KR100807818B1 - Communication network system of bus network structure and method for transmitting and receiving data between services using the system - Google Patents

Abstract

The present invention relates to a communication network system having a bus network structure and a method for transmitting and receiving data between services in the communication network system. According to the present invention, one or more services existing in one process are connected to a broker that handles message routing through a connector, and all brokers in a network are in full mesh form. In a communication network system of an interconnected bus-type network structure, an anycast group or multicast is registered according to a function of registering a first service to a broker through a connector and providing at least some of the registered first services by the service. A method of transmitting and receiving data is provided, wherein the method includes joining a multicast group and performing data transmission and reception between the first service and the second service subscribed to the anycast group or the multicast group.

Bus Type Network Architecture, Broker, Connector, Service, Anycast, Multicast

Description

Communication network system of bus-type network structure and data transmission / reception method using the same {COMMUNICATION NETWORK SYSTEM OF BUS NETWORK STRUCTURE AND METHOD FOR TRANSMITTING AND RECEIVING DATA BETWEEN SERVICES USING THE SYSTEM}

1 is a view showing a network connection between the game server according to the prior art.

FIG. 2 is a diagram illustrating a network connection between game servers that may occur as the number of game servers continues to increase in the related art.

3 is a diagram illustrating a schematic view of a bus network structure according to the present invention.

4 is a diagram schematically illustrating a connection state of a communication network system having a bus network structure according to the present invention.

5 is a diagram illustrating a connection of a broker, a connector, and a service in a communication network system according to the present invention.

6 is a diagram illustrating an example of how various servers are connected through an MRS network according to the present invention.

7 is a view for explaining the structure of a message used in a communication network system according to the present invention.

8 is a diagram illustrating an address system according to the present invention.

9 is a view for explaining a unicast data processing method according to an embodiment of the present invention.

10 is a diagram for describing a multicast data processing method according to an embodiment of the present invention.

11 and 12 are views for explaining an anycast data processing method according to an embodiment of the present invention.

13 is a flowchart illustrating a service registration process according to an embodiment of the present invention.

14 is a flowchart illustrating a service releasing process according to an embodiment of the present invention.

15 is a flowchart illustrating a message transmission / reception process according to an embodiment of the present invention.

16 is a flowchart illustrating a process performed when a broker is newly added to an MRS network according to an embodiment of the present invention.

17 is a flowchart illustrating a process that is performed when a broker is normally terminated according to an embodiment of the present invention.

18 is a flowchart illustrating a process that is performed when another broker detects abnormal termination of a broker according to an embodiment of the present invention.

19 is a flowchart illustrating a process that is performed when a connector detects abnormal termination of a broker according to an embodiment of the present invention.

20 is a block diagram showing the structure of a connector according to the present invention.

21 is a diagram for describing an API, which is a programming interface provided in a connector according to the present invention.

22 is a block diagram showing the structure of a message queue management module which is one component of a connector according to the present invention.

23 is a block diagram showing the structure of a service management module that is one component of a connector according to the present invention.

24 is a block diagram illustrating a structure of a connection management module that is one component of a connector according to the present invention.

25 is a block diagram showing the structure of a broker according to the present invention.

26 is a block diagram illustrating a structure of a link management module that is one component of a broker according to the present invention.

<Explanation of symbols for the main parts of the drawings>

500: MRS network

501: Broker

502: Connector

503: service

The present invention relates to a communication network system of a bus-type network structure and a method for transmitting and receiving data between services in the communication network system, and more particularly, to one or more services existing in one process. In a communication network system with a bus network structure that connects a broker that handles message routing through a connector, and interconnects all brokers in a network in full mesh, the first service is provided through a connector. Register at least a portion of the registered first service to an anycast group or a multicast group according to a function provided by the service, and register the first service and the anycast group or the multicast. Perform data transmission and reception between the second service that is joined to the cast group. It relates to a communication network system and a data transmitting and receiving method using the same according to claim.

In the prior art, game servers providing a game service are all connected in a mesh structure. FIG. 1 is a diagram illustrating a network connection between game servers according to the prior art.

According to the prior art as shown in Figure 1, each additional connection of the game server is bound to increase exponentially from the perspective of the overall network, Figure 2 is a continuous increase in the number of game servers in the prior art The figure shows a network connection between game servers that may occur.

As described above, according to the related art in which game servers are interconnected in a mesh structure, the connection structure becomes very complicated as the number of game servers increases, and as a result, it is difficult to expand the game server according to the increase of game users. It was. In particular, the expansion of game server-to-game connections globally made management difficult.

Moreover, as the number of counterpart servers connected to one server increases, the total number of connections increases exponentially. In the related art, one game server is typically connected to a login server, a ranking server, and a database server. Since it is grouped with a channel list server and a notification server in one multicast group, the actual number of connections existing in the entire network greatly exceeds the number of simple connections between game servers, and the management thereof is very difficult.

Accordingly, there has been a request for the emergence of a new communication network structure that can easily escape the network structure according to the prior art, in which all game servers are connected in a mesh form, simplify the connection structure between servers, and make it easy to manage and expand services efficiently. In this new communication network structure, a method for efficiently transmitting and receiving anycast data and multicast data between services is required.

The present invention has been made to solve the problems of the prior art as described above, in the new communication network system in which the connection structure between servers is simplified through a bus-type network structure, the transmission and reception of anycast and multicast data between services The object of the present invention is to provide a method that can be efficiently processed.

