JPS63113649A - Controller - Google Patents

Abstract

PURPOSE:To securely grasp the actual operation state processing ability when a controller is in operation, the utilization state of a common resource, etc., by storing execution control information at each execution control passage check point provided to a specific control part when the controller is in operation. CONSTITUTION:When a host computer sends a command processing request to the controller 10, respective control parts in the controller 10 perform processes corresponding to the contents of the command in order and perform specific control over respective devices. The respective control parts sends information on the control to an execution control information storage part 11, where the information is recorded. Consequently, pieces of execution control information of the respective control parts from the reception of the command to the end of the commands are recorded and gathered in the execution control information storage part 11. The pieces of execution control information recorded and gathered in this execution control storage part 11 are taken out and analyzed to securely grasp the service time to each device, the processing wait time of the device, the data transfer speed, the utilization state of the common resource, the execution operation state of each device, etc.

Description

[Detailed Description of the Invention] [Summary] An execution control information storage section is provided in a control device that is located between a host and a device and controls the operation of the device by each internal control section. Execution control information at each execution control passage checkpoint provided in the section is stored. This makes it possible to reliably grasp the actual operating status, processing capacity, usage status of shared resources, etc. during operation of the control device.

[Industrial application field]

The present invention is a control device that is located between a host and a device and controls the device, and has been improved so as to be able to reliably grasp the actual operating status of the control device, processing capacity, usage status of shared resources, etc. during operation. Regarding a control device.

[Conventional technology]

In a control device that receives commands from a host and controls a plurality of devices by performing multiple operations, equal service to each device and high processing speed are required.

The operational status within the control device, which is the center of device control, changes in a complex manner depending on the number of devices to be controlled, the processing content of each device, and the like.

Conventionally, when controlling multiple devices while performing remultiple operations using a control device, predicted values such as processing time and waiting time for each device are calculated theoretically based on fixed data, and these predicted values are calculated theoretically based on fixed data. was used to judge the operating status of the control device, processing capacity, usage status of shared resources, etc.

Furthermore, actual measurement data during actual application running has been obtained only for the host-side computer. For example, the time at which a command was sent from the host to the control device, the time at which a command completion notification was received from the control device, etc. are determined, and execution control information after the control device is not determined.

In addition, on the device side, that is, the terminal side, the responsiveness of the control device's processing and the quality of the service for each terminal were known from the intuitive processing responsiveness and waiting time obtained by the operator through actual processing operations. .

[Problem that the invention seeks to solve]

Conventionally, as mentioned above, the operating status and processing capacity of the control device that receives commands from the host and controls each device have been determined based on theoretically calculated predicted values, or the operator has determined the actual processing performance. They make intuitive judgments based on operations, and are in control.

There was no actual measurement of the operating status of the door device, processing time, waiting time, etc.

For this reason, there has been a problem in that the actual operating status, processing capacity, usage status of shared resources, etc. of the control device cannot be accurately grasped. Furthermore, it is difficult to obtain accurate data necessary for equalizing services for each device, speeding up processing, improving device performance, etc., making it difficult to achieve these goals.

The present invention records data such as processing time and waiting time of each control unit inside the control device during operation of the control device as execution control information, and utilizes the actual processing capacity, operating status, and shared resources during operation of the control device. The purpose is to provide an improved control device that can reliably grasp the situation, etc.

[Means for solving problems]

The solution taken by the present invention will be explained with reference to FIG. FIG. 1 is a basic configuration block diagram of the present invention.

In FIG. 1, a control device 10 is located between a host and a device and controls the operation of the device.

Reference numeral 11 denotes an execution control information storage section in which execution control information for each control section in the control device 10 is recorded and collected.

12 to 14 are examples of control units provided in the control device (10).

[For production]

When a command processing request is issued from the host to the control device 10, each control unit in the control device 10 sequentially executes processing corresponding to the contents of the command, and performs predetermined control on each device.

Each control unit performs its own control and sends information regarding the executed control to the execution control information storage unit 11 for recording. As a result, the execution control information storage section 11 records and collects the execution control information of each control section from the time the command is received to the time the command ends.

By extracting and analyzing the execution control information recorded and collected in the execution control information storage unit 11, the service time for each device, the processing waiting time of the device, the data transfer rate, the usage status of shared resources, and the usage status of each device can be determined. It is possible to reliably grasp the execution status, etc. Based on this data, it is possible to obtain indicators for equalizing services for each device, speeding up processing, optimizing the required number of shared resources, improving device performance, etc.

In addition, if a failure occurs in each control section during operation of the control device,
The fault investigation can be conducted quickly and accurately.

〔Example〕

An embodiment of the present invention will be described with reference to FIGS. 2 and 3. FIG. 2 is an explanatory diagram of the configuration of an embodiment of the present invention, and FIG. 3 is a processing timing chart of the embodiment.

(A) Configuration of Embodiment In FIG. 2, the control device 10 and execution control information storage section 11 are as described in FIG. 1. As shown in the figure, a plurality of devices are connected to the control device 10 to perform multi-operations.

A channel adapter 15 converts electrical signal levels and transfers control information between the host and the control device 10. A channel control unit 12 controls operations between the host and the control device 10 regarding command processing requests from the host and notifications of processing requests from terminals.

A device control unit 13 controls the operation of each device connected to the control device 10. A device adapter 16 converts electrical signal levels and transfers control information between each device and the control device 10.

