JPH07281966A - Array type storage system - Google Patents

Abstract

PURPOSE:To detect the abnormality of an input/output device or a stand-by input/output device by performing a parole seeking operation in the processing idle time when the instructions given from a host device are not processed. CONSTITUTION:A deciding means 24 selects an input/output device 30 or a stand-by input/output device 31 via a subordinate device interface control part 26 in the processing idle time when a control means 23 is not processing the instructions which are given from a host device 10 via a host device interface control part 21. Then the means 24 decides whether the selected device 30 or 31 normally operates or not. If the means 24 decides the abnormality of the selected device, the information on the abnormality is notified to the device 10 as the preventive maintenance information which is stored in a preventive maintenance information storing register 25. Thus the abnormality of the device 30 or 31 can be detected.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an input / output control device for controlling an input / output device based on a command from a host device,
Particularly, it relates to improvement of control for monitoring the state of the input / output device.
With the recent demand for high reliability in computer systems,
Higher reliability is required in the I / O subsystem. Therefore, an input / output subsystem having a spare input / output device is provided. In this I / O subsystem, the spare I / O device is not normally used, but is used only when an abnormality such as a read error or a failure occurs in another active I / O device.

At this time, in order for the spare input / output device to operate normally and function as a spare input / output device, it is necessary to monitor the normality / abnormality of the spare input / output device in advance to check for a hard error or a read error. It is necessary for the input / output subsystem to have a means for providing preventive maintenance information such as the above to the host device.

[0003]

2. Description of the Related Art As an input / output control device for providing preventive maintenance information of a spare input / output device to a host device in place of an abnormal input / output device, an array type magnetic disk control device which is an array type storage device has been conventionally used. Are known. This array type magnetic disk control device has an interface control unit with a higher-level device, an interface control unit with a lower-level device, a processor and various registers, and has a plurality of data disk devices as a lower-level device and one parity disk device. And one spare disk device is connected and these are synchronously controlled. The array type magnetic disk controller reads data and parity in parallel from each of the plurality of data disk devices and the parity disk device, and inspects whether or not there is an abnormality in the data. During normal times when there is no abnormality in the data, the data is transferred to the host device as it is.

However, when it is detected that the data is abnormal, the array type magnetic disk device reads from the remaining normal data disk device and parity disk device other than the one disk device which has read the abnormal data. Based on the issued data and parity, correct data is restored and transferred to the host device.

When an abnormality such as a read error or a failure occurs more than a prescribed number of times in one of the data disk devices which are the current input / output devices or in the parity disk device for some reason, the remaining normal data disk is left at that stage. From the device and the parity disk unit, all the data written in the abnormal data disk unit or the abnormal parity disk unit is automatically restored to the spare disk unit, after which an error occurs as the current I / O device. By using it instead of the disk device, you can continue the required processing operations,
System down can be prevented.

[0006]

However, even if there is a hard error or a read error in the spare disk device itself, the higher level device does not understand it at all, and the spare disk device is replaced by the spare disk device for the first time. When used as an input / output device, a hard error or a read error of the spare disk device itself may be found, and the spare disk device may not function as a spare disk device.

Therefore, in an apparatus having a normal system composed of a plurality of units and a spare unit of the normal system unit, the same input signal as that of an arbitrary unit of the normal system is applied to the spare unit, and the spare unit and the above optional unit are provided. There is known a method of monitoring a spare unit by comparing both output signals of the above unit (Japanese Patent Laid-Open No. 56-7235).
No. 9). However, since this monitoring method requires the standby unit to be operated at the same time as the current working unit of the normal system, the above-mentioned input / output control device is equivalent to substantially increasing the number of input / output devices to be controlled. The load on the device is large.

Further, a system for monitoring an abnormality of the input control device according to a time monitoring time table (Japanese Patent Laid-Open No. 62-212).
No. 856) is also known, but this one does not monitor abnormality in the spare input / output device, nor does it utilize idle time for processing. Further, in a conventional apparatus in which a central processing unit (CPU) has a dual structure for working and protection, a monitoring system for running a software even in a CPU of a protection system to perform diagnosis in a form close to actual operation (Japanese Patent Laid-Open No. 2-93953). (Japanese Patent Laid-Open No. 62-900) and a standby system for diagnosing the CPU of the standby system at fixed intervals
No. 68) has been conventionally known. However, none of the above-mentioned monitoring methods of the device in which the CPU is duplicated uses the idle time of processing to monitor the spare CPU.

