JPH11353128A - Magnetic disk drive - Google Patents

Abstract

PROBLEM TO BE SOLVED: To obtain the disk array device which has high fault tolerance by maintaining XOR operation data stored temporarily in a buffer memory etc. by providing a circuit which detects interface signal electric power decreasing for the magnetic disk drive with an XOR function. SOLUTION: Once electric power supply is switched from an AC fixed power source to a battery device by a leased signal line 35 from a power source switching unit, etc., and an interface 21, the device is powered down except a buffer memory 2, a microprocessor 36, a hard disk controller 37, a power source control part 38, a dedicated signal control part 39, and an interface control part 31. The powered-down part includes large-power-consumption places such as a spindle motor 40 and a magnetic head driving part 41. Further, the operation clock frequency of a microprocessor 36 is also decreased. Consequently, data including those in the buffer memory 2 can be maintained and the power consumption is greatly reduced.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a magnetic disk device which is a large-capacity direct access storage device of a computer, and a high-performance magnetic disk array device (also referred to as RAID) for connecting a plurality of magnetic disk devices.
The present invention relates to improving fault tolerance of a magnetic disk device having a built-in OR function.

[0002]

2. Description of the Related Art In recent years, a disk array device has been developed in which a plurality of small magnetic disk devices are combined to achieve higher fault tolerance and higher performance. In particular, using redundant data called parity data, even if one of the magnetic disk drives of a plurality of magnetic disk drives fails, the failure occurs using the user data and parity data recorded on the remaining magnetic disk drives. The function of restoring the data recorded on the magnetic disk device is effective in improving data integrity.

[0003] For disk array devices, PATT
ERSON et al., “ACASEFORREDUNDANT
ARRAY OF INEXPENSIVE DIS
KS (RAID) ", REPORT NO. UCB / C
SD87 / 391, COMPUTER SCIENCE
DIVISION, UNIVERSITY OFCA
LIFORNIA, BERKELEY, 1987. ", And an article on pages 102 to 103 of Nikkei Electronics, published April 26, 1993.

An XOR operation (exclusive OR operation) is used to generate parity data. Here, the function of executing the XOR operation is called an XOR function. That is, XO
The R function is to take out two of the data recorded in each of a plurality of magnetic disk devices, perform an XOR operation, and combine the result with another data recorded in another magnetic disk device. This is a function of obtaining the parity data by further repeating the XOR operation.

[0005] Disk array devices are classified into the following three types according to the execution part of the XOR function.

(1) The host computer has the XOR function. (2) The dedicated controller has the XOR function. (3) The XOR function is provided inside the magnetic disk device. Here, the magnetic disk device having the XOR function described in (3) above Let's take up a disk array device that uses.

In general, a recent magnetic disk device has a volatile temporary data storage section called a buffer memory, and an XOR operation is also performed on data in the buffer memory. Since the buffer memory is volatile, data is lost when the power is turned off.

[0008] X in a magnetic disk drive with an XOR function
An outline of the operation of the OR function will be described. Here, an operation at the time of data writing will be described with reference to FIG. 1 based on a SCSI interface command specified by ANSI (American National Standards Institute).

XD issued from host computer 4
The WRITE command 11 is sent to the first magnetic disk device 1 together with the write data 12. The write data 12 is temporarily stored in the buffer memory 2 inside the magnetic disk device. The corresponding old user data 9 is read from the magnetic disk 3, and an XOR operation 5 is performed with the write data 12 on the buffer memory 2. The XOR data 13 resulting from the operation is sent to the next magnetic disk device 6 through the interface. The write data 12 is magnetically recorded on the magnetic disk 3 from the buffer memory 2.

If the next magnetic disk device 6 is a parity disk, the transmitted XOR data 13 from the adjacent magnetic disk device 1 is temporarily stored in the buffer memory 2 and is stored in the buffer memory 2 with its own old parity data 7. XOR between
Operation 5 is performed. The calculation result is magnetically recorded on the magnetic disk 3 as new parity data 8 by replacing the old old parity data 7.

