JPH0310353A - Transmission controller - Google Patents

Abstract

PURPOSE:To always keep a uniform load by supplying a data transmission command to a data transmitting means at the time when loads of both of local and other computer systems are smaller than a reference value together. CONSTITUTION:A local computer system 1 has a transmission control part 5. When transmission request data is given to this control part 5, the control part 5 extracts local-system load state data and other-system load state from a local-system load storage part 7 and an other-system load storage part 9. When both loads are smaller than the reference value, the control part 5 gives the transmission command to a data transmitting part 4; but when at least one of loads is larger than the reference value, the control part 5 stores transmission request data in a transmission request storage part 10, and the control part 5 extracts stored data to give the transmission command to the data transmitting part 4 after both loads are reduced to the reference value or smaller. Thus, loads of respective computers are kept uniform.

Description

DETAILED DESCRIPTION OF THE INVENTION [Object of the Invention] (Industrial Application Field) The present invention relates to a transmission control device that controls the exchange of transmitted and received data according to the respective load states of a local computer and another computer.

(Prior Art) Data transmission and reception between a local computer system and another computer system is performed by a data transmission device.

FIG. 3 is a block diagram showing the flow of data between the local computer system 1 and the other computer system 2 in the past, and transmission data a sent from the central processing unit (not shown) on the local side is The transmitted data is stored in the transmission data storage section 3. Then, when the transmission request data b is given to the data transmission section 4, the data transmission section 4 extracts the transmission data a from the transmission data storage section 3 and transmits it to the other system side.

On the other hand, the transmission data a- transmitted from the other computer system 2 is taken in as reception data C by the data transmission section 4 of the own computer system. This received data C is stored in a received data storage unit 5, and upon receiving a read request from a central processing unit (not shown), the received data C is output and read by the central processing unit.

(Problem to be solved by the invention) However, in such conventional data transmission methods,
When a transmission request signal is given to the data transmission section 4 on the own system side, the transmission data a is forcibly sent to the other system side. This results in a high load. This is because, as can be understood from the computer load characteristic diagram shown in Figure 2, the transmission start time is the same as the transmission request time regardless of the load status of the computer system. The load has been high for some time.

In this way, when the computer system becomes highly loaded, the system may go down or data transmission becomes impossible, resulting in a problem that smooth data transmission cannot be performed.

The present invention has been made to solve these conventional problems, and its purpose is to monitor the load status of the 1' system and other computer systems, and to collect data at the optimal timing. The object of the present invention is to provide a transmission control device capable of transmitting.

[Structure of the Invention] (Means for Solving the Problem) In order to achieve the above object, the present invention provides a self-system computer monitoring means for monitoring the load state of the self-system computer system, and a self-system computer monitoring means for monitoring the load state of the other system computer system. When a transmission request command is given, the other system computer monitoring means determines whether the loads of both computer systems are below a reference value, and if both loads are below the reference value, issues a data transmission command. and a data transmission control means that outputs a transmission command after both loads become equal to or less than the reference value when at least one of the two loads is equal to or higher than the reference value; It is characterized by having a data transmission means for sending and receiving data.

(Function) With the configuration as described above, the loads of the own computer system and the other computer system are determined, and data transmission is performed only when both loads are below a reference value. Furthermore, if the load on at least one of the computer systems is equal to or greater than the reference value, data transmission is not performed, and data transmission is performed after both loads become equal to or less than the reference value. Therefore, the load on each computer is equalized.

(Embodiment) FIG. 1 is a configuration diagram showing an embodiment of the present invention. In addition,
Since the self-system computer system] and the other-system computer system 2 shown in the figure have the same configuration, the configuration of the own-system side will be explained and the explanation of the structure of the other-system side will be omitted.

As shown in the figure, when the own computer system 1 receives a transmission command from a transmission data storage section 3 that stores transmission data given from a central processing unit (not shown) and a transmission control section 5 to be described later, A data transmission unit 4 extracts transmission data from the transmission data storage unit 3 and transmits it to the other system, and also receives reception data given from the other system, and a central processing unit (not shown) stores the reception data. ) has a receiving data storage section 5 which outputs the received data every time there is a read request from the receiving data storage section 5.

Further, the own computer system 1 is coupled to the own system load monitoring unit 6 that monitors the load state of the system 1, the own system load storage unit 7 that stores this load state, and the other system computer system 2. , an other-system load monitoring unit 8 that monitors the load state of the other-system computer system 2, and an other-system load storage unit 9 that stores this load state.

Furthermore, when the local computer system 1 is given the transmission request data, it extracts the local system load state data and the other system load state data from the local system load storage section 7 and the other system load storage section 9, and If both loads are below the reference load, a transmission command is given to the data transmission unit 4, and if at least one of the loads is above the reference value, the transmission request data is stored in the transmission request storage unit 10, and both It has a transmission control section 5 that extracts the stored data after both loads become equal to or less than the reference load and gives a transmission command to the data transmission section 4.

