JP2017130130A - Storage device, virtual volume control system, and virtual volume control method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a storage device, a virtual volume control system, and a virtual volume control method, with which, when allocating a virtual volume to one virtual machine (VM), it is possible to allocate a new virtual volume to the VM even when there is no logical volume associated with the VM or there is no free space for adding a virtual volume to an associated logical volume.SOLUTION: When there is no LU 20 associated with a VM 3, an LU control unit 12 combines unused spaces of a plurality of storage devices 30 and logically creates a new LU 20. Furthermore, when there is an UL 20 associated with the VM 3, the LU control unit 12 combines unused spaces of the plurality of storage devices 30 and logically extends the LU 20 by an amount equal to a VVOL capacity included in a VVOL creation indication.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a storage apparatus, a virtual volume control system, and a virtual volume control method, and more particularly to a storage apparatus, a virtual volume control system, and a virtual volume control method that allocate a virtual volume to a virtual machine.

  In a SAN (abbreviation of “Storage Area Network”), which is a network connecting a host computer and a storage device, the host computer uses a block level protocol (for example, Fiber Channel) to connect to. Exchange data with the storage device. In addition, a disk array device is often used as a storage device. The disk array device provides an LU (abbreviation of “Logical Unit”), which is a logical storage, to a host computer.

  In addition, virtualization technology for host computers and servers has become common, and depending on the system, virtual machines (hereinafter also referred to as “VM (Virtual Machine)”) on the scale of hundreds to tens of thousands are created. Each VM requires a plurality of storages. It is very troublesome for an administrator to map the storage used by these many VMs to a logical storage and manage it manually.

  In the technique described in Patent Document 1, volume management information in which a logical volume (corresponding to an LU) is associated with a plurality of virtual volumes obtained by logically dividing the logical volume is prepared. Then, the plurality of volumes requested by the VM are automatically allocated to the free area (unused area) of the logical volume in the storage apparatus as a virtual volume. Then, the allocated virtual volume can be used in association with the requested VM. As a result, the necessary number of volumes can be automatically allocated to the VM at the required timing, and the workload of the administrator is greatly reduced.

  In Patent Document 2, even when a configuration change (addition, deletion, migration) of a virtual device (corresponding to a VM) is performed, assignment of a virtual logical volume, partitioning of a storage area, and the like do not occur. A technique that can reduce the user's workload is described.

JP 2012-079245 A JP 2010-140273 A

  In Patent Document 1, identification information of a VM that can access a logical volume is held as volume security information. However, there is no description of processing when identification information indicating the requesting VM does not exist in the volume security information when a virtual volume is allocated to a plurality of volumes requested by the VM. Therefore, when the identification information indicating the requesting VM does not exist in the volume security information, there is a problem that a virtual volume cannot be assigned to that VM.

  In addition, even if there is free space on the actual physical disk, if there is no free space allocated to the logical volume or if it is less than the required capacity, the virtual volume allocation process will fail. .

  Note that Patent Document 2 does not describe any configuration change technique when a virtual volume is allocated to one virtual device.

  An object of the present invention is to allocate a virtual volume to one VM (virtual machine), even if there is no logical volume associated with the VM, and a free space for adding a virtual volume to the associated logical volume. To provide a storage device, a virtual volume control system, and a virtual volume control method capable of allocating a new virtual volume to a VM even when there is no data.

The storage apparatus of the present invention
A plurality of storage devices;
A logical volume that is made redundant by combining the storage devices and assigned logical volume identification information for identifying each of the storage devices;
A virtual volume obtained by logically dividing the logical volume, to which virtual volume identification information for identifying each is assigned;
Logical volume information storage means for holding virtual machine identification information assigned to each virtual machine to identify at least one virtual machine and the logical volume identification information in association with each other;
Logical volume control means, and
The logical volume control means includes
Obtaining first virtual machine identification information indicating one virtual machine, and a first capacity value indicating a size of a first virtual volume allocated to the virtual machine;
When logical volume identification information associated with the first virtual machine identification information exists in the logical volume information storage unit, the first logical volume indicated by the logical volume identification information is the same as the first capacity value. Logically expanding by combining unused areas of the storage device by the amount, and making the expanded portion the first virtual volume,
On the other hand, if there is no logical volume identification information associated with the first virtual machine identification information in the logical volume information storage means, the unused capacity of each storage device is combined and the same as the first capacity value A second logical volume having a size is created, the created second logical volume is defined as the first virtual volume, and the second logical volume is associated with the first virtual machine identification information and indicates the second logical volume. Volume identification information is registered in the logical volume information storage means.

