JPS63184149A - Multicontroller system - Google Patents

Abstract

PURPOSE:To improve the activity efficiency of a multicontroller and an I/O device and to easily perform bracketing when a fault occurs, by providing a multicontroller control device which selects plural multicontrollers dynamically. CONSTITUTION:A connecting means 8 is the one to connect the multicontrollers MC1-MCn to the I/O devices IO1-IOn, and is constituted so as to be selected respectively by designating addresses. A control table A is the control table to manage the state of the I/O device, and is set by being connected to the multicontroller, and is provided with an I/O state flag 51 reset by final interruption. Also a control table B is the control table to manage the state of the multicontroller, and is constituted with an MC state flag 52 set while the multicontroller performs data transfer, and an I/O queue number 53 representing the number of I/O devices in processing.

Description

DETAILED DESCRIPTION OF THE INVENTION [Summary] A multi-controller system is provided that includes a multi-controller control device that dynamically selects a path (or path, bus) between a plurality of multi-controllers and an input/output device.

[Industrial application field]

The present invention relates to data processing devices, and more particularly to improvements in multi-controller systems that control input/output devices (unit record devices).

The input/output control device (hereinafter referred to as multi-controller MC) that controls unit record devices such as card leagues has a limit on the number of input/output devices of each type that can be connected under it, and many input/output devices are connected to the host computer. In some cases, multiple multi-controllers are prepared.

However, this multi-controller system (hereinafter, a system equipped with multiple multi-controllers and input/output devices is referred to as a multi-controller system) has traditionally had a static system configuration, and therefore, during transfer operations, the multi-controller The above-mentioned problems with the multi-controller, such as not being able to use other input/output devices connected to the multi-controller or being unable to isolate the fault between the multi-controller and the input/output device, have not been solved.

Therefore, there is a need for a multi-controller system that solves the above problems.

[Conventional technology]

FIG. 6 is a block diagram of a conventional multi-controller system. In the figure, 1 is a host computer, 2 is an input/output channel unit provided in the host computer, which performs multiplex transfer with multiple multi-controllers 3 and 4, and 3.4 controls input/output of the unit record device. Multi-controllers 3a to 3n and 4a to 4n are each unit record devices (input/output devices that handle fixed length data such as card leagues)
Input/output devices (10 devices) consisting of multi-controller 3.4 and 10 devices 3a to 3.
A multi-controller system 5 is composed of the controllers n and 4a to 4n.

Input/output control with the above configuration is performed as follows. That is, when an input/output request interrupt (attention) is input to the multi-controller 3 from the +1110 device 3a, the multi-controller 3 transfers the request contents to the input/output channel unit 2.

(2) Next, based on the request from the input/output channel section 2, the host computer l prepares the data necessary for input/output (at the time of output) or storage address (at the time of input), etc., and sends it to the input/output channel section 2.
Start.

(3) The input/output channel section 2 transfers a predetermined block in byte units between the main memory (not shown) and the IO device 3a via the multi-controller 3 based on a data output request or an input request from the device 3a. transfer data.

(4) IO device 3a that notifies completion of processing of human output data
The transfer operation ends with a termination interrupt.

In the above operation, while the multi-controller 3 is transferring data, the input/output control of the other ■0 devices 3n is put on standby, and therefore the IO device 3n cannot be used.

The multi-controller 4 is provided to perform input/output control of the ten devices 4a to 4n, and performs the same operations as the multi-controller 3.

[Problem that the invention seeks to solve]

When the host computer receives an input/output request and starts the input/output channel section, if the multi-controller that controls the corresponding 10 devices is busy transferring data, it will be restarted, but if the multi-controller that controls the corresponding 10 devices is busy transferring data, it will be restarted. In data transfer in block units in the 0 device, the channel is relatively long (occupied) and wasteful access due to the restart described above is likely to occur.

Furthermore, conventional methods have the problem that it is not possible to isolate the location of the failure, whether it is the multi-controller or the IO device, and the multi-controller must be investigated separately from the host computer.

The aforementioned multi-controller system using multiple multi-controllers is a static system in which the 10 devices connected to each multi-controller are fixed, and therefore the above-mentioned problems exist as well. A problem arises in that the percentage of useless accesses due to busy conditions increases.

SUMMARY OF THE INVENTION In view of the above problems, it is an object of the present invention to provide a multi-controller system that dynamically selects a multi-controller.

[Means for solving problems]

For the above purpose, the multi-controller system of the present invention includes a plurality of multi-controllers that each form a path between a designated input/output device and a plurality of multi-controllers, as shown in FIG. connection means (8) for connecting the input/output devices (IO1, IOn) and the plurality of multi-controllers (MCllMCn); A multi-controller control device (6) is provided which manages the operating state and selects the multi-controller with the least load for the designated input/output device to form the path.

[Effect]

The multi-controller MCI, MCn and the input/output device 101, Ion are connected so that the input/output device path specified by the host computer can be selected from multiple paths, and the multi-controller control device selects the path to be used. Select dynamically.

Therefore, the status of the multi-controller and 10 devices is managed, and when 10 devices are specified, an empty multi-controller is selected, and the multi-controller with the least load is selected.

As described above, it is possible to improve the usage efficiency of the multi-controller and input/output devices, and in the event of a failure, by changing the path used, it is possible to improve the operating rate and isolate the failure.

〔Example〕

Embodiments of the present invention will be described with reference to FIGS. 2 to 5.

