JPH02308644A - Communication protocol converter - Google Patents

Abstract

PURPOSE:To couple between each node and a computer with plural logic circuits by providing plural 2nd conversion means converting a communication protocol corresponding to a host computer into a communication protocol corresponding to a node, thereby assigning a data from each node supplied from a 1st conversion means selectively. CONSTITUTION:A parameter file is given to the control tables 22, 32a-32n of a communication protocol converter 12 and the address of units U1-Un converting a 2nd protocol into a 1st communication protocol is assigned to the table 22. Then the data transfer from a decentralized processing processor 11 to a host computer 13 or from the computer 13 to the processor 11 is judged based on a reception data. Then the data at every node is processed selectively depending on the address from tables 32a-32n as the 2nd communication protocol conversion means, information exchange areas 31a-31n and buffers 33a-33n and the table 22.

Description

[Detailed Description of the Invention] [Object of the Invention] (Industrial Application Field) The present invention relates to a communication protocol conversion device, and in particular, a communication protocol conversion device that is provided between a plurality of nodes constituting a distributed processing system and a host computer, and that is used to transfer data between them. The present invention relates to a communication protocol conversion device that converts communication protocols for communication purposes.

(Prior Art) Generally, in a distributed processing system, for the purpose of collecting data processing results etc. obtained from each of a plurality of nodes (data processing devices) constituting the system,
Each node is connected to a host computer by a predetermined line. If the communication protocol between each node and the communication protocol of the host computer are different, a communication protocol conversion device is provided between each node and the host computer in order to properly transfer data between the nodes.

The communication protocol conversion device converts a communication protocol compatible with a transfer source device to a communication protocol compatible with a transfer destination device, and has a first function of converting a communication protocol between each node to a communication protocol of a host computer; It has a second function of converting the communication protocol of the host computer into the communication protocol between each node.

However, in conventional protocol conversion devices, only one first function and one second function for protocol conversion are provided, so line connection can only be made between one node and one host computer. The disadvantage is that it is limited to logical channels. This is a major cause of reducing line usage efficiency.

(Problems to be Solved by the Invention) Conventional communication protocol conversion devices have the disadvantage that they can only connect a line between one node and one logical line of a host computer, resulting in low line usage efficiency.

The present invention was made in view of these points, and an object of the present invention is to provide a protocol conversion device that can connect each node and a host computer using multiple logical lines and improve the efficiency of line usage. shall be.

[Structure of the Invention] (Means for Solving the Problems) The present invention provides a communication protocol conversion system that is provided between a plurality of nodes constituting a distributed processing system and a host computer, and that performs communication protocol conversion for data transfer between them. In the apparatus, a first conversion means coupled to the plurality of nodes and converting a first communication protocol corresponding to the nodes into a second communication protocol corresponding to the host computer; and a first conversion means coupled to each of the host computers. , a plurality of second conversion means for converting the second communication protocol into the first communication protocol, and address information assigned corresponding to each of these second conversion means and transmitted from each of the nodes. and logical line allocation means for selectively allocating data from each node supplied to the first conversion means to the plurality of second conversion means based on transfer destination address information. do.

(Function) This protocol conversion device is provided with a plurality of second conversion means for converting a communication protocol compatible with a host computer into a communication protocol compatible with a node, and these second conversion means include a first one. The data from each node supplied to the conversion means of is selectively allocated. Therefore, each node and the host computer can be connected not only by one line but by a plurality of logical lines, thereby making it possible to improve line efficiency.

(Example) Hereinafter, the present invention will be described in detail with reference to the drawings.

FIG. 1 shows a system configuration using a communication protocol conversion device according to an embodiment of the present invention.

The distributed processing processor 11 is one of a plurality of nodes constituting the distributed processing system, and includes an online application program execution unit Zta for communication and a system task execution unit 11b. Here, among the plurality of distributed processing processors, the distributed processing processor 11
Although only one processor is shown as a representative, the other processors also have the same configuration as the processor 11. That is, each distributed processing processor is configured to be able to transfer data to each other based on the first communication protocol.

The communication protocol conversion device 12 converts communication protocols for data transfer between each distributed processing processor (distributed processing processor 11 and other distributed processing processors not shown) and the host computer 13. It is coupled to each distributed processing processor via L1, and connected to the host computer 1 via line L2.
Connected to 3.