The virtual volume control system of the present invention is
At least one virtual machine to which virtual machine identification information for identifying each is assigned;
A storage controller;
A storage device connected to the virtual machine and the storage control device,
The storage control device issues a virtual volume allocation instruction including first virtual machine identification information indicating one virtual machine and a first capacity value indicating the size of the first virtual volume allocated to the virtual machine. Sent to the storage device,
The storage device
A plurality of storage devices;
A logical volume that is made redundant by combining the storage devices and assigned logical volume identification information for identifying each of the storage devices;
A virtual volume obtained by logically dividing the logical volume, to which virtual volume identification information for identifying each is assigned;
Logical volume information storage means for associating and holding the virtual machine identification information and the logical volume identification information;
Logical volume control means, and
The logical volume control means acquires the virtual volume allocation instruction, and when the logical volume identification information associated with the first virtual machine identification information exists in the logical volume information storage means, the logical volume identification information The logical volume of the first logical volume indicated by is combined with the unused area of the storage device by the same amount as the first capacity value, and the expanded portion is used as the first virtual volume, When the logical volume identification information associated with the first virtual machine identification information does not exist in the logical volume information storage means, the unused area of each storage device is combined to have the same size as the first capacity value Creating a second logical volume, making the created second logical volume the first virtual volume, and The logical volume identification information indicating the second logical volume associated with the first virtual machine identification information registered in the logical volume information storage means.

Further, the virtual volume control method of the present invention includes:
Obtaining first virtual machine identification information indicating one virtual machine and a first capacity value indicating the size of a first virtual volume to be allocated to the virtual machine;
When logical volume identification information indicating a logical volume associated with the first virtual machine identification information exists in the logical volume information storage means, the first logical volume indicated by the logical volume identification information is stored in the first capacity. The unused areas of a plurality of storage devices are logically expanded by the same amount as the value, and the expanded part is used as the first virtual volume,
On the other hand, if there is no logical volume identification information associated with the first virtual machine identification information in the logical volume information storage means, the unused capacity of each storage device is combined and the same as the first capacity value A second logical volume having a size is created, the created second logical volume is defined as the first virtual volume, and the second logical volume is associated with the first virtual machine identification information and indicates the second logical volume. Volume identification information is registered in the logical volume information storage means.

The virtual volume control program of the present invention is
An acquisition process for acquiring first virtual machine identification information indicating one virtual machine and a first capacity value indicating the size of a first virtual volume allocated to the virtual machine;
When logical volume identification information associated with the first virtual machine identification information exists in the logical volume information storage means, the first logical volume indicated by the logical volume identification information is assigned the same capacity as the first capacity value. A virtual volume expansion process in which unused areas of a plurality of storage devices are combined and logically expanded, and the expanded portion is the first virtual volume;
On the other hand, if there is no logical volume identification information associated with the first virtual machine identification information in the logical volume information storage means, the unused capacity of each storage device is combined and the same as the first capacity value A second logical volume having a size is created, the created second logical volume is defined as the first virtual volume, and the second logical volume is associated with the first virtual machine identification information and indicates the second logical volume. And causing the computer to execute virtual volume creation processing for registering volume identification information in the logical volume information storage means.

  In the present invention, when a virtual volume is allocated to one VM (virtual machine), even when there is no logical volume associated with the VM, there is a free space for adding a virtual volume to the associated logical volume. Even if there is not, there is an effect that a new virtual volume can be allocated to the VM.

It is a block diagram which shows the 1st Embodiment of this invention. It is a figure which shows an example of the logical volume table 151 in 1st Embodiment. It is a figure which shows an example of the virtual volume table 152 in 1st Embodiment. FIG. 5 is a schematic diagram of an LU 20 based on an example of information stored in a logical volume table 151 shown in FIG. 2 and a virtual volume table 152 shown in FIG. 3 in the first embodiment. 4 is a flowchart showing the operation of the disk array control device 2 in the first embodiment. It is a flowchart which shows operation | movement of the controller 10 in 1st Embodiment. It is a figure which shows the other example of the logical volume table 151 in 1st Embodiment. It is a figure which shows the other example of the virtual volume table 152 in 1st Embodiment. FIG. 9 is a schematic diagram of an LU 20 based on an example of information stored in a logical volume table 151 shown in FIG. 7 and a virtual volume table 152 shown in FIG. 8 in the first embodiment. It is a block diagram which shows the 2nd Embodiment of this invention.

