JP3767570B2 - Array disk device - Google Patents

Description

その後、アレイコントローラ１０１は、論理ディスク６、及び７への上位からのアクセスを許可し、論理ディスクの移設は完了する。
実施例２
次に、図４（ｂ）左下側のように構成されているクラスタ９０８内の論理ディスク６を図４（ｂ）左上側のように構成されているクラスタ９０８のランク３に移設し、図４（ｂ）右側のような構成にすような、異なるクラスタ間での論理ディスクの移設について、図３、図５及び図６を用いて説明する。
【０１０２】
図３（ａ）が論理ディスクを異なるクラスタ９０８に移設する場合の論理ディスクステータス９０２の状態遷移、図５及び図６は処理フローである。
【０１０３】
移設前の各カードドライブのＡＩＲ情報２００を以下に示す。
クラスタ０／論理ディスク６：
R3/P0のCD(Enable ,1,6,3/0/30,3/0/30,3/1/31)
R3/P1のCD(Enable ,1,6,3/1/31,3/0/30,3/1/31)
また、この時点の論理ディスクステータス２０２は、図３（ｂ）３１１の状態にある。
【０１０４】
まず、上位装置から論理ディスク６のステータスを "Portable" に変更する命令が発行される。以降の処理フローを図５に示す。
【０１０５】
アレイコントローラ１０１は当該コマンドを受け付ける（Ｓ５０１）。
【０１０６】
アレイコントローラ１０１は、受け付けたコマンドを解析し、対象が論理ディスクが６であることを認識し、クラスタ９０８内に存在するすべてのＣＤ９０５のＡＩＲ情報２００を検索し、論理ディスク６を構成するＣＤ９０５を探し出す（Ｓ５０２）。
【０１０７】
この時点での、ＡＩＲ情報２００の内容は上記の通りである。
【０１０８】
アレイコントローラ１０１は、対象論理ディスク（論理ディスク６）の状態を "Portable" に変更することが指示されたことを認識する（Ｓ５０３）。
【０１０９】
アレイコントローラ１０１は、電源投入時に起動時に読み込んだ各ＣＤ９０５のＡＩＲ情報２００内に格納されている論理ディスクステータス２０２の内容を "Portable" に変更する（Ｓ５２４）。以下にこの時点のＡＩＲの情報２００を示す。
クラスタ０／論理ディスク６：
R3/P0のCD(Portable ,1,*,*/0/30,*/0/30,*/1/31)
R3/P1のCD(Portable ,1,*,*/1/31,*/0/30,*/1/31)
アレイコントローラ１０１は、ＣＤ９０５の取り外しに備え、当該論理ディスクに対する以降のアクセスを禁止する（Ｓ５１５）。
【０１１０】
アレイコントローラ１０１内に持つＡＩＲ情報２００について、上位装置からの命令により変更した結果を、対象の論理ディスクを構成する物理ディスクに書き戻す（Ｓ５１６）。
【０１１２】
以上により、当該論理ディスクは "Portable" 状態に設定されるので取り外し可能となる。この時点での論理ディスクステータス２０２は図３（ｂ）３１２に示す状態となる。
【０１１３】
次にオペレータは、当該論理ディスクが "Portable" 状態になったことを確認して、対象のＣＤ９０５をクラスタ９０８から引き抜き、移設先のクラスタ９０８に装着する。この時点で論理ディスクステータスは、図３（ｂ）３１３に示す状態にある。
【０１１４】
新たにＣＤ９０５が挿入された場合の処理フローを図６に示す。
【０１１５】
アレイコントローラ１０１及び１０１’は、新たにＣＤ９０５が挿入されたことを検出する（Ｓ６０１）。
【０１１６】
アレイコントローラ１０１及び１０１’は、当該ＣＤ９０５のＡＩＲ情報２００を含む構成制御情報を読みこむ（Ｓ６０２）。
【０１１７】
読み込みが完了した後、ＡＩＲ情報２００内の論理ディスクステータス２０２、レイドレベル２０３及び論理ディスクグループ２０５に矛盾が無いか検証する（Ｓ６０３）。
【０１１８】
矛盾が検出された場合は、論理ディスクを構成するＣＤ９０５の選択を間違えた等の人為的な重大問題が発生したとして、処理を異常終了する（Ｓ６１４）。
【０１１９】
異常が検出されなかった場合は、ＡＩＲ情報２００内の論理ディスクステータス２０２を参照し、次に成すべき処理を選択する（Ｓ６０４）。
【０１２０】
アレイコントローラ１０１及び１０１’は、挿入された論理ディスクステータス２０２が "Portable" であることから、別クラスタ９０８から移設された論理ディスクが挿入された事を認識し、クラスタ９０８内に備えられている全てのＣＤ９０５についてＡＩＲ情報２００を検索して、当該クラスタ９０８内で割り当てられている最大論理ディスク番号を探し出す（Ｓ６０５）。
【０１２１】
アレイコントローラ１０１は、１クラスタ９０８内での論理ディスクアドレス９０３の重複を避けるために、当該クラスタ９０８内で割り当てられている最大論理ディスク番号より一大きい論理ディスク番号を移設された論理ディスクに割り当て、挿入された論理ディスクを構成する全てのＣＤ９０５について、当該ＣＤ挿入時に読み込んだＡＩＲ情報２００内の論理ディスクアドレス２０３を更新する（Ｓ６０６）。
【０１２２】
最後に、アレイコントローラ１０１内に備えられた「位置情報を変更する機能（請求項１記載）」は、当該論理ディスクのＡＩＲ情報２００内の該当情報を更新する（Ｓ６０７）。更新した後の各ＣＤ９０５に格納されているＡＩＲ情報２００は、以下のようになる。
クラスタ１／論理ディスク３：
Ｒ３／Ｐ０のＣＤ（Ｐｏｒｔａｂｌｅ ，１，３，＊／０／３０，＊／０／３０，＊／１／３１）
Ｒ３／Ｐ１のＣＤ（Ｐｏｒｔａｂｌｅ ，１，３，＊／１／３１，＊／０／３０，＊／１／３１）
次に、論理ディスクステータス２０２をＥｎａｂｌｅに変更する命令が上位装置から発行され処理が継続するが、以降の処理は実施例１で示している、論理ディスク挿入後の処理と同様である。処理終了後のＡＩＲ情報２００は、以下のようになる。
クラスタ１／論理ディスク３：
Ｒ３／Ｐ０のＣＤ（Ｅｎａｂｌｅ ，１，３，３／０／３０，３／０／３０，３／１／３１）
Ｒ３／Ｐ１のＣＤ（Ｅｎａｂｌｅ ，１，３，３／１／３１，３／０／３０，３／１／３１）
以上で論理ディスクの移設が完了する。この時点で論理ディスクステータス２０２は、図３（ｂ）３１４の状態となる。
実施例３
次に、図４（ｃ）左側のように構成されているクラスタ９０８に、論理ディスク３を図４（ｃ）右側のような構成になるような、ランク２のポート０乃至ポート２にレイドレベル０の論理ディスクを論理ディスク番号を４として増設をする場合の動作について説明する。