According to the present invention, in a new communication network system in which a server-to-server connection structure is simplified through a bus-type network structure, a broker that receives anycast data receives the service as a registered service through a connector directly connected to itself among services belonging to the anycast group. Sending any anycast data and, if no such service exists, sending the received anycast data through another broker connected in full mesh form, dramatically reducing routing distances and implementing natural load balancing. The purpose.

The present invention dares to break away from the network structure according to the prior art, in which all game servers are connected in a mesh form, and to simplify the connection structure between servers, and to propose a new communication network structure that can be easily managed and efficient service expansion. It is done.

In order to achieve the above object and to solve the above problems of the prior art, a method of transmitting and receiving data between services in a communication network system of a bus-type network structure according to an embodiment of the present invention, the communication network system is a message A broker that handles routing, a connector, and a plurality of services that are communication terminal nodes connected to the broker through the connector, each service on the communication network system; Interconnecting brokers in the form of a full mesh (the broker is a module that establishes a routing path or establishes a connection relationship with the connector to process message routing), and connects the connector with the broker. Step, registering a first service with the broker through the connector, of the registered first service Subscribing at least a portion to an anycast group or a multicast group according to a function provided by the service, and a second service joined to the first service and the anycast group or the multicast group. And performing data transmission and reception between the two.

According to one side of the present invention, the unicast address of the first service and the anycast address or multicast address of the second service are registered in the broker, and the second service is subscribed to the anycast group. And performing the data transmission and reception between the first service and the second service, the broker receiving anycast data having a destination as an anycast address from the first service and the broker receiving the anycast data. And selecting one of a plurality of services subscribed to a cast group as the second service, and transmitting the anycast data.

According to another aspect of the invention, the step of selecting one of a plurality of services subscribed to the anycast group as the second service, the second routing service for the transmission of the anycast data is the minimum Select one of the services as a second service if there is a service registered through a connector directly connected to the broker that has received the anycast data, and select any one of the plurality of services if it does not exist. Provided is a method for transmitting and receiving data, characterized in that selecting as the second service.

Meanwhile, a communication network system of a bus type network structure according to an embodiment of the present invention includes a broker for processing message routing, a connector, and a plurality of services connected to the broker through the connector, and the service is a terminal capable of communicating. As a node, a network address that uniquely identifies each service is assigned to each service, and the connector is a module that mediates a connection between the service and the broker, and registers a first service with the broker, 1 is a module that subscribes at least a part of a service to an anycast group or a multicast group according to a function provided by the service, and the broker establishes a routing path or establishes a connection relationship with the connector to process message routing. Each broker is interconnected in full mesh form And transmitting and receiving data between a first service and a second service joined to the anycast group or the multicast group.

Hereinafter, a communication network system and a data transmission / reception method using the same will be described in detail with reference to the accompanying drawings.

3 is a diagram illustrating a schematic view of a bus network structure according to the present invention.

In the prior art, all game related servers including a game server are connected in a mesh structure as shown in FIG. 1, but in the bus network structure according to the present invention, all servers are connected through a bus structure as shown in FIG. 3. Therefore, the connection structure is greatly simplified.

4 is a diagram schematically illustrating a connection state of a communication network system having a bus network structure according to the present invention.

According to the related art of FIG. 1, whenever the game servers are additionally connected as shown in FIG. 2, the number of connections in the overall network view is inevitably increased. On the other hand, in the bus-type network structure according to the present invention, as shown in FIG. 4, each server only needs to maintain a connection with one broker, and even if the network is expanded, the intermediate connection is made through brokers. The number of connections from the point of view does not increase significantly. Therefore, the communication network system employing the bus-type network structure of the present invention as shown in Figs. 3 and 4 is easy to link new services, and its maintenance and management is also very convenient.

5 is a diagram illustrating a connection of a broker, a connector, and a service in a communication network system according to the present invention.

As shown in FIG. 5, a communication network system according to the present invention includes a plurality of services 503 connected to a broker 501 through a broker 501, a connector 502, and a connector 502 that process message routing. It is configured to include.

The service 503 is a terminal node that can communicate, and each service 503 is connected to and registered with the broker 501 through one connector 502.

In the communication network system according to the present invention, a network address uniquely identifying each service 503 is assigned to each service 503. At this time, the network address corresponds to an address value capable of uniquely identifying each service 503 in the entire communication network system according to the present invention.

The connector 502 is a module that mediates the connection between the service 503 and the broker 501. Each connector 502 is connected to only one broker 501, and the service 503 is connected to the broker through the connector 502. 501 may be registered.

According to one embodiment of the invention, the connector 502 and the service 503 are included in the same process, only one connector 502 exists in one process, the service 503 is at least one in a process May exist. That is, one connector 502 exists for each process, and the connector 502 may mediate a connection between all the services 503 and the broker 501 existing in the process to which the connector 502 belongs.

According to the present embodiment, a connector and a process may be matched 1: 1 to ensure unity of a communication network system, and services 503 having different processes belonging to each other may have the same broker 501 through the same connector 502. It can prevent inefficient routing that can be caused by being connected to the network, and can avoid confusion in data transmission and reception.

The broker 501 is a module that sets up a routing path or establishes a connection relationship with the connector 502 to handle efficient message routing, and each broker 501 is interconnected in the form of a full mesh.

