JP2005310186A - Storage system - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a portable medium-based storage system by solving a problem wherein it is desirable to install a storage medium group sharing redundant data in an easily recognizable location in order to facilitate maintenance in a storage system having the redundant data, but a copy-back processing having high overhead is necessary in replacing a disk device due to a failure or the like, in a conventional disk array. <P>SOLUTION: This storage system based on a portable medium is so structured that a new storage medium is moved, by using a robot in the storage system, to an installation part highly relevant with a storage medium belonging to a storage medium group sharing the redundant data with the new storage medium. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention relates to a highly available storage system for portable storage media. In particular, the present invention relates to a storage device system in which each component has redundancy in order to improve availability.

  As a known example closest to the invention, Non-Patent Document 1 shown below is known.

  Non-Patent Document 1 discloses a technique related to data arrangement on a disk array.

  The disk array is a mechanism for realizing high performance and high reliability of the disk system. In the disk array, a plurality of disk devices are physically made to appear as a single disk device to a processing device for high performance. On the other hand, for high reliability, when a failure occurs in a disk device that stores data, redundant data for data recovery is stored in another disk device.

  Normally, data serving as a read / write unit of a disk device is called a record, but Non-Patent Document 1 proposes several record arrangement methods. However, when a disk array is used, the data length may differ between a record that is a read / write unit viewed from the processing device and a record that is actually recorded on the disk device. Hereinafter, the former is called a logical record and the latter is called a physical record. Hereinafter, some record arrangement methods proposed in Non-Patent Document 1 will be described.

  The first arrangement method is an arrangement method in which a logical record, that is, a record viewed from the processing device side is divided into m physical records (m ≧ 1) and stored on the disk device. Hereinafter, this arrangement method is referred to as a divided arrangement method. When the divided arrangement is used, since one logical record can be transferred to m disk devices, it is possible to obtain the same effect as apparently improving the data transfer speed m times.

  Next, a method for creating redundant data in the divided arrangement will be described. In the divided arrangement, n (n ≧ 1) redundant data is created for m physical records obtained by dividing a logical record, and each of them is stored as one physical record (n in total) in the disk device. To do. Hereinafter, a physical record that stores data that is directly read / written by the processing device is referred to as a data record, and a physical record that stores redundant data is referred to as a parity record. A group composed of m data records and n parity records is called a parity group. Normally, if the number of parity records in a parity group is n, data in that parity group can be recovered even if a failure occurs in up to n disk devices. Since a disk device normally includes a plurality of records, one disk device includes records belonging to a plurality of sets of parity groups. Here, m + n disk devices each including a plurality of parity groups each composed of m + n records are referred to as a disk parity group. That is, the disk parity group is a set of disk devices that share redundant data.

  The second arrangement method is an arrangement method in which a logical record that is a read / write unit viewed from the processing device is stored on the disk device as one physical record, that is, one data record. Hereinafter, this is called non-divided arrangement. Therefore, a logical record is equivalent to a data record. (Because a data record or a parity record is assigned to each physical record, the physical record and the logical record are not necessarily equivalent. That is, one logical record is one physical record, but one physical record is (It is not a single logical record but may be a parity record.) The feature of the non-divided arrangement is that read / write processing can be executed for each disk device constituting the disk array. . (If the divided arrangement method is used, it is necessary to occupy a plurality of disk devices for reading / writing.) Therefore, the non-divided arrangement improves the multiplicity of read / write processing that can be executed in the disk array. It is possible to improve the performance. Even in the non-divided arrangement, n parity records are created from m data records and stored in the disk device. However, in the case of divided arrangement, the set of data records in the parity group forms one logical record as seen from the processing device, whereas in the case of non-division arrangement, each of the data records is viewed from the processing device. , It becomes a completely independent logical record.

  Patent Document 1 discloses a technique related to a spare disk in a disk array. In a disk array, when a failure occurs in a disk device, it can be recovered using redundant data. To this end, a new disk device is required. The spare disk is an unused disk device provided in advance in the disk array. Therefore, when a failure occurs in the disk device, the data recovered using the redundant data can be immediately stored in the spare disk.

