JPH088569B2 - Broadcast communication system - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION [Outline] Regarding a broadcast communication method for performing broadcast communication in wormhole routing, a header flit at the beginning of a flit obtained by dividing a message into transmission units is transmitted with broadcast communication range information. , The node that receives this repeatedly refers to the range information, saves it in its own node, and transmits it to the corresponding node repeatedly, aiming to perform broadcast communication in wormhole routing quickly and efficiently. A flit divided into transfer units has a header flit having broadcast communication range information at the beginning and a final flit at the end, and is sent sequentially from one node to another node on the network, and the receiving node refers to the above header flit. When the range information is transmitted to another node by updating the range information, It is configured such that the dufflit is transmitted to the node in the transmission direction and the flits subsequently transmitted are sequentially transmitted until the final flit.

[Industrial application field]

The present invention relates to a broadcast communication system for performing broadcast communication in wormhole routing.

[Problems to be Solved by Conventional Techniques and Inventions]

As a communication method between parallel computers, there is a method called wormhole routing. This is to divide a message into minimum transfer units called flits (for example, a few bytes), send a header flit that has transmission range information at the beginning, and this header flit creates a relay route from node to node and is used within the network. To the node. After this header flit, the route is continuously transmitted to the node until the final flit, occupying the route.
It is designed to send one set of messages to the target node.

Conventionally, when the same message is transmitted from a certain node to a plurality of other nodes by the above-mentioned wormhole routing, that is, when performing broadcast communication, the transmission is repeated one by one from a certain node to a plurality of other nodes. Therefore, there is a problem that broadcast communication cannot be performed quickly and efficiently.

According to the present invention, of the flits obtained by dividing a message into transfer units, the header flit at the head is transmitted with broadcast communication range information, and the node that receives this stores it in its own node by referring to the range information. The purpose is to perform broadcast communication in wormhole routing quickly and efficiently by repeatedly transmitting to the corresponding node.

[Means for solving the problem]

 FIG. 1 shows the principle configuration of the present invention.

In FIG. 1, flit 1 has contents (data) obtained by dividing a message into transfer units.

The header flit 1-1 is a head flit having range information of broadcast communication.

The final flit 1-2 is a flit representing the end (final) of the frit 1.

 The node 2 is a node on the network.

[Action]

According to the present invention, as shown in FIG. 1, a flit 1 obtained by dividing a message into transfer units has a header flit 1-1 having broadcast communication range information at the beginning and a final flit 1 at the end.
-2 is provided, and the range is transmitted from one node 2 to another node 2 on the network sequentially, and when the received node 2 refers to the header flit 1-1, the range information is transmitted to the other node 2. Update the information to update the header flit 1-
1 is transmitted to the node 2 in the transmission direction and the flit 1 transmitted subsequently thereto is the final flit 1-2.
I'm trying to send sequentially.

Therefore, the flit 1 that divides the message into transfer units
The header flit 1-1 at the head of the node is sequentially transmitted with the range information of the broadcast communication being transmitted, and the node 2 that receives the flit 1 refers to the range information and saves it in its own node and the node 2 in the transmission direction. It is possible to quickly and efficiently perform broadcast communication in the wormhole routing by repeating the transmission to the.

〔Example〕

Next, the configuration and operation of one embodiment of the present invention will be sequentially described in detail with reference to FIGS. 1 to 3.

FIG. 1A shows an example of a data flow of broadcast communication in the one-dimensional network example. 2a is the sending node,
The shaded area is the receiving node. In this case,
The transmission range information is 2, and broadcast communication is performed from the transmission node 2a to a node that is two destinations in both directions.

FIG. 1B shows an example of a data flow of broadcast communication in the two-dimensional network example. 2b is the sending node,
The shaded area is the receiving node. In this case,
The transmission range information is X direction 2 and Y direction 1, and broadcast communication is performed from the transmission node 2a to + X direction and two nodes ahead in the -Y direction, and one in the + Y direction and -Y direction from the transmission node 2a. Broadcast communication to the destination node.