【０１２３】
図３（ｃ）が論理ディスクを増設する場合の論理ディスクステータス２０２の状態遷移、図５及び図６が処理フローである。
【０１２４】
移設前の各ＣＤ９０５内のＡＩＲ情報２００を以下に示す。
増設用論理ディスク：
R2/P0に挿入すべきCD（Portable ,0,*,*/0/40,*/0/40,*/1/41,*/2/42）
R2/P1に挿入すべきCD（Portable ,0,*,*/1/41,*/0/40,*/1/41,*/2/42）
R3/P1に挿入すべきCD（Portable ,0,*,*/2/42,*/0/40,*/1/41,*/2/42）
論理ディスクの増設の処理は、異なるクラスタ９０８間の移設の場合の、当該論理ディスクを移設先のクラスタ９０８に挿入する場合と同様である。
【０１２５】
実施例４
実施例１から実施例３において、論理ディスクの移設の際に、当該論理ディスクを構成するＣＤ９０５の挿入されるポート位置が、移設前と移設後で同一であるならば、ＡＩＲ情報２００内に当該論理ディスクにおける組み合わせ情報を持つ必要が無い。したがって、移設後の論理ディスクを認識することについての信頼性という面では僅かに劣るものの、より簡潔な制御で本発明の目的とするアレイディスク装置を実現できる。
【０１２６】
【発明の効果】
請求項１に係る発明は、あらゆる構成のクラスタ間及び同一クラスタ内で、論理ディスクの移設を可能にするものである。
【０１２７】
これにより、例えば論理ディスクの転送系の障害が発生したときの障害要因の切り分け作業において、当該論理ディスクを別ランクへ移設して再現試験を行うことができるので、迅速かつ正確な障害復旧作業を行うことができる。
【０１２８】
また、コンピュータシステムにおける、データセットの再配置作業を、ボリュームのコピー等を行う必要なく実現することができ、時間と費用の大幅な削減を可能にすることがでる。
【０１２９】
さらに、新しく論理ディスクを増設する場合においても、当該ディスクを挿入する物理アドレスの制約が無く、ユーザごとに異なる論理ディスクの構成に各々対応した論理ディスクを作成する必要が無く、増設用論理ディスクの生産管理及び在庫管理を簡素化でき、大幅な生産性の向上が図れる。
【０１３０】
さらに、論理ディスクの移設の際に、当該論理ディスクを構成するディスク装置の相対位置が変更されても、移設後に正確に当該論理ディスクを再認識することが可能であり、より信頼性の高いアレイディスク装置を実現することができるとともに、移設作業者の精神的緊張の緩和にも寄与する。
【０１３１】
請求項２に係る発明は、論理ディスクの状態変更の契機を上位装置から与えることにより、統合的な保守を行うことが可能であり、保守作業の手順及び管理を簡易化できる。
【０１３２】
以上のように、本発明では、論理ディスクの自由な構成変更を可能とし、保守性、生産性、信頼性の高いディスクアレイ装置を実現できる。
【図面の簡単な説明】
【図１】 ディスクアレイ装置を含む計算機システムの構成図
【図２】 構成制御情報及び当該情報内に含まれるＡＩＲ情報の内容を示した図
【図３】 論理ディスクの移設及び増設時の論理ディスクステータスの遷移図
【図４】 論理ディスクの移設及び増設時のクラスタの構成の変化を示した図
【図５】 上位装置から論理ディスクの状態変更要求を受け付けたときのアレイコントローラの処理フロー
【図６】 新たに論理ディスクが挿入された場合のアレイコントローラの処理フロー
【図７】 論理ディスクの割り当て及び各論理ディスクのレイドモードの一例を示した図
【図８】 論理ディスクの割り当て及び各論理ディスクのレイドモードの一例を示した図
【図９】 アレイディスク装置全体を示す斜視図
【図１０】アレイディスク装置全体を示す正面図及び側面図
【図１１】カードドライブの斜視図[0001]
BACKGROUND OF THE INVENTION
The present invention relates to an array disk device.
[0002]
[Prior art]
The disk array device realizes a high-performance and highly reliable disk device by simultaneously operating a plurality of disks that have been processed as single physical disks in parallel.
[0003]
Specifically, as means for improving the reliability, there is known one provided with a disk dedicated to parity or Hamming code, and further provided with a hot spare disk. As a result, processing can be continued without stopping the system even when a single disk fails.
[0004]
In general, in a disk array device, a plurality of magnetic disks are arranged in parallel, and one logical disk is configured by a combination thereof. Several forms have already been proposed for this combination method, and each form is called a raid level, and the combined disk control method differs for each raid level. Each raid level is called raid level 0 to raid level 5 or the like. The concept and operation method of each raid level are described in The RAIDBook (The RAID Advisory Board, Inc., issued on November 18, 1993) and the like.