  Next, embodiments of the present invention will be described in detail with reference to the drawings.

[First Embodiment]
FIG. 1 is a block diagram showing a first embodiment of the present invention.

  Referring to FIG. 1, this system includes a disk array device 1, a disk array control device 2, at least one virtual machine (VM) 3 assigned with unique VM identification information for identifying each, and a VM control device. 4 is included. The VM 3 and the disk array device 1 are connected via a SAN. Further, the VM 3 and the VM control device 4, the VM control device 4 and the disk array control device 2, and the disk array control device 2 and the disk array device 1 are connected via a communication network such as a LAN (abbreviation of “Local Area Network”). Connected. The disk array control device 2 may be in the disk array device 1.

  The disk array device 1 includes a controller 10, a plurality of physical storage devices 30, and at least one LU (hereinafter referred to as “logical volume”) that is a logical storage made redundant by combining the plurality of storage devices 30. 20). Note that LUNs (abbreviation of “Logical Unit Number”), which are information for identifying within the disk array device 1, are assigned to the LUs 20, respectively. The storage device 30 is generally an HDD (abbreviation of “Hard Disk Drive”) or SSD (abbreviation of “Solid State Drive”), but is not limited thereto.

  The controller 10 includes a control unit 11 that transmits / receives data to / from the VM 3 and reads / writes data to / from the LU 20, a storage unit 15 that includes the logical volume table 151 and the virtual volume table 152, and the LU 20 creation, expansion, and storage unit 15 And an LU control unit 12 that controls each included table.

  The controller 10 includes a storage device (not shown) that stores a program and at least one processor (not shown) that reads the program into the memory and executes instructions.

  The VM control device 4 controls resources such as a CPU, a memory, and a disk used by the VM 3. Also, the disk array control device 2 is sent with a disk volume allocation instruction required by the VM 3.

  The disk array control device 2 creates a virtual volume (hereinafter also referred to as “VVOL (Virtual Volume)”) created by logically dividing the LU 20 based on the disk volume allocation instruction received from the VM control device 4. Is sent to the disk array device 1.

  FIG. 2 is a diagram showing an example of the logical volume table 151 in the present embodiment.

  Referring to FIG. 2, the logical volume table 151 includes an in-device LUN column, an LU capacity column, a logical sector column, and a VM identification column.

  In the in-device LUN column, a LUN for identifying the LU 20 in the disk array device 1 is registered in advance.

  In the LU capacity column, a value indicating the size (capacity) of the LU indicated by the LUN registered in the in-device LUN column is registered.

  Registered in the logical sector column is a logical area of the LU in the form of “value indicating start sector (hexadecimal number) to value indicating end sector (hexadecimal number)”.

  In the VM identification column, VM identification information indicating the VM 3 to which the LU is assigned is registered.

  For example, referring to the record in the first row in FIG. 2, “1” is registered in the in-device LUN column, “4 GB” is registered in the LU capacity column, and “0-7FFFFF” is registered in the logical sector column. “VM-A” is registered in the VM identification column. That is, an LU with a LUN of 1 has a size of 4 GB (gigabytes), exists in an area from 0 (zero) sector to 7FFFFF sector (hexadecimal number), and the allocated VM3 is identified as VM-A. It can be seen that this is VM3 indicated by the information. It is assumed that the capacity of one sector of the LU 20 is 512 bytes.

  FIG. 3 is a diagram showing an example of the virtual volume table 152 in the present embodiment. The virtual volume table 152 holds the information of the LU 20 and the information of the virtual volume (VVOL) generated by logically dividing the LU 20 in association with each other.

  Referring to FIG. 3, the virtual volume table 152 includes a VVOL identification column, a VM identification column, a VVOL capacity column, a virtual logical sector column, an in-device LUN column, and a logical sector column.

  In the VVOL identification column, VVOL identification information that is identification information assigned to each VVOL in order to identify the VVOL in the disk array device 1 is registered.

  In the VM identification column, VM identification information indicating the VM 3 to which the VVOL indicated by the VVOL identification information registered in the VVOL identification column is assigned is registered.

  A value indicating the size (capacity) of the VVOL is registered in the VVOL capacity column.

