JP2014041454A - Disaster recovery system, disaster recovery method, and program - Google Patents

Abstract

Even if a plurality of sites have recovery sites, it is easy to move a system operation site.
When the stop of the primary site 11 is notified, the primary site 11 stops the backup from the primary site 11 to the recovery sites 12 and 13 by the disaster recovery software S1 and stops the primary site 11 in a planned manner. Then, at the recovery site 12, the backup by the disaster recovery software S1 is reflected (synchronized), and the recovery site 12 is changed to the primary site. At this time, since the recovery site 12 that has already become the primary site has been set up for backup by the disaster recovery software S1, it is not necessary to reset the new backup.
[Selection] Figure 2

Description

  The present invention relates to recovery of a data processing service, and more particularly to a technique effective for disaster recovery for recovering and repairing a system.

  Disaster recovery (DR) is widely known as a technology for efficiently and quickly recovering and restoring a system damaged by a natural disaster or the like.

  As a technique for realizing this type of disaster recovery, for example, a disk on the DR site side is not subjected to a large load on the line by data transfer without grouping a plurality of disks on the primary site side, and at the time of recovery. A disaster recovery system is known in which the consistency of the system is maintained using a stationary point (see Patent Document 1).

  This disaster recovery system includes a consistency management device that manages data consistency by combining a quiesce point for each disk at the primary site, and a disk that serves as a recovery point at the time of recovery at the DR site. And a recovery point management device that determines that each quiesce point maintains data consistency among a plurality of disks at the DR site.

JP 2010-217993 A

  However, the present inventors have found that the above-described disaster recovery technology has the following problems.

  When a problem such as widespread damage or power shortage occurs due to a natural disaster or the like, it is considered necessary to have a service that has recovery sites at multiple sites and that allows easy movement of the system operation site.

  However, the above-described Patent Document 1 has a problem in that a service that allows easy movement of the system operation site cannot be provided because a disaster recovery site is not provided at a plurality of locations.

  An object of the present invention is to provide a disaster recovery technique capable of easily moving a system operation site even when recovery sites are provided at a plurality of bases.

  The above and other objects and novel features of the present invention will be apparent from the description of this specification and the accompanying drawings.

  Of the inventions disclosed in the present application, the outline of typical ones will be briefly described as follows.

  In order to achieve the above-described object, the present invention implements a mechanism that facilitates movement of an operation site (primary site) that provides services by taking backups at a primary site at a plurality of recovery sites.

  The present invention is a disaster recovery system having a primary site and N recovery sites that provide services on behalf of the primary site when the primary site stops.

  These N recovery sites are backed up at the primary site by disaster recovery software during normal operation of the primary site.

  The present invention is also applicable to a method using a computer system having a primary site and N recovery sites that provide services on behalf of the primary site when the primary site is stopped, and a program that causes the computer system to function. Can do.

  Among the inventions disclosed in the present application, effects obtained by typical ones will be briefly described as follows.

  (1) The processing time required for the planned stoppage in the disaster recovery system can be shortened.

  (2) It is possible to prevent an increase in operation errors of the disaster recovery system.

  (3) With the above (1) and (2), the operational quality in the disaster recovery system can be greatly improved.