In this specification, the network in which the brokers 501 are interconnected in the form of a full mesh is defined as a message routing server (MRS) network 500. Therefore, the MRS network 500 refers to a network service platform for efficient message transmission and reception between various systems to communicate. The connector 502 is a module that provides a programming interface used to perform message transmission and reception using the MRS network 500, and the service 503 is an MRS network through the programming interface provided by the connector 502. (500) is used.

Meanwhile, in the communication network system according to the present invention, as shown in FIG. 5, there is only one connection between the actual connector 502 and the broker 501. When each service 503 communicates with the broker 501, one connection is performed. Communicate sequentially through.

6 is a diagram illustrating an example of how various servers are connected through an MRS network according to the present invention.

As illustrated in FIG. 6, various game related servers including a game string server, a channel list server, a game server, a notification server, a management server, and a database server are connected through the MRS network 600, and each server is a full mesh form. Only one connection with any one broker among a plurality of brokers interconnected is maintained.

In the related art, since all game-related servers are connected in a mesh structure, as the number of opponent servers to which one server is connected increases, the total number of connections increases exponentially. On the other hand, according to the present invention, as shown in FIG. 6, each server only needs to maintain a connection with one broker, and even if the network is expanded, the intermediate connection is made through brokers. The advantage is that the number does not increase significantly.

FIG. 7 is a view for explaining the structure of a message used in a communication network system according to the present invention. Referring to FIG. 7, a connector and a broker, which is a subsystem of the communication network system according to the present invention, are exchanged between the broker and the broker. Describe the structure of the message.

In this specification, the structure of the message is described based on the data type generally used in Windows, without using octet notation as a data type for defining fields of each message. In this case, the Windows data type and octet notation are mapped as "BYTE: octet (8)", "WORD: octet (16)", "DWORD: octet (32)".

The messages used in the communication network system according to the present invention are largely classified into two types, MRMSGHeader and MRCMPHeader, and each message is divided into a common field, MRHeader, and a specialized field for each message.

MRHeader is message header information that all messages exchanged on the communication network system according to the present invention should have in common. The MRHeader message cannot be used alone, and the value described in the protocol type field and additional message information should be added and transmitted after the MRHeader.

type designation Explanation WORD version Indicates version information of the message. A major version is indicated in the upper 1 byte, and a minor version in the lower 1 byte. BBYTE Protocol type This value may have two values of PT_MESSAGE and PT_MRCMP. PT_MESSAGE specifies that the message following MRHeader is MRMSGHeader structure, and PT_MRCMP specifies that the message following MRHeader is MRCMPHeader structure. BBYTE TTL Time to live. The message transmitted and received on the communication network according to the present invention decreases the TTL value by 1 each time the broker of the MRS network processes the routing, and when it becomes 0, it does not route any more and generates a transmission error. BDWORD Length The length of the entire message including the MRHeader and the following MRMSGHeader or MRCMPHeader.

The message delivered in the structure of MRMSGHeader has a structure for transferring a payload value designated by a service among a plurality of services connected to the MRS network.

It describes the source address, which is the address of the sender that sends the message, and the destination address, which is the address of the receiver that receives the message. The MRS network uses routing based on the type of destination address and the connection information. Try. Description of each detail field is as follows.

type designation Explanation MRHeader (8bytes) Not defined The structure of the MRHeader described above. MRADDRESS (16 bytes) Source address The address of the message sender. On the other hand, MRADDRESS is a data type for defining the source address and destination address fields of the MRMSGHeader. MRADDRESS (16 bytes) Destination address The address of the message recipient. Not defined Not defined This is a user defined message. The length in the MRHeader structure of the message must include the entire length from the MRHeader to the user-defined payload.

The message transmitted in the structure of the MRCMPHeader is a message defined for transmitting and receiving signals between the connector and the broker, the broker and the broker, which are subsystems of the communication network system according to the present invention. Description of each detail field is as follows.

type designation Explanation MRHeader (8bytes) Not defined The MRHeader structure described above. WORD Control code Signal command to transmit / receive. The upper 1 byte performs the role classification of the signal, and the lower 1 byte performs the separator role in the corresponding role classification. Not defined Not defined Variable length additional field related to control code. This field can be changed in various forms depending on the content of the control code.

Hereinafter, the address system employed in the present invention will be described.

In the present invention, when referring to a source address and a destination address to transmit and receive data using an MRS network, a new address system according to the present invention is used instead of an IP address. The MRS network supports three address types, unicast, anycast, and multicast, to identify specific services. The address consists of a Cast type and an address by address type, and is 16 bytes in length. Has

In the case of an online game, a plurality of service instances work together and there is a lot of communication between the service instances. In the past, there is no example of assigning a network address to such a service instance. The problem was that the process had to handle a large number of service instance communications, including many service instances.

Accordingly, in the present invention, a new address system is introduced to allocate unique network addresses to individual service instances, thereby efficiently handling communication between service instances. In this case, since there is no need to distribute messages from game server to game room one by one, the management cost is significantly reduced.

To this end, in the present invention, a network address for uniquely identifying each service is assigned to each service, and the network address is defined as an address value for uniquely identifying each service in the entire communication network system according to the present invention. . In the present invention, based on the network address as described above, data transmission and reception between services registered in the MRS network through the connector and the broker.

In addition to unicast, the present invention supports three address types: anycast and multicast.

The communication network system according to the present invention registers a service to a broker through a connector using a unicast address, which is a network address assigned to each service, and at least one of the registered services (hereinafter referred to as "first service"). Joining some to anycast group or multicast group according to the function provided by the service, and joining the first service to anycast group or multicast group (hereinafter referred to as "second service") Data transmission and reception between the two) can be performed. That is, the present invention can transmit or receive data from the unicast address of the source transmitting the message to the anycast address of the destination receiving the message.

