JP2010239494A - Gateway system - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a gateway system having high functionality and excellent expandability. <P>SOLUTION: The GW system 1 includes a communication unit 20, a task processing unit 10, and a message router unit 30. When receiving data from a communication target system, the communication unit 20 transmits a message based on the data to the message router unit 30. When receiving a message from the message router unit 30, the communication unit 20 also transmits data based on the message to a corresponding communication target system. When receiving a message from the message router unit 30, the task processing unit 10 executes a predetermined process based on the contents of the message. When receiving a message transmitted from the communication unit 20 or the task processing unit 10, the message router unit 30 analyzes the contents of the message, and based on the result of the analysis, it transmits a message specifying the details of a process to the communication unit 20 or the task processing unit 10. <P>COPYRIGHT: (C)2011,JPO&INPIT

Description

  The present invention relates to a gateway system.

  Conventionally, various technologies have been proposed for gateways (GW) constructed to realize data exchange between systems with different protocols (for example, Patent Document 1).

  In Patent Document 1, a communication method that enables mutual connection between a plurality of hosts having different protocols with one client and between a plurality of clients having different protocols with one host without making the client and the host aware of protocol switching. Has been proposed.

JP-A-11-225171

  By the way, in recent financial institutions, in addition to absorbing protocol differences and realizing many-to-many data exchange, it is further possible from the viewpoints of handling various business processes, improving safety, maintainability, etc. In reality, it is desired to build a high-function GW with good expandability and enhanced additional functions.

  The present invention has been made in view of the above circumstances, and an object thereof is to provide a gateway system having high functionality and excellent expandability.

The gateway system according to the present invention is:
A gateway system comprising a communication means, a message router means, and a business processing means for performing data linkage between a plurality of systems,
When the communication means receives the data transmitted from the communication target system, the communication means transmits a message based on the data to the message router means, and receives the message transmitted from the message router means, based on the message Sending data to the corresponding communication target system;
The business processing means, when receiving a message transmitted from the message router means, executes a predetermined process based on the content of the message,
When the message router means receives the message transmitted from the communication means or the business processing means, it analyzes the content of the message, and based on the analysis result, the message specifying the processing content is sent to the communication means or the It transmits to the business processing means.

  According to the present invention, it is possible to realize a gateway system having high functionality and excellent extensibility.

It is a conceptual diagram which shows the operation | use aspect of GW system which concerns on one Embodiment of this invention. It is a figure which shows the function structure of the GW system of FIG. It is a figure for demonstrating a processing node. It is a figure for demonstrating a communication node. It is a figure which shows the format of a message | telegram. It is a flowchart which shows the procedure of the transfer process between nodes. It is a figure for demonstrating multi-processing of a processing node. It is a figure for demonstrating multi-processing of a communication node. It is a figure for demonstrating the usage example 1 of GW system. It is a figure for demonstrating the usage example 2 of GW system. It is a figure for demonstrating the usage example 3 of GW system. It is a figure for demonstrating the usage example 4 of GW system.

  Hereinafter, an embodiment of a gateway (GW) system according to the present invention will be described with reference to the drawings.

  The GW system 1 according to the present embodiment is a system that is installed in a financial institution and absorbs differences between systems to perform transaction linkage, data relay, and the like. As shown in FIG. 1, the GW system 1 includes a terminal system (for example, ATM (Automated Teller Machine): an automatic teller machine, a branch office terminal, etc.), a billing system (for example, a mainframe), an external system (for example, All systems such as the Zengin System etc.) are communicably connected via a predetermined network.

  As shown in FIG. 2, the GW system 1 functionally includes a business processing unit 10, a communication unit 20, and a message router unit 30. The business processing unit 10 performs editing processing (telegram editing processing) such as rewriting the contents of a message, processing for converting a character code of a message (more specifically, business data included in the message) (code conversion processing), and protocol processing The predetermined process related to the business such as is executed.

In the present embodiment, the GW system 1 manages these processes in the business processing unit 10 as separate processing nodes (processing nodes 100 ₁ , 100 ₂ ,...) As shown in FIG. Each processing node 100 executes a specific process based on the contents of a message transmitted from the message router unit 30.

The communication unit 20 controls data communication with a communication target system (terminal system, billing system, external system, etc.). In the present embodiment, as shown in FIG. 4, the GW system 1 performs data communication processing unique to each communication target system in the communication unit 20 as separate communication nodes (communication nodes 200 ₁ , 200 ₂ ,...). to manage. Each communication node 200 performs data communication processing corresponding to the communication protocol (lower layer) of each communication destination (for example, ATM, branch office terminal, mainframe, etc.).

  Each node (each processing node 100 and each communication node 200) is assigned an ID (node ID), and the node ID can be uniquely identified by the node ID.