The present invention has been made in view of the above points, and an object of the present invention is to provide an input / output control device for monitoring the states of a standby input / output device and / or a current input / output device. . Another object of the present invention is to provide an input / output control device for monitoring the status of the spare input / output device and / or the active input / output device during processing idle time when the processing from the host device is not executed. To provide.

[0010]

According to a first aspect of the present invention, a storage device for storing a plurality of data, a storage device for storing parity data, a spare data storage device, and the plurality of data are stored. A storage device, a storage device for storing parity data, and a lower device interface control unit connected to the spare data storage device, and the lower device interface control unit is a channel interface for receiving a command issued by the upper device. A control unit, and a storage unit that stores the plurality of data and the parity that controls the read and write operations of the storage unit that stores the data based on a command input from the host device via the channel interface control unit. When the storage device for storing data is normal and no hard error or read error is found, A storage device that stores a number of data and a storage device that stores the parity data, and further stores another normal data when an error is detected and / or a storage device that stores the parity data; An array having an operation control unit for controlling the spare data storage device and a unit for performing a patrol seek operation when the operation control unit is not processing a command input from the host device via the channel interface control unit. It is a type memory system.

According to a third aspect of the present invention, a storage device for storing a plurality of data, a storage device for storing parity data, a spare data storage device, and a storage device for storing the plurality of data are provided. A storage device for storing parity data; and a lower device interface control unit stored in the spare data storage device, the lower device interface control unit having a channel interface control unit for receiving a command issued by the upper device, A read / write operation of a storage device that stores the data is controlled based on a command input from a higher-level device via the channel interface control unit, and the storage device that stores the plurality of data and the parity data are stored. When the storage device is normal and no hard or read errors are found, And a storage device for controlling parity data and a storage device for storing parity data when an error is detected, and / or a storage device and spare data storage for storing parity data. An operation control unit for controlling the device, and a storage unit for storing the plurality of data and a storage unit for storing the parity data when the operation control unit controls the read and / or write operation of the spare data storage unit. An array-type storage system having means for performing read and / or write operations.

[0012]

According to the first aspect of the present invention, when the operation control unit is not processing the command input from the host device via the channel interface control unit, the patrol seek operation can be performed to detect the abnormality.

According to a third aspect of the present invention, the spare data storage device is used when the operation control unit uses a storage device for storing data and a storage device for storing parity data to control read and / or write operations. Anomalies can be detected by executing the read and / or write operations of

[0014]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS In order to explain the present invention in more detail, the following description will be given with reference to the accompanying drawings. FIG. 1 shows the principle configuration of the present invention. In FIG. 1, the input / output control device 20 includes a host device interface control unit 21, an inspection unit 22, and a control unit 2.
3, determination means 24, preventive maintenance information storage register 25,
It has a lower device interface control unit 26 and a patrol timer register 27. The host device interface controller 21 receives the command issued from the host device 10. The lower device interface control unit 26 is connected to each of the plurality of input / output devices 30 and one spare input / output device 31. The inspection means 22 reads the data and the error detection code from the input / output device 30 in parallel, performs an error check using the read data and the error detection code, and inspects the normality of the data of the input / output device 30.

When the inspection result of the inspection means 22 indicates that the read data of all the input / output devices 30 is normal, the control means 23 selects only the input / output device 30 and outputs from the host device 10. I / O controller 3 according to the command
Controls 0 operation. Therefore, the spare input / output device 31 is not used at this time.

On the other hand, if the inspection result of the inspection means 22 is abnormal in the read data of one of the plurality of input / output devices 30 and exceeds the specified number, the lower device interface controller 26 From the data and error detection codes read from the remaining normal I / O devices other than the I / O device in which the error occurred, restore all the data written in the I / O device in which the error occurred, and then use the restored data for backup I / O. Write to device 31. Therefore, after that, the spare input / output device 31 is used as the active input / output device instead of the abnormality occurrence input / output device.

The determination means 24 enters via the lower device interface control section 26 during the processing idle time when the control means 23 is not executing the processing of the instruction input from the upper apparatus 10 via the upper device interface control section 21. The output device or the spare input / output device 31 is selected, and it is determined whether the selected input / output device 30 or the spare input / output device 31 operates normally.