[0005]
There is also known an array disk device that can include these plural types of logical disks in the same housing. This is shown in FIG. In FIG. 1, a total of 24 disks, 6 in the horizontal direction and 4 in the vertical direction, have a matrix structure to constitute one array disk device.
[0006]
In FIG. 1, the horizontal arrangement of the drive module group 102 is called a rank, and one logical disk is generally composed of a combination with another physical disk in the same rank.
[0007]
A vertical arrangement is called a port, and data can be transferred independently for each port in terms of hardware.
[0008]
FIG. 7A shows an example of a logical disk allocation method. When the device of rank x / port y is described as DVxy, the 24 devices include DV00-DV04 as logical disk 0, DV10-DV14 as logical disk 1, DV20-DV24 as logical disk 2, and DV30-DV34. The logical disk 3 is allocated. In addition, HS-0, HS-1, HS-2, and HS-3 are hot spare disks, respectively. A hot spare disk is a physical disk that is copied from the contents of other disks that make up the logical disk to which the physical disk belongs when a physical disk fails and data cannot be read or written. This is a disk for newly storing data that would have been stored.
[0009]
FIG. 7B shows a raid level operation mode assigned to the logical disk in the above configuration. In FIG. 7B, both of the logical disks 0-3 are set to the raid level 3 or the raid level 5.
[0010]
Furthermore, another example is shown in FIG. In FIG. 8A, the 24 devices are DV00-04 with logical disk 0, DV10-11 with logical disk 1, DV12-13 with logical disk 2, DV14 with logical disk 3, and DV20-22. Are assigned as logical disk 4, DV23-24 as logical disk 5, DV30-31 as logical disk 6, and DV32-34 as logical disk 7. In addition, HS-0, HS-1, HS-2, and HS-3 are hot spare disks, respectively. The role of the hot spare disk is the same as in the case of FIG.
[0011]
FIG. 8b) shows the operation mode of the raid level assigned to the logical disk in the above configuration. In FIG. 8b), logical disk 0 is at raid level 3 or raid level 5, logical disk 1 and logical disk 2 are at raid level 1, logical disk 3 or logical disk 4 is at raid level 0, logical disk 5 or logical disk In this example, the disk 6 is set to raid level 1 and the logical disk 7 is set to raid level 0.
[0012]
In the array disk device having the above-described configuration, particularly in the case shown in FIG. 8, logical disks of various raid levels are mixed so that it is normal if the arrangement of the logical disks is not accurately grasped. The operation cannot be performed. For example, in FIG. 8, DV10-DV14 should not operate by recognizing raid level 3.
[0013]
In order to prevent such erroneous recognition, a position (hereinafter referred to as “physical address”) in the drive module group into which the physical disk is to be inserted is recorded in each physical disk in the apparatus. These pieces of information are collectively referred to as AIR (Array Integrity Record) information. This AIR information is written at the time of factory shipment.
[0014]
The array disk device refers to the AIR information recorded on the mounted physical disk, checks the physical address, and if an inconsistency between the actual insertion position and the physical address of the AIR information is detected, Make the logical disk unusable.
[0015]
As described above, erroneous recognition of a logical disk due to erroneous insertion into an inappropriate slot of a physical disk is prevented.
[0016]
[Problems to be solved by the invention]
However, recent array disk devices can be equipped with a plurality of logical disks in one housing. In the conventional array disk device, each disk device is controlled based on its physical position. Therefore, the logical disk control naturally depends on the physical position where the disk device is mounted, and the logical disk cannot be moved.
[0017]
The present invention provides an array disk device that makes it easy to relocate logical disks.
[0018]
[Means for Solving the Problems]
Therefore, in order to satisfy these requirements, in the present invention,
It is composed of a plurality of disk devices (905) for storing data transferred to and from the host device and a disk device (905) for storing redundant data created from data stored in the plurality of disk devices. A drive module group (102);
The command issued from the host device (103) is received and analyzed, and the disk device (905) is instructed to perform an instruction and positioning operation or data transfer from the host device, and the host device (103). And array controllers (101 and 101 ′) for controlling data transfer and the like of the disk device (905),
With
In the disk device (1405), configuration information including the position in the drive module where the disk is to be mounted is recorded,
The drive module group includes a plurality of logical disks configured by the plurality of disk devices (1405) and logically controlled by the array controller as one disk device;
The array controller is an array disk device having a function of prohibiting the use of the disk device when the configuration information recorded in the disk device and the actual state of the disk device are inconsistent,
The array controller includes a function of changing position information in the drive module stored in the disk device;
An array disk device is realized.
[0019]
Further, the configuration information recorded in the disk device includes the combination information indicating the position of the disk device in the logical disk that is logically controlled as one disk, thereby configuring the logical disk. Even when the relative position between them changes, it is possible to accurately grasp the configuration of the logical disk and the arrangement of the disk device, and to realize a more reliable array disk device.
[0020]
In addition, the position information in the drive module stored in the disk device is not changed from the maintenance device connected to the maintenance interface provided in the array controller, but is changed by a command from the host device. It also includes the function to perform, and enhance the uniformity of system construction work.
[0021]
The configuration information recorded in the disk device recognizes the combination of the physical disks constituting the logical disk in the drive module group and the state of the logical disk in order for the array controller to determine the validity of the insertion position of the disk. Used for. For this reason, the configuration information includes a “physical address” indicating the position in the drive module group in which the disk device is inserted, and “combination information” indicating the logical position of the disk in the logical disk to which the disk belongs, It has a “logical disk address” of a logical disk to which the disk belongs, a “physical position”, a “serial number”, and the like for all the disk devices constituting the logical disk to which the disk belongs.
[0024]
Here, regarding the transfer of the logical disk, two forms must be considered. That is, relocation within the same cluster and relocation between different clusters.
[0025]
In the case of relocation within the same cluster, the purpose is often closed to the array disk device in which it is desired to physically change the insertion position of the logical disk. Therefore, it is desirable for the host device to appear that no change has occurred in the configuration of the array disk device before and after the relocation. When the host device specifies data in the array disk device, the logical disk address is used. Therefore, the logical address of the logical disk to be transferred needs to be held before and after the transfer.