To this end, the connector of the communication network system according to the present invention registers a first service with a broker, and joins at least some of the registered first services to an anycast group or a multicast group according to a function provided by the corresponding service. The broker on the MRS network may serve to perform data transmission and reception between the first service and the second service subscribed to the anycast group or the multicast group. In addition, the broker registers an anycast address or multicast address of the second service together with the unicast address of the first service.

In one example, when one service A providing a high-stop game service is created, the connector may register the service A's unicast address with the broker and then join the service A to the multicast group for providing the high-stop game service. Then, if a service B sends a packet for the high-stop game services to query the number of users currently participating in the game, the broker receives it and joins the multicast group, including service A. It can transmit to the multicast address of all services, and service A can receive a response to the query via a broker.

As such, in the present invention, each service may be grouped into anycast or multicast group according to its property, and the grouping may be performed through a unicast address, which is a network address assigned to each service, and thus the grouping. The service may be a service running on different physical servers.

8 is a diagram illustrating an address system according to the present invention.

In FIG. 8, the Cast type indicates the type of the address and has one of CT_UNICAST, CT_MULTICAST, and CT_ANYCAST.

The unicast address, which is a network address assigned to each service, is a uniquely distinguishable address for all services using the MRS network. The unicast address includes a server name for identifying a server running a specific service in the entire network of the communication network system according to the present invention and an instance ID for uniquely identifying the corresponding service in the same server. .

The server name refers to a unique value of 11 bytes that identifies a server that is a computer hardware running a service using an MRS network. The server name is a unique value of 11 bytes that identifies a server running a service on an entire network. Can be.

The instance ID is a unique identifier for a service within the same server. Some services are assigned a reserved value to the instance ID, and others are assigned a dynamically generated value from the server. Can be.

For example, a value between 1 and 65535 is reserved for services that require a fixed unicast address, and values after 65536 can be uniquely assigned and used within the server. Here, a service requiring a fixed unicast address may include a service continuously operating from the start to the end of the communication network system according to the present invention.

These unicast addresses can be arranged as shown in the table below.

type designation Explanation BYTE Cast type It is always CT_UNICAST for unicast addresses. DWORD Instance ID If multiple computers need more than one address, they can be identified using instance numbers. The instance ID can be used as a reserved address from 0x0000 to 0xffff. BYTE (x11) Server name An identifier that can identify the computer. The server name can usually be the NetBIOS Name of the local computer. Therefore, every computer using an MRS network must have a computer name that can be distinguished from other computers, and its length is less than 11 bytes.

Since the multicast address and anycast address simply use a value of 15 bytes, it can be freely set between services. This value must be unique across the entire network and must be announced in advance.

Multicast / Anycast addresses can be arranged as shown in the table below.

type designation Explanation BYTE Cast type In the case of a multicast address, it is defined as CT_MULTICAST, and in the case of an anycast address, it is defined as CT_ANYCAST. BYTE (x15) Service name Identifier to identify the service. Multicast and anycast addresses are virtual address systems that do not refer to computers or services. In addition, this service name is a value uniquely identified throughout the MRS network.

In the case of using the MRS network according to the present invention, (1) the service is connected to the MRS network in order to use the functions provided by the other service and (2) the service to process the request from the other service There may be occasions when connecting to an MRS network to provide.

As an example of the case (1) in which the service connects to the MRS network to use a function provided by another service, there may be a service that sends a request to the login server and receives a response to confirm user login information. The service for using the functions provided by other services operates as follows through the connector, which is a module that mediates the MRS network and services.

First, the programming interface is initialized to transmit and receive data between the service and the connector at the start of the process. The unicast address, which is the network address of the service, is registered in the MRS network. When all the functions provided by the other services are used, the unicast address of the service is released from the MRS network, and the programming interface is terminated when the process ends.

As an example of the case of (2) in which the service connects to the MRS network to provide a function for processing a request from another service, the service providing a database inquiry function, providing login information or location information of a user There may be a service. This service for providing specific functions to other services operates as follows through MRS network and connector which is a module that mediates the service.

First, it initializes the programming interface to send and receive data between the service and the connector at the start of the process, registers the unicast address of the service in the MRS network, and then joins an anycast or multicast group according to the functions provided by the service, Receive a request message from another service and send a response message. When all the specific functions are provided to other services, the subscribers leave the subscribed anycast or multicast group, release the unicast address of the service from the MRS network, and terminate the programming interface at the end of the process.

As such, in the present invention, the connector registers the unicast address of the service to the MRS network, and joins the service to an anycast or multicast group according to the function to provide the service, and when the service ends, the subscribed anycast or multicast. You can leave the cast group.

Hereinafter, a data transmission / reception scheme supported by the MRS network according to the present invention will be described.

First, the transmission / reception method of unicast data will be described.

9 is a view for explaining a unicast data processing method according to an embodiment of the present invention. 9 to 12, S1 is a service not joined to an anycast to multicast group, S2, S4 and S6 are services subscribed to an anycast group, and S3 and S5 are services subscribed to a multicast group.

As shown in FIG. 9, in the MRS network according to the present invention, data can be transmitted from a unicast address of a source to a unicast address of a destination, and all unicast addresses registered in the MRS network are Data can be received from a remote unicast address. In order to transmit or receive unicast data in this way, the unicast address of the source is registered in the MRS network, and the unicast address of the destination registered in the MRS network is known.