When the determining means 24 determines that there is an abnormality, information about the abnormality is stored in the preventive maintenance information storage register 25. This is for notifying the higher-level device 10 later as preventive maintenance information. The processing idle time for which the judging means 24 makes a judgment is judged from the count value of the patrol timer register 27.

The determination means 24 is the spare input / output device 3
When the signal sent from the spare input / output device 31 indicates a hard error after writing of data to 1 or the seek operation, it is determined to be abnormal. Further, the judging means 24 reads data from the spare input / output device 31, and if the read data has a read error, it is judged as abnormal.

According to the input / output control device 20 having such a configuration, it is possible to detect the presence / absence of abnormality of the spare input / output device 31 by utilizing the processing idle time even when the spare input / output device 31 is not used. . Further, when the spare I / O device 31 has an abnormality, the preventive maintenance information from the preventive maintenance information storage register 25 is notified to the higher-level device 10, so that the higher-level device 10 performs the preventive input / output based on the preventive maintenance information. A hardware error or a read error of the device 31 itself can be confirmed.

Further, according to the input / output control device 20, it is possible to detect whether or not there is an abnormality in the input / output device 30 as well as the spare input / output device 31. In this case, the determination means 24 performs a seek operation on the input / output device 30, and then the input / output device 30.
When a hard error signal is input from, it is determined to be abnormal.

This input / output control device 20 is shown in FIG.
It is also possible to provide two sets as shown by 0 ₁ and 20 ₂ , share the host device 10 and share a plurality of logical devices 40 ₀ to 40 _N. Here, the logical devices 40 ₀ to 4
Each 0 _N comprises a plurality of input / output devices 30 and one spare input / output device 31.

According to this configuration, the input / output control device 20
₁ and 20 ₂ can simultaneously select and control different logical devices based on a command from the host device 10. Next, an example of FIG. 3 will be described. In the figure, the array type magnetic disk controller 60 corresponds to the input / output controller 20. The array type magnetic disk controller 60 includes a channel interface controller 61 corresponding to the upper device interface controller 21, an operation controller 62a, a determination controller 62b, a lower device interface controller 63 corresponding to the lower device interface controller 26, and a preventive device. Maintenance information storage register 64, patrol timer register 65
And a rotation synchronization control unit 66.

The operation control unit 62a is the inspection means 2 described above.
2. The determination control unit 62 is a circuit unit that constitutes the control unit 23.
Reference numeral b is a circuit portion which constitutes the above-mentioned determination means 24, and each is a processor 621, a control storage 622,
System reset timer register 623, operating time monitoring timer register 624, seek address register 62
5, a logical device address register 626, an error detection flag register 627, and a data transfer control unit 628.

The processor 621 controls the entire array type magnetic disk controller 60 of the micro program control system. The control storage 622 stores the instruction code of the processor 621 and is also used as a firmware control table.

The data transfer control unit 628 includes a channel interface control unit 61 and a lower device interface control unit 6.
3 to control data transfer to and from the device 3, generate parity of transfer data, and use it to generate a lower device interface control unit 6
Transfer to 3. The lower device interface control unit 63
It has disk control units 630 to 639 of 0 to # 9. Further, the channel interface control unit 61 has a control register group, and performs bidirectional data communication with the host device 50. The host device 50 is a central processing unit (CPU)
It is composed of. Further, the rotation synchronization control unit 66 synchronously rotates the magnetic disks of the ten magnetic disk devices in each of the logical devices 70 ₀ to 70 _N described later.

On the other hand, the disk control units 630-639 have N
+1 logical device 70₀~ 70 _NConnected to each
There is. Logical device 70₀~ 70_NHave the same configuration,
It is composed of ten magnetic disk devices 700 to 709. This
Of these, the magnetic disk devices 700-707 are data
Data is written in advance on the magnetic disk with the disk device.
In addition, the configuration is such that writing and reading are possible at will.
ing.

A magnetic disk device 708 is a parity disk device and is a magnetic disk for recording / reproducing (hereinafter,
A parity bit of the data written in the data disk devices 700 to 707 is written in the parity disk). Further, the magnetic disk device 709 is a spare disk device, and data or parity is not written to the magnetic disk for recording / reproducing (hereinafter referred to as a spare disk) at the initial stage. Logical device 70 ₀
At about 70 _N, only one logical device is controlled by the array type magnetic disk controller 60 at the same time.