In a computer system, there are a magnetic tape, an optical storage device, etc. as a storage device often used in addition to a disk device. Recently, DVD (Digital Video Disk) has attracted attention. The features of these storage devices are that the storage medium and R / W (Read / Write) device are separated, and the storage medium is loaded into an arbitrary R / W device, and the data on the storage medium is read and written. It is a point to do. In general, these media are called portable media. In a large-scale computer system, a library is introduced in order to easily manage a very large number of portable media. In addition to the storage medium and the R / W device, the library includes a storage that stores a large number of storage media, and a robot that transfers the storage medium between the storage and the R / W device. .

  Since the data handled by a computer system is becoming larger and larger, the need for improving its availability is very high. Therefore, it is effective to realize high availability by applying the concept proposed in Non-Patent Document 1 even in the storage device system configured by the portable medium as described above.

  There is Non-Patent Document 2 as a technique in which such a concept is applied to a portable medium. Non-Patent Document 2 proposes RAIL (Redundant Arrays of Inexpensive Libraries) having redundancy by combining a plurality of ordinary libraries composed of DVDs, R / W devices, robots, and the like.

U.S. Pat. No. 4,914,656 Outside D.Patterson, A Case for Redundant Arrays of Inexpensive Disks (RAID), A. Sea. M. ACM SIGMOD conference proceeding, June 1988, pages 109-116 Alan E. Bell, Comdex 96: DVD Applications (DVD Applications COMDEX 96), November 20, 1996

  As disclosed in Patent Document 1, in a disk array, when a failure occurs in a disk device, data recovered using redundant data is stored in a spare disk.

  After this, a maintenance engineer or the like replaces the failed disk with a new disk. To simplify the operation of the disk array, a set of disk devices belonging to the same disk parity group (redundant disk) is used. It is desirable that the set of disk devices sharing the data can be easily recognized. This is because, for example, if a disk device belonging to the same disk parity group is mistakenly removed from the disk parity group, the data stored in the disk parity group is deleted. This is because access to the data becomes impossible. In order to avoid this, copy back processing is required to return the data stored in the spare disk to the newly replaced disk device. However, this copy-back process requires a large transfer amount because it is necessary to transfer data of the entire disk.

  Similar problems also occur in a storage system based on portable media.

  An object of the present invention is to make use of the characteristics of a portable medium in a storage system based on a portable medium, and to perform switching processing to a new storage medium in the event of a storage medium failure, as compared with the prior art. It is to provide a technology that performs efficiently.

  How the above-described problems are achieved in the present invention will be described.

  In the conventional disk array, when a disk failure occurs, the recovery process is not started by putting a new disk in the installation location of the failed disk and using the spare disk before that. Start. The reason for this is that the physical replacement of the disk requires manual maintenance such as maintenance personnel, so the recovery process is started after the physical replacement. This is because the time during which is operated becomes longer. That is, there is a problem in availability.

  In the present invention, the portability, which is a feature of the portable medium, is used. First, a spare storage medium is prepared in a storage warehouse in the storage device system. When a failure occurs in the storage medium, a spare storage medium is loaded into the R / W device using a robot in the storage device system. Furthermore, a storage medium necessary for recovering data stored in the storage medium in which the failure has occurred is also loaded into the R / W device. Thereafter, using these storage media, the data stored in the failed storage medium is recovered and stored in a spare storage medium. After the recovery process is completed, the robot is used to store the spare storage medium in the storage location in the storage warehouse in which the storage medium in which the failure occurred has been stored. Of course, the spare storage medium may be stored in a storage location in the storage warehouse where the failed storage medium has been stored before the recovery process is started.

  As a result, the new storage medium can be transferred to the storage location in the storage warehouse where the failed storage medium has been stored before, without the need for human intervention and without performing high-load processing such as copy-back processing. Can be stored. That is, even if a failure occurs, a set of storage media that share redundant data can be efficiently stored in a highly relevant storage location in the storage warehouse.