  Returning to FIG. 2, the message router unit 30 analyzes a message received from the communication node 200 of the communication unit 20 or the processing node 100 of the business processing unit 10, and then performs processing (node processing node 100 or communication node 200). ). Then, a message specifying the determined node is generated and transmitted to the business processing unit 10 or the communication unit 20.

  Here, a message handled in the present embodiment will be described. The electronic message is a message exchanged between the message router 30 and the business processing unit 10 and between the message router 30 and the communication unit 20 in the GW system 1. As shown in FIG. 5, this message is composed of a header part and a business data part. The header part stores a message length (data size of the message), a message type, a source node ID, a destination node ID, and the like. The size of the header part is, for example, 64 bytes.

  The business data section stores data relating to actual business (for example, transaction request data transmitted from a branch terminal). The data size of the business data section has a variable length, and can store, for example, a maximum of 8128 bytes of data.

  Next, a message transfer process (internode transfer process) by the message router unit 30 will be described in detail with reference to the flowchart of FIG. When the message router unit 30 receives a message from the business processing unit 10 or the communication unit 20 (YES in step S101), the message router unit 30 extracts information (distribution information) included in a predetermined area of the message (step S102).

  The distribution information may be scattered not only in one area of the message but also in a plurality of areas.

  Here, transmission of a message to the message router unit 30 by the business processing unit 10 and the communication unit 20 will be described. When the processing node 100 designated by the message router unit 30 completes the predetermined processing, the business processing unit 10 generates a message reflecting the processing result and transmits the message to the message router unit 30. For example, when the code conversion process is executed by the processing node 100, the data in which the character code is converted by the code conversion process is stored in the business data portion of the message.

  When the communication unit 20 receives data from the communication target system, the communication unit 20 generates a message based on the data and transmits the message to the message router unit 30.

  When extracting the distribution information, the message router unit 30 refers to the definition file. In this definition file, information (extraction information) about the storage area for distribution information is shown. The extracted information includes, for example, one or more pairs of information about the position where acquisition starts (for example, the number of bytes from the beginning of the message) and information about the data length to be acquired (for example, byte length). Yes.

  The definition file is a text format file (for example, an INI file) in which the extracted information, information related to other processing of the message router unit 30, and the like are described. The definition file is stored in a storage device (not shown) such as a semiconductor memory provided in the GW system 1.

  Next, the message router unit 30 opens a node information file stored in a storage device (not shown) as in the above definition file (step S103). The node information file is a text format file (for example, an INI file) in which information (node information) about each processing node 100 of the business processing unit 10 and each communication node 200 of the communication unit 20 is described.

  Two types of node information files for the processing node 100 and the communication node 200 may be prepared, or both may be integrated into one file.

  The message router unit 30 determines a node as a destination (forwarding destination) of the message based on the extracted distribution information and the node information stored in the node information file (step S104). Then, the message router unit 30 transmits a message specifying the determined node, that is, a message in which the node ID of the determined node is set as the destination of the header part to the business processing unit 10 or the communication unit 20 (step S105). Thereafter, the message router unit 30 repeatedly executes the processes of steps S101 to S105.

  For example, when a message is transmitted from the message router unit 30 to the job processing unit 10 and the designated processing node 100 receives the message, the processing node 100 performs a job process specialized in itself (message editing process, code). Conversion processing, protocol processing, etc.).

  On the other hand, when a message is transmitted from the message router unit 30 to the communication unit 20, and the designated communication node 200 receives the message, the communication node 200 executes a data communication process specialized for itself, and the message The data for transmission based on this is generated, and this is transmitted to a communication destination (for example, mainframe etc.).

  As described above, the message router unit 30 transfers the message to any processing node 100 of the business processing unit 10 or any communication node 200 of the communication unit 20, but there are various patterns of such transfer routes. For example, there are patterns such as communication node 200 → message router unit 30 → communication node 200 or message router unit 30 → processing node 100 → message router unit 30 → processing node 100.

  As shown in FIG. 7, in each processing node 100 of the business processing unit 10, one business process can be made redundant by a plurality of processes. By adopting such a specification, even if a failure occurs in one of the processes, business processing can be continued in another process.

  Moreover, as shown in FIG. 8, each communication node 200 of the communication unit 20 can generate a plurality of processes and execute data communication processing with different communication destinations in each process.

  Next, a usage example of the GW system 1 having the above functions will be described.

(Usage example 1)
FIG. 9 is a conceptual diagram showing 1: n cooperation between a terminal and a plurality of distributed systems (A, B, C). In this example, the GW system 1 performs message linkage with the systems A, B, and C based on a message transmitted from one terminal (a branch office terminal or the like).