The array type magnetic disk control shown in FIG.
Two control devices 60 are provided in parallel as shown in FIG.
And shares the host device 50 with the logical device 70.₀
~ 70 _NAre connected so that they can be controlled respectively. this
The array type magnetic disk controller 60 having the above-mentioned configuration
8 bytes of data based on the command from the unit 50
At the same time, write to the data disk devices 700-707
And the parity of those data is also
Disk device 708 to write and read them
Therefore, the data transfer speed is
Special feature that it can be faster than using a disk device.
There is a long.

Moreover, when it is found that a read error or a failure abnormality has occurred in any of the above nine disk devices 700 to 708 when an instruction from the host device 50 is executed, the disk device in which the abnormality has occurred is found. The contents are automatically restored in the magnetic disk subsystem from the data of the remaining eight normal disk devices, and the spare disk device 7
Since the restored data can be written in 09, there is a feature that the reliability is high.

For example, the data written on eight magnetic disks is D _{0 to} D ₇ , and the parity written on the parity disk of one parity disk device 708 is P _0. When an abnormality occurs in the magnetic disk 702, the unreadable data D ₂ is replaced with other data D ₀ , D that could be normally read.
Restore from ₁ , D _{3 to} D ₇ and parity P ₀ . When the data disk device 702 has malfunctioned more than the specified number of times, all the data written in the data disk device 702 is automatically transferred from the remaining eight normal disk devices in the magnetic disk subsystem. And write it to the spare disk.
A spare disk device 709 is used in place of 02.

In the input / output subsystem using the array type magnetic disk controller 60 as described above, the operation of each embodiment will be described which is mainly executed when the instruction from the host device 50 is not executed. First, the operation of the first embodiment of the present invention will be described with reference to FIG. In this embodiment, the system reset timer register 623, the operation time monitoring timer register 624, the seek address register 625,
The logical device address register 626 and the error detection flag register 627 are not used, and the spare disk device 7 is used.
Only the 09 patrol operation is executed. In FIG.
First, the processor 621 determines whether or not there is an instruction from the host device 50 (step 81). Here, when the host device 50 including the central processing unit (CPU) issues a command such as data write and read to one logical device via the array type magnetic disk controller 60, the array type magnetic disk controller 60 is Disk control unit 630-6
Data and parity are simultaneously written to and read from the nine magnetic disks of the disk devices 700 to 708 via 39.

That is, each time the processor 621 executes one instruction, it checks whether or not there is an instruction from the higher-level device 50 as shown in FIG. 4 (step 81). If the above instruction is detected, then the patrol operation is performed. Then, it is judged whether or not it is an instruction to the logical device in which the error is detected (step 82). Normally, since it is not, the command from the higher-level device 50 is executed (step 83) and the process returns to step 81.

Here, assuming that the data is, for example, 8 bytes, each 1-byte data is written through the disk control units 630 to 637 at the time of writing.
The data is output in parallel to 00 to 707, and the parity generated by the data transfer control unit 628 from these 8-byte data is output to the parity disk device 708 via the disk control unit 638. At the time of reading, the data and parity reproduced by the disk devices 700 to 708 are transferred to the data control transfer unit 6 via the disk control units 630 to 638.
28 is input.

On the other hand, if it is determined in step 81 that there is no command from the host device 50, it is determined whether or not interrupt processing is required for the host device 50 (step 84). For example, because of the command chain, it is determined whether or not interrupt processing such as interrupt processing for the higher-level device 50 based on the device end notification from the device after the end of seek is necessary.

If an interrupt is required, the interrupt process is executed on the host device 50 (step 85). If no interrupt is required, the patrol timer register 65 is read (step 86) and incremented (step 8).
7) Sequentially stores (step 88) and determines whether the value after the increment of the patrol timer register 65 exceeds a predetermined value (that is, a value corresponding to a specified time) (step 89). ). When it is determined in step 89 that the predetermined value is not exceeded, the process returns to step 81 again.