  In a storage system having redundant data, it is desirable to install it in a place where a storage medium group sharing redundant data can be easily recognized in order to facilitate maintenance.

  In the present invention, in a storage system based on a portable medium, a new storage medium is shared by using a robot in the storage system, and the storage medium group that shares redundant data with the storage medium. Move to an installation location highly relevant to the storage medium belonging to. As a result, even if the storage medium is replaced due to a failure, the shared storage medium group can be efficiently installed in a place where it can be easily recognized.

  Embodiments of the present invention will be described below with reference to the drawings. The present invention is not limited to this embodiment.

  First, contents common to the embodiments will be described.

  FIG. 2 shows the configuration of a computer system that is an object of the present invention. The computer system includes a processing device 1300, a control device 1305, two or more R / W devices 1304, two or more storage warehouses 1306, and one or more robots 1307. The processing device 1300 may be configured by a CPU 1301, a main memory 1302, and a channel 1303. The control device 1305 executes transfer processing between the processing device 1300 and the disk device 1304 in accordance with a read / write request from the processing device 1300. The control device buffer 1310 is a buffer that temporarily stores data read and written by the control device 1305.

  The storage warehouse 1306 stores a plurality of physical storage media 1311 storing data. The robot 1307 carries the physical storage medium 1311 between the storage warehouse 1306 and the R / W device 1304. The R / W device 1304 reads / writes the physical storage medium 1311 set by the robot 1307.

  FIG. 3 shows the configuration of another computer system that is the subject of the present invention. The difference from the configuration illustrated in FIG. 2 is that the control device 1305 includes a cache memory 1308, a directory 1309, a nonvolatile memory 1400, and nonvolatile memory management information 1401. A cache memory (hereinafter simply abbreviated as “cache”) 1308 stores a part of data of the physical storage medium 1311 set in the R / W device 1304. The directory 1309 stores management information of the cache 1308. The non-volatile memory 1400 is a non-volatile medium, and stores a part of data of the physical storage medium 1311 set in the R / W device 1304 in the same manner as the cache 1308. The nonvolatile memory management information 1401 is also a nonvolatile medium, and stores management information of the nonvolatile memory 1400. In this case, the control device 1305 executes a read / write operation between the R / W device 1304 and the cache 1308 asynchronously with the read / write request from the processing device 1300. However, as shown in FIG. 7, a configuration in which two or more directors 1312 are included in the control device, and each director 1307 receives a read / write request from the processing device 1300 and executes a read / write operation. The present invention is effective.

  Usually, the unit of data read / written by the processing device 1300 with the disk device is called a record. However, in the present invention, the record viewed from the processing device 1300 and the record stored on the physical storage medium 1311 may differ depending on the record arrangement of the disk array. The data recording format when the disk array is applied will be described below.

  Next, the recording format of the physical storage medium 1311 in this embodiment will be described with reference to FIGS. 4, 5, and 6. The logical storage medium 400 is a single storage medium viewed from the processing device 1300. On the other hand, the physical storage medium 1311 is a single storage medium as described above, and is a storage unit of the storage warehouse 1306, a transport unit of the robot 1307, and a set unit of the R / W device 1304. In the configuration of FIG. 4, m + n physical storage media 1311 are a single logical storage medium 400. As shown in FIG. 5, the logical record 401 is a record that is read / written from the processing apparatus 1300. On the other hand, as shown in FIG. 6, a unit that is read / written between the R / W device 1304 and the control device 1305, that is, a unit recorded in the physical storage medium 1311 is referred to as a physical record 1502. In the present invention, there are two types of physical records 1502 stored on the physical storage medium 1311: a data record 1500 and a parity record 1501. The data record 1500 is a physical record 1502 that stores the contents of the logical record 401. On the other hand, the parity record 1501 is a record used for processing for recovering the lost content when the physical storage medium 1311 fails and the content of the data record 1501 is lost. In this case, if the value of the data record 1500 is changed, the content of the parity record 1501 needs to be changed accordingly.

