JPH01256245A - Communication control system - Google Patents

Abstract

PURPOSE:To enable impartial transmission permission service by allowing a transmission right assignment circuit to arbitrate a transmission request of other ports in one and the same node at the release of a packet by a port in a node and the allowing the circuit to assign the transmission right in a similar way when each port is connected independently to a ring. CONSTITUTION:Since the transmission right is moved in the same direction on the ring as the packet circulating direction at every transmission of one packet in the use of a conventional packet access system with ports 4 connected independently to the ring, the transmission permission service is not made impartial. Thus, the same system of the transmission assignment as the case with that each port 4 connected independently to the ring is adopted for the transmission right assignment to the ports 4 in the node 2 when the plural ports exist in the node 2. Thus, the impartial transmission permission service to the ports 4 in the node is realized.

Description

DETAILED DESCRIPTION OF THE INVENTION [Field of Industrial Application] The present invention relates to a communication control system, and more particularly, to a communication control system, in particular, a fair bucket 1 to 1 between a plurality of ports in a ring LAN having a plurality of bauds in a node. Concerning transmission right allocation method.

[Conventional technology]

Conventionally, transmission right allocation to multiple ports within a node in a ring network system is based on previous allocation information and the current Based on the transmission request state, a ROM or the like is used to determine the next port to be assigned the transmission right. To explain this using Figure 2, p! (X=1 to 4) indicates a port to which a transmission right is assigned, and rx (x=1 to 5) is a bit pattern of transmission requests of all ports arranged.

When the port to which the transmission right was previously assigned is pz and the current transmission request pattern is rz, the next port to which the transmission right is assigned is p4.

[Problem to be solved by the invention]

The above-mentioned conventional technology does not give consideration to the strict fairness of allocation, and there is a possibility that the transmission permission service will be biased toward a specific baud. this.

m px (x=i, j), which will be explained with reference to FIG.
) indicates a transmission request pattern. Now, after the transmission right is transferred from pl to PJ by rl, when the transmission right is returned to p by r2, ports other than pI and PJ are not transmitting during that period, so if PJ issues a request, it will be sent. The pattern becomes rl again, forming a loop, and there is a possibility that transmission permission services will be concentrated.

An object of the present invention is to realize a fair transmission permission service by devising a transmission right allocation algorithm.

[Means to solve the problem]

The purpose of the above is that even when a port within a node releases a packet, the transmission right allocation circuit discards transmission requests from other ports within the same node, similar to when each port is independently connected to the ring. This is achieved by allocating transmission rights.

[Operation] When each port is connected to the ring independently, if a general packet access method is used, the transmission right moves on the ring in the same direction as the packet circulates each time one packet is transmitted. Permit services are not biased.

Therefore, when there are multiple ports within a node, by assigning transmission rights to the intra-node ports in the same way as when each port is independently connected to a ring, fair transmission permission can be given to the intra-node ports. Service can be realized.

The transmission right allocation algorithm for intra-node ports is shown below (ports are ps to P1.).

(1) If the circulating packet is empty, the transmission right is assigned to the port with the smallest port number among the ports issuing transmission requests.

If there is no port issuing a transmission request, the packet is passed through empty.

(2) When pI releases the circulating packet, the transmission right is assigned to the port with the smallest port number among the ports that have a larger port number than 1 and have issued a transmission request. If there is no corresponding port, the packet is released and output.

〔Example〕

Hereinafter, one embodiment of the present invention will be described with reference to the drawings.

Figure 4 shows the entire ring-type LAN, with multiple nodes 2
are connected to each other by transmission line 1. A plurality of ports 4 exist inside each node 2.

Information is exchanged by circulating packets in the direction of the arrow on the transmission line 1 and sharing the packets between the respective ports.

FIG. 1 is a diagram showing the main features of the present invention, and shows the internal configuration of the node 2. Transmission data received from the input side transmission path 1 is input to the node basic section 3, and the serial-parallel After converting.

It is output to the reception bus 5. Port 4 receives a packet addressed to itself from the reception bus, and in the case of packet transmission, port 4 outputs packet data to transmission bus 6, node basic unit 3 inputs the packet data, and performs parallel-to-serial conversion. After that, it is output to the transmission line 1 on the output side.

Transmission right allocation control when a plurality of ports 4 are issuing packet transmission requests is performed by the transmission right allocation circuit 7. The node basic unit 3 outputs a packet free signal to the transmission right allocation circuit 7, and also inputs a packet release signal from the transmission right allocation circuit 7.

The operation of the transmission module allocation circuit is explained with reference to FIG. 5.6 Packet transmission enable input signal 0 is turned on when the packet input from transmission path 1 is empty or when port 4 at the previous stage releases the packet. Become.

Bucket 1 - Send enable input signal 10 is input with the packet transmit enable output signal 13 of the previous stage port 4 if there is a previous stage port 4, and if it is the first stage port 4, the packet transmit enable input signal 10 is input from the node basic unit 3. Packet [・Input empty signal 8. At port 4, where the packet transmission enable input signal 10 is turned on,
If there is a packet transmission request, the packet transmission permission signal 1 is sent.
1- is set to 0, the packet transmission enable output signal 13 to the subsequent port 4 is turned off, and the packet data is output to the transmission bus 6.

The port 4 that releases the packet input from the reception bus 5 sets the packet transmission enable on signal to Y1, and turns on the packet transmission enable output signal 13 to the subsequent port 4. The packet transmission enable output signal 13 of port 4 in the last stage indicates that no port 4 uses the packet at that time.
The packet is inputted to the node basic unit 3 as a packet release signal 9 instructing to output it as an empty packet.

By the above operation of the transmission right allocation circuit 7, each port 4
It is possible to allocate transmission rights in the same way as when the nodes are independently connected to the ring.

〔Effect of the invention〕

According to the present invention, it is possible to allocate transmission rights to ports within a node while maintaining fairness, so each port is guaranteed to have appropriate transmission capability.

[Brief explanation of the drawing]

Figure 1 is the internal configuration of a node, Figure 2 is a conventional transmission right allocation flowchart, Figure 3 is an explanatory diagram of the conventional transmission right allocation method, Figure 4 is the entire ring type LAN, and Figure 5 FIG. 2 is a diagram showing a transmission right allocation circuit. DESCRIPTION OF SYMBOLS 1... Transmission path, 2... Node, 3... Node basic part, 4... Port, 5... Reception bus, 6... Transmission bus, 7... Transmission right allocation circuit , 8...Packet empty signal, 9...Packet release signal, 10...Packet transmittable input signal, 11...Packet transmittable transmission signal, 12...Packet. Packet transmission enabled on signal, 13...Packet transmission enabled output
. Signal, 14 to 17... Baud to which transmission rights are assigned
5. 7 Figure/ 2z Figure 3

Claims (1)

[Claims] 1. A plurality of node devices are connected by a common loop-shaped transmission path, and each node has a plurality of ports for packet communication,
In a data communication system that circulates multiple packets on the transmission path and dynamically shares the packets between ports to send and receive data between ports, a transmission right allocation circuit that mediates transmission requests between the ports. 2. A communication control system, wherein the transmission right allocation circuit arbitrates transmission requests from other ports within the node when a packet is released by one port within the node.