JPH1155304A - Switching hub - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a switching hub for operating flow control with high reliability and high transmission efficiency. SOLUTION: This is a switching hub 11 having plural ports and a buffer 23 which temporarily preserves transfer data between ports. When data 32 from a terminal 12a to the destination of a terminal 12d are received during the stop of transmission to the terminal 12d according to a request from the terminal 12d, a transmission stop instruction 33 is issued to the terminal 12a being the origin of the transmission of the data. Thus, transmission from the terminal 12a is stopped so that the overflow of the buffer 23 can be prevented.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

The present invention relates to a switching hub for transferring data between a plurality of ports, and more particularly to a switching hub for performing flow control with high reliability and high transmission efficiency.

[0002]

2. Description of the Related Art Switching hubs have recently attracted attention as LAN devices that can easily increase the bandwidth of a network. As shown in FIG.
Terminals 12a to 12f are connected to the ports 1a and 11b, respectively. By connecting the switching hubs in this way, a system having a larger scale can be provided as compared with a system using only one switching hub.

The switching hub has a plurality of ports, and relays data only to necessary ports by checking the destination of the data. For example, terminals 12a and 12b, 12c and 12
d, 12e and 12f can be simultaneously communicated in a plurality of sets.

FIG. 7 shows the inside of a switching hub. The switching hub 11 is provided with a switching unit 21 for exchanging data, network interface units 22a to 22d of each port, and a buffer 23.

[0005] The switching hub stores data in a buffer when data of the same destination is received at the same time and transmission competition occurs, or when transmission processing cannot be performed immediately due to processing capacity. When the buffer is full of data waiting to be transmitted, data is lost.

[0006] The terminal also has a buffer, and when data is received one after another, the data is stored in the buffer. However, if the internal buffer becomes full because the processing cannot keep up with the processing capacity, the data is lost. Occurs.

[0007] In order to prevent such data loss, it is necessary to perform flow control for adjusting the amount of data flowing on the network to an appropriate value.

As a flow control in Ethernet, a back pressure method is known. This method intentionally creates a collision situation by jam signal etc.,
This is to make the sending side wait.

In a full-duplex Ethernet capable of simultaneously transmitting and receiving data, the back pressure method cannot be used. For this reason, the IEEE 802.3 committee, which standardizes Ethernet, defines a special flow control frame in the standard of full-duplex Ethernet.

[0010]

As shown in FIG. 2, it is assumed that the terminal 12d issues a transmission stop command 31 to the switching hub 11. At this time, the switching hub 11 transmits the data 32 addressed to the terminal 12d from another port.
Is received, the data cannot be transmitted to the terminal 12d, and the data is stored in the buffer 23. As described above, the state in which data cannot be transmitted to the terminal 12d continues for a long time,
In the meantime, when data 32 destined for the terminal 12d is received one after another as shown in FIG.
3, the buffer 23 eventually overflows, and the received data is lost.

An object of the present invention is to solve the above-mentioned problems and to provide a switching hub which performs flow control with high reliability and high transmission efficiency.

[0012]

According to the present invention, there is provided a switching hub having a plurality of ports and a buffer for temporarily storing transfer data between the ports. If data from another terminal is received while the transmission to the terminal is stopped, a transmission stop command is issued to the source terminal of the data.

In a switching hub having a plurality of ports and having a buffer for temporarily storing transfer data between the ports, when transmission to the terminal is stopped by a request from the terminal, the transmission to the terminal is stopped. When data from another terminal is received, a jam signal is transmitted to the source terminal of the data.

[0014]

An embodiment of the present invention will be described below in detail with reference to the accompanying drawings.

As shown in FIG. 2, the switching hub 11 is provided with network interface units 22a to 22d of a plurality of ports, a switching unit 21 for exchanging data between ports, and a buffer 23 for temporarily storing data. I have. The switching hub 11 and the terminals 12a to 12d connected to the respective ports can issue a transmission stop command for temporarily stopping data transmission from the other party to the other party. When the switching hub 11 receives a transmission stop command from a terminal, the switching hub 11 enters a transmission stop state in which transmission from a port to which the terminal is connected is stopped. Further, when data from another terminal is received addressed to the terminal, a transmission stop command is issued to the source terminal of the data.

Here, a transmission stop command 31 is issued from the terminal 12d to the switching hub 11, and while the transmission from the switching hub 11 to the terminal 12d is stopped, the terminal 12a transmits the data 32 addressed to the terminal 12d. Consider the case of transmitting one after another.

As shown in FIG. 1, when the switching hub 11 receives the data 32 addressed to the terminal 12d from the terminal 12a, the transmission to the terminal 12d is stopped. 23, and at the same time, issues a transmission stop command 33 to the terminal 12a that is the source of the data 32. The terminal 12a is the terminal 1
The transmission of data 32 destined for 2d is tried one after another, but transmission is stopped when the transmission stop command 33 is received. Therefore, after this, the terminal 12a is connected to the switching hub 11.
Will not receive the data 32 addressed to the terminal 12d. Therefore, the buffer 23 does not overflow due to the data 32 received one after another.

In this way, it is possible to avoid a situation in which the buffer 23 overflows because another terminal sequentially transmits data to the terminal that has stopped transmitting.