  The storage medium parity group 1610, the record parity group 1600, and the spare storage medium 600 according to this embodiment will be described with reference to FIG. In the configuration illustrated in FIG. 6, the storage medium parity group 1610 corresponds to m + n physical storage media 1311 corresponding to one logical storage medium 400.

  Next, the record parity group 1600 will be described. Corresponding data records 1500 are stored on m physical storage media 1304 from physical storage media a1601 to physical storage media d1604 constituting a set of storage media parity groups 1610, respectively. From these m data records 1500, n parity records 1501 are created and stored in the corresponding physical storage medium e1605 to physical storage medium f1606, respectively. Therefore, in FIG. 6, a record parity group 1600 is composed of m data records 1500 and n parity records 1501. In general, in a record parity group 1600 including n parity records 1501, n physical storage media among m + n physical storage media in which the physical records 1502 in the record parity group 1600 are stored. Even if 1311 fails, the contents of all physical records 1502 in the record parity group 160 can be recovered. As described above, high reliability of the physical storage medium 1311 can be realized. Of course, each physical storage medium 1311 includes a plurality of physical records 1502, and one parity group storage medium 1610 has a plurality of parity group records 1600.

  On the other hand, when a failure occurs in the physical storage medium 1311, the spare storage medium 600 is used to store data stored so far in the physical storage medium 1311 in which the failure has occurred. That is, the spare storage medium 600 is a physical storage medium 1311 that does not belong to the storage medium parity group 1610 in a normal state. Further, when a failure occurs in the physical storage medium 1311 included in the storage medium parity group 1610, the spare storage medium 600 is included in the storage medium parity group 1610 instead of the physical storage medium 1311. become. Data stored in the failed physical storage medium 1311 can be recovered using another physical storage medium 1311 in the storage medium parity group 1610 including the failed physical storage medium 1311. .

  Further, as shown in FIG. 8A, a plurality of logical storage media 400 may correspond to a set of parity group storage media 1610. In the present invention, as shown in FIG. 8B, a plurality of sets of parity group storage media may correspond to one logical storage medium 400.

FIG. 9 shows an R / W device parity group 900 and a logical R / W device 901. The parity group 900 includes m + n R / W devices 1304 and is loaded with a set of parity group storage media 1610. In the present embodiment, it is assumed that one or more R / W device parity groups 900 are connected to the control device 1305. On the other hand, the logical R / W device 901 is a logical device that executes R / W processing as viewed from the processing device 1300, and is loaded with the logical storage medium 400. As shown in FIG. 9A, when one storage medium parity group 1610 corresponds to one logical storage medium 400, or one storage medium parity group 1610 corresponds to a plurality of logical storage media 400. When it corresponds, it corresponds one-to-one with the R / W device parity group 900. On the other hand, as shown in FIG. 9B, when a plurality of storage medium parity groups 1610 correspond to one logical storage medium 400, the logical R / W device 901 includes a plurality of R / W device parity groups. 900.

  FIG. 10 shows the configuration of the storage warehouse 1306. The storage warehouse 1306 has a plurality of slots 1000, an inlet 1001, and an outlet 1001. The slot 1000 is a unit for storing one physical storage medium 1311. The input port 1001 is an entrance for inputting a new physical storage medium 1311 to the storage warehouse 1306. Conversely, the discharge port 1002 is an outlet for discharging the physical storage medium 1311 that has caused a failure or the like from the storage warehouse 1306. Of course, the present invention is effective even when the inlet 1001 and the outlet 1001 are combined into one port. Furthermore, the present invention is effective even when the storage warehouse 1306 does not have the input port 1001 and the discharge port 1001.

  FIG. 11 shows a slot parity group 1100, a logical slot 1101, and a spare slot 1102. The slot parity group 1100 is a set of m + n slots 1000 storing m + n physical media 1311 belonging to one storage medium parity group 1610. In the configuration shown in FIG. 11, the slot 1000 belonging to the slot parity group 1100 is the slot 1000 in one storage warehouse 1306. However, of course, the present invention is effective even when two or more slots 1000 belonging to one slot parity group 1100 are included in the same storage warehouse 1306. Alternatively, it is effective that all slots 1000 belonging to one slot parity group 1100 are included in different storage warehouses 1306.