It is explanatory drawing which shows an example of the disaster recovery system which takes object backup between the three bases by Embodiment 1 of this invention. It is explanatory drawing which shows an example which changes a primary site in the disaster recovery system of FIG. It is explanatory drawing which shows an example of the process sequence of FIG. It is explanatory drawing which shows the other example which changes a primary site in the disaster recovery system of FIG. It is explanatory drawing which shows an example of the process sequence of FIG. It is explanatory drawing which shows an example of the disaster recovery system which takes asymmetric backup between three bases which this inventor examined. It is explanatory drawing which shows an example which changes a primary site in the disaster recovery system of FIG. It is explanatory drawing which shows an example of the process sequence of FIG. FIG. 7 is an explanatory diagram showing another example of changing the primary site in the disaster recovery system of FIG. 6. It is explanatory drawing which shows an example of the process sequence of FIG. It is explanatory drawing which shows an example of the disaster recovery system which takes object backup between the four bases by Embodiment 2 of this invention. It is explanatory drawing which shows an example which changes a primary site in the disaster recovery system of FIG. It is explanatory drawing which shows an example of the process sequence of FIG. It is explanatory drawing which shows the other example which changes a primary site in the disaster recovery system of FIG. It is explanatory drawing which shows an example of the process sequence of FIG. FIG. 12 is an explanatory diagram showing still another example of changing the primary site in the disaster recovery system of FIG. 11. It is explanatory drawing which shows an example of the process sequence of FIG. It is explanatory drawing which shows an example of the disaster recovery system which takes asymmetric backup between four bases which this inventor examined. It is explanatory drawing which shows an example which changes a primary site in the disaster recovery system of FIG. It is explanatory drawing which shows an example of the process sequence of FIG. It is explanatory drawing which shows the other example which changes a primary site in the disaster recovery system of FIG. It is explanatory drawing which shows an example of the process sequence of FIG. It is explanatory drawing which shows the further another example which changes a primary site in the disaster recovery system of FIG. It is explanatory drawing which shows an example of the process sequence of FIG. It is explanatory drawing which shows the difference in the processing procedure of the disaster recovery system which takes a symmetrical backup, and the disaster recovery system which takes an asymmetrical backup.

  Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings. Note that components having the same function are denoted by the same reference symbols throughout the drawings for describing the embodiment, and the repetitive description thereof will be omitted.

(Embodiment 1)
<Summary of invention>
The outline of the present invention is a disaster having a primary site (primary site 11) and N recovery sites (recovery sites 12, 13) that provide services in place of the primary site when the primary site is stopped. This is a recovery system (disaster recovery system 10).

  The N recovery sites are each backed up at the primary site by disaster recovery software (disaster recovery software S1).

  The outline of the present invention includes a primary site (primary site 11) and N recovery sites (recovery sites 12 and 13) that provide services in place of the primary site when the primary site stops. This is a disaster recovery method using a computer system (disaster recovery system).

  This disaster recovery method includes the following steps.

  This is a step of performing backup of the primary site to N recovery sites by the disaster recovery software.

  This is a step of canceling backups at N recovery sites when it is decided to stop the primary site.

  This is a step of stopping the primary site after stopping the backup of the primary site.

  When the primary site is stopped, one of the N recovery sites is changed to the primary site and is operated.

  Furthermore, the outline of the present invention includes a primary site (primary site 11) and N recovery sites (recovery sites 12, 13) that provide services on behalf of the primary site when the primary site stops. A program to be executed by a computer system (disaster recovery system).

  This program causes a computer system to execute the following steps.

  This is a step of performing backup of the primary site to each of the N recovery sites by the disaster recovery software.

  This is a step of canceling backups at N recovery sites when it is decided to stop the primary site.

  This is a step to stop the primary site after stopping the backup.

  When the primary site is stopped, one of the N recovery sites is changed to the primary site and is operated.

  Hereinafter, the embodiment will be described in detail based on the above-described outline.

<Configuration example of disaster recovery system>
FIG. 1 is an explanatory diagram showing an example of a disaster recovery system 10 that takes a target backup between three sites.

  The disaster recovery system 10 has a primary site 11, a recovery site 12, and a recovery site 13, respectively. The primary site 11 is provided at the first base. The recovery site 12 is provided at a second site that is different from the first site. The recovery site 13 is provided at a third base that is different from the first and second bases.

  In the primary site 11, disaster recovery software S1 is set. The disaster recovery software S1 is, for example, OS (Operating System) level backup software. The backup at the primary site 11 is taken at the recovery site 12 and the recovery site 13 using the disaster recovery software S1.

  Hereinafter, various operations (functions) in the disaster recovery system 10 at the time of normal operation and power saving are software programs stored in a program storage memory (not shown) provided in the disaster recovery system 10. This is realized by the CPU (Central Processing Unit) (not shown) of the primary site 11 and the recovery sites 12 and 13 being executed.