As shown in FIG. 3, the switching hub 11 transmits a transmission stop command 31 from the terminal 12d.
When data 32 addressed to the terminal 12d is received from the terminal 12a in a state where transmission to the terminal 12d is stopped according to, the data 32 is temporarily stored in the buffer 23, and at the same time, transmitted to the source terminal 12a. Transmission stop instruction 3
Issue 3. As a result, the terminal 12a stops transmitting. Here, it is assumed that the terminal 12b has transmitted the data 32 addressed to the terminal 12d. The switching hub 11 is a terminal 1
The data from 2b is temporarily stored in the buffer 23, and a transmission stop command is issued to the terminal 12b of the transmission source. Further, when the terminal 12c transmits the data 32 addressed to the terminal 12d,
A transmission stop command is also issued to the terminal 12c. As a result, all the terminals 12a to 12a that transmit data addressed to the terminal 12d
2c is in a transmission stop state.

Another embodiment of the present invention described below is to prevent all terminals from being in a transmission stop state.

As shown in FIG. 4, the switching hub 11 is connected to network interface units 22a to 22d of a plurality of ports, a switching unit 21 for exchanging data between ports, a buffer 23 for temporarily storing data, and ports. Address search unit 5 for registering and searching for the address of the terminal that has been sent and the address of the terminal in the transmission suspended state
1. A jam signal generator 52 for generating a jam signal and sending it to a desired port is provided. Switching hub 11 and terminals 12a to 12d connected to each port
Can issue a transmission stop command to temporarily suspend data transmission from the other party to each other. When the switching hub 11 receives a transmission stop command from a terminal, the switching hub 11 enters a transmission stop state in which transmission from a port to which the terminal is connected is stopped. Further, the address of the terminal in the transmission stop state is retrieved by the address search unit 51.
, And when the data is received, the address search unit 51 is searched, and if the data is addressed to a terminal in a transmission stopped state, a jam signal is transmitted to the terminal that transmitted the data.

Here, a transmission stop command 31 is issued from the terminal 12d to the switching hub 11, and while the transmission from the switching hub 11 to the terminal 12d is stopped, the terminal 12a transmits the data 32 addressed to the terminal 12d. Consider the case of sending.

It is registered in the address search section 51 that the terminal 12d is in the transmission stop state. As shown in FIG. 5, when the switching hub 11 receives the data 32 addressed to the terminal 12d from the terminal 12a, the switching hub 11 searches the address search unit 51 to know that the terminal 12d is in the transmission stop state, and buffers the data 32. Discard without storing in 23,
The jam signal 42 is sent from the jam signal generator 52 to the terminal 12a.
Is sent. Terminal 12a that has received this jam signal 42
Knows that the transmission has failed, and retransmits the data 32. The switching hub 11 sends a jam signal 42 also to the retransmission data. The IEEE 802.3 committee stipulates that the retransmission of 10M Ethernet is limited to 16 times. If the number of retransmissions exceeds 16, the transmission of the data is regarded as completely failed, and the transmission of the data is stopped. Therefore, the terminal 12a stops transmitting the data 32 addressed to the terminal 12d after trying retransmission 16 times.
As a result, the terminal 12a can perform transmission / reception with another terminal.

Similarly, when the other terminals 12b and 12c transmit data addressed to the terminal 12d, the switching hub 1
No. 1 discards data without storing it, and sends a jam signal 42 to the terminals 12b and 12c to urge retransmission and transmission stop. After each terminal attempts retransmission 16 times, it stops transmitting data addressed to terminal 12d. As a result, each terminal can transmit and receive to and from another terminal, and all terminals do not enter a transmission stop state.

In this way, it is possible to avoid a situation in which the buffer 23 overflows due to the data transmission of the other terminals one after another to the terminal that has stopped transmitting, and all the terminals are in the transmission stopped state. The situation will also be avoided.

[0026]

The present invention exhibits the following excellent effects.

(1) Since the buffer does not overflow, a highly reliable system can be constructed.

(2) Since a situation in which all terminals stop transmitting is avoided, a system with high transmission efficiency can be constructed.

[Brief description of the drawings]

FIG. 1 is a diagram illustrating a data transmission diagram between a switching hub and a terminal according to an embodiment of the present invention.

FIG. 2 is a configuration diagram of the inside of a switching hub and a system using the switching hub according to an embodiment of the present invention.

FIG. 3 is a diagram illustrating a data transmission diagram between a switching hub and a terminal according to an embodiment of the present invention;

FIG. 4 is a configuration diagram of the inside of a switching hub and a system using the switching hub according to another embodiment of the present invention.

FIG. 5 is a diagram illustrating a data transmission diagram between a switching hub and a terminal according to another embodiment of the present invention;

FIG. 6 is a configuration diagram of a system using a switching hub.

FIG. 7 is an internal configuration diagram of the switching hub.

FIG. 8 is a diagram illustrating a data transmission diagram between a switching hub and a terminal according to the related art.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 11 Switching hub 12a, 12b, 12c, 12d Terminal 23 Buffer 32 Data 33 Transmission stop command 42 Jam signal

Claims (2)

[Claims] In a switching hub having a plurality of ports and a buffer for temporarily storing transfer data between the ports, when transmission to the terminal is stopped in response to a request from the terminal, the destination is addressed to the terminal. Wherein when a data is received from another terminal, a transmission stop command is issued to a source terminal of the data. 2. A switching hub having a plurality of ports and having a buffer for temporarily storing transfer data between the ports, when transmission to the terminal is stopped in response to a request from the terminal, the destination is addressed to the terminal. Wherein when a data from another terminal is received, a jam signal is transmitted to a terminal from which the data is transmitted.