On the other hand, when it is determined in step 89 that the predetermined value is exceeded, the process proceeds to step 90, and the patrol operation is executed for the spare disk device 709 (step 90). Specifically, the processor 621 generates data of a specific pattern predetermined by itself and inputs it to the disk control unit 639 via the data transfer control unit 628, where the error detection code is converted into the specific pattern data. It is generated based on the above and is added to the data of the specific pattern. Then, the data of these specific patterns and the error detection code are used as the spare disk unit 639 in the logical device designated by the logical device address register 626.
Write to one track and read it.

The spare disk device 639 sends a hard error signal to the disk controller 639 when the patrol operation (read or write operation) is not normally performed. The data and error detection code read and output from the spare disk by the read operation are input to the data transfer control unit 628 via the disk control unit 639. The processor 621 determines whether or not the patrol operation has been normally completed depending on whether or not the hard error signal is input and whether or not there is an error in reading the read data or the like (step 91). When there is no error, the processor 621 determines that the process has ended normally and resets the error detection flag by the patrol operation in the control storage 622 (step 92).

On the other hand, when it is determined in step 91 that an error has occurred, the processor 621 collects detailed information of an error state such as a hard error such as a seek not normally completed or a read error and stores the preventive maintenance information. The data is stored in the register 64 (step 93) and the error detection flag by the patrol operation in the control storage 622 is set (step 94).

When the process of step 92 or 94 is completed, the process returns to step 81. Thereafter, similarly to the above, in the processing idle time when there is no command from the upper level device 50 (step 8
1) At every prescribed time determined by the patrol timer register 65 (steps 86 to 89), the above-mentioned specific pattern data and error are detected for one track of the spare disk of the spare disk device 709 of each logical device. Code writing and reading, error detection, etc. are performed (step 90).

When the above-mentioned writing and reading to the first one track of the logical device 70 _N are completed, then the above-mentioned specific pattern is applied to the next one track of the spare disk of the spare disk unit 709 of the logical device 70 _0. Data and error detection code are written and read, and error detection is performed. Thereafter, the same operation as above is repeated.

After that, when an instruction is issued from the upper level device 50 to the logical device to which the spare disk whose error is detected by the patrol operation belongs (step 8).
1, 82), the processor 621 reads the preventive maintenance information stored from the preventive maintenance information storage register 64, and sends it to the upper device 50 via the channel interface control unit 61, and an error of the spare disk device occurs. After notifying the information (step 95), the process returns to step 81.

Thus, according to this embodiment, when the spare disk unit 709 itself has a hard error or a read error, the array type magnetic disk controller 6 is used.
Based on the preventive maintenance information notified from 0, it is possible to perform repair or replacement in advance for a hard error or a read error of the spare disk device 709 itself. As a result, when the spare disk device 709 is used as a substitute for the disk device in which the abnormality has occurred, the spare disk device 709 can be used immediately.

Next, regarding the operation of the second embodiment of the present invention,
Description will be made with reference to the flowcharts of FIGS. 5 and 6. In this embodiment, not only the patrol operation for the spare disk device 709 but also the patrol operation for the data disk devices 700 to 707 and the parity disk device 708 which are the current input / output devices is executed. .

In FIG. 5, first, when the array type magnetic disk controller 60 is turned on, step 1 in FIG.
At 01, the power-on sequence is executed. By this power-on sequence, the above-mentioned various registers 64, 6
5, 623 to 627 are initialized. Also,
When the power is turned on, the logical devices 70 ₀ to 70 _N are turned on, and the spare disk device 709 is also turned on similarly to the other disk devices 700 to 708.

Subsequently, the processor 621 is the host device 50.
Whether there is an instruction from (step 10
2). Here, when the host device 50 including the central processing unit (CPU) issues a command such as data write and read to one logical device via the array type magnetic disk controller 60, the array type magnetic disk controller 60 is Disk device 70 via the disk control units 630-639
Data and parity are simultaneously written to and read from nine magnetic disks 0 to 708.

That is, each time the processor 621 executes one instruction, it checks whether or not there is an instruction from the host device 50 as shown in FIG. 5 (step 102). When the above instruction is detected, the patrol operation is performed next. Then, it is judged whether or not the instruction is to the logical device in which the error is detected (step 103). Normally, it is not, so after executing the instruction from the host device 50 (step 104) and initializing the operation time monitoring timer register 624 (step 10).
5) and returns to step 102.