<Operation example of disaster recovery system in normal times>
In the normal state, the disaster recovery system 10 is backed up symmetrically from the primary site 11 to the recovery site 12 and the recovery site 13 by using the disaster recovery software S1. Both the recovery site 12 and the recovery site 13 have backup settings for the disaster recovery software S1.

<Operation example of disaster recovery system during power saving>
Next, power saving will be described.

  FIG. 2 is an explanatory diagram illustrating an example in which the primary site 11 is a target of planned power outage and the recovery site 12 is changed to the primary site in the disaster recovery system 10 of FIG. FIG. 3 is an explanatory diagram showing an example of a processing procedure when the recovery site 12 in FIG. 2 is changed to the primary site.

  When the primary site 11 is a target of planned power failure, there are a case where the recovery site 12 is changed to the primary site and a case where the recovery site 13 is changed to the primary site.

  First, a case will be described in which the primary site 11 is a target of a planned power outage and the recovery site 12 is changed to the primary site as shown in FIG.

  First, when a stop notification of the primary site 11 due to a planned power failure is notified to the operation management department or the like (procedure T101), the primary site 11 stops backup from the primary site 11 to the recovery site 12 by the disaster recovery software S1 ( Procedure T102).

  Subsequently, the primary site 11 stops the backup from the primary site 11 to the recovery site 13 (procedure T103), shuts down the virtual machine of the primary site 11 and performs a planned stop of the primary site 11 (procedure T104). ).

  Then, at the recovery site 12, the backup by the disaster recovery software S1 is reflected (synchronized), and the recovery site 12 is changed to the primary site (procedure T105).

  At this time, the recovery site 12 has already been set up for backup by the disaster recovery software S1, so that it is not necessary to set a new backup again.

  Next, a case where the recovery site 13 is changed to the primary site 11 will be described.

  FIG. 4 is an explanatory diagram showing an example in the case where the primary site 11 is a target of planned power outage and the recovery site 13 is changed to the primary site in the disaster recovery system 10 of FIG. FIG. 5 is an explanatory diagram showing an example of a processing procedure when the recovery site 13 of FIG. 4 is changed to the primary site.

  First, when the stop notification of the primary site 11 due to the planned power failure is notified (procedure T201), the primary site 11 stops the backup from the primary site 11 to the recovery site 12 by the disaster recovery software S1 (procedure T202).

  Subsequently, the primary site 11 stops the backup from the primary site 11 to the recovery site 13 (procedure T203), shuts down the virtual machine of the primary site 11 and performs a planned stop of the primary site 11 (procedure T204). ).

  Then, the recovery site 13 reflects (synchronizes) the backup by the disaster recovery software S1, and changes the recovery site 13 to the primary site (procedure T205).

  At this time, the recovery site 13 has already been set up for backup by the disaster recovery software S1, so that it is not necessary to reset the backup.

  As described above, since the backup is performed symmetrically in both cases of FIG. 2 and FIG. 4, only the recovery site 12 needs to be synchronized, and the recovery site 13 does not need to be synchronized. Therefore, the number of processing procedures is 5 as shown in FIG. 3 and FIG.

  As described in the background art, in the event of a natural disaster, etc., when a problem such as widespread damage or power shortage occurs, there is a service that has recovery sites at multiple bases and easy movement of the system operation site. Necessary.

  In general, a disaster recovery system continuously transfers data at a primary site to a disaster recovery site at a remote location (base) to back up the same data. When the primary site stops due to a disaster (disaster), the disaster recovery site is replaced and the same data processing service as the primary site is quickly recovered.

  Therefore, the disaster recovery software does not correspond to a plurality of bases, and in the case of corresponding to a plurality of bases, it is necessary to consider a technique for using a plurality of disaster recovery software in combination.

<Configuration example of disaster recovery system for asymmetric backup>
FIG. 6 is an explanatory diagram showing an example of a disaster recovery system 100 that takes asymmetric backup between three bases examined by the present inventors.

  The disaster recovery system 100 includes a primary site 101, a recovery site 102, and a recovery site 103, respectively. The primary site 101 is provided at the first base, and the recovery site 102 is provided at the second base. The recovery site 103 is provided at the third base. These first to third bases are different places.

