KR20000009582A - High-availability system and data protection method of thereof for protection of data - Google Patents

Abstract

PURPOSE: A high-availability system and data protection method of thereof is provided to protect a common disk by removing approach right if an active system owns the common disk. CONSTITUTION: The high-availability system includes an active system by using source of a common disk, a common disk presents data to the active system, and a standby system which owns the common disk or hands over an ownership of the common disk. The standby system owns the common disk if an error is happened in the active system, or hands over the ownership of the common disk if the active system is capable of acting again normally. The high-availability system can protect data through a reset command language, e.g. "SCSI RESERVE", "SCSI RELEASE" and "SCSI BUS".

Description

High availability systems with data protection and data protection methods in high availability systems

The present invention relates to a high availability system capable of data protection and a data protection method of a high availability system, and more particularly, to a system and method for protecting data on a shared disk.

1 is a block diagram of a high availability system according to a conventional method. As is well known to those skilled in the art, a high availability system is a system that is configured to have a high resilience against system failure while operating two systems in the active and standby state to increase the availability (availability) of the system.

Here, the active system 100 refers to a system that performs a practical important task, the standby system 110 after detecting the error of the active system, the shared resources 120 owned by the active system (120) ) Refers to a system that owns itself and continues to perform the important tasks that the active system was performing.

Shared resources are system resources shared by active and standby systems, including disk, teletypewriter (TTY), Ethernet, X.25, and SNA (System Network Architecture). The owner of these resources is the active system, and the standby system is the active system. Can be owned when an error occurs. At this time, the standby system owns the shared resource and becomes the active system.

Referring to this, the operation of the conventional high availability system is described. In the prior art, the standby system periodically monitors the state of the active system and, if it is determined that the active system has failed, becomes the owner of the shared resources Disk, TTY, and Ethernet. Allow service to continue

However, in the conventional method, since there is no data protection device for the shared disk, the active and standby systems can use the disk without any restrictions. Thus, if the active system became the owner of the disk, then the standby system would have to prevent access to the shared disk at its source. Therefore, if the active system and the standby system write to the same disk at the same time, the data is broken and becomes useless.

Therefore, the present invention was devised to solve the above problems. When the active system becomes the owner of the shared disk, the standby system protects the data on the shared disk by removing the right to access the shared disk. An object of the present invention is to provide a data protection method for a high availability system and a high availability system.

Other objects and advantages of the present invention will become more apparent from the following detailed description of the invention and the accompanying drawings.

1 is a block diagram of a high availability system according to a conventional method.

2 is a block diagram of a high availability system according to the present invention.

3 is a flowchart illustrating a data protection method of a high availability system according to the present invention.

<Explanation of symbols for the main parts of the drawings>

100: system in operation

110: waiting system

120: shared disk

200: system in operation

210: waiting system

220: shared disk

In order to achieve the above object, according to the present invention, a preferred embodiment of a high availability system capable of data protection,

An operating system using resources of the shared disk;

A shared disk for providing data to the operating system; And

A standby system that monitors whether the operating system has an error and owns the shared disk when an error occurs in the operating system, and transfers ownership of the shared disk when the operating system is able to operate normally; It is made.

In the embodiment of the present invention, it is preferable that the shared disk does not meet the ownership requirement of another system unless the system that owns the shared disk gives up ownership.

A preferred embodiment of a data protection method of a high availability system capable of data protection according to the present invention,

System A is activated to become the shared disk owner;

A monitoring process in which system B monitors the failure of system A;

A detection process in which system B owns a shared disk when a failure of system A is detected by the monitoring process;

Transferring the ownership of the shared disk to System A so that System B becomes a standby system; And

The system A again owns a shared disk by the previous process.

In another embodiment of the present invention, the sensing process,

It is desirable to further include a bus reset step of resetting the system bus before System B takes ownership of the shared disk,

The previous process,

Abandonment of system B giving up ownership of the shared disk; And

Preferably, the system B further includes a notification step of informing the system A of the renunciation of the shared disk.

The transfer process preferably does not satisfy the ownership requirement of another system, unless the system that owns the shared disk gives up ownership.

In the following description, with reference to the accompanying drawings, a high availability system capable of protecting data and a method of protecting data of a high availability system according to a preferred embodiment of the present invention, many specific details, such as the operation of the system, provide a more general understanding of the invention. Is shown to provide. However, it will be apparent to those skilled in the art that the present invention can be sufficiently implemented by the above-described technical spirit of the present invention without these detailed items.

In addition, features and functions of well-known high availability systems are not described in detail in order not to obscure the present invention, and the same terminology is used in English initials or Korean language for convenience of explanation and understanding.