On the other hand, when it is determined in step 102 that there is no command from the host device 50, it is determined whether the host device 50 needs interrupt processing such as control unit end (CU End) or device end. (Step 106). If interrupt is required, host device 50
Interrupt processing is executed for (step 107). If no interrupt is required, patrol timer register 65
Of the system reset timer register 623 (step 1)
09) are sequentially performed to determine whether the value of the system reset timer register 623 exceeds a predetermined value corresponding to 10 minutes (step 110), and whether the value of the patrol timer register 65 exceeds the predetermined value (that is, the specified value). It is sequentially determined whether or not the value corresponding to the time of 1 second has been exceeded (step 111). If neither of steps 110 and 111 exceeds the predetermined value, step 10 is performed again.
Return to 2. One second defined by the patrol timer register 65 is a logical device selection cycle, as will be described later, and this is a time determined by experience so as not to hinder the instruction processing from the host device 50. is there.

On the other hand, if it is determined in either of the steps 110 and 111 that the value exceeds the predetermined value, the process proceeds to step 112, and the hardware switch setting on the maintenance panel or the host device 50 is set. Command determines whether the patrol operation is prohibited. Step 1 if patrol operation is prohibited
02, on the other hand, in the normal case where the patrol operation is not prohibited, the mode for returning the control unit busy (Cu Busy) to the command from the upper device 50 is set (step 113), and then the patrol operation is executed. The contents of the logical device address register 626 are read (step 114) and the logical device is selected (step 115).

Then, it is judged whether the logical device is in a usable state (step 116). This is because even if the logical device is not powered on, the logical device is selected in step 115, so the processor 621 checks the status from the logical device to check whether the logical device is in the usable state. is there. When the logical device is in the usable state, it is determined whether the logical device is being used by another system (step 11).
7). That is, when two or more array type magnetic disk controllers 60 are used at the same time as shown in FIG. 2, the logical device is already in use by the array type magnetic disk controller of another system. This is because sometimes it cannot be used.

When the logical device is not in the usable state (step 116) or when the logical device is being used by another system (step 117), the selected state of the logical device is released (step 118) and the patrol is performed. The operation execution logical device address register 626 is incremented and stored (step 119). That is, the selection of the logical device is given up and the next logical device is selected. After that, the patrol timer register 65 and the operating time monitoring timer register 62
4 are initialized respectively (step 120), and step 10
Return to 2.

On the other hand, when the logical device is in a usable state and is not being used by another system (step 11).
6, 117), the process proceeds to step 121 in FIG. 6, and the physical devices (that is, the data disk devices 700 to 707 and the parity disk device 708) in the relevant logical device.
And the state of the spare disk device 709) is read (step 121).

Then, it is judged whether or not a command has been executed for the logical device within 20 seconds (step 122). Whether or not it is “20 seconds” is determined by whether or not the value of the operation time monitoring timer register 624 has reached a value (number of times) corresponding to 20 seconds. Further, the value of “20 seconds” itself is an empirical value and is not necessarily limited to this time.

When the command is not executed within 20 seconds, the patrol operation mode is set to the logical device mode (step 123). This logical device mode is a mode in which the current data disk devices 700 to 707 and the parity disk device 708 are used. When this mode is switched, the seek address register 625 for executing patrol operation is incremented next (step 124), and then each head of the above-mentioned logical device (that is, the disk devices 700 to 708) is temporarily fixed from the current position. A seek operation of moving the distance and returning to the original position is executed (step 125). This seek operation is a patrol seek operation, and if the head is left stationary at a certain position for a long time, dust adheres to the head and adversely affects the recording / reproducing operation. Therefore, it is possible to prevent dust from adhering to the head. To be done for.

When the above patrol seek operation is not normally completed, a hard error signal is sent from the disk device which is not normally completed to the corresponding disk control unit. Therefore, the processor 621 detects the presence / absence of an error from the presence / absence of this hard error signal (step 12).
6) When the error is detected, the process of step 138 described later is executed, and when the error is not detected, the process of step 140 described later is executed.

On the other hand, when it is determined in step 122 that the command has been executed within 20 seconds, it is confirmed whether the spare disk device 709 is in the operable state (standby state) (step 127), and then the patrol operation mode is set. To the physical device mode (step 128). This physical device mode is a mode in which only the spare disk device 709 is used. When this mode is switched, the seek address register 625 for executing the patrol operation is incremented next (step 129), and then the spare disk device 7 is used.
A seek operation is executed for 09 (step 130).