In this embodiment, two sets of multi-controllers and one of 3 Mi
Figure 2 shows an example of a control table, Figure 3 is a block diagram of the multi-controller system of the embodiment, and Figure 4 shows an example of an event occurrence to explain the operation. Figures 5(a) and 5(b) are operation flowcharts. In FIG. 3, 6 is a multi-controller control device, and a control table 50 for managing the operating states of multi-controllers MC1, MC2, 10 devices 101-103 and 10 queues, and a control table 50 for controlling multi-controllers MCI, MC2 based on the control table 50. Consisting of a selection unit 9 that selects one of them to form a path with the designated 10 devices, and a data transfer unit 10 that controls data transfer between the input/output channel unit 2 and the selected multi-controller MC. .

Furthermore, the connection configuration between the multi-controllers MCI, MC2, which is the connection means 8 shown in FIG.
102 and 103, and each can be selected by specifying an address.

The control table 50 is composed of a control table A, a control table B, and an IO queue table 50a, an example of which is shown in FIG. That is, the control table A is a control table that manages the states of the 10 devices IO1 to IO103, and has an IO state flag 51 that is set by connection with a multi-controller and reset by a termination interrupt.

Control table B is a control table that manages the states of multi-controller MCI and MC2, and is a control table that manages the states of multi-controller MCI and MC2.
, an MC status flag 52 that is set when the MCI is in the process of data transfer, and a number of 0 queues 53 representing the number of devices being processed by the current multi-controller.

The IO queue table 50a has ten device numbers waiting for processing arranged in the order of input/output requests, and is provided for each multi-controller MCI.

Based on the above control table 50, an empty multi-controller that is not transferring data (MC state flag 51 is “O”)
Among C), the path with the smallest number of IO queues 53 is selected to determine the paths to be used so as to equally divide the load on the multi-controllers.

Hereinafter, an example of the control operation in the multi-controller control device when data is transferred from the host computer 1 to 10 devices will be explained based on an example of event occurrence shown in FIG.

Refer to FIGS. 4 and 5+8) and (b). In the following explanation, the status flags are distinguished by the corresponding MC code and 10 code.

First, the control table 50 is initialized at the start of operation.

(1) Select MCI from host computer 1 using input/output instruction control table B for IOI Bus ■ Update control tables A and B as follows (10 Update of queue table 50a is shown in FIG. 5(a), ( b) Reference) +01
Status flag 1'' MCI status flag ``1'' Instruct MCI's IO queue '1' to cent (21101) to transfer data to MCI.

Upon completion of the data transfer, select the MC (MC2') with the smallest IO queue among the MC status flags 0'' in the input/output instruction control table B for 31102, and start data transfer. Bus ■ 102 status flag 1" MC2 status flag 1" Number of IO queues of MC2 "1" (For 41103, select the smallest MC (MCI) of 10 queues among the MCs with input/output instruction MC status flag "0", transfer start bus ■ 103 Status flag 1'' MCI status flag 1'' Number of MCI ■○ queues 12'' (Data transfer complete for 51102 MC2 status flag 0'' (6) Data transfer complete for IO3 MCI status flag 0'' (7) Termination interrupt check Polling instruction (with termination interrupt) for the head l0 (IOI) of the IO queue table 50a of the MC (MCI) with the MC status flag "0" 101 Status flag O'' (81102, polling instruction for IO3 (no interrupt) (9 ) Asynchronous interrupt check IO status flag 0'' ■ MC status flag 0'' for 0 devices, polling instruction to the least MC of 10 queues (with interrupt) Interrupt processing of the corresponding 10 devices α01 P-precision side entry check 102, An example is the order in which the following events occur: interrupt from IO3, 102, IO3 status flag 0' (1) to 00).
Even if the occurrence occurs arbitrarily, predetermined processing is performed based on the control table 50.

Note that the above item (9) is polling for accepting input/output requests from the IO device.

As described above, the KO queue (
Dynamic control that selects the MC with the smallest MC for data transfer makes it possible to improve the usage efficiency of IO devices and equally divide the load on multiple controllers.

Further, when the multi-controller control device 6 selects the multi-controller MC and starts data transfer, if a failure occurs in the bus used, it selects another multi-controller and tries again.

This improves the operating rate of the multi-controller system and makes it easier to isolate faults.

〔Effect of the invention〕

The present invention provides a multi-controller system equipped with a multi-controller control device that dynamically selects a plurality of multi-controllers, thereby improving the usage efficiency of the multi-controllers and IO devices, and improving isolation in the event of a failure. The effect of making it easier is extremely large.

[Brief explanation of the drawing]

Fig. 3 is a multi-controller system block diagram of the embodiment, Fig. 4 is a diagram showing an example of an event occurrence for explaining the operation, Fig. 5 (a) and (b) are operation flowcharts, and Fig. 6 is a conventional This is a multi-controller system block diagram. In the figure, l is the host computer, 2 is the input/output channel section, 3.4
is a multi-controller, 33 to 3n, 4a to 4n are input/output devices (10 devices), 5 is a conventional multi-controller system, 6 is a multi-controller control device, 7 is a multi-controller system, 8 is a connection means, 9 is a selection unit , 10 is a data transfer unit, 101, IO2, 103 are ■0 devices, MC1, MCz, MCn are multi-controllers, 50
is a control table, A and B are management tables, and 50a is 10
In the queue table, 51 is an IO status flag, 52 is a MC status flag, and 53 is the number of IO queues representing the number of waiting processes of the IO device.

Claims (1)

[Claims] A plurality of input/output devices (IO1, IOn) and a plurality of multicontrollers that form paths with the designated input/output devices and control data transfer between the host computer (1) and the host computer (1). (MC1, MCn), the plurality of input/output devices (IO1, IOn ) and a plurality of said multi-controllers (MC1, MCn) (8)
and manages the operating status of the multi-controller (MC1, MCn) and the input/output device (IO1, IOn), selects the multi-controller with the least load on the specified input/output device, and performs the corresponding operation. A multi-controller system comprising a multi-controller control device (6) for forming a passage.