  Disaster recovery software S10 is set in the primary site 101, and disaster recovery software S11 is set in the recovery site 102.

  The disaster recovery software S10 is, for example, OS (Operating System) level backup software, and the disaster recovery software S11 is, for example, storage level backup software.

  The backup at the primary site 101 is taken to the recovery site 102 using the disaster recovery software S10. The backup at the recovery site 102 is taken to the recovery site 103 using the disaster recovery software S11.

<Operation example of disaster recovery system for asymmetric backup during normal operation>
In the normal case, as shown in FIG. 6, backup is taken from the primary site 101 to the recovery site 102 using the disaster recovery software S10. Further, backup is taken from the recovery site 102 to the recovery site 103 using the disaster recovery software S11.

<Operation example of disaster recovery system for asymmetric backup during power saving>
FIG. 7 is an explanatory diagram illustrating an example in which the primary site 101 is a target of planned power outage and the recovery site 102 is changed to the primary site in the disaster recovery system 100 of FIG. FIG. 8 is an explanatory diagram showing an example of a processing procedure when the recovery site 102 in FIG. 7 is changed to the primary site.

  First, when the stop notification of the primary site 101 due to the planned power failure is notified (procedure T1001), the backup from the primary site 101 to the recovery site 102 by the disaster recovery software S10 is stopped (procedure T1002). Further, the backup from the recovery site 102 to the recovery site 103 by the disaster recovery software S11 is stopped (procedure T1003).

  Subsequently, the virtual machine of the primary site 101 is shut down and the primary site 101 is scheduled to be stopped (procedure T1004). At the recovery site 102, the backup by the disaster recovery software S10 is reflected (synchronized) (procedure T1005), and the recovery site 102 is activated (procedure T1006) to change to the primary site.

  As a result, since the recovery site 102 has been changed to the primary site, the disaster recovery software S10 is reset so that the data of the recovery site 102 that has become the primary site is backed up to the recovery site 103 (step T1007).

  As described above, when the recovery site 102 is changed to the primary site, a backup is taken from the recovery site 102 that has become the primary site to the recovery site 103.

  However, since the disaster recovery software S11 that is storage level backup software is only set in the recovery site 103, it is necessary to newly reset the disaster recovery software S10 that is OS level backup software. Therefore, the number of processing procedures is seven.

  On the other hand, in the disaster recovery system 10 shown in FIG. 2, when the recovery site 12 is changed to the primary site, as shown in FIG. 3, the number of processing steps is five, and the number of processing steps is reduced. be able to.

  By reducing the processing man-hours, the planned stoppage time of the primary site can be shortened, and an increase in operational errors and the like can be prevented.

  FIG. 9 is an explanatory diagram illustrating an example in which the primary site 101 is a target of planned power outage and the recovery site 103 is changed to the primary site in the disaster recovery system 100 of FIG. FIG. 10 is an explanatory diagram showing an example of a processing procedure when the recovery site 103 in FIG. 9 is changed to the primary site.

  First, when the stop notification of the primary site 101 due to the planned power failure is notified (procedure T2001), the backup from the primary site 101 to the recovery site 102 by the disaster recovery software S10 is stopped (procedure T2002). Further, the backup from the recovery site 102 to the recovery site 103 by the disaster recovery software S11 is stopped (procedure T2003).

  Subsequently, the virtual machine of the primary site 101 is shut down and the primary site 101 is scheduled to be stopped (procedure T2004). After that, the recovery site 102 reflects (synchronizes) the backup by the disaster recovery software S10 (procedure T2005). In the recovery site 103, the backup by the disaster recovery software is reflected (synchronized) (procedure T2006). As a result, the recovery site 103 is changed to the primary site.

  Thus, when the recovery site 103 is changed to the primary site, it is necessary to take a backup from the recovery site 103 to the recovery site 102. The backup from the recovery site 103 to the recovery site 102 requires the disaster recovery software S10 that is OS level backup software. Here, the disaster recovery software S10 is set in the recovery site 102, so that the resetting is performed. It becomes unnecessary. Accordingly, there are six procedures for changing the recovery site 103 to the primary site.