2 is a block diagram of a high availability system according to the present invention. Referring to the configuration of the present invention with reference to the drawings, a high availability system according to the present invention includes a system 200 in operation using the resources of the shared disk;

Shared disk 220 for providing data to the operating system; And

While waiting for an error in the operating system, if the operating system has an error, the shared system owns the shared disk, and if the operating system is able to operate normally again, the waiting system 210 to transfer ownership of the shared disk. It is composed of

As such, the high availability system issues specific commands to the shared disk to allow only the active system that owns the shared disk to access the shared disk. This particular command is SCSI RESERVE and SCSI RELEASE. As is well known to those skilled in the art, SCSI RESERVE is a command used to exclusively use the device for other systems.

A device that receives a RESERVE command does not have a relationship with another system unless it receives a RELEASE command from the system that issued the command or a SCSI BUS reset. Therefore, the system that issued the RESERVE command performs input and output with the target device without interference from other systems. Since the SCSI RESERVE / RELEASE command is performed in units of logical unit numbers (LUNs), the owner is determined by one disk unit in the operating system.

As such, the target device receiving the SCSI RESERVE command performs input / output independently of the system that issued the command. If the system that issued the SCSI RESERVE command goes down, the backup system cannot access the target device. Since the target device receives the RESERVE command from the down system, it cannot input / output with the backup system.

In order to solve the preservation state of the target device, it is necessary to execute the RESERVE command or reset the SCSI BUS in the down system. Only the bus reset is possible because the system cannot be down and issue the RELEASE command. However, there is no way to reset the SCSI bus on a UNIX system. Therefore, in the present invention, a fake device is made to reset the SCSI bus.

The operation of the system will be described with reference to a data protection method flowchart of the high availability system according to the present invention of FIG.

The data protection method according to the present invention includes a process 300 in which System A is activated to become a shared disk owner; A monitoring process 310 in which System B monitors the failure of System A; A detection process 320 in which System B owns a shared disk when a failure of System A is detected by the monitoring process; Transferring the ownership of the shared disk to system A in order for the system B to become a standby system (330); And a process (340) (300) of the system A again owns the shared disk by the previous process.

In this case, the sensing process may further include a bus resetting step of resetting the system bus before the system B has ownership of the shared disk to have ownership of the shared disk.

The transfer process may also include abandonment of system B giving up ownership of the shared disk; And a notification step of the system B informing the system A of giving up the shared disk, and ownership of the unique disk is transferred to the system A.

The shared disk at this time prevents two systems from accessing the shared disk at the same time by preventing the system that owns the shared disk from complying with the ownership request of the other system unless it gives up ownership.

In the above description, the present invention has been described and limited by way of example with reference to the drawings. However, it will be apparent to those skilled in the art that various changes and modifications can be made without departing from the spirit of the present invention. will be.

Therefore, it is to be understood that the invention is not limited to the specific forms referred to in the specification, but rather that the invention is defined by all the modifications, equivalents and equivalents within the spirit and scope of the invention as defined by the appended claims. It should be understood to include substitutes.

According to the present invention operating as described above, the administrator of the standby system randomly writes the shared disk, or if the standby system temporarily fails, the standby system assumes that the active system is down and proceeds to write to the shared disk. Protects data on shared disks by preventing

Claims (6)

In a high availability computer system, An operating system using resources of the shared disk; A shared disk providing data to the operating system; And It is provided with a waiting system that monitors whether an error occurs in the operating system and if the operating system fails, owns the shared disk, and transfers ownership of the shared disk if the operating system is able to operate normally again. High availability system with data protection. The high availability system of claim 1, wherein the shared disk does not comply with the ownership requirement of another system unless the system that owns the shared disk gives up ownership. System A is activated to become the shared disk owner; A monitoring process in which system B monitors the failure of system A; A detection process in which the system B owns a shared disk when a failure of the system A is detected by the monitoring process; Transferring the ownership of the shared disk to System A so that System B becomes a standby system; And And a process in which System A again owns a shared disk by the transfer process. The method of claim 3, wherein the sensing process, A method of protecting data in a high availability system, further comprising a bus reset step of resetting the system bus before System B takes ownership of the shared disk. The method of claim 3, wherein the transfer process Abandonment, where System B gives up ownership of the shared disk; And A method of data protection in a high availability system, wherein system B further comprises a notification step of informing system A of abandonment of a shared disk. 6. The method of claim 5, wherein the transfer process does not comply with ownership requirements of another system unless the system that owns the shared disk gives up ownership.