10 is a diagram for describing a multicast data processing method according to an embodiment of the present invention.

As shown in FIG. 10, in the MRS network according to the present invention, data may be transmitted from a unicast address of a source to a multicast address of a destination.

To this end, a broker on an MRS network receives multicast data having a destination as a multicast address from a unicast address of a service corresponding to a source, and multicasts all services subscribed to the multicast group. Can be sent sequentially to the address.

FIG. 10 illustrates a process in which data is transmitted from S1 of a unicast address to S3 and S5 of a multicast address. In order to transmit the multicast data in this way, the unicast address of the source is registered in the MRS network, and the multicast address of the destination subscribed to the MRS network is known.

On the other hand, in order to receive the data transmitted to the multicast address, as shown in S3 and S5 of Fig. 10, first to join the multicast group to receive the unicast address registered in the MRS network. When the subscription process is completed, the data transmitted to the multicast address can be received.

11 and 12 are views for explaining an anycast data processing method according to an embodiment of the present invention.

11 and 12, in the MRS network according to the present invention, data can be transmitted from a unicast address of a source to an anycast address of a destination.

To this end, a broker on an MRS network receives anycast data having a destination as an anycast address from a unicast address of a service corresponding to a source, and sends the anycast data to any of the services subscribed to an anycast group. Select to transmit the anycast data.

In order to transmit anycast data, the unicast address of the source is registered in the MRS network, and the anycast address of the destination subscribed to the MRS network is known.

According to an embodiment of the present invention, a broker on an MRS network that receives anycast data having a destination as an anycast address from a unicast address of a service corresponding to a source has a minimum routing distance for transmitting the anycast data. A service may be selected to transmit the anycast data.

In the present embodiment, the broker on the MRS network that receives anycast data operates to transmit data to the service when there is a service directly connected to the service among members subscribed to the anycast group. If not, you can choose a service to send data randomly through another broker connected in full mesh.

That is, the broker on the MRS network that receives the anycast data selects one of the services as a service to transmit the anycast data if there is a service registered through a connector directly connected to it, but if it does not exist, the anycast group Any any one of a plurality of services subscribed to may be selected to transmit the anycast data.

FIG. 11 shows a CS4 broker receiving anycast data from S1 according to the present embodiment and transmitting the anycast data to S2 directly connected to S2, S4, and S6 subscribed to the Anycast group. It is. As shown in Figure 11, in this case, the routing length can be significantly shortened.

If it is assumed in FIG. 11 that S2 is a service not subscribed to an anycast group, according to the present embodiment, the CS4 broker receiving anycast data from S1 transmits data to S6, which is an anycast address connected to another broker CS6. In this case, data is transmitted to S4, an anycast address connected to another broker CS8. This is illustrated in FIG.

According to the present embodiment, by processing anycast data as described above, the routing distance is drastically shortened to enable rapid routing, and natural load balancing is realized even without using an L4 switch.

Meanwhile, in order to receive data transmitted to an anycast address, as in S2, S4, and S6 of FIGS. 11 and 12, first, a subscribe to an anycast address to receive a unicast address registered in an MRS network is required. When the subscription process is completed, the data transmitted to the anycast address can be received.

Hereinafter, an operation process of a service, a connector, and a broker which is a subsystem of a communication network system according to the present invention will be described with reference to FIGS. 13 to 19.

FIG. 13 is a flowchart illustrating a service registration process according to an embodiment of the present invention. In a communication network system according to the present invention, a system for providing a specific service or using a service must register itself with an MRS network through a connector. do.

The service transmits a service registration message to the connector (S1301), and the connector analyzes the service registration message to check whether the service is already registered (S1302), and if the service is not already registered, recalls the service registration message. Deliver to the broker (S1303).

The broker updates the routing table by adding the routing information of the service that has transmitted the service registration message to its routing table (S1304), and transmits the routing information to another broker (S1305). The own routing table is updated using the routing information (S1306).

As such, in the present invention, when the routing table is updated, the broker transmits the updated information to other brokers constituting the MRS network so that the other brokers always maintain the latest routing information.

14 is a flowchart illustrating a service releasing process according to an embodiment of the present invention, in which a system that registers itself with an MRS network performs a service releasing process through a connector to remove itself from an MRS network, and performs a service releasing process. After the execution, all service requests through the MRS network are blocked.

The service transmits a service release message to the connector (S1401), the connector analyzes the service release message and checks whether it is the final release (S1402), and if it is the final release, delivers the service release message to the broker (S1403). .

The broker updates the routing table by deleting routing information of the service that has transmitted the service release message from its routing table (S1404), notifies another broker of the deletion of the routing information (S1405), and receives the other broker. Detects the deletion of the routing information and updates its routing table (S1406).

15 is a flowchart illustrating a message transmission / reception process according to an embodiment of the present invention, and illustrates a process of transmitting a message to a service or using a message for a service request in the present invention. .

A service that wants to use a specific service first establishes a virtual connection by transmitting a connection message to the connector (S1501), and defines an address of a service to be used at this time.

At the time of message transmission, the service performs message transmission using the programming interface of the connector (S1502), and the connector MRP header according to the message routing protocol (MRP) used in the MRS network for the message transmitted from the service. After adding the message, the message is transmitted to the broker associated with it (S1503), and the broker searches for the destination of the message received from the connector (S1504), and transmits the message to the broker or the connector (S1505).