  Here, too, the number of processing steps is increased as compared with the five procedures by the disaster recovery system 10 shown in FIG. Thus, by reducing the processing man-hours, the planned stoppage time of the primary site can be shortened, and an increase in operational errors and the like can be prevented.

  Thereby, according to this Embodiment 1, the operation quality in the disaster recovery system 10 can be improved significantly.

(Embodiment 2)
<Configuration example of disaster recovery system>
In the first embodiment, the disaster recovery system 10 that takes a target backup between three bases has been described. In the second embodiment, the disaster recovery system 10 that takes a target backup between four bases is described. To do.

  FIG. 11 is an explanatory diagram showing an example of a disaster recovery system 10 that takes a target backup between four sites.

  The disaster recovery system 10 includes a primary site 11, a recovery site 12, a recovery site 13, and a recovery site 14, respectively. The primary site 11 is provided at the first base as in the first embodiment. The recovery sites 12 to 14 are respectively provided at the second to fourth sites that are different from the first site.

  In the primary site 11, disaster recovery software S1, which is OS (Operating System) level backup software, is set. Backups at the primary site 11 are taken at the recovery site 12, the recovery site 13, and the recovery site 14, respectively, using the disaster recovery software S1.

<Operation example of disaster recovery system in normal times>
In normal times, the disaster recovery software S1 is used to symmetrically back up from the primary site 11 to the recovery site 12, the recovery site 13, and the recovery site 14, respectively.

<Operation example of disaster recovery system during power saving>
Next, power saving will be described.

  FIG. 12 is an explanatory diagram illustrating an example in which the primary site 11 is a target of a planned power outage and the recovery site 12 is changed to the primary site in the disaster recovery system 10 of FIG. FIG. 13 is an explanatory diagram showing an example of a processing procedure when the recovery site 12 of FIG. 12 is changed to the primary site.

  When the primary site 11 is subject to a planned power outage, the recovery site 12 is changed to the primary site, the recovery site 13 is changed to the primary site, and the recovery site 14 is changed to the primary site. There is.

  First, a case will be described in which the primary site 11 is a target of a planned power outage and the recovery site 12 is changed to the primary site as shown in FIG.

  First, when the stop notification of the primary site 11 due to the planned power failure is notified (procedure T301), the primary site 11 stops the backup from the primary site 11 to the recovery site 12 by the disaster recovery software S1 (procedure T302).

  Subsequently, the primary site 11 stops the backup from the primary site 11 to the recovery site 13 (procedure T303).

  Then, the virtual machine which the primary site 11 has is shut down, and the planned stop of the primary site 11 is performed (procedure T304). When the primary site 11 is stopped, the recovery site 12 reflects (synchronizes) the backup by the disaster recovery software S1, and changes the recovery site 12 to the primary site (step T305).

  At this time, the recovery site 12 has already been set up for backup by the disaster recovery software S1, so that it is not necessary to set a new backup again.

  Next, a case where the recovery site 13 is changed to the primary site will be described with reference to FIGS. 14 and 15.

  FIG. 14 is an explanatory diagram illustrating an example of the disaster recovery system 10 of FIG. 11 in which the primary site 11 is the target of a planned power outage and the recovery site 13 is changed to the primary site. FIG. 15 is an explanatory diagram showing an example of a processing procedure when the recovery site 13 in FIG. 14 is changed to the primary site.

  First, when the stop notification of the primary site 11 due to the planned power failure is notified (procedure T401), the primary site 11 stops the backup from the primary site 11 to the recovery site 12 by the disaster recovery software S1 (procedure T402).

  Subsequently, the backup from the primary site 11 to the recovery site 13 is stopped (procedure T403). When these backups are stopped, the virtual machine of the primary site 11 is shut down and the primary site 11 is scheduled to be stopped (procedure T404).

  Then, the recovery site 13 reflects (synchronizes) the backup by the disaster recovery software S1, and changes the recovery site 13 to the primary site (step T405).

  At this time, the recovery site 13 has already been set up for backup by the disaster recovery software S1, so that it is not necessary to reset the backup.