[0026]
On the other hand, in the case of relocation between different clusters, the situation is different. When such operations are performed, the purpose is often to change the configuration of the entire array disk system. Therefore, it is not necessary to store the logical disk address for a specific logical disk, and if several sets of logical disks already exist in the transfer destination cluster, the same logical disk is stored in the same cluster. There may be a plurality of logical disks with addresses, which would be inconvenient because it would be out of control.
[0027]
As described above, in the case of logical disk migration within the same cluster, it is necessary to retain the logical disk address. In the case of logical disk migration between different clusters, on the contrary It is necessary to be able to reset the disk address.
[0028]
Considering the above two forms, an operation for satisfying these requirements will be described.
[0029]
When the array disk device receives an instruction to change the logical disk status to "Enable" for a certain logical disk from the host device, the array disk device contains each physical disk constituting the logical disk in its configuration information. The stored physical address is set to the currently inserted position, the physical address positions of all physical disks recorded as a logical disk group are set to the currently inserted position, and the logical disk status is set to "Enable". The configuration information is updated by updating and writing the updated value back to the physical disk, and thereafter, accepting access from the host device is permitted.
[0031]
If it is necessary to move the rank within the same cluster to the array disk device, first instruct the array disk device to change the rank status to "Move". To do. Upon receiving the instruction, the array disk device performs the above-described processing, prohibits access from the host device, and then changes the logical disk status of the target rank to “Move”.
[0032]
The operator confirms that the status of the rank is "Move" from the display of the LEDs and maintenance tools provided on the physical disk, and then removes the target rank from the chassis, and then moves the target rank to the target slot. Insert a rank.
[0033]
When the insertion of the rank is completed, the host device instructs the array disk device to set the status to “Enable”. Upon receiving the instruction, the array disk device performs the above-described processing and sets the target rank state to “Enable”.
[0034]
As described above, the transfer of the rank within the same cluster is completed, and then the access to the logical disk is resumed.
[0035]
Next, when it becomes necessary to move the rank to a different cluster, the host device first instructs the array disk device to change the status of the rank to “Portable”. Upon receiving the instruction, the array disk device performs the above-described processing, prohibits the reception of access from the host device, and then changes the logical disk status of the target rank to “Portable”.
[0036]
The operator confirms that the status of the rank is "Portable" from the display of the LEDs and maintenance tools provided on the physical disk, and then removes the target rank from the chassis. The rank is inserted into.
[0037]
Processing and operation after the insertion of the rank is completed are the same as in the case of rank transfer within the same cluster.
[0038]
As described above, the transfer of ranks between different clusters is completed, and then access to the logical disk is resumed.
[0039]
When adding a logical disk, add a disk whose logical disk status is "Portable" stored in the configuration information.
[0040]
The operator inserts the expansion logical disk into the target cluster and instructs the host device to change the status of the logical disk to “Enable”. The operation of the array disk device after "Enable" is instructed is the same as in the case of rank transfer.
[0041]
This completes the rank expansion.
[0042]
Next, the operation when the array disk device having such means is used will be described.
[0043]
For example, consider a case where a failure occurs in access to rank 0. Normally, the content of the failure is reported as sense information to the higher-level device, so the detailed content of the failure can be obtained by analyzing the sense information. As a result of analyzing the detailed contents, if the failure is a fixed failure of the physical disk and occurred during data transfer, the cause is in the physical disk itself, or the chassis into which the physical disk is inserted It is difficult to determine whether the connector is present.
[0044]
In this case, since the replacement operation of the physical disk is relatively easy, for the time being, the physical disk is replaced with a new one, and it is observed whether or not the failure reoccurs.
[0045]
However, if the failure is caused by the connector of the chassis, even if the physical disk is replaced as described above, the failure will reoccur, and the replacement of the physical disk itself becomes useless, resulting in cost and time. The result is just wasting.
[0046]
Therefore, in the array disk device according to the present invention, if there is another free slot in the disk array device, is the same failure caused by moving the failed logical disk to the free slot? If it occurs, it can be judged as a physical disk failure, and if it is not set, it can be judged as a failure on the connector side, which is very convenient.
[0047]
In addition, there is a case where logical disk relocation is requested for the purpose of changing the system configuration in operation. In this case, for example, the purpose is often load distribution of data sets, for example, and therefore, logical disk migration is usually performed in different clusters.
[0048]
Therefore, it is rare that the configuration of the transfer source cluster is the same as that of the transfer destination cluster, and it is desirable that the configuration after the transfer should not be restricted by the configuration before the transfer.
[0049]
In this case as well, as in the case of relocation between the same clusters, the restriction that the AIR information and the actual insertion position must be prevented is avoided, so relocation is possible even when relocating to a different cluster. Therefore, it is not necessary to perform a long work such as copying a volume, and a quick work can be expected.
[0050]
Further, consider a case where the configuration at the time of shipment is set to be half the number of logical disks that can be mounted, and then logical disks are added as necessary. The configuration information of the expansion logical disk is stored at the time of shipment from the factory, but since the logical disk and the physical position can be controlled separately, there is no need to worry about the actual insertion position. As a result, it is not necessary to reconstruct the configuration information of the expansion logical disk for each configuration of each user at the time of factory shipment, and productivity is improved.
[0051]
Embodiment
[0052]
【Example】
Example 1
FIG. 9 is a perspective view showing an overall view of the array disk device. Moreover, the same number is attached | subjected to the same components through all the figures.
[0053]
The array disk device is divided into three stages in the height direction, and each stage is further divided into front and rear. Drive module groups (hereinafter referred to as clusters 908) are provided before and after the upper and middle stages, and four clusters are provided in one housing. A power switch 903 and a power supply unit 904 are provided at the front and rear of the lower stage, the power supply unit 904 on the front is provided in the cluster provided in the middle and upper stages on the front, and the power supply unit on the back is provided in the middle and upper stages on the back. Power is supplied to each cluster.