  In the virtual logical sector column, a virtual area of the VVOL is registered in the format of “value indicating start sector (hexadecimal number) to value indicating end sector (hexadecimal number)”.

  The LUN indicating the LU 20 in which the VVOL is generated is registered in the in-device LUN column.

  In the logical sector column, a value indicating a logical area in the LU 20 indicated by the LUN registered in the in-device LUN column of the VVOL is expressed as “value indicating start sector (hexadecimal) to value indicating end sector ( Hexadecimal number) "format is registered.

  For example, referring to the record in the first row in FIG. 3, “1” is registered in the VVOL identification field, “VM-A” is registered in the VM identification field, and “4 GB” is registered in the VVOL capacity field. Then, “0-7FFFFF” is registered in the virtual logical sector column, “1” is registered in the in-device LUN column, and “0-7FFFFF” is registered in the logical sector column.

  In other words, a VVOL with a VVOL identification of 1 is an allocated VM 3 is a VM 3 indicated by identification information VM-A, has a size of 4 GB (gigabytes), and a virtual area ranges from 0 sector to 7 FFFFF sector It is understood that the LUN indicating the LU 20 generated by itself is 1 and the logical area of the LU 20 within the LU 20 is from 0 sector to 7FFFFF sector (hexadecimal number). In this state, since one VVOL is generated in the LU 20 having the LUN 1, the value indicating the virtual area stored in the virtual logical sector column and the logical volume stored in the logical sector column are displayed. This value is the same as the value indicating the correct area.

  4 is a schematic diagram of the LU 20 based on an example of information stored in the logical volume table 151 shown in FIG. 2 and the virtual volume table 152 shown in FIG.

  Referring to FIG. 4, the LU 20 assigned to the VM 3 indicated by the VM identification information “VM-A” has a LUN “1”, and the logical area is from 0 sector to 7FFFFF sector. Then, only one virtual volume is created in the LU 20, the VVOL identification of the virtual volume is “1”, and it can be seen that the virtual area is from sector 0 to sector 7FFFFF.

  Next, operations of the disk array control device 2 and the disk array device 1 when creating a virtual volume (VVOL) will be described with reference to the flowcharts of FIGS.

  FIG. 5 is a flowchart showing the operation of the disk array control apparatus 2 when creating a virtual volume (VVOL).

  Referring to FIG. 5, first, the disk array control device 2 receives a volume allocation instruction including the necessary disk volume capacity and VM identification information indicating the VM 3 to which the disk volume is allocated from the VM control device 4 (step). S101). Then, the disk array control device 2 generates a VVOL creation instruction based on the volume assignment instruction and sends it to the disk array device 1 (step S102). The VVOL creation instruction to be sent includes VM identification information included in the volume allocation instruction and a value indicating the VVOL capacity to be created (that is, the same capacity as the required disk volume capacity).

  Next, based on the VVOL creation instruction, the disk array control device 2 includes VVOL identification information indicating the VVOL created by the disk array device 1 and a value indicating a virtual logical sector indicating the virtual area of the VVOL. Receive creation completion notification. Then, the disk array control device 2 sends an allocation completion notification including the VVOL identification information and a value indicating the virtual logical sector to the VM control device 4 (step S103).

  FIG. 6 is a flowchart showing the operation of the controller 10 included in the disk array device 1 when a VVOL creation instruction is received from the disk array control device 2.

  Referring to FIG. 6, first, the LU control unit 12 included in the controller 10 receives a VVOL creation instruction from the disk array control apparatus 2 (step S201).

  The LU control unit 12 searches the VM identification column of the logical volume table 151 based on the VM identification information included in the VVOL creation instruction, and checks whether there is a record including the same VM identification information (step S202). .

  When there is a record in which the same VM identification information as the VM identification information included in the VVOL creation instruction is registered (in the case of “YES” in step S202), the LU control unit 12 is stored in the in-device LUN column of the record. Get LUN Then, the LU control unit 12 logically expands the capacity of the LU 20 indicated by the LUN by combining unused areas of the storage device 30 by the VVOL capacity included in the VVOL creation instruction (step S203).

