JPH01226252A - System for dividing transmission data for plural hierarchy protocols - Google Patents

Abstract

PURPOSE:To reduce overhead at the time of transmitting data by dividing transmission data based on the transmission data length, the maximum transfer data length of respective hierarchies and an addition data length in respective hierarchies and executing a processing based on a protocol with respect to the divided transmission data. CONSTITUTION:First information 113 with respect to the transmission data length, second information 115 on the maximum transfer data length in respective hierarchies of the protocol consisting of plural hierarchies and the data length added in respective hierarchies are induced to a data division designation means 111, and an instruction on the division of transmission data is given. Transmission data is introduced into a data division means 121 and transmission data is divided in accordance with the instruction of the data division designation means 111. Transmission data which the data division means 121 has divided are introduced to a protocol processing means 131 and the processing is executed based on the protocol consisting of plural hierarchies. Consequently, a system as a whole is constituted that transmission data are divided based on the transmission data length, the maximum transfer data length and the additional data length.

Description

[Detailed Description of the Invention] [Summary] The purpose of this invention is to reduce the overhead during data transmission regarding a transmission data division method of a multi-layer protocol when transmitting data that exceeds the maximum transfer length of each layer protocol. A data division specifying means that includes first information regarding the data length, and second information regarding the maximum transfer data length and the data length added at each layer in each layer of a protocol consisting of multiple layers, and provides an instruction regarding division of transmission data. , transmission data is introduced, data division means divides the transmission data according to instructions from the data division designation means, transmission data divided by the data division means is introduced, and processing is performed based on a protocol consisting of multiple layers. and a protocol processing means for performing the protocol processing.

(Industrial Field of Application) The present invention relates to a transmission data division method for a multi-layer protocol, and particularly relates to a transmission data division method for a multi-layer protocol when transmitting data exceeding the maximum transfer length of each layer protocol.

[Conventional technology]

In recent years, open system interconnection (OpenSystem)
Hierarchization of communication procedures is becoming common, as typified by the MS Interconnection (hereinafter referred to as SI) reference model. Therefore, there are many cases in which multiple layers of protocols are implemented within one communication control device.

The data units in each layer in such a communication control device are different, and when data is transferred between each layer, protocol control information is added. Therefore, it is necessary to divide data appropriately when transferring data between protocols.

FIG. 5 shows a conventional method of dividing transfer data.

For example, the <n> layer and <
Focus is on the n-1> layer.

In the figure, "transmission data" is from <n> layer n-1>
It shows the data to be transferred to the layer, and this sending data is <
Protocol data unit at layer n> ((n)-PDU
)become.

At the <n-1> layer, when this (n)-PDU is received,
Furthermore, Protocol 1-Col control information (Proto-I Col header) is added and transferred to the lower layer as an (n-1)-PDU. However, if this (n-1)-PDU exceeds the maximum data length in the <n-1> layer, the data is divided so as not to exceed the maximum data length.

For example, as shown in FIG. 5, the (n)-PDU is divided into three pieces of data a, b, and c. (n) In addition to the transmission buffer that stores the PDU, two transmission buffers are prepared, and data a and data b are copied to these buffers. As a result, data a is stored in each of the three transmit buffers.
, b, and c are stored, and a protocol header is added to each data as transfer data.

[Problem to be solved by the invention]

By the way, in the conventional method that uses two consecutive methods, the data length of the protocol data unit is checked every time data is transferred between each layer, and if the value exceeds a predetermined value, the data is copied and divided into one piece each time. . Therefore, when the number of layers increases, the time and effort required for this copying and two-part processing increases, resulting in an increase in overhead.

The present invention was created in view of these points, and an object of the present invention is to provide a transmission data division method for a multilayer protocol that reduces overhead during data transmission.

[Means for Solving the Problems] FIG. 1 is a principle block diagram of a transmission data division method of a multi-layer protocol according to the present invention.

In the figure, the data division specifying means 111 is introduced with first information 113 regarding the transmission data length, and second information 115 regarding the maximum transfer data length in each layer of a protocol consisting of multiple layers and the data length added in each layer, Provides instructions regarding division of transmitted data.

The data division means 121 receives the transmission data and divides the transmission data according to instructions from the data division designation means 111.

The transmission data divided by the data division means 121 is introduced into the protocol processing means 131, and the transmission data is processed based on a protocol consisting of multiple layers.

Therefore, as a whole, the transmission data is divided based on the transmission data length 1, the maximum transfer data length of each layer, and the additional data length.