The communication protocol conversion device 12 includes an information exchange area 21 and a control table 2 as a unit for converting a first communication protocol corresponding to each distributed processing processor into a second communication protocol corresponding to the host computer 13.
2 and a memory buffer 23 are provided. The protocol conversion device 12 also includes a plurality of units Ul-Un'E- for converting the second communication protocol into the first communication protocol. That is, the information exchange area 31a, the control table 32a and the memory buffer 33
a constitutes the first unit Ul, and the information exchange area 31b, control table 32b and memory buffer 33b constitute the second unit U2, and information exchange area 31n1 control table 3
2n and the memory buffer 33n constitute an n-th unit Un. These first to n-th units U1 to Un each transmit the second communication protocol to the first
Executes a conversion function to convert the communication protocol. Further, the communication protocol conversion device 12 is provided with a system task execution unit 34, and the system task execution unit 34 executes the control tables 22.32a to 32n.
A parameter file is set for each. In other words, the control table 22 contains the address of the information exchange area 21,
The addresses of the control tables 32a to 32n are dynamically assigned, thereby logically linking the information exchange area 21, the control table 2-2, and each control table 32a to 32n. Furthermore, the addresses of the corresponding information exchange areas 31a to 31r+ and the address of the control table 22 are dynamically assigned to each of the control tables 32a to 32n, and the information exchange areas 31a to 81n and the control table 32a corresponding thereto are dynamically assigned. 32n and the control table 22 are logically coupled. Furthermore, the control tables 32a~
32n is provided with areas S and D to which are respectively assigned the address of the distributed processing processor to be communicated with and the address indicating the logical line of the host computer.

In this manner, the communication protocol conversion device 12 is provided with a plurality of conversion units that convert the second communication protocol corresponding to the host computer 13 into the first communication protocol corresponding to each processor. Data from each processor supplied to the information exchange area 21 is selectively assigned to the conversion unit. Therefore, between each processor and the host computer 13,
Connected by multiple logical lines.

Next, the operation of the communication protocol conversion device 12 will be explained with reference to the flowchart in FIG.

First, as mentioned above, the control tables 22.32a to 3
2n is given a parameter file, and the addresses of the units U1 to Un that convert the second communication protocol into the first communication protocol are assigned to the control table 22 (step AI). Next, based on the received data, it is determined whether the data should be transferred from the distributed processor 11 to the host computer 13 or from the host computer 13 to the distributed processor 11 (step A2).

In the case of data transfer from the distributed processing processor 11 to the host computer 13, the information exchange area 21 and the control table 22 are first logically coupled, and then the control table 2
2 information is developed in the memory buffer 23 (step A
3). In this case, the address of the first unit U1, that is, the address of the area of the control table 32a is read from the control table 22. Next, a comparison process is performed between the transfer destination address of the received data input to the information exchange area 21 and the address of the unit Ul (step A).
4) Based on the comparison result, it is determined whether the addresses are the same (step A5). If they are the same, the address of unit U1 is set as the transfer destination logical unit address for the received data (step A6), and the data is transferred to the host computer 13 (step A8). Further, as a result of the determination in step A5, if the addresses are not the same, the address of the second unit U2 from the control table 22 is developed into the buffer 23 (step A7), and the address of the unit U2 and the received data are transferred. Comparison with the destination address is again made in step A4. It will be held in A5.

On the other hand, in the case of data transfer from the host computer 13 to the distributed processing processor, first, in units U1 to Un, the information exchange area and the control table in the unit to which the address corresponding to the received data is assigned are logically combined. Then, the information in the control table is expanded to the corresponding memory buffer (step A9). and,
The address set in area S of the control table, that is, the address indicating the distributed processing processor to be communicated with, is set as the transfer destination logical unit address of the received data (step Al0), and the data is transferred to the distributed processing processor (step A11). ).

In this way, in this protocol conversion device, each node and the host computer can be connected not only by one line but by a plurality of logical lines, thereby making it possible to improve line efficiency.

[Effects of the Invention] As described above, according to the present invention, each node and the host computer can be connected by a plurality of logical lines, thereby making it possible to improve the efficiency of line usage.

[Brief explanation of the drawing]

FIG. 1 is a block diagram showing a system configuration using a protocol conversion device according to an embodiment of the present invention, and FIG. 2 is a flowchart for explaining the operation of the protocol conversion device shown in FIG. 1. il...Distributed processing processor, 12...Protocol conversion device, 13...Host computer, 21.31
a~3in...information exchange area, 22.32a~32
n...Control table, 23.33a-33n...Memory buffer.

Claims (1)

[Scope of Claims] A communication protocol conversion device that is provided between a plurality of nodes constituting a distributed processing system and a host computer and converts a communication protocol for data transfer therebetween, comprising: a first conversion means for converting a first communication protocol corresponding to a node into a second communication protocol corresponding to the host computer; Based on a plurality of second conversion means for converting into a communication protocol, address information assigned correspondingly to each of these second conversion means, and transfer destination address information sent from each of the nodes, the first A communication protocol conversion device comprising: logical line allocation means for selectively allocating data from each node supplied to the conversion means to the plurality of second conversion means.