When receiving a message, the broker receives a message from another broker (S1506), searches for a destination of the received message (S1507), transmits a message to the corresponding connector (S1508), and the connector sends an MRP header of the transmitted message. In operation S1509, the message is transmitted to the corresponding service and the destination address and the instance of the message transmitted from the broker are retrieved. The corresponding service receives the message (S1510).

In the communication network system according to the present invention, messages transmitted to a broker through a connector are transparently transmitted and received to another broker or a connector through the above process, and messages transmitted by a specific service are brokers existing on a path through a routing path. It can be transparently transmitted and received between.

16 is a flowchart illustrating a process performed when a broker is newly added to an MRS network according to an embodiment of the present invention.

The newly added broker first waits for connection of other brokers and is in a connection waiting state (S1601), and then connects to other brokers that are already running (S1602). The brokers connected to the newly added broker update their broker list by adding the newly added broker to the broker list in which other brokers connected to the broker are recorded (S1603). In the same way, the newly added broker connects to another broker already running (S1604), and accordingly the broker list of newly connected brokers is updated (S1605), thus all running on the MRS network. The broker list of brokers can be updated.

The newly added broker connects to all already executed brokers, randomly selects one of them (S1606), requests the selected broker for a routing table (S1607), and receives it (S1608). Reflect to its own routing table (S1609) and notify other brokers that it is ready to connect with the connector (S1610).

The broker notified of the preparation facts calculates the number of reset connectors to be transferred to the new broker among the connectors connected to it, and selects the same number of connectors (S1611). In addition, the broker notified of the preparation informs all connectors connected to it that the new broker is connected (S1612), and the connectors notified of this add a new broker to the list of brokers in which the brokers connected to it are recorded (S1613). ).

Meanwhile, a message for resetting a connection is transmitted to the selected reset connectors (S1614), and the received connectors connect a new broker and transmit a service registration message for services connected to the new broker to the connected new broker. (S1615).

Steps S1610 to S1615 may be performed for all brokers running on the MRS network, and through this process, a portion of the connectors and services connected to the brokers that are already running are connected. Moving to a broker newly added to the MRS network allows efficient load distribution between brokers.

17 is a flowchart illustrating a process that is performed when a broker is normally terminated according to an embodiment of the present invention.

The broker that is normally terminated sets the connector to no longer connect to itself (S1701), notifies other brokers that it is about to be terminated (S1702), and notifies the terminated broker and the scheduled to be terminated. Received brokers inform the connectors associated with the fact that the termination is scheduled (S1703).

The terminated broker transmits a message about a connector reset to move to another broker to the connectors connected to it (S1704), and the connectors receiving the message connect to another broker to register service for services connected to them. It transmits (S1705).

A broker newly connected to the connector due to the broker being terminated updates its routing information and transmits the updated routing information to the broker and other brokers that are terminated (S1706).

The terminated broker updates its routing table using the transmitted routing information, checks whether a connection to the updated destination no longer exists in its routing table (S1707), and no longer exists. If not, terminate the connection.

On the other hand, the terminated broker checks whether a predetermined time has elapsed from the time of transmitting a message regarding a connector reset to move to another broker to the connectors connected thereto (S1709), and after the predetermined time has elapsed, If there is a connected connector ends the connection with all connectors, and terminates itself (S1710).

18 is a flowchart illustrating a process that is performed when another broker detects abnormal termination of a broker according to an embodiment of the present invention.

When the broker abnormally terminates (S1801), the other broker detects abnormal termination of a specific broker (S1802), and adjusts its maximum capacity accordingly (S1803).

For example, if the maximum number of connectors that can be connected to one broker is 50, the original maximum capacity, if another broker is detected abnormally terminated, readjust the maximum number of connectors that can be connected to one broker to 60. As a result, connectors connected to brokers that terminate abnormally can be moved to other brokers quickly. In this case, the time for which the service connection is interrupted can be significantly shortened.

When the broker detects abnormal termination of another broker, the broker updates its routing information and notifies other brokers to update the routing table (S1804), and notifies the connectors that the broker has terminated so that the connectors list their brokers. To update (S1805).

19 is a flowchart illustrating a process that is performed when a connector detects abnormal termination of a broker according to an embodiment of the present invention.

When the broker is abnormally terminated (S1901), the connector connected with the broker detects that the broker connected with the broker is abnormally terminated (S1902) and deletes the abnormally terminated broker from its broker list (S1903).

The connector which deletes the abnormally terminated broker from the broker list arbitrarily selects one broker on its broker list (S1904), connects to the selected broker (S1905), and connects all services connected to the broker to the connected broker. Register (S1906).

Meanwhile, the broker in which the services are additionally registered as described above transmits its updated routing information to other brokers to notify the other brokers of the service registration (S1907).

Hereinafter, the structure of the connector, which is a subsystem of the communication network system according to the present invention, and the function of each component will be described.

20 is a block diagram showing the structure of a connector according to the present invention.

As shown in FIG. 20, the connector 2000 includes an API 2001, a message queue management module 2002, a service pool management module 2003, a service management module 2004, and a connection management module 2005. It is composed.

The API 2001 is an application programming interface that exposes a function provided by the connector 2000 to a service connected to the connector 2000. The system to use the MRS network according to the present invention transmits and receives data. To use the API (2001).

FIG. 21 is a diagram for explaining a relationship between a connector and a process of a service, and an API 2001. FIG.