This seek operation is a seek operation performed in advance at the time of writing, and the seek operation in which the spare disk device 709 which is the object of this embodiment moves the head by a certain distance prior to the time of writing and the time of reading, respectively. This is because it is structurally necessary. However, this seek operation also prevents dust from adhering to the head as in the case of the patrol seek. If this seek operation is not normally completed, the spare disk device 709 causes the disk controller 6 to operate.
A hard error signal is sent to 39. Therefore, in the next step 131, when the hard error signal is input, it is determined that an error has occurred, and when the hard error signal is not input, it is determined that the error is normal.

If it is normal, the write operation of the data of the specific pattern and the error detection code is executed to the spare disk device 709 (step 132). When the above write operation is not normally performed, the spare disk device 639 sends a hard error signal to the disk control unit 639 as in the seek operation.
Reference numeral 21 checks whether or not an error has occurred based on the presence or absence of the input of this hard error signal (step 133). continue,
If there is no error, a seek operation prior to the read operation is executed for the spare disk device 134 (step 13
4), the above error detection code and data were written 1
After moving the head to the head position of the track, it is checked whether or not an error occurs by the presence or absence of a hard error signal (step 135), and if there is no error, a read operation is executed (step 136), and the above data and error Play the detection code.

If there is a hard error at the end of this read operation, a hard error signal is supplied to the disk controller 639. Further, the data and error detection code read and output from the spare disk by the read operation are input to the data transfer control unit 628 via the disk control unit 639. The processor 621 determines whether or not the hard error signal is input and whether or not there is a read error (step 137). When there is no error, the processor 621 determines that the process has ended normally and resets the error detection flag of the error detection flag register 627 (step 140).

On the other hand, steps 126, 131, 133,
When it is determined in 135 or 137 that an error has occurred, the processor 621 collects detailed information of an error state such as a hard error such as a seek not normally completed, or a read error, and the preventive maintenance information storage register 64.
(Step 138) and sets the error detection flag of the error detection flag register 627 (step 1
39).

When the processing in step 139 or 140 is completed, or in step 127, the spare disk device 709.
If it is determined that the device is not in a patrol-enabled state, the Cu Busy state is released (step 14).
1), after canceling the selected state of the current logical device in steps 118 to 120 of FIG. 4, the patrol operation completion logical device address register 626 is incremented to specify the next logical device, and the patrol timer register 65 and Operating time monitoring timer register 120
After initialization, the process returns to step 102.

Thereafter, similarly to the above, in the processing idle time when there is no instruction from the host device 50 (step 102), every prescribed time (normally 1 second) judged by the patrol timer register 65 (step 111), The writing and reading of the data of the specific pattern and the error detection code and the error detection are performed on one track of the spare disk of the spare disk device 709 of each logical device (steps 129 to 137).

When the above-mentioned writing and reading to the first 1 track of the spare disk unit 709 of the logical device 70 _N are completed, next to the next 1 track of the spare disk of the spare disk unit 709 of the logical device 70 _0. On the other hand, writing and reading of the above-mentioned specific pattern data and error detection code and error detection are performed. Thereafter, the same operation as above is repeated.

Here, when a logical device is selected after one second, the track on which data is written and read on the spare disk is not a track adjacent to the previous track but a track separated by a certain number of tracks. That is, the increment number of the seek address register 625 in step 129 is predetermined so that the recording surface of the spare disk is divided into a plurality of zones and the data is written in the representative track of each divided zone. As a result, the normality of the spare disk can be determined in a short time.

After that, when an instruction is issued from the higher-level device 50 to the logical device to which the spare disk in which an error has been detected by the patrol operation belongs (step 10).
2, 103), the processor 621 reads out the preventive maintenance information stored from the preventive maintenance information storage register 64, and sends it out to the higher-level device 50 via the channel interface control unit 61. After notifying the information (step 142), the error detection flag by the patrol operation in the error detection flag register 627 is reset (step 143), and step 102
Return to.

As a result, according to the present embodiment, not only when the spare disk device 709 itself has a hard error or a read error, but also when the current data disk devices 700 to 707 and the parity disk device are hard disks. Array-type magnetic disk controller 60 even if there is an error
Based on the preventive maintenance information notified from, it is possible to repair or replace the hardware error or the reading error in advance.