  Next, the case where the recovery site 14 is changed to the primary site will be described with reference to FIGS. 16 and 17.

  FIG. 16 is an explanatory diagram showing an example of the disaster recovery system 10 of FIG. 11 in which the primary site 11 is a target of planned power outage and the recovery site 14 is changed to the primary site. FIG. 17 is an explanatory diagram showing an example of a processing procedure when the recovery site 14 of FIG. 16 is changed to the primary site.

  First, when the stop notification of the primary site 11 due to the planned power failure is notified (procedure T501), the primary site 11 stops the backup from the primary site 11 to the recovery site 12 by the disaster recovery software S1 (procedure T502).

  Subsequently, the backup from the primary site 11 to the recovery site 13 is stopped (procedure T503). When these backups are stopped, the virtual machine of the primary site 11 is shut down and the primary site 11 is scheduled to be stopped (procedure T504).

  Then, the recovery site 14 reflects (synchronizes) the backup by the disaster recovery software S1, and changes the recovery site 13 to the primary site (procedure T505).

  At this time, the recovery site 14 has already been set up for backup by the disaster recovery software S1, so that it is not necessary to reset the backup.

  As described above, in any case, the number of processing procedures is 5 as shown in FIGS. 13, 15, and 17, respectively.

<Configuration example of disaster recovery system for asymmetric backup>
FIG. 18 is an explanatory diagram showing an example of a disaster recovery system 100 that takes asymmetric backup between four bases examined by the present inventors.

  The disaster recovery system 100 includes a primary site 101, a recovery site 102, a recovery site 103, and a recovery site 104, respectively. The primary site 101 is provided at the first base, and the recovery site 102 is provided at the second base. The recovery site 103 is provided at the third base, and the recovery site 104 is provided at the fourth base.

  Disaster recovery software S10 is set in the primary site 101, and disaster recovery software S11 is set in the recovery sites 102 and 103.

  The disaster recovery software S10 is, for example, OS (Operating System) level backup software, and the disaster recovery software S11 is, for example, storage level backup software.

  The backup at the primary site 101 is taken to the recovery site 102 using the disaster recovery software S10. The backup at the recovery site 102 is taken to the recovery site 103 using the disaster recovery software S11. The backup at the recovery site 103 is taken to the recovery site 104 using the disaster recovery software S11.

<Operation example of disaster recovery system for asymmetric backup during normal operation>
In the normal case, as shown in FIG. 18, backup is taken from the primary site 101 to the recovery site 102 using the disaster recovery software S10. Further, backup is taken from the recovery site 102 to the recovery site 103 using the disaster recovery software S11, and backup is taken from the recovery site 103 to the recovery site 104 using the disaster recovery software S11.

<Operation example of disaster recovery system for asymmetric backup during power saving>
FIG. 19 is an explanatory diagram showing an example of the disaster recovery system 100 of FIG. 18 in which the primary site 101 is the target of a planned power outage and the recovery site 102 is changed to the primary site. FIG. 20 is an explanatory diagram showing an example of a processing procedure when the recovery site 102 in FIG. 19 is changed to the primary site.

  First, when the stop notification of the primary site 101 due to the planned power failure is notified (procedure T3001), the backup from the primary site 101 to the recovery site 102 by the disaster recovery software S10 is stopped (procedure T3002). Further, the backup from the recovery site 102 to the recovery site 103 by the disaster recovery software S11 and the backup from the recovery site 103 to the recovery site 104 by the disaster recovery software S11 are respectively stopped (procedures T3003 and T3004).

  Subsequently, the virtual machine of the primary site 101 is shut down and the primary site 101 is planned to be stopped (procedure T3005). Then, after the backup by the disaster recovery software S10 is reflected (synchronized) at the recovery site 102 (procedure T3006), the recovery site 102 is activated (procedure T3007) to change to the primary site.

  As a result, since the recovery site 102 has been changed to the primary site, the disaster recovery software S10 is reset so that the data of the recovery site 102 that has become the primary site is backed up to the recovery site 103 (step T3008).