(Usage example 2)
FIG. 10 is a conceptual diagram showing an example of taking consistency of character codes between systems. In this example, when receiving a message from system A (using EBCDIC as a character code), GW system 1 converts the character code into JIS8 and transfers it to system B. Conversely, when a message from system B is received, the character code is converted from JIS8 to EBCDIC and transferred to system A.

(Usage example 3)
FIG. 11 is a conceptual diagram for explaining a message editing process of the GW system 1. In this example, when receiving a message (for example, an XML message) from an online terminal, the GW system 1 converts the message into a physical message (transaction message) that can be recognized by the main frame, and transfers the message to the main frame. On the contrary, when a physical message from the mainframe is received, it is converted into an online system format (ie, XML format) message and transferred to the online terminal.

(Usage example 4)
FIG. 12 is a conceptual diagram for explaining a mirror test using the GW system 1. Here, an example will be described in which the function of the GW system 1 is used for the degradation confirmation test of the test billing system.

  In FIG. 12, the GW system 1 is communicably connected to a test GW system via a predetermined network. The test GW system has a function equivalent to that of the GW system 1. The test GW system is communicably connected to a test billing system (mainframe or the like) via a predetermined network.

  The GW system 1 transfers a transaction request message transmitted from a branch office terminal, ATM, or the like to a billing system that is actually operated, and transmits a copy of the message to the test GW system. The test GW system transmits a copy of the transaction request message transmitted from the GW system 1 to the test billing system as if it was a transaction request message transmitted from a subordinate terminal.

  Upon receipt of the transaction request message transmitted from the test GW system, the test accounting system executes processing according to the actual operation based on the content of the received transaction request message, and the transaction response message is received as the test GW. Send to the system. When receiving the transaction response message from the test billing system, the test GW system discards it without transmitting it to the GW system 1.

  As described above, the function of the GW system 1 can be used to carry out the degradation confirmation test of the test billing system without hindering actual work.

  As described above, according to the GW system 1 of the present embodiment, it is possible to absorb differences between systems and easily perform transaction cooperation, data relay, and the like. In addition, each function unit (the business processing unit 10, the communication unit 20, and the message router unit 30) in the GW system 1 mainly executes each process with reception of a message as an event (so-called message driven method). Therefore, it is possible to flexibly cope with connections between various subsystems.

  In the business processing unit 10 and the communication unit 20, the processing contents are managed in units of nodes, and the message router unit 30 analyzes the message using the definition file, and analyzes the analysis contents, the contents of the node information file, Based on, the message distribution (determination of the transfer destination node) is performed. Since the contents of such definition files and node information files can be easily changed using a simple user I / F, it is possible to flexibly cope with changes in transfer rules, traffic increase, etc. Excellent.

  The present invention is not limited to the above-described embodiments, and various modifications can be made without departing from the scope of the present invention.

  For example, in the above-described embodiment, an example in which the GW system 1 is applied to a financial institution system has been described. It can be applied to any system that requires an excellent gateway system.

DESCRIPTION OF SYMBOLS 1 Gateway (GW) system 10 Business processing part 20 Communication part 30 Message router part 100 Processing node 200 Communication node

Claims (7)

A gateway system comprising a communication means, a message router means, and a business processing means for performing data linkage between a plurality of systems,
When the communication means receives the data transmitted from the communication target system, the communication means transmits a message based on the data to the message router means, and receives the message transmitted from the message router means, based on the message Sending data to the corresponding communication target system;
The business processing means, when receiving a message transmitted from the message router means, executes a predetermined process based on the content of the message,
When the message router means receives the message transmitted from the communication means or the business processing means, it analyzes the content of the message, and based on the analysis result, the message specifying the processing content is sent to the communication means or the Send to business processing means,
A gateway system characterized by that. The business processing means manages a plurality of processing contents that can be executed as separate processing nodes,
The communication means manages data communication control processing specific to each communication target system as a separate communication node,
When the message router means receives the message transmitted from the communication means or the business processing means, the message router means extracts predetermined information from the message as distribution information, and based on the extracted distribution information, Determining the communication node or the processing node, and transmitting a message specifying the determined communication node or the processing node to the communication means or the business processing means.
The gateway system according to claim 1. The message router means extracts information included in a predetermined area of a message transmitted from the communication means or the business processing means as the distribution information.
The gateway system according to claim 1 or 2, characterized by the above-mentioned. The message router means extracts the distribution information from the message according to the contents of the definition file indicating the information about the storage area of the distribution information in the message;
The gateway system according to claim 3. The definition file is a text file;
The gateway system according to claim 4. The message router means, based on the distribution information and the contents of one or a plurality of node information files storing information about the communication node and the processing node, Determine processing nodes,
The gateway system according to any one of claims 2 to 5, wherein The node information file is a text file;
The gateway system according to claim 6.

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