As shown in FIG. 21, according to an embodiment of the present invention, a connector and a service are included in the same process, only one connector exists in one process, and at least one service may exist in one process. That is, there is one connector for each process, and the connector may mediate the connection between all services existing in the process to which it belongs and the broker configuring the MRS network.

According to the present embodiment, connectors and processes are matched 1: 1 to ensure uniformity of a communication network system, and inefficient routing, in which processes belonging to each other, can be caused by connecting different services to the same broker through the same connector. It can prevent and confusion in data transmission and reception.

Meanwhile, as shown in FIG. 21, one or more services existing in one process may be connected to the MRS network through one connector 2000, where the connection and data transmission and reception between the service and the connector 2000 may be performed through an API ( 2001).

That is, in order to transmit and receive data using the MRS network, the service cannot directly transmit and receive data by establishing a connection with the MRS network, but transmits and receives data using the API 2001 provided by the connector 2000. . As a result, the API 2001 receives a request for registration or release of the service from the service, a request for data transmission to the broker 2010, and the like.

The connector 2000 is a module that provides the API 2001, and is loaded in each process using the MRS network and is in charge of a message transmission / reception function to the MRS network for all services generated in the process.

The message queue management module 2002 manages a message routing protocol (MRP) packet used on an MRS network according to the present invention, which is transmitted and received, wherein the MRP packet is a connector 2000 and a broker. (2010) means a unit of data transmitted and received.

22 is a block diagram showing the structure of such a message queue management module 2002. As shown in FIG.

As shown in FIG. 22, the message queue management module 2002 may include a transmission queue 2201 and a reception queue 2202.

Here, the transmission queue 2201 manages MRP packets to be transmitted to the broker 2010, and the reception queue 2202 is responsible for managing MRP packets received from the broker 2010.

The service pool management module 2003 registers or removes a service in the broker 2010 and manages a registered service, and the service management module 2004 manages information on the registered service. Do it.

23 is a block diagram showing the structure of such a service management module 2004. As shown in FIG.

As shown in FIG. 23, the service management module 2004 may include a reception message queue 2301, a reception buffer queue 2302, and a completion status queue 2303.

Here, the reception message queue 2301 manages the message received from the broker 2010, the reception buffer queue 2302 manages the reception buffer registered by the service, and the completion status queue 2303 is for the input / output requested by the service. It is responsible for managing the finished result.

The connection management module 2005 manages a socket connection with the broker 2010 by transmitting and receiving an MRP packet.

24 is a block diagram showing the structure of such a connection management module 2005. As shown in FIG.

As shown in FIG. 24, the connection management module 2005 may include a message transmission module 2401 and a connection control module 2402.

Here, the message transmission module 2401 loads an MRP packet to be transmitted from the message queue management module 2002 and transmits the MRP packet to the broker 2010, and transmits the MRP packet received from the broker 2010 to the message queue management module ( 2002). On the other hand, the connection control module 2402 is responsible for controlling the connection between the two by processing a control message between the connector 2000 and the broker (2010).

Hereinafter, a structure of a broker, which is another subsystem of a communication network system according to the present invention, and a function of each component will be described.

25 is a block diagram showing the structure of a broker.

As shown in FIG. 25, the broker 2500 includes a link management module 2501, a routing information management module 2502, a message classification module 2503, a message router 2504, a message deserializer 2505, and a message translator. 2506, message serializer 2507, and automatic configurator 2508.

The link management module 2501 maintains and manages a connection with a connector or another broker, and performs data transmission and reception with the connector or other broker.

The routing information management module 2502 maintains and manages routing information of services registered in the broker 2500, and includes a connection pool including connection information with a connector connected to the broker 2500 or another broker. Can be maintained.

The message classification module 2503 grasps the type of data received by the link management module 2501 and classifies the received data into a simple message and a complex message according to a predetermined criterion.

The message router 2504 receives a simple message from the message classification module 2503, obtains location information of a destination associated with the simple message from the routing information management module 2502, and delivers the location information to the link management module 2501. do.

The message deserializer 2505 (deserializer) receives a complex message from the message classification module 2503, and processes the complex message to objectize the complex message.

The message transactor 2506 receives an object from the message deserializer 2505 and controls the broker 2500 using the object.

The message serializer 2507 receives the object from the message transactor 2506, processes the object into transmittable linear data, and delivers the object to the link management module 2501.

The automatic configurator 2508 tracks the state of the network to which the broker 2500 belongs and automatically adjusts the state of the broker 2500.

26 is a block diagram showing the structure of the link management module 2501.

As shown in FIG. 26, the link management module 2501 stores the OS socket subsystem 2601, the link acceptor 2602, the data receiving module 2603, the data transmission module 2604, and the link agent 2605. It may include.

The OS socket subsystem 2601 serves as an interface for transmitting and receiving data with a connector or another broker connected to the broker 2500.

The link acceptor 2602 receives a connection request from the connector or another broker connected with the broker 2500 through the OS socket subsystem 2601, and receives connection information according to the connection request from the routing information management module 2502. It is responsible for keeping track of the pool of connections it maintains.

The data receiving module 2603 is responsible for receiving data from the connector or other broker connected with the broker 2500 through the OS socket subsystem 2601 and delivering it to the message classification module 2503.

The data transmission module 2604 is responsible for receiving the processed data from the message serializer 2507 and transmitting it to the connector or other broker connected with the broker 2500 via the OS socket subsystem 2601.