  The spare slot 1102 is a slot 1000 for storing the spare storage medium 1311. Furthermore, the physical storage medium 1311 may not be stored and may be in an empty state. Further, the physical storage medium 1311 that has failed may be stored. In particular, if there is no outlet 1102 in the storage warehouse 1306, the failed physical storage medium 1311 is stored in the spare slot 1311 in principle.

  The logical slot 1101 is a logical storage unit that stores the logical storage medium 400 viewed from the processing device 1300. When the storage medium parity group 1610 corresponds to one logical storage medium 400, the logical slot 1101 corresponds to the slot parity group 1100 on a one-to-one basis as shown in FIG. On the other hand, when the storage medium parity group 1610 corresponds to a plurality of logical storage media 400, the slot parity group 1100 corresponds to a plurality of logical slots 1101, as shown in FIG. Further, as shown in FIG. 11C, when a plurality of storage medium parity groups 1610 correspond to one logical storage medium 400, a logical slot 1101 corresponds to a plurality of slot parity groups 1100. The spare slot 1102 is described only in (a), but it is assumed that the storage warehouse 1306 also includes the spare slots 1102 in the configurations of (b) and (c). In the configurations of (b) and (c), the meaning of the spare slot 1102 is the same as that already shown, and does not change.

  In each embodiment described below, a case where the storage medium parity group 1610 corresponds to one logical storage medium 400 will be described. Of course, the present invention is also effective when the storage medium parity group 1610 corresponds to a plurality of logical storage media 400.

  FIG. 1 shows the configuration / operation of the first embodiment.

  As information regarding the first embodiment, the control device 1305 includes the spare slot state 100 in the control device buffer 1310, the directory 1309, the nonvolatile memory management information 1401, and the like.

  The spare slot state 100 is information corresponding to the spare slot 1101. In the spare slot state 100, whether the spare storage medium 600 is stored in the corresponding spare slot 1101, whether the failed physical storage medium 1311 is stored, or the physical storage medium 1311 is not stored. Represents.

  The main functions of the director 1312 in the control device 1305 are a recovery process mount unit A113, a recovery process R / W unit A114, and a recovery process demount unit A115.

  The recovery processing mount unit A113 has a function of determining that data recovery processing of the physical storage medium is executed when a failure occurs in the physical storage medium 1311. The processing flow will be described below.

  In step 150, the control device 1305 loads another physical storage medium 1311 including the failed physical storage medium 1311 into the R / W device 1304 using the robot 1307. In step 151, the control device 1305 refers to the spare slot state 100 and loads the spare storage medium 600 stored in the spare slot 1102 into the R / W device 1304 using the robot 1307. In step 152, the control device 1305 sets the corresponding spare slot state 100 to a state in which the physical storage medium 1311 is not stored. Thereafter, the control device 1305 may execute Step 170. However, the specific description of step 170 will be made in the recovery processing demount unit A115. In step 153, a request is made to execute recovery processing. In response to this, the execution of the recovery process R / W unit A114 is started.

  In the above processing flow, the control device 1305 transports the spare storage medium 600 from the spare slot 600 to the R / W device 1304. However, the spare storage medium 600 is first used as a physical storage medium in which a failure has occurred. It may be transported to the slot 1000 in which 1311 is stored and then transported to the R / W device 1304. When the above method is adopted, the process of transporting the failed physical storage medium 1311, that is, the process corresponding to step 170, the spare storage medium 600 is first performed on the failed physical storage medium 1311. Needless to say, it is necessary to execute the process of transporting to the slot 1000 in which the card is stored.

  The recovery processing R / W execution unit 114 has a function of executing data recovery processing of the physical storage medium when a failure occurs in the physical storage medium 1311.