[For production]

The data division specifying means 111 includes first information 113 regarding the transmission data length, and second information 1 regarding the maximum transfer data length of each layer of Pro 1 to Full and the data length added at each layer.
15 will be introduced. And based on this information,
The data division means 121 sends instructions regarding division of transmission data.
give to

The data division means 121 divides the transmission data according to the instruction, and the protocol processing means 131 processes the divided transmission data based on the protocol.

In the present invention, the transmission data is divided based on the transmission data length, the maximum transfer data length of each layer, and the additional data length of each layer, and the divided transmission data is processed based on the protocol. By doing so, the overhead during data transmission can be reduced.

〔Example〕

Hereinafter, embodiments of the present invention will be described in detail based on the drawings.

FIG. 2 shows the configuration of an embodiment to which the multi-layer protocol transmission data division method of the present invention is applied.

(2) Correspondence between the embodiment and FIG. 1 Here, the correspondence between the embodiment of the present invention and FIG. 1 will be shown.

The data division specifying means 111 corresponds to the bus control section 211.

The first information 113 is transmitted from the CPU 201 to the bus control unit 211.
Corresponds to the transmission data length notified by .

The second information 115 corresponds to the maximum data length and header length of each protocol layer notified from the protocol control unit 231 to the bus control unit 211.

The data dividing means 121 corresponds to the bus control section 211.

The protocol processing means 131 includes a protocol control section 231
．． It corresponds to the transmission buffer 241.

Examples of the present invention will be described below assuming that the correspondence relationship as described above exists.

↓-Kakusekanq In Figure 2, the communication system to which the multi-layer protocol transmission data division method of the present invention is applied has a CPU 201 that performs overall control and data processing, and a CPU 201 that stores data processed by the CPU 201. memory 203 and CPU
The communication control unit 210 transmits data processed by the communication system 201 to another communication system (not shown) or receives data sent from another communication system.

The communication control unit 210 also includes a bus control unit 211 that controls data exchange with the CPU 201, and a protocol control unit 231 that performs processing based on the protocol.
The communication control unit 210 includes a physical layer control unit 233 that exchanges data with the transmission path, and a transmission buffer 241 that temporarily stores data input and output between each component in the communication control unit 210.

For example, consider the case where the O3I reference model is applied. The protocol control unit 231 performs control based on data link protocols, network protocols, and transport protocols.

Furthermore, the transmission buffer 241 physically consists of multiple buffers, and if the protocol data unit for each protocol exceeds the capacity of each buffer, one protocol data unit may be stored in two or more buffers. It becomes possible.

CPU201. The memory 203 and the bus control section 211 in the communication control section 210 are connected by a bus.

The protocol control unit 231 is connected to the bus control unit 211 and the physical layer control unit 233, and is further connected to the physical layer control unit 233.
33 is connected to a transmission line. Also, send buffer 2
41 is shared by each component within the communication control unit 210.

・　　l-Urazoku sex story work Next, the operation of the embodiment of the present invention described above will be explained.

(i) Bus control. Operation FIG. 3 shows the operation procedure of the embodiment when focusing on the bus control section 211.

First, the CPU 201 notifies the bus control unit 211 of the transmission data length prior to data transmission.

The bus control unit 211 receives the transmission data length sent from the CPU 201 (step 311).

Next, the bus control unit 211 sends a notification request for the protocol header length and maximum transfer data length of each protocol layer (data link layer, network layer, and transport layer) to the protocol control unit 231 (step 312).

In response to the notification request from the bus control unit 211, the protocol control unit 231 sends back the protocol header length and maximum transfer data length of each protocol layer to the bus control unit 211,
The lotus control unit 211 receives the information (step 313).

Next, the bus control unit 211 determines how to divide the transmission data based on the transmission data length received in step 311, the header length of each protocol layer, and the maximum transfer data length received in step 313. (Step 314). Since the maximum transfer data length in each layer of the protocol is known, and the header length of each layer that should be included in it is also known, the divided transmission data can be determined so as not to exceed the maximum transfer data length in each layer of the protocol (details will be described later). .

Next, the bus control unit 211 receives and receives the transmission data from the CPU 201 (step 315) and sends one of the L division units to the protocol control unit 231 (step 316).

The protocol control unit 231 first performs processing in the transport layer and adds a transport protocol header. Similarly, a header is added to each layer of the network layer and data link layer. The data to which each header has been added is sent to the transmission path via the physical layer control unit 233. Note that since the maximum transfer data length in each layer is taken into consideration in advance, there is no need to copy and divide the data into two at this point.

Next, the lotus control unit 211 determines whether all data transmission has been completed (step 317). If the determination is negative, the process returns to step 315 and repeats the process for another division unit.