The link agent 2605 attempts to connect to the connector or another broker connected with the broker 2500 through the OS socket subsystem 2601 at the request of the data transfer module 2604, and if the connection is successful, It is responsible for updating the connection pool maintained by the routing information management module 2502 using the connection information generated accordingly.

On the other hand, the data transmission module 2604 inquires the connection pool to check whether the connection with the connector or other broker associated with the destination of the data to be transmitted, and if the connection is not set up, the broker 2500 to the link agent 2605 After requesting to establish a connection to a connector or other broker connected to the), it can operate to attempt data transfer.

The method for transmitting and receiving data on a communication network according to the present invention may be implemented in the form of program instructions that can be executed by various computer means and recorded on a computer readable medium. The computer readable medium may include program instructions, data files, data structures, etc. alone or in combination. Program instructions recorded on the media may be those specially designed and constructed for the purposes of the present invention, or they may be of the kind well-known and available to those having skill in the computer software arts. Examples of computer-readable recording media include magnetic media such as hard disks, floppy disks, and magnetic tape, optical media such as CD-ROMs, DVDs, and floppy disks. Magneto-optical media, and hardware devices specifically configured to store and execute program instructions, such as ROM, RAM, flash memory, and the like. The medium may be a transmission medium such as an optical or metal wire, a waveguide, or the like including a carrier wave for transmitting a signal specifying a program command, a data structure, or the like. Examples of program instructions include not only machine code generated by a compiler, but also high-level language code that can be executed by a computer using an interpreter or the like. The hardware device described above may be configured to operate as one or more software modules to perform the operations of the present invention, and vice versa.

As described above, although the present invention has been described with reference to limited embodiments and drawings, the present invention is not limited to the above embodiments, and those skilled in the art to which the present invention pertains various modifications and variations from such descriptions. This is possible.

Therefore, the scope of the present invention should not be limited to the described embodiments, but should be determined not only by the claims below but also by the equivalents of the claims.

According to the present invention, a method for efficiently transmitting and receiving anycast and multicast data between services in a new communication network system in which a server-to-server connection structure is simplified through a bus network structure is provided.

According to the present invention, in a new communication network system in which a server-to-server connection structure is simplified through a bus-type network structure, a broker that receives anycast data is a service registered through a connector directly connected to itself among services belonging to the anycast group. By sending the received anycast data and transmitting the received anycast data through another broker connected in the form of a full mesh when such service does not exist, the routing distance is greatly shortened and the natural load distribution is realized. Can be obtained.

According to the present invention, a new communication network structure is proposed, which drastically deviates from the network structure according to the prior art, in which all game servers are connected in a mesh form, and simplifies the connection structure between servers, thereby allowing easy management and efficient service expansion.

Claims (11)

In the method of transmitting and receiving data between services in a communication network system of a bus network structure, The communication network system includes a broker that handles message routing, a connector, and a plurality of services that are communication terminal nodes connected to the broker through the connector, Interconnecting each broker in the communication network system in full mesh form, wherein the broker is a module that establishes a routing path or establishes a connection relationship with the connector to process message routing; Connecting the connector with the broker; Registering a first service with the broker through the connector and subscribing at least a part of the registered first service to an anycast group or a multicast group according to a function provided by the corresponding service; And Performing data transmission / reception between the first service and a second service subscribed to the anycast group or the multicast group Including, And the connector and the first service are included in the same process. The method of claim 1, And the unicast address of the first service and the anycast address or multicast address of the second service are registered in the broker. The method of claim 2, The second service is a service joined to the anycast group, The step of performing data transmission and reception between the first service and the second service, Receiving, by the broker, anycast data having a destination as an anycast address from the first service; And The broker selecting one of a plurality of services subscribed to the anycast group as the second service and transmitting the anycast data Data transmission and reception method comprising a. The method of claim 3, The step of selecting one of a plurality of services subscribed to the anycast group as the second service, And selecting a service having a minimum routing distance for transmitting the anycast data as the second service. The method of claim 4, wherein The step of selecting one of a plurality of services subscribed to the anycast group as the second service, If there is a service registered through a connector directly connected to the broker that has received the anycast data, one of them is selected as the second service, and if not, any one of the plurality of services is selected as the second service. Data transmission and reception method characterized in that the selection. The method of claim 2, The second service is a service joined to the multicast group, The step of performing data transmission and reception between the first service and the second service, Receiving, by the broker, multicast data having a destination as a multicast address from the first service; And The broker sequentially transmitting the multicast data to all of the second services Data transmission and reception method comprising a. The method of claim 1, Only one broker is connected to each connector. Each service is connected to the broker through one connector, And the connector and the service are included in the same process. The method of claim 7, wherein And there is only one connector in one process, and at least one service exists in one process. The method of claim 2, And the unicast address is a network address value uniquely identifying a corresponding service in the entire communication network system. A computer-readable recording medium in which a program for executing the method of any one of claims 1 to 9 is recorded. In the communication network system of the bus network structure, A broker that handles message routing; A connector; And A plurality of services connected to the broker through the connector Including, The service is a terminal node capable of communicating, and a network address uniquely identifying each service is assigned to each service, The connector is a module for mediating a connection between the service and the broker. The connector registers a first service to the broker, and an anycast group according to a function of providing at least a part of the registered first service. Or join a multicast group, The broker is a module for establishing a routing path or establishing a connection relationship with the connector to process message routing. Each broker is interconnected in a full mesh form, and the first service and the anycast group are connected to each other. Or transmitting and receiving data between second services subscribed to the multicast group, The connector and the first service are included in the same process.

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