  Next, the LU control unit 12 updates the LU capacity column and the logical sector column of the logical volume table 151 with the capacity of the expanded LU 20 and the logical sector value indicating the logical area of the expanded LU 20. (Step S204). That is, the LU control unit 12 updates the value registered in the LU capacity column with a value obtained by adding the newly expanded capacity to the capacity of the existing LU 20. The LU control unit 12 adds the number of sectors corresponding to the newly expanded capacity to the end sector value among the start sector value and end sector value indicating the existing LU 20 area registered in the logical sector column. Update with the number of sectors. Then, the logical sector column is updated in the format of “value indicating start sector to value indicating updated end sector”.

  Next, the LU control unit 12 adds the extended portion of the LU 20 expanded in step S203 to the virtual volume table 152 as a new VVOL (step S205). That is, newly determined VVOL identification information is registered in the VVOL identification field, and VM identification information included in the VVOL creation instruction is registered in the VM identification field. The expanded capacity of the LU 20 (that is, a new VVOL capacity) is registered in the VVOL capacity column, and the LUN indicating the expanded LU 20 is registered in the in-device LUN field.

  Then, the LU control unit 12 registers a value indicating the virtual area of the new VVOL in the virtual logical sector column. That is, 0 (zero) sector is set as the start sector, and the number of sectors corresponding to the expanded capacity is set as the end sector, and registered in the format of “value indicating start sector to value indicating end sector”.

  Then, the LU control unit 12 registers a value indicating a logical area in the LU 20 of the new VVOL in the logical sector column. That is, the record having the largest end sector value in the logical sector column is selected from the records having the same LUN registered in the in-device LUN column. Then, a value obtained by adding one sector to the value of the end sector is set as a start sector, and a sector obtained by adding the value of the number of sectors corresponding to the additional capacity to the start sector is set as a value of the end sector. Then, it is registered in the logical sector column in the format of “value indicating start sector to value indicating end sector”.

  Next, the LU control unit 12 sends a VVOL creation completion notification including VVOL identification information indicating the new VVOL and a value in the virtual logical sector column indicating the virtual area of the VVOL to the disk array control device 2 ( Step S206).

  Here, for example, the logical volume table 151 and the virtual volume table 152 when a VVOL having a capacity of 40 GB allocated to the VM 3 indicated by the VM identification information VM-A is newly created are shown in FIG. 7 and FIG. It is shown in FIG.

  Referring to FIG. 7, compared with the contents of the original logical volume table 151 shown in FIG. 2, the value registered in the LU capacity column is updated to 44 GB by adding 40 GB corresponding to the expansion of LU 20. Further, the end sector of the logical sector column is updated to “0 to 57FFFFF” by adding the number of sectors of 40 GB corresponding to the expansion of LU20.

  Referring to FIG. 8, a record indicating a newly created VVOL is added as compared to the original virtual volume table 152 shown in FIG. That is, it can be seen that the new VVOL has a VVOL identification of “2”, the allocated VM 3 is a VM 3 indicated by the identification information “VM-A”, and has a size of 40 GB. The virtual logical sector of the new VVOL is from 0 sector to 4FFFFFF sector (hexadecimal number), the LUN indicating the LU 20 generated by itself is 1, and its logical area in the LU 20 is 800000. It can be seen from the sector (hexadecimal number) to the 57FFFFF sector (hexadecimal number).

  FIG. 9 is a schematic diagram of the LU 20 based on an example of information stored in the logical volume table 151 shown in FIG. 7 and the virtual volume table 152 shown in FIG.

  Referring to FIG. 9, the LU 20 assigned to the VM 3 indicated by the VM identification information “VM-A” has a LUN “1”, and the logical area is from 0 sector to 57 FFFFF sector. In the LU 20, two virtual volumes with VVOL identifications “1” and “2” are created. In other words, the VVOLs assigned to the VM 3 indicated by the VM identification information “VM-A” are the two VVOLs having VVOL identifications “1” and “2”.

  It can be seen that a VVOL whose VVOL identification is “1” includes both a logical area in the LU 20 and a virtual area as a VVOL from the 0 sector to the 7FFFFF sector. Further, it can be seen that a VVOL having a VVOL identification of “2” has a logical area in the LU 20 from 800,000 to 57FFFFF sectors, and a virtual area as a VVOL is from 0 to 4FFFFFF sectors.

  Returning to the flowchart of FIG.

  In step S202, when there is no record in which the same VM identification information as the VM identification information included in the VVOL creation instruction is registered in the logical volume table 151 (in the case of “NO” in step S202), the LU control unit 12 A new LU 20 is created based on the creation instruction (step S207). That is, the LU control unit 12 logically creates an LU 20 having the same capacity as the VVOL capacity included in the VVOL creation instruction by combining unused areas of a plurality of storage devices 30.