[0054]
Each cluster 908 is covered with a cover 906, and further, the front door 901 and the back door 902 cover all of the upper, middle and lower tiers.
[0055]
One cluster 908 is divided into four stages, and one unit is called a rank 907, and one cluster is composed of four ranks. Each rank is composed of six card drives (hereinafter referred to as “CD”) 905. The CD 905 is a physical disk device.
[0056]
10A is a front view of the array disk device with the front door 901 removed, and FIG. 10B is a side view of the array disk device with a side door (not shown) removed.
[0057]
FIG. 11 is a perspective view of the card drive 905. The card drive 905 can be freely inserted into and removed from the slot of the array disk device even during energization.
[0058]
The card drive has a connector 1101 for electrical connection with a housing, a converter 1102, a disk device 1103, and an ejector 1104 that is an instrument for assisting insertion / removal of a CD on an electrically wired card 1106. And an LED 1105 indicating the state of the disk device.
[0059]
There are a plurality of equal-length blocks in the disk device, and numbers are assigned to the respective blocks in ascending order from block number 0. In this embodiment, a disk drive having a capacity of about 2 gigabytes is used, the user data capacity of one block is used as 1024 bytes, and there are 2270625 blocks from block number 0 to block number 2270624. Among these, the user block area that permits reading and writing of data from the host device is from block 0 to block 2265656, and from block 2265567 to block 2270624 is called the configuration control information area.
[0060]
FIG. 2A shows the configuration control information area. In the configuration control information, in addition to the AIR information 200, a microcode 201 for controlling the array disk device and the like are stored.
[0061]
Details of the AIR information are shown in FIG. The AIR information includes a logical disk status 202 indicating the state of the logical disk, a logical disk address 203 indicating the number of the logical disk to which the physical disk belongs, and a raid level indicating the raid level of the logical disk to which the physical disk belongs. 204, logical group information 205 indicating physical positions in the drive module group of all CDs constituting the logical disk to which the physical disk belongs, and physical in the drive module group in which each CD is inserted. A physical address 206 indicating a position and a serial number 207 for each CD are recorded.
[0062]
The array controller recognizes and controls a combination of logical disks from the AIR information and serial number recorded in the disk device.
[0063]
FIG. 1 is a block diagram showing the configuration of an array disk device. The array disk device 100 includes array controllers 101 and 101 ′ and a drive module group 102. The array controllers 101 and 101 ′ are coupled to the drive module group 102, respectively, and can access all the CDs 905 in the drive module group 102.
[0064]
The array controllers 101 and 101 ′ receive a command generated from the host device 103, analyze the command, and control the positioning of the requested logical disk and data transfer between the disk and the host device. In this embodiment, the host device and the array disk device are controlled based on the SCSI interface protocol.
[0065]
In the drive module group 102, the vertical position is called a rank, and the horizontal position is called a port, and card drives in one cluster can be uniquely specified by the rank number and the port number.
[0066]
When the power of the array disk device is turned on, the array controllers 101 and 101 ′ select an arbitrary CD 905 and read the array controller control microcode 201 and the AIR information 200 in the configuration control area stored in the CD. .
[0067]
When the array controllers 101 and 101 ′ have finished reading the array controller control microcode 201, the array controllers 101 and 101 ′ perform control based on the microcode.
[0068]
The array disk controller initializes registers and the like based on the microcode, and then refers to the AIR information 200 included in the control information in the configuration control area that has already been read, to configure the subordinate CD 905. Recognize
[0069]
The array controllers 101 and 101 ′ do not read the data in the configuration control area again after the power is turned on unless there is a special instruction. Browse the data. This is for speeding up the processing.
[0070]
Here, when the AIR information and the serial number of each physical disk are indicated in this specification, the above information is
(Logical disk status, raid level, logical disk address, physical address and serial number (rank / port / serial number), physical address and serial number rank / port / serial number of disk unit belonging to logical disk group), ...)
It shall be expressed as: For example,
(Enable, 5,1,2 / 0 / 91,2 / 0 / 91,2 / 1 / 92,2 / 2 / 93,2 / 3 / 94,2 / 4/95)
In this case, the logical disk status of this physical disk is Enable, the RAID level is set to RAID level 5, the logical disk address is 1, and the physical address and serial number are rank 2 port 0 serial number. 91. The physical addresses and serial numbers of all the physical disks constituting the logical disk to which the physical disk belongs are rank 2 port 0 serial number 91, rank 2 port 1 serial number 92, rank 2 port 2 serial. It is also shown that the number 93, the port 3 serial number 94 of rank 2 and the port 4 serial number 95 of rank 2 are shown.
[0071]
In this embodiment, the command issued from the host device to the array disk device uses the “Mode Select” command in the SCSI interface protocol. This command is a command for setting the detailed rules of the interface from the host device to the disk device, and several types of parameters are transferred following the command. In this parameter, there is information called “Vender unique”, which stores the target logical disk address and the like that need to be changed in the logical disk status. In this embodiment, the “Mode Select” command is used to notify a change in the state of the logical disk. However, other commands may be used as long as they do not violate the interface protocol.
[0072]
Next, regarding the operation when a logical disk is relocated to another rank in the same cluster so that the cluster configured as shown on the left side of FIG. 4A becomes the configuration shown on the right side of FIG. This will be described with reference to FIGS. 3, 5, and 6.
[0073]
FIG. 3A shows the state transition of the logical disk status when the logical disk is relocated, and FIGS. 5 and 6 are processing flows.
[0074]
The AIR information of each card drive before relocation is shown below. The value indicated by * may be any value.
