JPS62256062A - Protocol parallel processing system for communication processor - Google Patents

Abstract

PURPOSE:To shorten a total processing time for a session user data unit by starting a protocol processing of respective layers without waiting for the completion of the processing of a high order layer. CONSTITUTION:At the time of the rise of a system, a session layer processor 9 receives the session user data 156 from a computer interface processor 10. A session header area in which information is not set is maintained, this session header area is delivered to a processing programs in which a session protocol is execute, the contents, namely, a session header 155 is requested to be set and the control is shifted without waiting for the completion of this processing. A transport header area in which the information is not set is maintained, this header area is delivered to a transport layer processor 8, and the contents, namely transport headers 154a, 154b are requested to be set.

Description

[Detailed Description of the Invention] [Industrial Application Field] This invention relates to a communication processing device that is composed of microprocessors interconnected (via a system bus) and that executes a communication protocol consisting of multiple layers. It is related to parallel processing methods.

[Conventional technology]

FIG. 2 is a block diagram showing an example of the configuration of a communication processing device that is effective by applying the protocol parallel processing method according to the present invention, and FIG. FIG. 2 is an explanatory diagram of transmission data in units of transmission data for explaining the flow of processing according to a conventional method for data received from a computer.

In FIG. 2, 1 is a computer, 2 is a data communication network, 3 is a communication processing device that is interposed between the computer 1 and the data communication network 2 and performs communication protocol processing, and 4 to 10 are the communication processing units described above. Components of device 3, 4 is a system path,
5 is a physical layer processing processor, 6 is a data link layer processing processor, 7 is a network layer processing processor, 8 is a transport layer processing processor, 9 is a session layer processing processor, 10 is a computer interface processor,
The physical layer processing processor 5 sends and receives data to and from the data communication network 2, and the computer interface processor 10
is used to send and receive data to and from the computer 1.

Further, in FIG. 6, 5 to 10 are the same processors as those given the same reference numerals in FIG. 1, and 15 is a data link-data unit which is a data unit of the data link layer. 151 and 152 are a data link header and a data link trailer, respectively, which are data link layer protocol control information, 153 is a network header, which is network layer protocol control information, and 154a and 154b are transport layer protocol control information. a transport header, 155
is the session layer protocol control information.
Header 156 is session user data 16, which is data communicated between upper-level programs in the session layer.
, 17, and 18 are network [phase] data units, transport Φ data units, and session data units, which are data units of the network layer, transport layer, and session layer, respectively.

Next, the operation will be explained. First, data transferred via the computer 1 is received by the computer interface processor 10 and sent to the session layer processor 9.
passed to. However, the data transfer K within the communication processing device 3 does not necessarily involve physical movement of the data, and may be a process such as transferring the start address of the data storage area, for example. The session layer processor 9 that receives the session user data 156 processes it, adds session layer protocol control [1155], and passes it to the transport layer processor 8 as a session data unit 18. The transport layer processor 8 that has received the session data unit 18 performs the same processing as in the case of the session layer, adds transport layer protocol control information 154a and 154b, and creates the transport data unit 17. It is passed to the network processing processor 7. From now on, do the same thing, and set up the network.
The data link layer and the data link layer are sequentially processed, and finally, the data link data unit 15 is transferred to the data communication network 2 through the physical processing processor 5.

[Problem that the invention seeks to solve]

Processing of transmission data to a data communication network in a conventional communication processing device is performed according to the procedure described above.
The lower layer processing processor has to wait until the upper layer processing is completed, which poses a problem in that the total processing time per session/user data is long.

This invention was made in order to solve the above-mentioned problems, and it is possible to shorten the waiting time of the lower layer processing processor and to improve the protocol parallel processing of communication processing equipment, which shortens the total processing time per session/user data. The purpose is to obtain a method.

[Means and steps for solving problems]

In the protocol parallel processing method of the communication processing device according to the present invention, in addition to the means by which the session layer processing processor executes normal protocol functions, the session layer processor analyzes the session user data to be transmitted and selects the distribution processing target from the session layer. A system that causes the lower layer to asynchronously create corresponding N protocol control information, adds this information to session user data in order, and passes it directly to the physical processor as a data link data unit. It is.

[For production]

The protocol parallel processing method of the communication processing device according to the present invention performs the process of creating N protocol control information from the session layer to the lowest layer to be distributed to 6i layers below.
By making it possible to start without waiting for the upper layer to finish processing,
To shorten the waiting time of a lower layer and the total processing time per session/user data.

〔Example〕

An embodiment of the present invention will be described below with reference to the drawings. Second
As mentioned above, the figure is a block diagram showing an example of the configuration of an effective communication processing device by applying the protocol parallel processing method according to the present invention, and is a block diagram showing the internal configuration of the session layer processing processor 9 of FIG. It is a diagram. In FIG. 3, 11 is a Senyong protocol execution program, 12
ID sending (Analyzes the session/user data to be transferred and creates N protocol control information from the session layer to the lowest layer to be distributed to the corresponding processor or program asynchronously. Execution of distribution processing. Program 13 is a work area for holding transmission data during distribution processing.

FIG. 1 shows an embodiment of the present invention, in which data received from the computer 1 side is processed by the protocol parallel processing method according to the present invention inside the communication processing device 3 having the configuration shown in FIGS. 2 and 3. FIG. 2 is a transmission explanatory diagram of a transmission data unit for explaining the flow. Here, the data link layer is the lowest layer to be distributed, and protocol processing from the session layer to the data link layer is executed in parallel. Here, all the symbols in FIG. 1 are the same as those in FIG. 6.