If an affirmative determination is made in step 317, the data transmission operation ends.

(11) How to divide transmission data FIG. 4 shows a specific how to divide data in data transmission according to the embodiment.

For example, the transmission data supplied from the CPU 201 to the communication control unit 210 are data a, b, c, and d.

Let us consider the case of dividing into five parts e.

The bus control unit 211 determines the division method based on the transmission data length sent from the CPU 201, the header length of each layer, and the maximum transfer data length sent from the protocol control unit 231 (as described above) i) Operation of Hass Control Unit" step 314).

First, the bus control unit 211 adds a protocol header in the transport layer and divides the data so as not to exceed the maximum transfer data length of the transport protocol. Note that here, data is not actually divided, but virtual division is performed.

For example, as shown in Figure 4, three data (data a
, b, data c, d, and data e), and a transport protocol header (hereinafter referred to as a T header) is added to each data to form three protocol data units.

In FIG. 4, the T header is represented by "T", the network protocol header (N header) is represented by "N", and the data link protocol header (D header) is represented by D.

Next, the lotus system? The first section 211 adds an N header to each of the three protocol data units and divides the data so as not to exceed the maximum transfer data length of the network protocol.

For example, if adding an N header to data a and b with a T header would exceed the maximum transfer data length of the network protocol, then data a,
Divide b. Similarly, data c and d are also divided.

In this state, a T header and an N header are added to each of data a, data C, and data e, and data b and data d are
N headers are added to each of the 5 protocol data units.

Next, the hash control unit 211 adds a D header to each of the five protocol data units and divides the data so as not to exceed the maximum transfer data length of the data link protocol.

For example, assuming that the maximum transfer data length of the data link protocol is not exceeded even if a D header is added to the five protocol data units described above, the five protocol data units are obtained by adding a D header to each of the data link protocols.

In this way, the bus control unit 211 virtually attempts processing in each layer of the protocol and obtains the final division state in the data link layer. Thereafter, the bus control unit 211 stores each of transmission data a to e in separate buffers of the transmission buffer 241, and each layer of the protocol control unit 231 performs processing according to the protocol.

■Summary of the embodiment In this way, the bus control unit 211 controls the CP, U 201
The transmission data length sent from the protocol control unit 2
The header length of each layer sent from 31.

Based on the maximum transfer data length, the transmission data is divided assuming the final protocol data unit in the data link layer. The protocol control unit 231 processes each of the divided data.

Therefore, there is no need to copy and divide data into two parts during processing in the protocol control unit 231, and overhead during data transmission can be reduced.

■1 Changes in the Invention Dear Mr. ζ In the above-described embodiment of the present invention, the O3l reference model was considered, but the present invention can be applied to anything that performs processing using a multi-layer protocol.

In addition, in ``correspondence between Examples and Figure 1'',
Although the correspondence between the present invention and the embodiments has been described, those skilled in the art will easily assume that the present invention is not limited to this and that there are various modifications.

〔Effect of the invention〕

As described above, according to the present invention, transmission data is divided based on the transmission data length, the maximum transfer data length of each layer, and the additional data length of each layer, and the divided transmission data is By performing processing based on the protocol, the overhead during data transmission can be reduced, which is extremely useful in practice.

[Brief explanation of the drawing]

Fig. 1 is a principle block diagram of the transmission data division method of the multi-layer protocol of the present invention, Fig. 2 is a block diagram of an embodiment to which the transmission data division method of the multi-layer protocol of the invention is applied, and Fig. 3 is the implementation. FIG. 4 is an explanatory diagram of data division in the embodiment, and FIG. 5 is an explanatory diagram of the conventional example. In the figure, 111 is data division specifying means, 113 is first information, 115 is second information, 121 is data division means, 131 is protocol processing means, and 201 is CPU. 203 is a memory, 210 is a communication control unit, 211 is a bus control unit, 231 is a protocol control unit, 233 is a physical layer control unit, and 241 is a transmission buffer.

Claims (1)

[Claims] (1) First information (113) regarding the transmission data length, and second information regarding the maximum transfer data length in each layer of a protocol consisting of multiple layers and the data length added in each layer.
data division specifying means (111) into which the information (115) is introduced and gives an instruction regarding division of the transmission data;
A data dividing means (121) that divides the transmission data according to an instruction from the data dividing means (111), and the transmission data divided by the data dividing means (121) are introduced;
A transmission data division method for a multi-layer protocol, comprising: a protocol processing means (131) that performs processing based on the multi-layer protocol.