FIG. 1C shows an example of frit. This frit 1
Is a message divided into transfer units (for example, several bytes), and is composed of a header flit 1-1, a flit having data, and a final flit 1-2 representing the end. The header flit 1-1 stores the transmission range information in the above-mentioned broadcast communication. The range information of this transmission is range information of how many nodes ahead in the case of a one-dimensional network, and how many nodes ahead in the ± X and ± Y directions of a two-dimensional network. It is range information. The final flit 1-2 is EOD by setting the end bit to "1".
(End of file, final of flit).

Next, according to the order shown in the flowchart of FIG.
The operation of the diagram structure will be described in detail.

In FIG. 2, the header flit is received and stored. This is because, for example, the node 2 shown by (a) and (b) in FIG. 1 receives the header flit 1-1 shown in (c) of FIG. 1 and stores the contents in its own node.

 Refers to the range information of the transmission in the header lit.

Determines whether it is other than 0 (zero). If YES, flits (header flits or flits) are sequentially sent in the transmission direction. In the case of NO, since the own node is the last node of the broadcast communication, it is saved from the next flit to the final flit without being sent to another node.

Decrements the transmission range information by -1. This is because the transmission range information is determined to be other than 0 (zero), so it is necessary to transmit to another node, so the transmission range information is updated by -1.

Sends flits (head frit, frit) in the transmission direction. As a result, the flit is transmitted to the adjacent nodes in the transmission direction.

Determines whether or not the transmission of the final flit has been completed. In the case of YES, since the header flit is transmitted in the transmission direction up to the final flit, the process ends. In the case of NO, the next flit is received and stored with, and is sent in the sending direction repeatedly with.

According to the above procedure, in a certain node, when the received range information of the transmission of the head frit 1-1 is other than 0 (zero), the range information of the transmission is decremented by -1 to the node in the transmission direction from the head frit 1-1. By sequentially transmitting to the final flit 1-2 for the first time, broadcast communication is performed until the range information becomes 0 (zero).

FIG. 3A shows an example of one node. This shows an example of one node in the example of the two-dimensional network of FIG. 1B, is a block for routing in the X direction, and is a block for routing in the Y direction. The FIFO is a buffer that temporarily stores data (flit) flowing in the X direction. Here, corresponding to the range information in the X direction in the head frit 1-1 received by the block, the range information in the X direction is -1 and transmitted to the adjacent node in the + X direction or the adjacent node in the -X direction. To do. Corresponding to the range information in the Y direction in the header flit 1-1 received by the block, the range information in the Y direction is subtracted by -1 and transmitted to the adjacent node in the + Y direction or the adjacent node in the -Y direction.

FIG. 3 (b) shows the first example of one node in FIG. 3 (a).
The entire configuration when a two-dimensional network is configured as shown in FIG. Here, the routing is to perform the ± X direction and ± Y direction routing, and the processor performs the above-described processing to perform broadcast communication within the range information and various processing.

〔The invention's effect〕

As described above, according to the present invention, a message is divided into flits 1 as a transfer unit, the header flit 1-1 at the head is sequentially transmitted with the range information of the broadcast communication being transmitted, and this is received. By adopting a configuration in which the node 2 referred to stores the range information, saves it in its own node, and transmits it to the node 2 in the transmission direction, the broadcast communication in the wormhole routing is performed quickly and efficiently. You can

[Brief description of drawings]

FIG. 1 is a principle block diagram of the present invention, FIG. 2 is a flowchart for explaining the operation of the present invention, and FIG. 3 is a block diagram of one embodiment of the present invention. In the figure, 1 is a frit, 1-1 is a header flit, 1-2.
Represents the final flit, 2 represents a node, and represents a block.

Claims (1)

[Claims] 1. In a broadcast communication system for performing broadcast communication in wormhole routing, a header flit (1-1) having broadcast communication range information at the beginning of a flit (1) obtained by dividing a message into transfer units.
And a final flit (1-2) is provided at the end of the header, and a node (2) sequentially transmits to another node (2) on the network, and the node (2) having received the header flit (1-1).
When the range information is transmitted to another node (2) by referring to, the range information is updated and the header flit (1-
1) is transmitted to the node (2) in the transmission direction, and flits (1) transmitted subsequently thereto are sequentially transmitted to the final flit (1-2). .