  Next, the LU control unit 12 adds information indicating the newly created LU 20 to the logical volume table 151 (step S208). That is, the LU control unit 12 registers the newly determined LUN in the in-device LUN column, and registers the value of the VVOL capacity included in the VVOL creation instruction in the LU capacity column. Further, the VM identification information included in the VVOL creation instruction is registered in the VM identification field, and the start sector value and end sector value indicating the logical area of the created LU 20 are displayed in the logical sector field. The value is registered in the format of “value to value indicating end sector” (at this time, the start sector is 0 (zero) sector, and the end sector is a value obtained by subtracting 1 from the number of sectors corresponding to the created capacity).

  Next, the LU control unit 12 adds the newly created LU 20 to the virtual volume table 152 as a new VVOL (step S205). That is, newly determined VVOL identification information is registered in the VVOL identification field, and VM identification information included in the VVOL creation instruction is registered in the VM identification field. Then, the capacity of the newly created LU 20 (that is, the new VVOL capacity) is registered in the VVOL capacity field, and the LUN indicating the created LU 20 is registered in the in-device LUN field.

  The LU control unit 12 registers a value indicating a logical area in the LU 20 of the new VVOL in the logical sector column. That is, the same value as that registered in the logical sector column of the logical volume table 151 is registered.

  Then, the LU control unit 12 registers a value indicating the virtual area of the new VVOL in the virtual logical sector column. That is, the same value as the value indicating the area registered in the logical sector column is registered.

  Next, the LU control unit 12 sends a VVOL creation completion notification including VVOL identification information indicating the new VVOL and a value in the virtual logical sector column indicating the virtual area of the VVOL to the disk array control device 2 ( Step S206).

  In this way, the LU control unit 12 creates a new VVOL even when there is no already assigned LU 20 in the VM 3 indicated by the VM identification information included in the VVOL creation instruction received from the disk array control device 2. Can be created and assigned.

  As described above, in this embodiment, when a virtual volume is allocated to one VM (virtual machine), even if there is no logical volume associated with the VM, a new logical volume and virtual volume are created and the VM is created. Can be assigned. Further, even when there is no free space for adding a virtual volume to the associated logical volume, there is an effect that the logical volume can be expanded and the virtual volume can be allocated to the VM.

  The reason is that when there is no LU 20 associated with the VM 3 (that is, when there is no record in the logical volume table 151 in which the same VM identification information as the VM identification information included in the VVOL creation instruction is registered), the LU The control unit 12 logically creates a new LU 20 by combining unused areas of the plurality of storage devices 30. When there is an LU 20 associated with the VM 3 (that is, when there is a record in which the same VM identification information as the VM identification information included in the VVOL creation instruction is registered in the logical volume table 151), the LU control unit 12 This is because the LU 20 is logically expanded by combining unused areas of the storage device 30 by the amount of the VVOL capacity included in the VVOL creation instruction.

[Second Embodiment]
Next, a second embodiment including the basic configuration of the first embodiment of the present invention will be described.

  FIG. 10 is a block diagram showing this embodiment.

  Referring to FIG. 10, the disk array device 5 includes a plurality of physical storage devices 70, a logical volume 60, a virtual volume 80 obtained by logically dividing the logical volume 60, a logical volume control unit 52, and a logical volume. Information storage unit 551.

  The logical volume 60 is a logical storage that is made redundant by combining a plurality of storage devices 70 and assigned logical volume identification information for identifying each.

  Virtual volume identification information for identifying each is assigned to the virtual volume 80.

  The logical volume information storage unit 551 is accessed by the virtual machine identification information assigned to each virtual machine to identify at least one virtual machine (not shown) connected to the disk array device 5 and the virtual machine. The logical volume identification information assigned to the possible logical volume 60 is held in association with it.

  The logical volume control unit 52 obtains first virtual machine identification information indicating one virtual machine (not shown) and a first capacity value indicating the size of the first virtual volume assigned to the virtual machine. To do. Then, the logical volume control unit 52 determines whether or not there is logical volume identification information associated with the first virtual machine identification information in the logical volume information storage unit 551.