Referring to FIG. 2, a case where the next magnetic disk device 6 is a user disk for recording user data will be described. In this case as well, the operation of the first magnetic disk device 1 is the same as that of FIG. 1, but the next magnetic disk device 6 transmits the XOR data 13 from the adjacent magnetic disk device 1 that has been sent.
Is temporarily stored in the buffer memory 2 and an XOR operation 5 is performed with the old user data 9 of the buffer memory 2 itself. The new XOR data 14 resulting from the operation is sent to the next magnetic disk device 15 via the interface.

In the same manner, this operation is repeated for the number of connected magnetic disk devices. Finally, the parity data of the parity disk device 16 is updated, and the process is terminated.

[0013]

In these processes, an XOR operation is performed via a volatile memory such as a buffer memory and necessary registers inside each magnetic disk device. Therefore, if the power is turned off without a prediction of a power failure or the like, data temporarily stored in a nonvolatile memory such as a buffer memory may be lost.

In the case where the dedicated controller has the XOR function (the second item), a battery device is built in the controller to take measures to prevent data loss. However, when using the magnetic disk device with the XOR function, such a battery device or the like is not prepared.

Recently, the capacity of the buffer memory is several MB.
The capacity has never been larger, and data integrity in the buffer memory has become a serious problem.

It is an object of the present invention to provide a disk array device having a high fault tolerance by preserving XOR operation data temporarily stored in a buffer memory or the like in a magnetic disk device having an XOR function. It is to provide.

[0017]

In order to achieve the above object, according to the present invention, a magnetic disk drive having an XOR function is provided with a circuit for detecting a decrease in interface signal power. Alternatively, a dedicated signal line for detecting a power abnormality is provided. In addition, a battery device or the like is provided on a path for supplying power to the magnetic disk device. Further, after detecting a power abnormality, a function for minimizing power consumption related to functions other than data security such as a volatile buffer memory is added.

That is, according to the present invention, the magnetic disk device with the XOR function is always backed up by a battery or the like together with the AC fixed power supply. If the AC fixed power supply is cut off due to some kind of failure, it is detected that the power of the interface signal or the dedicated signal line from the host computer has dropped, and the portion other than the portion related to the data temporarily stored in the volatile buffer memory or the like is detected. To cut the power consumed.
Since a backup power supply such as a battery has a limited power supply capability, the load is reduced as much as possible to extend the battery power supply time. Here, the portion where the electric power is cut off includes a spindle motor for rotating a disk, a voice coil motor for driving a magnetic head, and the like.

In general, a magnetic disk device has a relatively large power consumption because it has a mechanical drive portion. However, if only a portion related to a buffer memory or the like is used, the power consumption is small.
The operation time of a battery or the like that is backed up from the outside can be extended.

[0020]

Embodiments of the present invention will be described below with reference to the drawings.

FIG. 3 shows a hardware configuration of a disk array device 26 using the magnetic disk device 1 with the XOR function according to the present invention. The magnetic disk device 1 shown here is connected to a host computer 4 by a fiber channel (FC-AL) interface 21. However,
The logical instruction system conforms to the SCSI standard. The plurality of magnetic disk devices 1 including the host computer 4 are mutually connected in a loop form.

The magnetic disk drive 1 is supplied with power from a power supply 23 connected to an AC fixed power supply 22, a battery 24 and a power supply switching device 25. These devices are collectively referred to as a disk array device 26.
When there is a malfunction in the AC fixed power supply 22 and the power supply device 23, the power supply is switched to the battery device 24.