The present invention is not limited to the above embodiment, and for example, patrol timer register 65 is used.
The preventive maintenance information storage register 64 does not have to be hardware, and the processor 621 may execute a timer function by firmware or store the preventive maintenance information in the control storage 622.

[0068]

As described above, the input / output control device according to the present invention is connected to a plurality of input / output devices and one spare input / output device, and simultaneously controls a plurality of input / output devices. It is suitable for high-speed data transfer because it writes and reads data from the host device in parallel, and when monitoring the status of the spare input device and / or the current input / output device, It is possible to monitor the status of the spare input / output device and / or the active input / output device during the processing idle time when the processing of the instruction is not executed.

[Brief description of drawings]

FIG. 1 is a diagram showing a basic principle configuration of the present invention.

FIG. 2 is a diagram in which a host device and a plurality of logical devices are shared 2
It is a block diagram of the input-output control apparatus of a stand.

FIG. 3 is a configuration diagram of an embodiment of an input / output device according to the present invention.

FIG. 4 is an operation explanatory diagram of the first embodiment of the present invention.

FIG. 5 is a flowchart (No. 1) for explaining the operation of the second embodiment of the present invention.

FIG. 6 is a flowchart (part 2) for explaining the operation of the second embodiment of the present invention.

[Explanation of symbols]

 10 host device 20 input / output control device 21 host device interface control unit 22 inspection unit 23 control unit 24 determination unit 25 preventive maintenance information storage register 26 lower device interface unit 27 patrol timer register 30 input / output device 31 spare input / output device

Claims (4)

[Claims] 1. A storage device for storing a plurality of data, a storage device for storing parity data, a spare data storage device, a storage device for storing the plurality of data, and a storage device for storing parity data. A lower device interface control unit connected to the spare data storage device, the lower device interface control unit receiving a command issued by the upper device, and the upper device via the channel interface control unit. A read / write operation of a storage device that stores the data is controlled based on a command input from the device, and a storage device that stores the plurality of data and a storage device that stores the parity data are normal and a hard error and a read operation are performed. A storage device for storing the plurality of data when no error is detected; An operation control unit that controls a storage device that stores parity data and further controls a storage device that stores other normal data and / or a storage device that stores parity data and a spare data storage device when an error is detected. And an operation unit for performing a patrol seek operation when the operation control unit is not processing a command input from the host device via the channel interface control unit. 2. The operation control unit comprises a determination means for determining whether or not the next command is input within a predetermined time after the control of the plurality of data storage devices and the parity data storage device is completed, The means for performing the patrol seek operation performs the patrol seek operation only on the spare data storage device when the determination means determines when the next command is input within a predetermined time, 2. The array type storage system according to claim 1, wherein when it is determined that no command has been input, the patrol seek operation is performed including the plurality of data storage devices and the parity data storage device. 3. A storage device for storing a plurality of data, a storage device for storing parity data, a spare data storage device, a storage device for storing the plurality of data, and a storage device for storing parity data. And a lower device interface control unit stored in the spare data storage device, the lower device interface control unit receiving the command issued by the upper device, and the upper device via the channel interface control unit. A read / write operation of a storage device that stores the data is controlled based on a command input from the device, and a storage device that stores the plurality of data and a storage device that stores the parity data are normal and a hard error and a read operation are performed. A storage device for storing the plurality of data when no error is detected; An operation control unit that controls a storage device that stores parity data and further controls a storage device that stores other normal data and / or a storage device that stores parity data and a spare data storage device when an error is detected. And a read and / or write operation of the spare data storage device when the operation control unit controls a read and / or write operation using a storage device that stores the plurality of data and a storage device that stores parity data. An array type storage system comprising: means for executing. 4. The operation control unit comprises a determination means for determining whether or not the next command is input within a predetermined time after the control of the plurality of data storage devices and the parity data storage device is completed, The executing means executes the read and / or write operation only on the spare data storage device when the determining means determines that the next command is input within a predetermined time, and then executes the next command. 4. The array type storage system according to claim 3, wherein, when it is determined that no data has been input, the read and / or write operation is performed including the plurality of data storage devices and the parity data storage device. .