Next, the operation will be explained.

The self-system load monitoring unit 6 monitors the load state of the self-system computer system 1 at a predetermined period, and calculates the load amount using, for example, the following method.

First, the processing time T per disk processed by the own computer system 1- is calculated as the product of the average access time T2 of the external storage device and the number of accesses N. That is, the following (
1) is the formula.

T I = T 2 X N (
L) In reality, the time required for data processing includes memory access time, arithmetic processing time, etc. in addition to the average access time T2 of the external storage device, but these times are different from the time T2. It's very short so I'm ignoring it.

On the other hand, if the average number of accesses per unit time in the own computer system 1 is A, then the number M of data that can be processed per unit time is determined by the following equation (2).

M=A/Tl (2) and
The obtained number M of data processing per unit time is set as the load amount 100 [%], and the current load amount is determined as a percentage from the ratio of this to the current number of data processing cases.

The load amount of the own computer system 1 obtained in this way is stored in the own system load storage section 7 as the own computer load data d. In this storage section 7, the stored data is updated every time the load data d is obtained by the own system load monitoring section 6.

Further, this load data d is transmitted via the own system load monitoring section 8 to the other system load monitoring section 8- on the own system side.

On the contrary, the other-system load monitoring section 8 on the own side takes in the load data d- transmitted from the other-system side as the other-system load data e, and stores this in the other-system load storage section 9.

Now, when the transmission data storage section 3 is supplied with the transmission data a from the central processing unit (not shown) and the transmission control section 5 is given the transmission request data b, the transmission control section 5 stores the own system load storage section 7. , and the other-system load storage unit 9, respectively, to extract own-system load data d and other-system load data e. and,
These data d and e are compared with a preset reference value, and if it is determined that both data d and e are less than the reference value, it is determined that data transmission is possible, and the data transmission unit A transmission control button g is output to instruct transmission to 4.

Furthermore, if it is determined that at least one of the data d and e is less than the reference value, it is determined that the data cannot be transmitted and is stored in the transmission request storage section 1o.

Thereafter, the transmission control unit 5 extracts the load data d, e stored in each load storage unit 7, 9 each time the stored data is updated, and compares it with a reference value. Then, when both data d and e become equal to or less than the reference value, transmission request storage data f is extracted from the transmission request storage section 10 and transmission control data g that instructs the data transmission section 4 to transmit is supplied.

At the same time, the transmission control section 5 transmits the transmission command to the transmission control section 5' on the other system side. Upon receiving this, the transmission control section 5- on the other system side outputs transmission control data g instructing the data transmission section 4- to receive the data.

Then, the data transmission section 4 on the own system side extracts the transmission data a from the transmission data storage section 3, and extracts the transmission data a from the transmission data storage section 3, and
- as received data C-. This received data C
' is passed from the data transmission section 4' to the received data storage section 5', and then sent to a central processing unit (not shown).

In this way, data is transmitted from the own system to the other system.

Figure 2 shows a characteristic diagram of the computer load at this time.As shown in the figure, a transmission request is given at time t2, and transmission is stopped at time t3 when the computer load falls below the reference value. It can be seen that the computer load is equalized compared to the conventional device.

In this way, in this embodiment, the own computer system 1
The load status of the other computer system 2 is also monitored, and when both loads are below a reference value, pig transmission is performed.

Therefore, the load on each computer system], 2 does not become abnormally high, and data can be transmitted while maintaining a uniform load.

Although this embodiment describes data transmission at two locations, the own system side and the other system side, it goes without saying that this embodiment can be applied to three or more locations.

[Effects of the Invention] As explained above, in the present invention, the load status of the own 81 computer system and the other computer system is monitored, and the load of both old computer systems is below the reference value. In this case, a data transmission command is supplied to the pig transmission means. Therefore, the load on each computer system does not increase, and a uniform load can always be maintained.

Therefore, problems such as system failure and inability to transmit data do not occur as in the prior art, and it is possible to achieve the effect that smooth data transmission is possible.

[Brief explanation of the drawing]

FIG. 1 is a block diagram showing an embodiment of the present invention, FIG. 2 is a characteristic diagram showing computer load, and FIG. 3 is a block diagram showing a conventional example. ]... Own computer system 2... Other computer system 4.4'... Data transmission section 5.5'... Transmission control section 66'... Own system load monitoring section 8.8'... Other system load monitoring unit 10.10--Transmission request storage unit

Claims (1)

[Scope of Claims] Own system computer monitoring means for monitoring the load state of the own system computer system; and other system computer monitoring means for monitoring the load state of the other system computer system; when a transmission request command is given, both of the above Determine whether the load of the computer system is above the reference value, and if both loads are below the reference value, output a data transmission command,
data transmission control means that outputs a transmission command after both loads become below the reference value when at least one of the two loads is equal to or higher than the reference value; A transmission control device comprising: a data transmission means for performing the following;