Next, the operation will be explained. The distribution processing execution program 12 in the session layer processing processor 9 that receives the session user data 156 from the computer interface processor 10 executes the N protocol control information, a data link header 151 and a data link trailer 152, according to the algorithm described below. Network header 153, transport header 154a, 15
4b and session header 155 are respectively created asynchronously by the corresponding processors.

FIGS. 4 and 5 are 70-charts showing the execution algorithm of this distribution process. In the figure, ST■ to ST
(2) STO to STQ are each processing step. Here, the data transmission control procedure in the data link layer is 1.
HDLC (High-1 level Data Lin)
k Control) procedure, and the X.25 packet level protocol is adopted as the network layer protocol. In the figure, DL, NL, TL, and SL are respectively a data link layer processing processor 6, a network layer processing processor 7, a transport layer processing processor 8,
This is an abbreviation for session layer processing processor 9.

The execution algorithms shown in FIGS. 4 and 5 are based on the assumption that the session number user data 156 is not assembled or divided in any layer from the session layer to the lowest layer to be distributed.

First, the session layer processor 9 receives session user data 156 from the computer interface processor 10 in step ST2 when starting up the system. The next step ST■ and subsequent steps relate to parallel processing, but the control returns to step ST■ every time the processing for one session number user data 156 is completed.

Step ST■ secures a session header area in which no information is set, and step ST■
The header area is handed over to a processing program that executes the session protocol, and the contents, that is, the session header 15
5, and without waiting for this process to be completed, control is transferred to step 8T■.

In steps 8T■ and ST■, a transport header area in which no information is set is secured, this header area is handed over to the transport layer processing processor 8, and a request is made to set the contents, that is, the transport header 154ai54b. do. Similarly, step ST■ to ST■
request that the packet header and data link header areas be secured and their contents set. As a result of step 8T■ to ST■, the processing from step 5T (D onwards) is performed for those waiting for the contents of the session header area and data link header area to be set.

In step ST◎, it is determined whether the session header area ta session header 155 has been set, and if it has been set, control moves to step ST [phase].

Step S T (up to step 9, all N protocol control information from the session layer to the lowest layer to be distributed, ie, data link header 151, data link trailer 152, network header 153, transport header 154a.

154b and the session header 155 have been created, and if the processing has been completed, a data link data unit 15 is created from the session user data 156 and each of the above N protocol control information, and the physical It is handed over to the waste processing processor 5.

〔Effect of the invention〕

As described above, according to the present invention, when a session layer processor receives session user data from an upper processor, it transmits N protocol control information from the session layer to the lowest layer to be distributed to each corresponding layer. have a processor or program create it asynchronously,
This information is sequentially appended to the session user data and passed directly to the physical waste processing processor as a data link unit, so the protocol processing of each layer can be started without waiting for the processing of the upper layer to finish. This has the effect of providing a protocol parallel processing method for a communication processing device that requires a short total processing time for session book user data units.

[Brief explanation of drawings]

FIG. 1 is an explanatory diagram of transmission data units showing a protocol parallel processing method of a communication processing device according to an embodiment of the present invention, and FIG. 2 is a communication processing device effective by applying the protocol parallel processing method according to the present invention. 3 is a block diagram showing an example of the configuration of the session layer processing processor, FIGS. 4 and 5 are flowcharts showing the execution algorithm of distribution processing, and FIG. 6 is a conventional FIG. 2 is an explanatory diagram of transmission in units of transmission data for explaining the flow of processing according to the method of FIG. 1 is a computer, 2 is a data communication network, 3 is a communication processing device, 4
is a system path, 5 is a physical waste processing processor, 6 is a data link layer processing processor, T is a network layer processing processor, 8 is a transport layer processing processor, 9 is a session layer processing processor, 1 (1: total of X machine interface processors) , 11 is a session protocol execution log, ym, 12 is a distribution processing execution program, 13 is a work area, 15 to 18 are N data units, 15 is a data link data unit, 16 is a network data unit,
17 is transbow) - data unit, 18 is session
Data unit, 151-155RNp. 151 is a data link header of data link layer protocol control information, 152 is a data link trailer of data link layer protocol control information, 153 is a network header, 154a, 15
4b is a transport header, 155 is a session Φ header, and 156 is session user data. Patent applicant Mitsubishi Electric Corporation Figure 3 Figure 4 Figure 5 Figure 6

Claims (1)

[Claims] In a protocol parallel processing method for a communication processing device in which a plurality of microprocessors are interconnected via a system bus, processing of a multi-layered communication protocol is executed by the microprocessor, and the lowest layer of the communication protocol is As a layer, the Nth layer from this first layer is the Nth layer, and in order to execute the protocol of this Nth layer, N protocol control information is transferred within this Nth layer, and this N protocol control information, The logical unit of data in the N layer is N data units, consisting of one N user data corresponding to (N+1) data units, and the data transmission control procedure in the communication protocol is executed in the data link layer. When the data link layer is N layer, N data units and N protocol control information are used as data link, data unit, and data link layer protocol control information, and distribution processing is held in a specific layer above the data link layer. ,
In the process of configuring the data passed from the upper layer into the data link/data units mentioned above without performing any assembly/disassembly processing, the layer that owns this distribution processing processes the N protocol control information areas below the specific layer. These N protocol control information areas are transferred to each layer from the above-mentioned specific layer to the data link layer in order to execute the protocols asynchronously, and then the data link is generated from the N protocol control information and session/user data output from each layer. - A protocol parallel processing method for communication processing equipment that is characterized by creating data units and directly delivering them to the lowest physical layer.