  When the logical volume identification information associated with the first virtual machine identification information exists in the logical volume information storage unit 551, the logical volume control unit 52 selects the first logical volume indicated by the logical volume identification information as the first logical volume. The unused area of the storage device 70 is combined and logically expanded by the same amount as the capacity value of 1. Then, the logical volume control unit 52 allocates the expanded part as the first virtual volume.

  On the other hand, when there is no logical volume identification information associated with the first virtual machine identification information in the logical volume information storage unit 551, the logical volume control unit 52 combines the unused areas of the storage device 70 with the first area. A second logical volume having the same size as the capacity value is created. Then, the logical volume control unit 52 allocates the second logical volume as the first virtual volume, associates the logical volume identification information indicating the second logical volume with the first virtual machine identification information, and sets the logical volume information. Register in the storage unit 551.

  As described above, in this embodiment, as in the first embodiment, when a virtual volume is assigned to one virtual machine, even if there is no logical volume associated with the virtual machine, a new logical volume and virtual volume are created. Can be created and assigned to a virtual machine. In addition, even when there is no space for adding a virtual volume to the associated logical volume, the logical volume can be expanded and the virtual volume can be allocated to the virtual machine.

  The reason is that when there is no logical volume associated with the virtual machine (that is, when there is no logical volume identification information associated with the first virtual machine identification information in the logical volume information storage unit 551), The volume control unit 52 creates a second logical volume by combining unused areas of the plurality of storage devices 70. When there is a logical volume associated with the virtual machine (that is, when logical volume identification information associated with the first virtual machine identification information exists in the logical volume information storage unit 551), a logical volume control unit This is because the first logical volume indicated by the logical volume identification information 52 is logically expanded by combining unused areas of the storage device 70 by the same amount as the first capacity value.

1 disk array device 2 disk array control device 3 VM
4 VM control device 5 Disk array device 10 Controller 11 Control unit 12 LU control unit 15 Storage unit 20 LU
30 storage device 52 logical volume control unit 60 logical volume 70 storage device 80 virtual volume 151 logical volume table 152 virtual volume table 551 logical volume information storage unit

Claims (10)

