JP2001005769A - Input/output processing system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To perform an input/output processing while efficiently balancing the load between an IOP(input-output processor) and a CH(channel). SOLUTION: This system is provided with an inter-IOP communicating means 160 connecting between IOPs 130. Each IOP 130 collects the load information of subordinate CHs 120, records the load information on a CH load information table 240 and notifies the other IOP 130 of the load information through the means 160. CH selecting means included in the IOPs 130 select a CH 120 to request input-output processing on the basis of the load information of the CH 120 recorded on the CH load information table, start the selected CH 120 when the CH 120 is subordinate to their own IOP 130 and request the IOP 130 having the selected CH 120 as a subordinate to perform input-output processing by using a message transmitting and receiving means when the CH 120 is subordinate to the other IOP 130.

Description

DETAILED DESCRIPTION OF THE INVENTION

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an input / output processing system having a plurality of input / output processing devices for performing input / output processing in a computer system. The present invention relates to an input / output processing system suitable for balancing.

2. Description of the Related Art In an input / output processing system in a computer system, an input / output processing device (hereinafter referred to as an IO) is provided independently of an instruction processing device (hereinafter abbreviated as IP) for executing a user program.
There is a method called P) which includes a processing device dedicated to input / output processing. The IOP usually comprises a unique processor and a storage device used by the processor (hereinafter referred to as an IOP local storage), and is controlled by a dedicated program installed in advance. As an example of such a computer system, there is a computer system disclosed in JP-A-2-32448 "I / O device startup processing method". According to the patent, the input / output processing system includes a plurality of channels (hereinafter referred to as CH) for controlling devices and executing input / output, and a plurality of IOPs. ) In this specification, I
All IOPs and CHs are connected to a main storage (MS). When the IP executes an input / output instruction, the operand of the instruction is passed to the IOP via the MS, and the IOP selects a CH requesting input / output processing based on the device specified in the operand of the input / output instruction, and performs input / output. Requesting a process, the CH controls the device and performs an actual input / output process. The input / output processing system of such a computer system has the following advantages. (1) The IOP and the CH process input / output processing relatively slower than the execution speed of the IP, so that the processing capacity of the IP can be allocated to other processing. (2) IOPs and CHs that perform only input / output processing require less processing power than IPs, and therefore can be manufactured at low cost. In addition, because of the low cost, it can be equipped more than IP. (3) By preparing a plurality of IOP and CH pairs capable of processing input / output to one device (hereinafter, this IOP and CH pair is referred to as a channel path), a certain IOP and CH pair can Even when a device is being used for input / output processing to a device, input / output processing can be performed using a different set of IOP and CH, and the performance of the input / output processing system can be improved. (4) By preparing a plurality of channel paths for one device, even if a failure occurs in one channel path, it is possible to perform input / output using another channel path, and high availability is achieved. It becomes possible to configure an input / output processing system.

According to the prior art, it is possible to construct an input / output processing system having the above-mentioned advantages. However, there are the following problems to be improved. In order to provide a high-performance I / O processing system using relatively inexpensive and low-performance IOPs and CHs according to the conventional technology, it is necessary to equip many IOPs and CHs. In the case of the system disclosed in JP-A-2-32448, a maximum of eight IOPs and 256 CHs can be provided. In order for such a system to work efficiently, it is important to properly balance the load between the IOP and the CH, but for that purpose, it is necessary to exchange load information between them. However, in the configuration of the input / output processing system according to the related art, there is no device other than the MS that can be used for this purpose. Generally, unlike an IP that executes a user program, an IOP or a CH has only low access performance to an MS. As a result, I
Exchanging information between the OP and the CH involves a large overhead, making it difficult to properly balance the load on the IOP and the CH. An object of the present invention is to provide a configuration of an input / output processing system that can efficiently perform load balancing between the IOPs and CHs in an input / output processing system including a plurality of IOPs and CHs. It is.

[Means for Solving the Problems] Communication means for connecting only between IOPs is provided. Each IOP includes a table for recording load information for each CH. Each IOP sends the load information of the subordinate CH to another IOP via this communication means. Other IOP
The IOP receiving the communication from the IOP holds the load information of the CH included in the communication in its own IOP local storage. Each IO
P, when instructed by the IP to execute an input / output instruction, selects a CH to execute the input / output instruction based on the load information of the CH in its own IOP local storage, and the CH is placed under its own subordinate. If so, the CH is requested to perform input / output processing; otherwise, the IOP having the CH under its control is requested to perform input / output processing using the CH through the above-described communication means. A storage means shared only between IOPs is provided. A table for recording load information for each CH in the storage means,
A message queue for performing communication between OPs is provided. Each IOP records the load information of the subordinate CHs in a table of the storage means. When each IOP is instructed to execute an input / output instruction from the IP, the IOP selects a CH to execute the input / output instruction based on the load information of the CH in the storage unit, and the CH is under its own control. If this is the case, the input / output processing is requested to the CH. Otherwise, the IOP having the CH under the request is requested to perform the input / output processing using the CH through the above-described message queue.

