickly create a record of the error block without affecting subsequent processing.

Furthermore, by the array control unit 13 writing the restoration data to the alternate block, the restoration process can be executed as an internal process of the array disk device, and the restoration process can be performed while the array control unit 13 is free. However, the utilization efficiency of the array control section 13 can be improved.

Furthermore, by causing the array control unit 13 to replace the data block with the restored data with the data block containing the error, block replacement can be executed as an internal process of the array disk device, and the array control unit 13 took advantage of his free time to change blocks,
Repairing data blocks with data check errors further increases the utilization efficiency of the array control unit 13, and
Since the array control unit 13 actively repairs data, it is possible to allocate data blocks in which errors occur to replacement blocks one after another, thereby reducing the possibility that further errors will occur on the same rotational block. High reliability of data can be maintained.

This makes it possible to eliminate the need for intervention by a host device in automatic recovery processing, improve processing efficiency, and maintain high-speed performance obtained by the array structure without degrading it due to data check errors.

[Brief explanation of drawings]

Fig. 1 is a diagram of the principle of the present invention (part 1), Fig. 2 is a diagram of the principle of the invention (part 2), Fig. 3 is a diagram of the device configuration of the invention, and Fig. 4 is a diagram of the embodiment. FIG. 5 is a process flow in the embodiment. FIG. 6 is a configuration diagram of a conventional device. 11...Array disks 11a, llb, llc, lid, lle...disk devices 12a, 12b, 12c. ...Drive control section 13...Array control sections 14a, 14b, 14c. ...Error list 12d. 14d. 2e 4e

Claims (7)

[Claims] (1) When a data check error is detected in the array disk device, the error list (14i (i=a, b, . . .
. . , n, or p)); and allocating a replacement block after processing is completed. 2. The method for automatically allocating alternate blocks in an array disk device according to claim 1, wherein data is restored from another disk device and written to the alternate block corresponding to the data block with the error location. (3) The error list (14i (i=a, b, . . .
, n, or p)) with an error location is replaced with a data restored replacement block. (4) Multiple disk devices (11i (i=a, b,...
. , n, p)) to configure one logical disk, each of the plurality of disk devices (11i (i=a, b, . . . , n, p)) An array control unit (13) that allocates data in predetermined recording units, and each disk device (11i (i=a, b,
..., n, or p)) and stores the position of the error block when a data error occurs.
, or p))) (12i (i=
A, b, . . . , n, p))). (5) The drive control unit (12i (i=a, b, . . .
, n, p)) is the error list (14i (i=a,
5. The automatic replacement block allocation apparatus in an array disk device according to claim 1, wherein the error location is stored in b, . . . , n, or p)). (6) The array control unit (13) restores data from another disk device and writes it into a replacement block corresponding to the data block with the error location. An automatic allocation device for alternate blocks in an array disk device according to . (7) The array control unit (13) restores the data of the data block containing the error location stored in the error list (14i (i=a, b, . . . , n, or p)). 7. The automatic replacement block allocation apparatus in an array disk device according to claim 3, wherein the replacement block is replaced with a replacement block.