14 is a main control unit that manages the control of multiple devices within the control device 10 and issues execution instructions to the channel control unit 12 and device control unit 13;

The execution control information storage section 11 is connected to the channel control section 12, the device control section 13, and the main control section 14, and is used to sequentially record events as they occur and to collect history information of the program execution process. (Trace) method is used to record and collect execution control information of each part.

(B) Operation of the embodiment The operation of the embodiment shown in FIG.
For example, assume that the points of abandonment, device interruption, and release are the checkpoints for execution control.
This will be explained with reference to the processing timing chart in FIG.

When a command request for a certain device n is received from the host, it is input to the channel control unit 12 via the channel adapter 15 . The channel control unit 12 uses the command reception interrupt time (tl) from the host as a passage checkpoint for execution control. The execution control information is sent to the execution control information storage section 11 together with the identification information of the device n, the process content identification information, etc., and is recorded.

Since the main control unit 14 manages the control of a plurality of devices, a queue for the main control unit 14 is set at time t2. At time t3, the main control unit 14
An execution instruction is given to the device control unit 13.

The device control unit 13 prepares an instruction to device n, and issues an execution instruction at time t4. Note that when device n is unable to execute, the execution right is relinquished at time t4. Since this execution right acquisition (or execution abandonment) time t4 is a checkpoint to check whether execution control has passed, the device control unit 13 uses this t4 as execution control information together with the identification information of device n, processing content identification information, etc. It is sent to the execution control information storage unit 11 and recorded.

When device n completes an operation (usually data transfer) for one command, it issues an interrupt to the main control unit 14 at time t to end the operation, and receives the next command. Since this operation end time point t is also a checkpoint for checking whether the execution control passes, it is sent to the execution control information storage section 11 as execution control information and stored along with other identification information and the like.

Similarly, at time points 1b and t, the main control 1
4 issues an execution instruction to the device control unit 13,
Time points t7 and t,. At , the device control unit 3 issues an execution instruction to device n, and at time t and t
In , device n requests the device control unit 13 to terminate the operation. And point L? tflt
tl. and the t-th information are sent to the execution control information storage unit 11 as execution control information and stored together with other identification information.

When all the operations of device n are completed, the main control unit 14 notifies the channel control unit 12 of the end of the command at time t1□. The channel control unit 12 at time t1
In step 3, an interrupt is issued to the host to indicate the end of the command. This time point t13 is sent as execution control information to the execution control information storage unit 11 and stored together with other identification information.

As described above, the execution control information storage unit 11 stores information on each point in time of execution control that has passed through each unit in the control device 10 from receiving a processing request command from the host to notifying the end of the command. It is recorded as execution control information together with identification information, process content identification information, etc.

The execution control information stored in the execution control information storage section 11 is read out by the main control section 14 and sent to the host. Furthermore, a floppy disk or mini disk (not shown) may be installed in the control device 10, and the execution control information stored in the execution control information storage section 11 may be recorded on this floppy disk or mini disk at any point during operation. You can also do it.

By analyzing this execution control information, it is possible to reliably grasp the service time, data transfer rate, waiting time of shared resources, execution status and processing capacity of each device, etc. for each device. Furthermore, based on these data,
It is possible to obtain indicators for improving the performance of each device, speeding up processing, and optimizing the required number of shared resources.

In addition, the execution control information stored in the execution control information storage unit 11 can be recorded on a floppy disk, mini disk, etc. at any point during operation, and if necessary, the processing time chart as shown in Fig. 3 can be edited. By outputting the information, it is possible to grasp the processing capacity, operating status, etc. of the control device at any time period without degrading the performance of the control device during execution of processing. Thereby, failure investigation during operation within the control device can be conducted appropriately and promptly.

Although one embodiment of the present invention has been described above, the execution control information stored in the execution control information storage unit 11 of the present invention is not limited to the content of the embodiment, and may be stored at other times or at other control units. This also includes the case where execution control information is stored.

〔Effect of the invention〕

As explained above, according to the present invention, the following effects can be obtained.

(b) Actual execution control information such as processing time and waiting time of each control unit during operation of the control device can be recorded and collected.

(b) By analyzing this execution control information, it is possible to reliably grasp the operational status, processing capacity, and usage status of shared resources during operation of the control device.

(c) By means of (a) and (b) above, it is possible to equalize services for each device of the control device, speed up processing, optimize the required number of shared resources, and obtain indicators for improving device performance.

Further, it is possible to quickly and accurately investigate a failure occurring within the control device.

[Brief explanation of the drawing]

Fig. 1...Explanatory diagram of the basic configuration of the present invention, Fig. 2...
FIG. 3 is an explanatory diagram of the configuration of an embodiment of the present invention, and a processing timing chart of the embodiment. In FIG. 1 and FIG. 2, 10...control device, 11...execution control information storage unit,
12... Channel control unit, 13... Device control unit, 14... Main control unit, 15... Channel adapter,
16...Device adapter.

Claims (1)

[Claims] It is located between the host and the device, and includes various control units (11
, 12, 13, etc.) to control the operation of the device, an execution control information storage section (11) is provided in the control device (10), and an execution control information storage section (11) is provided in a predetermined control section during operation of the control device. A control device that stores execution control information at each execution control passing checkpoint.