Logical disk 0:
R0 / P0 CD (Enable, 5,0,0 / 0 / 00,0 / 0 / 00,0 / 1 / 01,0 / 2 / 02,0 / 3 / 03,0 / 4/04)
R0 / P1 CD (Enable, 5,0,0 / 1 / 01,0 / 0 / 00,0 / 1 / 01,0 / 2 / 02,0 / 3 / 03,0 / 4/04)
R0 / P2 CD (Enable, 5,0,0 / 2 / 02,0 / 0 / 00,0 / 1 / 01,0 / 2 / 02,0 / 3 / 03,0 / 4/04)
R0 / P3 CD (Enable, 5,0,0 / 3 / 03,0 / 0 / 00,0 / 1 / 01,0 / 2 / 02,0 / 3 / 03,0 / 4/04)
R0 / P4 CD (Enable, 5,0,0 / 4 / 04,0 / 0 / 00,0 / 1 / 01,0 / 2 / 02,0 / 3 / 03,0 / 4/04)
Logical disk 6:
R3 / P0 CD (Enable, 1,6,3 / 0 / 10,3 / 0 / 10,3 / 1/11)
R3 / P1 CD (Enable, 1,6,3 / 1 / 11,3 / 0 / 10,3 / 1/11)
Logical disk 7:
R3 / P2 CD (Move, 0,7, * / * / 20, * / * / 20, * / * / 21, * / * / 22)
R3 / P3 CD (Move, 0,7, * / * / 21, * / * / 20, * / * / 21, * / * / 22)
R3 / P4 CD (Move, 0,7, * / * / 22, * / * / 20, * / * / 21, * / * / 22)
Further, the status of the logical disk is in the state 301 in FIG.
[0075]
First, a command for changing the status of the logical disk 0 to “Move” is issued from the host device. The subsequent processing flow is shown in FIG.
[0076]
The array controller 101 receives the command (S501).
[0077]
The array controller 101 analyzes the received command, recognizes that the target is the logical disk 0, searches the AIR information 200 of all the CDs 905 existing in the cluster 908, and searches for the CD 905 constituting the logical disk 0. (S502).
[0078]
Furthermore, it is recognized that an instruction to change the state of the logical disk to Move is given (S503).
[0079]
The AIR information 200 of the logical disk 0 at this point is as described above.
[0080]
Since the array controller 101 recognizes that the state of the target logical disk (logical disk 0) is changed to “Move”, the logical disk stored in the AIR information 200 of each CD 905 read when the power is turned on. The content of the status 202 is changed to “Move” (S504). The AIR information 200 at this time is as follows.
Logical disk 0:
R0 / P0 CD (Move, 5,0, * / 0/00, * / 0/00, * / 1/01, * / 2/02, * / 3/03, * / 4/04)
R0 / P1 CD (Move, 5,0, * / 1/01, * / 0/00, * / 1/01, * / 2/02, * / 3/03, * / 4/04)
R0 / P2 CD (Move, 5,0, * / 2/02, * / 0/00, * / 1/01, * / 2/02, * / 3/03, * / 4/04)
R0 / P3 CD (Move, 5,0, * / 3/03, * / 0/00, * / 1/01, * / 2/02, * / 3/03, * / 4/04)
R0 / P4 CD (Move, 5,0, * / 4/04, * / 0/00, * / 1/01, * / 2/02, * / 3/03, * / 4/04)
The array controller 101 prohibits subsequent access to the logical disk in preparation for the removal of the logical disk 0 (S515).
[0081]
In the array controller 101 About the AIR information 200 you have, Change by command from host device Results , Target logical disk Physical disks that make up (S516).
[0082]
Further, if necessary, the other array controller 101 ′ is notified that the AIR information 200 has been updated (S517).
[0083]
As a result, the logical disk is set to Move and can be removed. At this point, the status of the logical disk is as shown in FIG.
[0084]
Next, since an instruction for changing the status of the logical disk 6 to “Move” is issued from the host device, the same processing as that for the logical disk 0 is performed on the logical disk 6, and the AIR information of the logical disk 6 is obtained. 200 is updated as follows.
Logical disk 6:
R3 / P0 CD (Move, 1,6, * / 0/10, * / 0/10, * / 1/11)
R3 / P1 CD (Move, 1,6, * / 1/11, * / 0/10, * / 1/11)
With respect to the logical disk 7, since it is assumed that the logical disk 7 is already in the “Move” state, no particular processing is required.
[0085]
Next, the operator confirms that all of the logical disks 0, 6, and 7 are in the “Move” state, and pulls out the target CD 905 from the slot. The CD 905 may be pulled out each time the status of each logical disk is changed to “Move”, but in the present embodiment, it is collectively performed for convenience. Thereafter, each logical disk is mounted in the transfer destination slot. At this time, the status of the logical disk is in the state shown in FIG.
[0086]
FIG. 6 shows a processing flow when the CD 905 is newly inserted.
[0087]
The array controllers 101 and 101 ′ detect that a new CD 905 has been inserted (S601).
[0088]
The array controllers 101 and 101 ′ read the configuration control information including the AIR information 200 of the CD 905 (S602).
[0089]
After the reading is completed, it is verified whether the logical disk status 202, the raid level 204, and the logical disk group 205 in the AIR information 200 are consistent (S603).
[0090]
If a contradiction is detected, the process is terminated abnormally (S614), assuming that an artificial serious problem such as a wrong selection of the CD 905 constituting the logical disk has occurred.
[0091]
If no abnormality is detected, the logical disk status 202 in the AIR information 200 is referred to, and the next process to be performed is selected. Since the logical disk status 202 is “Move” this time, the process ends without performing anything (S604).
[0092]
This completes the processing of the array controller when the CD 905 is inserted.
[0093]
Next, an instruction for changing the status of the logical disks 0, 6, and 7 to "Enable" is issued from the host device so that the transferred logical disk can be used. In this embodiment, it is assumed that a state change command is first issued to the logical disk 0 for convenience. The subsequent processing is shown in FIG.
[0094]
The array controller 101 receives a state change command for the logical disk 0 (S501).
[0095]
The array controller 101 recognizes that the processing target is the logical disk 0, searches the AIR information 200 of all the CDs 905 existing in the cluster 908, and searches for all the CDs 905 constituting the logical disk 0 (S502). . Since the logical disk 0 is newly moved to rank 3 this time, the target CD 905 is DV30, DV31, DV32, DV33, DV34.