  FIG. 21 is an explanatory diagram showing an example of the case where the primary site 101 is a target of planned power outage and the recovery site 103 is changed to the primary site in the disaster recovery system 100 of FIG. FIG. 22 is an explanatory diagram showing an example of a processing procedure when the recovery site 103 in FIG. 21 is changed to the primary site.

  First, when the stop notification of the primary site 101 due to the planned power failure is notified (procedure T4001), the backup from the primary site 101 to the recovery site 102 by the disaster recovery software S10 is stopped (procedure T4002). Further, the backup from the recovery site 102 to the recovery site 103 by the disaster recovery software S11 and the backup from the recovery site 103 to the recovery site 104 by the disaster recovery software S11 are respectively stopped (procedures T4003 and T4004).

  Thereafter, the virtual machine of the primary site 101 is shut down and the primary site 101 is scheduled to be stopped (procedure T4005). Subsequently, the recovery site 102 reflects (synchronizes) the backup by the disaster recovery software S10 (procedure T4006), and the recovery site 103 reflects (synchronizes) the backup by the disaster recovery software S11 (procedure T4007).

  As described above, when the recovery site 103 is changed to the primary site, a backup is performed from the recovery site 103 to the recovery site 102 and from the recovery site 102 to the recovery site 104. However, when the recovery site 103 is synchronized, a procedure for synchronizing the recovery site 102 first is newly added.

  FIG. 23 is an explanatory diagram showing an example in the case where the primary site 101 is a target of planned power outage and the recovery site 104 is changed to the primary site in the disaster recovery system 100 of FIG. FIG. 24 is an explanatory diagram showing an example of a processing procedure when the recovery site 104 in FIG. 23 is changed to the primary site.

  First, when the stop notification of the primary site 101 due to the planned power failure is notified (procedure T5001), the backup from the primary site 101 to the recovery site 102 by the disaster recovery software S10 is stopped (procedure T5002). Further, the backup from the recovery site 102 to the recovery site 103 by the disaster recovery software S11 and the backup from the recovery site 103 to the recovery site 104 by the disaster recovery software S11 are respectively stopped (procedures T5003 and T5004).

  Thereafter, the virtual machine of the primary site 101 is shut down and the primary site 101 is scheduled to be stopped (procedure T5005). Subsequently, the recovery site 102 reflects (synchronizes) the backup by the disaster recovery software S10 (procedure T5006). Thereafter, the recovery site 103 reflects (synchronizes) the backup by the disaster recovery software S11 (procedure T5007), and the recovery site 104 reflects (synchronizes) the backup by the disaster recovery software S11 (procedure T5008).

  As described above, when the recovery site 104 is changed to the primary site, a backup is performed from the recovery site 104 to the recovery site 102, and a backup is performed from the recovery site 102 to the recovery site 103. However, when the recovery site 104 is synchronized, a procedure for synchronizing the recovery site 102 and the recovery site 103 first is added.

  Therefore, in a disaster recovery system between four sites taking asymmetric backup, the number of processing procedures at the time of power saving is 8 procedures in the case of FIGS. 20 and 24 and 7 procedures in the case of FIG.

  Even in this case, the number of processing steps is increased as compared with the five procedures by the disaster recovery system 10 shown in FIG. Thus, by reducing the processing man-hours, the planned stoppage time of the primary site can be shortened, and an increase in operational errors and the like can be prevented.

<Disaster recovery system with symmetrical backup and disaster recovery system with asymmetric backup and comparative example>
FIG. 25 is an explanatory diagram showing a difference in processing procedure between the disaster recovery system 10 that takes the symmetric backup shown in FIGS. 1 and 11 and the disaster recovery system 100 that takes the asymmetric backup shown in FIG. 6 and FIG. is there.

  In FIG. 25 (a), on the left side, the types and number of steps of processing procedures when the recovery site 102 is changed to the primary site and the recovery site 103 is changed to the primary site in the disaster recovery system 100 of FIG. Show.

  On the right side, the types and number of procedures are shown when changing the recovery site 12 to the primary site in FIG. 1 and when changing the recovery site 13 to the primary site.