A plurality of storage devices;
A logical volume that is made redundant by combining the storage devices and assigned logical volume identification information for identifying each of the storage devices;
A virtual volume obtained by logically dividing the logical volume, to which virtual volume identification information for identifying each is assigned;
Logical volume information storage means for holding virtual machine identification information assigned to each virtual machine to identify at least one virtual machine and the logical volume identification information in association with each other;
Logical volume control means, and
The logical volume control means includes
Obtaining first virtual machine identification information indicating one virtual machine, and a first capacity value indicating a size of a first virtual volume allocated to the virtual machine;
When logical volume identification information associated with the first virtual machine identification information exists in the logical volume information storage unit, the first logical volume indicated by the logical volume identification information is the same as the first capacity value. Logically expanding by combining unused areas of the storage device by the amount, and making the expanded portion the first virtual volume,
On the other hand, if there is no logical volume identification information associated with the first virtual machine identification information in the logical volume information storage means, the unused capacity of each storage device is combined and the same as the first capacity value A second logical volume having a size is created, the created second logical volume is defined as the first virtual volume, and the second logical volume is associated with the first virtual machine identification information and indicates the second logical volume. A storage apparatus for registering volume identification information in the logical volume information storage means. Virtual volume information storage means for holding the virtual machine identification information, the logical volume identification information, and the virtual volume identification information in association with each other;
The logical volume control means includes
When the first logical volume is expanded, virtual volume identification information indicating the first virtual volume, first virtual machine identification information, and logical volume identification information indicating the first logical volume are included. In association with the virtual volume information storage means,
On the other hand, when the second logical volume is created, virtual volume identification information indicating the first virtual volume, first virtual machine identification information, and logical volume identification information indicating the second logical volume The storage apparatus according to claim 1, wherein the information is registered in the virtual volume information storage unit. The logical volume control means is a value of a first logical area indicating a logical area of the expanded first logical volume, or a second logical area indicating a logical area of the second logical volume. The storage apparatus according to claim 1 or 2, wherein each value is registered in the logical volume information storage unit in association with the logical volume identification information indicated by the first or second logical volume. The logical volume control means uses a value of a first virtual area indicating a virtual area in the first or second logical volume of the first virtual volume as a virtual value indicating the first virtual volume. The storage apparatus according to claim 2, wherein the storage apparatus is registered in the virtual volume information storage unit in association with volume identification information. At least one virtual machine to which virtual machine identification information for identifying each is assigned;
A storage controller;
A storage device connected to the virtual machine and the storage control device,
The storage control device issues a virtual volume allocation instruction including first virtual machine identification information indicating one virtual machine and a first capacity value indicating the size of the first virtual volume allocated to the virtual machine. Sent to the storage device,
The storage device
A plurality of storage devices;
A logical volume that is made redundant by combining the storage devices and assigned logical volume identification information for identifying each of the storage devices;
A virtual volume obtained by logically dividing the logical volume, to which virtual volume identification information for identifying each is assigned;
Logical volume information storage means for associating and holding the virtual machine identification information and the logical volume identification information;
Logical volume control means, and
The logical volume control means acquires the virtual volume allocation instruction, and when the logical volume identification information associated with the first virtual machine identification information exists in the logical volume information storage means, the logical volume identification information The logical volume of the first logical volume indicated by is combined with the unused area of the storage device by the same amount as the first capacity value, and the expanded portion is used as the first virtual volume, When the logical volume identification information associated with the first virtual machine identification information does not exist in the logical volume information storage means, the unused area of each storage device is combined to have the same size as the first capacity value Creating a second logical volume, making the created second logical volume the first virtual volume, and Virtual volume control system for registering a logical volume identification information indicating the second logical volume to the logical volume information storage means in association with the first virtual machine identification information. The storage device further includes virtual volume information storage means for associating and holding the virtual machine identification information, the logical volume identification information, and the virtual volume identification information,
The logical volume control means includes
When the first logical volume is expanded, virtual volume identification information indicating the first virtual volume, first virtual machine identification information, and logical volume identification information indicating the first logical volume are included. In association with the virtual volume information storage means,
On the other hand, when the second logical volume is created, virtual volume identification information indicating the first virtual volume, first virtual machine identification information, and logical volume identification information indicating the second logical volume The virtual volume control system according to claim 5, wherein the virtual volume information storage unit is registered in association with each other. The logical volume control means includes virtual volume identification information indicating the first virtual volume, and a value of a first virtual area indicating a virtual area of the virtual volume in the first or second logical volume. The virtual volume control system according to claim 5 or 6, wherein a virtual volume allocation completion notification including: is sent to the storage control device. Obtaining first virtual machine identification information indicating one virtual machine and a first capacity value indicating the size of a first virtual volume to be allocated to the virtual machine;
When logical volume identification information indicating a logical volume associated with the first virtual machine identification information exists in the logical volume information storage means, the first logical volume indicated by the logical volume identification information is stored in the first capacity. The unused areas of a plurality of storage devices are logically expanded by the same amount as the value, and the expanded part is used as the first virtual volume,
On the other hand, if there is no logical volume identification information associated with the first virtual machine identification information in the logical volume information storage means, the unused capacity of each storage device is combined and the same as the first capacity value A second logical volume having a size is created, the created second logical volume is defined as the first virtual volume, and the second logical volume is associated with the first virtual machine identification information and indicates the second logical volume. A virtual volume control method for registering volume identification information in the logical volume information storage means. When the first logical volume is expanded, virtual volume identification information indicating the first virtual volume, first virtual machine identification information, and logical volume identification information indicating the first logical volume are included. In association with the virtual volume information storage means,
On the other hand, when the second logical volume is created, virtual volume identification information indicating the first virtual volume, first virtual machine identification information, and logical volume identification information indicating the second logical volume The virtual volume control method according to claim 8, wherein the virtual volume information storage unit is registered in association with each other. An acquisition process for acquiring first virtual machine identification information indicating one virtual machine and a first capacity value indicating the size of a first virtual volume allocated to the virtual machine;
When logical volume identification information associated with the first virtual machine identification information exists in the logical volume information storage means, the first logical volume indicated by the logical volume identification information is assigned the same capacity as the first capacity value. A virtual volume expansion process in which unused areas of a plurality of storage devices are combined and logically expanded, and the expanded portion is the first virtual volume;
On the other hand, if there is no logical volume identification information associated with the first virtual machine identification information in the logical volume information storage means, the unused capacity of each storage device is combined and the same as the first capacity value A second logical volume having a size is created, the created second logical volume is defined as the first virtual volume, and the second logical volume is associated with the first virtual machine identification information and indicates the second logical volume. A virtual volume control program for causing a computer to execute virtual volume creation processing for registering volume identification information in the logical volume information storage means.

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