[0096]
When the search is completed, the array controller 101 recognizes that the command received from the host device is an “Enable” command, and selects a process (S503). For each CD 905 constituting the logical disk 0, the array controller 101 changes the contents of the logical disk status 202 stored in the AIR information of each CD read when the CD is inserted to “Enable” (S504).
[0097]
Also, the physical address stored in the AIR information 200 is updated to the position where each CD 905 is currently inserted (S505).
[0098]
In addition, logical disk group information 2 05 is another C belonging to the logical disk D9 05 of The physical address is stored (S506).
[0099]
In the array controller 101 About AIR information 200 , Changed by instruction from host device Results Is written back to the CD 905 (S507). The AIR information 200 stored in each CD 905 after writing back is as follows.
Logical disk 0:
CD of R0 / P0 (Enable, 5, 0, 3/0/00, 3/0/00, 3/1/01, 3/2/02, 3/3/03, 3/4/04)
R0 / P1 CD (Enable, 5, 0, 3/1/01, 3/0/00, 3/1/01, 3/2/02, 3/3/03, 3/4/04)
R0 / P2 CD (Enable, 5, 0, 3/2/02, 3/0/00, 3/1/01, 3/2/02, 3/3/03, 3/4/04)
R0 / P3 CDs (Enable, 5, 0, 3/3/03, 3/0/00, 3/1/01, 3/2/02, 3/3/03, 3/4/04)
R0 / P4 CDs (Enable, 5, 0, 3/4/04, 3/0/00, 3/1/01, 3/2/02, 3/3/03, 3/4/04)
Thereafter, if necessary, the array controller 101 notifies the array controller 101 ′ of the other system that the AIR information 200 has been updated (S508).
[0100]
Since the logical disk relocation has been completed, access from the higher-level device to the logical disk 0 is finally permitted (S509). At this point, the state shown in FIG.
[0101]
Subsequently, the same processing is performed on the logical disks 6 and 7, and the AIR information 200 is written back to each CD 905. The AIR information 200 stored in each CD 905 after writing back is as follows.

Thereafter, the array controller 101 permits access from the upper level to the logical disks 6 and 7, and the transfer of the logical disk is completed.
Example 2
Next, the logical disk 6 in the cluster 908 configured as shown in the lower left side of FIG. 4B is moved to rank 3 of the cluster 908 configured as shown in the upper left side of FIG. (B) The transfer of logical disks between different clusters as configured on the right side will be described with reference to FIG. 3, FIG. 5 and FIG.
[0102]
FIG. 3A shows the state transition of the logical disk status 902 when the logical disk is moved to a different cluster 908, and FIGS. 5 and 6 show the processing flow.
[0103]
The AIR information 200 of each card drive before relocation is shown below.
Cluster 0 / logical disk 6:
R3 / P0 CD (Enable, 1,6,3 / 0 / 30,3 / 0 / 30,3 / 1/31)
R3 / P1 CD (Enable, 1,6,3 / 1 / 31,3 / 0 / 30,3 / 1/31)
Further, the logical disk status 202 at this time is in the state shown in FIG.
[0104]
First, a command for changing the status of the logical disk 6 to “Portable” is issued from the host device. The subsequent processing flow is shown in FIG.
[0105]
The array controller 101 receives the command (S501).
[0106]
The array controller 101 analyzes the received command, recognizes that the target is the logical disk 6, searches the AIR information 200 of all the CDs 905 existing in the cluster 908, and selects the CD 905 constituting the logical disk 6. Search (S502).
[0107]
The contents of the AIR information 200 at this point are as described above.
[0108]
The array controller 101 recognizes that it has been instructed to change the state of the target logical disk (logical disk 6) to “Portable” (S503).
[0109]
The array controller 101 changes the contents of the logical disk status 202 stored in the AIR information 200 of each CD 905 read at startup when the power is turned on to “Portable” (S524). The AIR information 200 at this time is shown below.
Cluster 0 / logical disk 6:
R3 / P0 CD (Portable, 1, *, * / 0/30, * / 0/30, * / 1/31)
R3 / P1 CD (Portable, 1, *, * / 1/31, * / 0/30, * / 1/31)
In preparation for removing the CD 905, the array controller 101 prohibits subsequent access to the logical disk (S515).
[0110]
In the array controller 101 About the AIR information 200 you have, Change by command from host device The result Target logical disk Physical disks that make up (S5) 1 6).
[0112]
As a result, the logical disk is set to "Portable" and can be removed. At this time, the logical disk status 202 is in the state shown in FIG.
[0113]
Next, the operator confirms that the logical disk is in the “Portable” state, pulls out the target CD 905 from the cluster 908 and mounts it in the transfer destination cluster 908. At this time, the logical disk status is in the state shown in FIG.
[0114]
FIG. 6 shows a processing flow when the CD 905 is newly inserted.
[0115]
The array controllers 101 and 101 ′ detect that a new CD 905 has been inserted (S601).
[0116]
The array controllers 101 and 101 ′ read the configuration control information including the AIR information 200 of the CD 905 (S602).
[0117]
After the reading is completed, it is verified whether the logical disk status 202, the raid level 203, and the logical disk group 205 in the AIR information 200 are consistent (S603).
[0118]
If a contradiction is detected, the process is terminated abnormally (S614), assuming that an artificial serious problem such as a wrong selection of the CD 905 constituting the logical disk has occurred.
[0119]
If no abnormality is detected, the logical disk status 202 in the AIR information 200 is referred to, and the process to be performed next is selected (S604).
[0120]
Since the inserted logical disk status 202 is “Portable”, the array controllers 101 and 101 ′ recognize that the logical disk moved from another cluster 908 has been inserted, and are provided in the cluster 908. The AIR information 200 is searched for all the CDs 905 to find the maximum logical disk number assigned in the cluster 908 (S605).