FIG. 4 shows the internal hardware configuration of the magnetic disk drive 1 with the XOR function according to the present invention. Data from the host computer or the adjacent magnetic disk drive
The data enters the interface control unit 31 via the fiber channel (FC-AL) interface, and is temporarily stored in the buffer memory 2. Thereafter, the data is recorded on the magnetic disk 3 by the magnetic head 33 via the data signal processing unit 32. If it is detected by the dedicated signal line 35 from the power supply switching device or the like and the interface 21 that the power supply is switched from the fixed AC power supply to the power supply by the battery device, the buffer memory 2, the microprocessor 36, the hard disk controller 37, the power supply control unit 38, dedicated signal control unit 3
9. Power other than the interface control unit 31 is cut off.
The parts to be cut include high power consuming parts such as the spindle motor 40 and the magnetic head driving unit 41. Further, the operation clock frequency of the microprocessor 36 is also reduced.

As a result, in the disk array using the magnetic disk device with the XOR function, the data including the buffer memory 2 can be maintained, and the power consumption can be greatly reduced.

To return from the power saving state to the normal state, a dedicated signal line 35 from the power supply switching device 25 and
The recovery of the power supply state is detected by the interface signal line 34, and the power and control of each of the above components are returned to the normal state under the control of the microprocessor 36.

FIG. 5 is a flowchart showing the flow of the control.

[0027]

According to the present invention, even when the power supply is stopped due to a power failure, the temporarily stored data in the volatile buffer memory built in the magnetic disk device can be economically obtained in cooperation with the battery device or the like. Can be maintained. In particular, by stopping the functions of high power consumption parts such as the spindle drive unit and the head drive unit of the magnetic disk drive, there is an effect of extending the buffer memory retention time of the battery device.

[Brief description of the drawings]

FIG. 1 is an explanatory diagram showing the operation of two magnetic disk devices with an XOR function.

FIG. 2 is an explanatory diagram showing the operation of four magnetic disk devices with an XOR function.

FIG. 3 is a hardware configuration diagram of the disk array device of the present invention.

FIG. 4 is an internal hardware configuration diagram of the magnetic disk drive with the XOR function of the present invention.

FIG. 5 is a flowchart showing a control flow of the magnetic disk drive with the XOR function of the present invention.

[Explanation of symbols]

DESCRIPTION OF SYMBOLS 1 ... Magnetic disk drive, 2 ... Buffer memory, 3 ... Magnetic disk, 4 ... Host computer, 5 ... XOR operation,
6 ... Next magnetic disk device, 7 ... Old parity data, 8 ... New parity data, 9 ... Old user data,
10: New user data, 11: XDWRITE instruction,
12 ... write data, 13 ... XOR data, 14 ...
New XOR data, 15 ... More magnetic disk unit,
16 parity disk device, 21 fiber channel (FC-AL) interface, 22 fixed AC power source, 23 power supply device, 24 battery device, 25 power supply switching device, 26 disk array device, 31 interface control unit 32, a data signal processing unit, 33, a magnetic head, 35, a dedicated signal line, 36, a microprocessor, 37, a hard disk controller, 38, a power control unit, 39, a dedicated signal control unit, 40, a spindle motor, 41, magnetic Head drive unit.

Claims (6)

[Claims] In a magnetic disk drive having an XOR function, a circuit for detecting a power stop of an interface signal is provided. By detecting the power stop, data stored in a volatile buffer memory built in the magnetic disk drive can be read. A magnetic disk drive characterized by security. 2. The magnetic disk device according to claim 1, wherein data stored in a volatile buffer memory built in the disk device is preserved by a battery device or an uninterruptible power supply device. 3. A magnetic disk according to claim 1, wherein power consumption of a function other than data security such as a volatile buffer memory is minimized by detecting a power stop of an interface signal. apparatus. 4. The magnetic disk drive according to claim 1, wherein data stored in a volatile buffer memory built in the disk drive is preserved by detecting power stoppage by a dedicated signal line. Magnetic disk drive. 5. The magnetic disk drive according to claim 1, wherein the magnetic disk drive is a magnetic disk array device using a magnetic disk drive. 6. A magnetic disk drive according to claim 1, further comprising a magnetic tape device or an optical disk device.