Embodiments of the present invention will be described below in detail with reference to the drawings. FIG. 1 is an overall configuration diagram of a first embodiment of the present invention. A plurality of IPs 100 share the MS 110, and a plurality of IOPs 130 share the same MS 110 although access performance is low. IOP1
30 has a plurality of CHs 120 under its control, receives an input / output command executed by the IP 100, and can process the CHs under its control.
0, and requests input / output processing to the CH 120. C
The H 120 receives a request from the IOP 130, controls a plurality of devices 150 through a control unit (hereinafter, CU) 140, and processes input / output. All CH120 are MS11
Access to 0 is possible. To perform communication between the IOPs 130, the inter-IOP communication means 160 is used. FIG.
FIG. 1 is a configuration diagram of an IOP 130 according to a first embodiment of the present invention. The IOP 130 is the IOP processor 18
0 and IOP local storage 230. The IOP processor unit 180 includes a CH load collecting unit 190, a CH selecting unit 200, a message transmitting / receiving unit 210, and a CH activating unit 22.
0 is included. The IOP local storage 230 includes a CH load information table 240. CH load sampling means 19
0 collects the loads of all the CHs 120 under the control of the IOP 130, and includes the CHs included in the CH load information table 240.
120 is updated. Here, the load on the CH 120 is a quantitative representation of the operation status of the CH 120. The simplest example is a value indicating that the CH 120 is in operation if the input / output processing is being performed, and a value indicating that the CH 120 is not operating if the CH 120 is not executing the input / output processing. Further, in the case of the CH 120 capable of simultaneously processing a plurality of input / output processes, (the number of input / output processes currently being processed) / (the number of input / output processes that can be processed simultaneously) can be used as the load information.
Further, the average value per unit time of the load information thus collected can be used again as the load information. In addition to the examples given here, other values that can be used as load information are conceivable. It is the CH load collecting means 190 that collects the above-described load information for each subordinate CH 120 and records it in the CH load information table 240. CH selecting means 200 selects CH 120 capable of processing the input / output command received from IP 100. The message transmitting / receiving means 210 uses the inter-IOP communication means 160,
Exchanges messages with other IOPs 130. The CH activating means 220 outputs the CH 120 selected by the CH selecting means 200.
Is under the IOP 130, the CH 120
Request input / output processing. CH load information table 240
Is used to record, for each CH 120, the load information of the CH 120 collected by the CH load collecting unit 190. The CH load information table 240 includes another IOP 13
The load information of the CH 120 subordinate to 0 is also included. The load information of the CH 120 under the control of another IOP 130 is stored in the
When the load information of the CH 120 is collected, the CH 120 is transmitted via the message transmitting / receiving means 210 and the IOP communication means 160.
IOP1 that was passed along with the number and received the message
30 includes the IOP
Recorded in the CH load information table 240 included in 130. FIG. 3 is an overall configuration diagram of the second embodiment of the present invention. IP100, MS110, IOP130,
The relationship between the CH 120, the CU 140, and the device 150 is the same as in the case of FIG. The inter-IOP storage means 170
The storage device is shared only between the OPs 130. FIG.
FIG. 14 is a configuration diagram of an IOP 130 and an inter-IOP storage unit 170 according to the second embodiment of the present invention. IOP13
0 is the IOP processor unit 180 and the IOP local storage 2
30. The IOP processor unit 180 includes a CH load collection unit 190, a CH selection unit 200, a message transmission / reception unit 210, and a CH activation unit 220. The IOP shared type CH load information table 2 is stored in the inter-IOP storage means 170.
50 and a message queue table 260.
The CH selecting means 200 and the CH activating means 220 are the same as those in FIG. The CH load sampling means 190 outputs the IOP1
The load of all CHs 120 under 30 was collected, and the IOP
CH1 included in the shared type CH load information table 250
20 load information is updated. Message sending / receiving means 210
Exchanges messages with another IOP 130 using the message queue table 260 included in the inter-IOP storage means 170. The IOP shared type CH load information table 250 is used to record, for each CH 120, the load information of the CH 120 collected by the CH load collecting unit 190 of each IOP. The IOP shared type CH load information table 250 includes load information of all the CHs 120. FIG. 5 is an example of the configuration of the message queue table 260 according to the second embodiment of this invention. The message queue table 260 includes a plurality of message queues 270. Each message queue 270 is a general FIFO buffer, and is allocated for each IOP 130. The message sending / receiving means 210 of each IOP 130 periodically checks the contents of the message queue 270 assigned to itself, and if a message is registered, moves it to the local storage 230. To send a message to another IOP 130, the message is registered in the message queue of the destination IOP 130 using the message sending / receiving means 210. FIG. 6 is an example of the CH selection processing in the present invention. This corresponds to the CH in the IOP processor unit 180.
4 is an example of a process performed by the selection unit 200. Here, the case of the first embodiment will be described for convenience, but the same applies to the case of the second embodiment. Step 1
000, the activation information of the input / output instruction executed by the IP 100 is acquired. In step 1010, a set of CHs 120 to which the device 150 is connected is obtained from the obtained activation information. Generally, one device 150 is connected to a plurality of CHs 120 to improve availability and input / output performance. In step 1020, the current load information of CH 120 included in the set obtained in step 1010 is represented by C
It is obtained from the H load information table 240. Step 10
At 30, based on the load information of the CH 120 obtained in the step 1020, the CH 120 with the lowest load is selected. It is determined whether or not the selected CH 120 is under the control of the own IOP 130 (step 1040). If the selected CH 120 is under the control of the own IOP 130, a request for input / output processing is made to the CH 120 using the CH activation means 220 (step 1060). If not, the C selected using the message sending / receiving means 210
Step 100 is added to the IOP 130 having the H120 under its control.
Pass the activation information of the input / output instruction acquired in step 0 (step 1
050). The above is the description of the processing performed by the CH selection unit 200. FIG. 7 is another example of the CH selection processing according to the present invention. This is another example of the processing shown in FIG. Here, the case where the first embodiment is adopted will be described for convenience, but the same applies to the case of the second embodiment. In step 1100, activation information of an input / output instruction executed by the IP 100 is acquired. In step 1110, the CH 120 to which the device 150 is connected is
Find the set of In step 1120, step 111
The average load information of the CH 120 included in the set obtained at 0 is acquired from the CH load information table 240. In step 1130, the C obtained in step 1120
Based on the average load information of H120, C with the lowest average load
Choose H120. The selected CH 120 is its own IOP 130
(Step 1140), and
If it is under the control of its own IOP 130, it requests the CH 120 to perform input / output processing using the CH activation means 220 (step 1).
160), if not subordinate, message sending / receiving means 210
130 having CH120 selected under the control of IOP
Then, the activation information of the input / output instruction acquired in step 1100 is passed (step 1150). The above is the CH selection means 20
7 is a description of another example of the processing performed in step S0. If there is any information that can be collected by the CH load information collecting unit 190 other than the load information of the CH 120, the CH selection processing shown in FIGS. 6 and 7 may use the current load information of the CH 120 or the average load information instead. It should be understood that even if other information is used, the CH 120 can be appropriately selected according to the information to be used. For example, if the load information of the CU 140 can be collected, the CH 120 can be selected according to the load information of the CU.

