JPS6274136A - File subsystem - Google Patents

Abstract

PURPOSE:To realize a magnetic disk subsystem with high reliability by providing plural memory controlling circuit on one cache memory, in a magnetic disk subsystem with a cache memory. CONSTITUTION:A magnetic disk subsystem 3 is constituted of one piece of cache memory 6, and two pieces of ECC.memory controlling circuits 7A, 7B which are connected in parallel to said memory. The ECC.memory controlling circuit 7A is connected to a magnetic disk control device (DKC) 4A, and on the other hand, the controlling circuit 7B is connected to a DKC 4B. Both of them execute the control of operation of the memory part 6, generation of an error code at the time of write of information against said control, and the correcting operation of an error at the time of read-out. Both the DKC 4A and 4B are connected to a host 9 and a magnetic device 5, and control a mutual transfer operation, etc. of storage information between these devices and the cache memory 6.

Description

DETAILED DESCRIPTION OF THE INVENTION [Field of Industrial Application] The present invention relates to a file subsystem used in a computer system, and in particular to a semiconductor storage device such as an electronic disk subsystem or a magnetic disk subsystem with memory. The present invention relates to a file subsystem having a section.

[Conventional technology]

Computer systems are connected to large-capacity storage devices such as magnetic disk drives in order to store large amounts of data and programs, but since such large-capacity storage devices generally have long access times, this is the time required for the entire computer system. This has become a bottleneck for improving performance. In order to solve this problem, disk caches (cache memory) and semiconductor disks (electronic disks) using semiconductor memory elements that can be accessed at high speed were devised.
There are two types that have become rapidly popular in recent years.

FIG. 2 is a block diagram showing an example of a conventional magnetic disk subsystem with cache memory.

As shown in FIG. 2, a conventional magnetic disk subsystem 12 with a cache memory has a cache memory having one semiconductor storage element section (hereinafter referred to as a memory section) 6 and one ECC/memory control circuit 7. The memory 13 is connected to two magnetic disk controllers (DKC) 4A and 4B, and among the information stored in the magnetic disk device 5, the information that controls the frequency of use is transferred to the element section 6. The central processing unit fi6j (host) 9 accesses the information directly to the cache memory 131 via the DKC 4A or 4B, thereby speeding up the access.

Therefore, since conventional magnetic disk subsystems with gassy memory have only one ECC/memory control circuit, if a failure occurs in this circuit, the entire subsystem immediately becomes inoperable, and the computer system cannot operate. It has the disadvantage of having a significant impact on The above-mentioned situation is exactly the same in the electronic disk subsystem.

[Problem that the invention seeks to solve]

The problem to be solved by the present invention, in other words, the purpose of the present invention is to eliminate the drawbacks of the conventional file save system having a semiconductor memory element section as described above, and to solve the problem that a failure occurs in the ECC/memory control circuit. It is an object of the present invention to provide a file subsystem that does not immediately become inoperable even when the computer is in use, and thereby improves the reliability of a combiner system.

[Failure to solve the problem]

The file subsystem of the present invention includes a plurality of file control devices, and two ECC/memory control circuits provided corresponding to each group obtained by appropriately dividing the plurality of file control devices into two groups. , and one semiconductor memory element portion 217 connected to the two FCC/memory control circuits.

〔Example〕

Next, embodiments of the present invention will be described in detail based on the drawings.

FIG. 1 is a prong diagram showing an embodiment in which the present invention is applied to a magnetic disk subsystem with cache memory.

As shown in the figure, the cache memory 3 includes one memory section 6 and two FCC/memory circuits 7A and 7B connected in parallel to the memory section 6. E.C.C.
The memory control unit 7A is connected to I) KC4A, and is connected to the FCC/memory control circuit 7B ViDKC4B to control the operation of the memory unit 6 and generate error codes when writing information to it. Corrects errors during reading. Both DKCs 4A and 4B are connected to the host 9 and the magnetic disk device 5, and control the exchange of information with the host 9 and mutual transfer of stored information between the magnetic disk device 5 and the cache memory 3. .

The magnetic disk subsystem configured as described above is
When a failure occurs in either the FCC/memory control circuit 7A or 7B, for example, the ECC/memory control circuit 7A, the memory section 6 can be accessed by the remaining ECC/memory control circuit 7B. . Therefore, unlike the conventional magnetic disk subsystem illustrated in FIG. 1, the subsystem does not become inoperable immediately.

The electronic disk subsystem is a subsystem in which the magnetic disk device 5 is not connected in FIG. 1 and the portion corresponding to the cache memory 3 is used as an electronic disk. Just as in the case of the system, if a failure occurs in one ECC/memory control circuit, the memory section can be accessed by the other ECC/memory control circuit, so the electronic disk subsystem becomes inoperable. There isn't. (In the case of an electronic disk subsystem, the part corresponding to the magnetic disk control device is the electronic disk control device.) In the case of an electronic disk subsystem, three or more electronic disk control devices may be connected. However, in this case, it is divided into two groups (so that the number is as equal as possible), and each group is connected to a separate FCC/memory control circuit.

〔Effect of the invention〕

In recent years, improving the reliability of computer systems has become a very important issue, and the occurrence of failures, especially in large computers used in online systems, can become a major social problem. Not a little.

The file subsystem of the present invention has the advantage that even if one of the FCC/memory control circuits fails, its functions can be maintained by the other ECC/memory control circuit. This has the great effect of improving the reliability of a computer system using a file subsystem.

[Brief explanation of drawings]

FIG. 1 is a block diagram showing an embodiment of the present invention, and FIG. 2 is a block diagram showing an example of a conventional memory control method. 2...Magnetic disk subsystem, 3-...
- Cache memory, 4A, 4B... Magnetic disk control device. Hayabusa 1 page

Claims (1)

[Claims] A plurality of file control devices, a plurality of ECC/memory control circuits provided corresponding to each group obtained by dividing the plurality of file control devices into a plurality of groups, and the plurality of ECC
- A file subsystem characterized by comprising a semiconductor storage element section connected to a memory control circuit.