  In step 160, the control device 1305 executes partial area recovery processing. In step 161, the control device 1305 checks whether the recovery processing for all areas has been completed. If completed, the control device 1305 activates the recovery demount execution unit 115 in step 162. If not completed, the process returns to step 160 to perform the next recovery process. Note that step 170 may be executed before returning to step 160. However, the specific description of step 170 will be given in the recovery processing demount unit 115. In step 163, the control device 1305 requests execution of the demount process. In response to this, the execution of the recovery processing demount unit A115 is started. However, the demount process need not be performed immediately after the recovery process is completed. This is because there is a possibility that the processing device 1300 has made a use request to the storage medium parity group 1610 that is performing the recovery process.

  The recovery process demount unit A115 has a function of executing a process of returning each physical medium 1311 to the slot 1000. In step 170, the control device 1305 uses the robot 1307 to discharge the storage medium 1311 that has failed from the storage warehouse 1306. Alternatively, it is stored in a spare slot 1102 that does not store the physical storage medium 1311. When stored in the spare slot 1102, the corresponding spare slot state 100 is changed to a state in which the physical storage medium 1311 that has failed is stored. As described above, the processing in step 170 may be executed in the recovery processing mount unit A113 and the recovery processing R / W unit A114.

  At least after the recovery process is completed, instead of the failed physical storage medium 1311, the physical storage medium 1311 that was the spare medium 600 until now (the data stored in the failed physical storage medium 1311 is stored). The physical storage medium 1311) storing the data is newly incorporated into the storage medium parity group 1610. In step 171, the controller 1305 uses the robot 1307 to return the storage medium parity group 1610 including the physical storage medium 1311 newly incorporated in the storage medium parity group 1610 to the slot parity group 1000. In this case, there is no need to return to the slot parity group 1100 that previously stored the storage medium parity group 1610. However, a set of slots 1000 belonging to one slot parity group 1100 exists in a physically recognizable physical location (including when distributed to two or more storage warehouses 1306). Then. Therefore, at least when the physical storage medium 1311 newly incorporated in the storage medium parity group 1610 is decided to be used in place of the failed physical storage medium 1311, the slot 1000 ( The spare slot 1102) is not returned.

  FIG. 12 shows a second embodiment. In the second embodiment, the recovery processing of the storage medium parity group 16100 loaded in the R / W device parity group 900 is performed. Actually, the failure of the physical storage medium 1311 is often detected during the read / write process. Therefore, the recovery process for the storage medium parity group 16100 already loaded in the R / W device parity group 900 is performed. Is likely to be executed. Therefore, in the second embodiment, the physical storage medium 1311 to be newly loaded into the R / W device 1304 is only the spare storage medium 600.

  As information regarding the second embodiment, the control device 1305 includes the spare slot state 100 in the control device buffer 1310, the directory 1309, the nonvolatile memory management information 1401, and the like, as in the first embodiment. The configuration / meaning of the spare slot state 100 is the same as that in the first embodiment.

  The main functions of the director 1312 in the control device 1305 are a recovery process mount unit B213, a recovery process R / W unit B214, and a recovery process demount unit B215. Each of the functions corresponds to the recovery processing mount unit A113, the recovery processing R / W unit A114, and the recovery processing demount A unit 115 in the first embodiment. The difference from the first embodiment will be described below.

  The process flow of the recovery process mount B213 will be described. In step 250, the control device 1305 ejects the failed physical storage medium 1311 from the storage warehouse 1306 using the robot 1307, or refers to the spare slot state 100 and does not store the physical storage medium 1311. It is stored in the spare slot 1102. When the spare slot 1102 is stored, the corresponding spare slot state 100 is changed to a state in which the failed physical storage medium 1311 is stored. Since other processes are the same as those of the recovery process mount unit A213, the description thereof is omitted.

  In the processing flow described above, the control device 1305 transports the spare storage medium 600 from the spare slot 600 to the R / W device 1304. However, as in the first embodiment, also in the first embodiment, the spare storage medium 600 is transported to the slot 1000 in which the failed physical storage medium 1311 was stored, and then the R / W A method of transporting the apparatus 1304 may be used.

  The recovery process R / W unit B 214 and the recovery process demount B unit 215 include step 170 in the recovery process R / W unit A 114 and the round process demount A unit 115, that is, processing of the physical storage medium 1311 in which the failure has occurred. Not only, the rest is the same. Therefore, the description is omitted here.