According to the present invention, it is possible to configure an input / output processing system capable of efficiently balancing the load of CH.

[Brief description of the drawings]

FIG. 1 is an overall configuration diagram of a first embodiment of the present invention.

FIG. 2 is a configuration diagram of an IOP according to the first embodiment of the present invention.

FIG. 3 is an overall configuration diagram of a second embodiment of the present invention.

FIG. 4 shows an IOP and an IOP according to a second embodiment of the present invention.
The figure which shows an example of a structure of an interim storage means.

FIG. 5 is a diagram illustrating an example of a configuration diagram of a message queue table according to the second embodiment of this invention.

FIG. 6 is a diagram showing an example of a CH selection process according to the present invention.

FIG. 7 is a diagram showing another example of the CH selection processing of the present invention.

[Explanation of symbols]

100 ... instruction processing unit (IP), 110 ... main storage unit (MS), 120 ... channel (CH), 130 ... input / output processing unit (IOP), 140 ... control unit (CU), 15
0: device, 160: inter-IOP communication means, 170: I
Inter-OP storage means, 180... IOP processor section, 190
... CH load information collecting means, 200 ... CH selecting means, 21
0: message sending / receiving means, 220: CH starting means, 23
0: IOP local storage, 240: CH load information table, 250: IOP shared type CH load information table, 26
0: Message queue table, 270: Message queue.

 ──────────────────────────────────────────────────続 き Continuing on the front page (72) Inventor Shingo Shibauchi 1st Horiyamashita, Hadano-shi, Kanagawa Prefecture Inside the Hitachi Server Enterprise Server Division (72) Inventor Dai Dai Tagawa 1st Horiyamashita, Hadano-shi, Kanagawa Prefecture Hitachi (72) Inventor Keito Goto, 1st Horiyamashita, Hadano-shi, Kanagawa Prefecture Within Hitachi Information Technology Co., Ltd. (72) Inventor Takeshi Fukue 1st, Horiyamashita, Hadano-shi, Kanagawa Prefecture Information Technology, Inc. F term (reference) 5B014 GA13 GA20 GA25 5B045 BB30 BB49 GG04 GG07 5B098 AA10 GC08 GC16 GD07

Claims (1)

[Claims] A plurality of instruction processing devices and a plurality of input / output processing devices, wherein the instruction processing devices and the input / output processing devices share one main storage device, and the input / output processing devices subordinate a plurality of channels; 2. An input / output processing system for a computer system according to claim 1, wherein communication means is provided between said input / output processing devices.