  On the right side, in the disaster recovery system 100 of FIG. 18, the types and the number of procedures when the recovery site 102 is changed to the primary site, the recovery site 103 is changed to the primary site, and the recovery site 104 is changed to the primary site. Is shown.

  On the right side, the types and number of procedures in the case where the recovery site 12 is changed to the primary site, the recovery site 13 is changed to the primary site, and the recovery site 14 is changed to the primary site in FIG.

  On the right side, in the disaster recovery system having one primary site and a plurality of recovery sites (4 or more), the type and number of procedures for changing the primary site by the disaster recovery system taking asymmetric backup, and It shows the types and number of procedures when changing the primary site with a disaster recovery system that takes a symmetric backup. FIG. 25B is an explanatory diagram showing the difference in the increase order between the disaster recovery system that takes an asymmetric backup and the disaster recovery system that takes a symmetric backup.

  As shown in FIG. 25A, it can be seen that the disaster recovery system 10 that takes a symmetric backup has fewer types of procedures and the number of procedures than the disaster recovery system 100 that takes an asymmetric backup.

  In the disaster recovery system 100 that takes asymmetric backup, the number of procedures increases each time the number of bases (recovery sites) increases. In the disaster recovery system 10 that takes a symmetric backup, the number of bases (recovery sites) There is no change in the number of procedures even if it is increased. Therefore, as the number of bases (recovery sites) increases, the number of processing steps in disaster recovery can be significantly reduced.

  In this way, the disaster recovery system 10 that takes a symmetric backup can reduce the number of processing steps in disaster recovery. Therefore, it is possible to shorten the planned downtime of the primary site, and to prevent an increase in operational errors and the like.

  Thereby, also in the second embodiment, the operational quality in the disaster recovery system 10 can be greatly improved.

  As mentioned above, the invention made by the present inventor has been specifically described based on the embodiment. However, the present invention is not limited to the embodiment, and various modifications can be made without departing from the scope of the invention. Needless to say.

  The present invention is suitable for disaster recovery technology having recovery sites at a plurality of bases.

10 disaster recovery system 11 primary site 12 recovery site 13 recovery site 14 recovery site 100 disaster recovery system 101 primary site 102 recovery site 103 recovery site 104 recovery site S1 disaster recovery software S10 disaster recovery software S11 disaster recovery software

Claims (9)

The primary site,
And N recovery sites that provide services on behalf of the primary site when the primary site stops,
N recovery sites are
A disaster recovery system, wherein the primary site is backed up by disaster recovery software. The disaster recovery system according to claim 1,
The disaster recovery software
A disaster recovery system, which is backup software for performing OS level disaster recovery. The disaster recovery system according to claim 1,
A disaster recovery system, wherein, when the primary site stops, any one of the N recovery sites is changed as the primary site. A disaster recovery method by a computer system having a primary site and N recovery sites that provide services on behalf of the primary site when the primary site stops,
Performing backup of the primary site to each of the N recovery sites by disaster recovery software;
Canceling backups at each of the N recovery sites when it is decided to stop the primary site;
After stopping the backup, stopping the primary site;
And a step of changing any one of the N recovery sites as the primary site when the primary site is stopped. The disaster recovery method according to claim 4, wherein
The primary site backup is
A disaster recovery method, which is a backup for performing OS level disaster recovery. The disaster recovery method according to claim 5, wherein
When any one of the N recovery sites is changed to the primary site, backup is performed to the remaining recovery sites by the disaster recovery software of the changed recovery site. Disaster recovery method characterized by this. A program that is executed by a computer system having a primary site and N recovery sites that provide services on behalf of the primary site when the primary site stops,
Performing backup of the primary site to each of the N recovery sites by disaster recovery software;
Canceling backups at each of the N recovery sites when it is decided to stop the primary site;
After stopping the backup, stopping the primary site;
And a step of changing any one of the N recovery sites as the primary site when the primary site is stopped. The program according to claim 7, wherein
When any one of the N recovery sites is changed to the primary site, a backup of the changed recovery site is performed to the remaining recovery sites. Program. The program according to claim 8, wherein
The recovery site backup that has been changed
A program executed by backup software for performing OS level disaster recovery.

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