[0121]
The array controller 101 assigns a logical disk number larger than the maximum logical disk number assigned in the cluster 908 to the relocated logical disk in order to avoid duplication of the logical disk address 903 in one cluster 908. For all the CDs 905 constituting the inserted logical disk, the logical disk address 203 in the AIR information 200 read when the CD is inserted is updated (S606).
[0122]
Finally, the “position information changing function (claim 1)” provided in the array controller 101 updates the corresponding information in the AIR information 200 of the logical disk (S607). The AIR information 200 stored in each CD 905 after the update is as follows.
Cluster 1 / logical disk 3:
R3 / P0 CD (Portable, 1, 3, * / 0/30, * / 0/30, * / 1/31)
R3 / P1 CD (Portable, 1, 3, * / 1/31, * / 0/30, * / 1/31)
Next, an instruction to change the logical disk status 202 to “Enable” is issued from the host device, and the processing continues. The subsequent processing is the same as the processing after the logical disk insertion shown in the first embodiment. The AIR information 200 after the processing is as follows.
Cluster 1 / logical disk 3:
R3 / P0 CD (Enable, 1, 3, 3/0/30, 3/0/30, 3/1/31)
R3 / P1 CD (Enable, 1, 3, 3/1/31, 3/0/30, 3/1/31)
This completes the transfer of the logical disk. At this point, the logical disk status 202 is in the state shown in FIG.
Example 3
Next, in the cluster 908 configured as shown in the left side of FIG. 4C, the RAID level is set to the ports 0 to 2 of rank 2 so that the logical disk 3 is configured as shown in the right side of FIG. The operation in the case where a 0 logical disk is added with a logical disk number of 4 will be described.
[0123]
FIG. 3C shows the state transition of the logical disk status 202 when adding a logical disk, and FIGS. 5 and 6 show the processing flow.
[0124]
The AIR information 200 in each CD 905 before relocation is shown below.
Expansion logical disk:
CD to be inserted into R2 / P0 (Portable, 0, *, * / 0/40, * / 0/40, * / 1/41, * / 2/42)
CD to be inserted into R2 / P1 (Portable, 0, *, * / 1/41, * / 0/40, * / 1/41, * / 2/42)
CD to be inserted into R3 / P1 (Portable, 0, *, * / 2/42, * / 0/40, * / 1/41, * / 2/42)
The process of adding a logical disk is the same as when inserting the logical disk into the transfer destination cluster 908 in the case of transfer between different clusters 908.
[0125]
Example 4
In the first to third embodiments, when a logical disk is relocated, if the port position into which the CD 905 constituting the logical disk is inserted is the same before and after relocation, the AIR information 200 includes There is no need to have combination information in the logical disk. Therefore, although the reliability of recognizing the logical disk after the transfer is slightly inferior, the array disk device which is the object of the present invention can be realized with simpler control.
[0126]
【The invention's effect】
The invention according to claim 1 makes it possible to relocate logical disks between clusters of any configuration and within the same cluster.
[0127]
As a result, for example, when a failure in the transfer system of a logical disk occurs, it is possible to perform a reproduction test by moving the logical disk to another rank in order to perform quick and accurate failure recovery work. It can be carried out.
[0128]
In addition, the data set rearrangement operation in the computer system can be realized without the need to copy the volume, and the time and cost can be greatly reduced.
[0129]
Furthermore, when adding a new logical disk, there is no restriction on the physical address to insert the disk, and there is no need to create logical disks corresponding to different logical disk configurations for each user. Production management and inventory management can be simplified, and productivity can be greatly improved.
[0130]
further Even when the relative position of the disk device constituting the logical disk is changed when the logical disk is moved, the logical disk can be re-recognized accurately after the transfer, and the array disk is more reliable. The device can be realized and also contributes to alleviating the mental tension of the relocation worker.
[0131]
Claim 2 In the invention according to the present invention, it is possible to perform integrated maintenance by giving an opportunity to change the state of the logical disk from the host device, and the procedure and management of the maintenance work can be simplified.
[0132]
As described above, according to the present invention, it is possible to freely change the configuration of a logical disk, and it is possible to realize a disk array device with high maintainability, productivity and reliability.
[Brief description of the drawings]
FIG. 1 is a configuration diagram of a computer system including a disk array device.
FIG. 2 is a diagram showing the contents of configuration control information and AIR information included in the information.
[Figure 3] Transition diagram of logical disk status when a logical disk is relocated and expanded
FIG. 4 is a diagram showing changes in the cluster configuration when a logical disk is relocated and expanded.
FIG. 5 is a processing flow of the array controller when a logical disk status change request is received from a higher-level device.
FIG. 6 shows the processing flow of the array controller when a new logical disk is inserted.
FIG. 7 is a diagram showing an example of logical disk allocation and a raid mode of each logical disk.
FIG. 8 is a diagram showing an example of logical disk allocation and a raid mode of each logical disk.
FIG. 9 is a perspective view showing the entire array disk device.
FIG. 10 is a front view and a side view showing the entire array disk device.
FIG. 11 is a perspective view of a card drive.

Claims (2)

An array disk device capable of constructing a plurality of logical disks composed of a plurality of physical disks,
A drive module group comprising a plurality of physical disks for storing data transferred to and from the host device;
A physical disk for storing redundant data created from data stored in the plurality of physical disks;
At least one array that receives a command issued from the host device, analyzes its contents, changes the status of the physical disk selected by the command, and controls transfer data between the host device and the physical disk A controller,
A plurality of logical disks are configured in the drive module group,
Each of the logical disks includes a selected physical disk of the plurality of physical disks;
Each of the selected physical disks has configuration information including physical location information in the drive module group of all physical disks in the logical disk and logical combination information in the logical disk;
When the physical position information recorded on the physical disk in the logical disk is different from the physical position information in the drive module group in which the physical disk is actually mounted,
An array disk device, wherein the array controller reconfigures a logical disk without changing logical combination information in the logical disk by changing physical position information recorded on the physical disk . 2. The disk array device according to claim 1 , further comprising means for the array controller to change physical position information recorded on the physical disk in accordance with an instruction issued from the host device.

Images