Overview of the first embodiment of the present invention Configuration of a computer system subject to the present invention Configuration of another computer system subject to the present invention Configuration of logical storage medium 400 Relationship between logical record and physical record Configuration of storage device parity group and record parity group Configuration when there are multiple directors Relationship between logical storage device and storage device parity group Configuration of R / W device parity group and logical R / W device Storage warehouse composition Slot parity group and logical slot configuration Outline of the second embodiment of the present invention

Explanation of symbols

100: Reserve slot state 113: Recovery processing mount part A
114: Recovery processing R / W part A
115: Recovery processing demount part A
213: Recovery processing mount part B
214: Recovery processing R / W part B
215: Recovery processing demount part B

Claims (5)

A plurality of portable storage media;
A plurality of read / write devices loaded with a portable storage medium and reading / writing data from / to the portable storage medium;
A plurality of storage warehouses each having a plurality of slots for storing portable storage media;
A robot for transporting a portable storage medium between the slot and the read / write device;
A storage device system having a control device for controlling the plurality of read / write devices,
Process read / write requests for data stored in portable storage media sent from the processing device,
A plurality of storage media using a plurality of portable storage media each having a data record accessed from the processing device, and a portable storage medium having a redundant record used to recover data of the data record Configure a parity group,
A plurality of slots in which portable storage media included in the same storage medium parity group are stored, and a plurality of slot parity groups corresponding to each of the plurality of storage medium parity groups are configured,
If any of the multiple portable storage media included in the storage media parity group fails,
The control device controls the robot to be included in the same storage medium parity group as the portable storage medium in which the failure has occurred, and any storage medium other than the portable storage medium in which the failure has occurred Transport spare portable storage media not included in the parity group to multiple read / write devices,
By controlling the read / write device, the failure is detected from data stored in a portable storage medium other than the failed portable storage medium that is included in the same storage medium parity group as the failed portable storage medium. Generate the data stored in the resulting portable storage medium, store it in the spare portable storage medium,
The robot is controlled to transport the spare portable storage medium to a slot in a slot parity group corresponding to a storage medium parity group that includes a failed portable storage medium among a plurality of slot parity groups. A storage device system. The storage system according to claim 1.
The storage system, wherein the robot transports a portable storage medium in which a failure has occurred to any slot in a storage warehouse. The storage system according to claim 1.
The robot system discharges a portable storage medium in which a failure has occurred from a storage warehouse. The storage system according to claim 1.
The storage device system, wherein the control device controls the robot to transport the spare portable storage medium to a slot in which a failed portable storage medium is stored. A plurality of portable storage media;
A plurality of read / write devices loaded with a portable storage medium and reading / writing data from / to the portable storage medium;
A plurality of storage warehouses each having a plurality of slots for storing portable storage media;
A robot for transporting a portable storage medium between the slot and the read / write device;
A storage system management method comprising a control device for controlling the plurality of read / write devices,
Processing a read / write request for data stored in the portable storage medium transmitted from the processing device;
A plurality of storage media using a plurality of portable storage media each having a data record accessed from the processing device, and a portable storage medium having a redundant record used to recover data of the data record Steps in which a parity group is configured; and
A plurality of slot parity groups corresponding to each of the plurality of storage medium parity groups using a plurality of slots in which portable storage media included in the same storage medium parity group are stored;
If any of the multiple portable storage media included in the storage media parity group fails,
A portable storage medium other than the failed portable storage medium included in the same storage medium parity group as the failed portable storage medium, and a spare portable storage not included in any storage medium parity group A medium is conveyed to a plurality of read / write devices;
Store data in a portable storage medium that has failed from data stored in a portable storage medium other than the failed portable storage medium that is included in the same storage medium parity group as the failed portable storage medium Generated data is stored in the spare portable storage medium; and
Transporting the spare portable storage medium to a slot in a slot parity group corresponding to a storage medium parity group including a portable storage medium in which a failure has occurred among a plurality of slot parity groups. A storage device system.

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