CN101146051A

CN101146051A - An enterprise-level instant communication interconnection system and method for realizing enterprise interconnection

Info

Publication number: CN101146051A
Application number: CNA200710176975XA
Authority: CN
Inventors: 黎巍; 何卫星
Original assignee: Tencent Technology Shenzhen Co Ltd
Current assignee: Tencent Technology Shenzhen Co Ltd
Priority date: 2007-11-07
Filing date: 2007-11-07
Publication date: 2008-03-19
Anticipated expiration: 2027-11-07
Also published as: CN101146051B

Abstract

The invention discloses an enterprise-level instant messaging interconnection system and a method of realizing enterprise interconnection. A special authentication server used for enterprise users is set up; in each RTX enterprise network, complete the enterprise authentication function and public network linkage function by different equipment and the interconnection among different RTX enterprise networks is completed by a transfer server. In enterprise interconnection, the enterprise gateway launching interconnection obtains a signature and an IP address of the target transfer server on the authentication server and then, an enterprise interconnection application launching interconnection logs on the corresponding target transfer server and establishes the connection with the public network. The target transfer server searches and transmits data to the transfer server which the target enterprise logs on according to the target enterprise mark. The transfer server which the target enterprise logs on sends the data to the interconnection application of the target enterprise network. The invention can improve the expansibility and safety of the whole system.

Description

Enterprise-level instant messaging interconnection system and method for realizing enterprise interconnection

Technical Field

The invention relates to an enterprise interconnection technology, in particular to an enterprise-level instant messaging interconnection system and a method for realizing enterprise interconnection.

Background

With the rapid development of Instant Messaging (IM) technology, IM technology has been gradually popularized and used in various application environments. The method aims at the requirement of smooth communication in the enterprise, is suitable for the instant communication platform in the enterprise to come up, and can realize efficient communication in the enterprise. Further, in order to realize the intercommunication between different Real-Time eXchange (RTX) enterprises and the intercommunication with the instant messaging network, an enterprise-level instant messaging interconnection system based on an enterprise-level instant messaging platform is provided.

At present, an enterprise-level instant messaging interconnection system is proposed as shown in fig. 1, where fig. 1 shows a system architecture for intercommunication between two enterprises, and in practical application, more enterprise interconnections can be supported. In fig. 1, a transfer device bqqcon connected to two RTX enterprise networks is deployed in a public network, and the transfer device is also connected to an instant messaging server and is responsible for forwarding data between an RTX user and an instant messaging user.

Each RTX enterprise network comprises: the system comprises an RTX Server (Server), a Gateway (GW), and a plurality of clients, wherein the clients are connected with the RTX Server and the Gateway through a local area network. The RTX server is an enterprise-level instant communication platform and is used for realizing an instant communication function among all users in an enterprise, all enterprise users can easily search for personnel needing to communicate through an organization structure configured by the server, and adopt rich communication modes to carry out real-time communication, and can adopt text messages, file transmission and the like to meet communication forms in different office environments; and the authority control can be performed on different departments, groups and individuals in the enterprise through the operation of the server. And the gateway is deployed in the RTX enterprise and used for converting the protocol between the RTX and the instant messaging.

Although the scheme can realize enterprise-level instant messaging interconnection, when different enterprises are interconnected, a gateway in the scheme not only needs to map an RTX account and an instant messaging number, but also needs to process protocol conversion between the RTX and the instant messaging, and the realization logic is complex and the coupling is strong.

In the prior art, another enterprise-level instant messaging interconnection scheme adopting GK-Express is also provided, where the GK-Express itself may be personal instant messaging software (Lava-Lava) of a public network, and a number segment is allocated to each enterprise, so that numbers between users inside the enterprise and outside the enterprise are unified, and the interworking of users between enterprises does not require mapping of numbers any more.

However, in the scheme, the numbers of all GK-Express users are globally unique, which is inconvenient for enterprise users to manage the whole account system, and moreover, a server deployed inside an enterprise must establish a connection with a public network to acquire the number field of the enterprise, otherwise, the server cannot operate, which brings great inconvenience to the users. Meanwhile, the GK-Express server is complex to install and deploy, needs the support of professional technical personnel of the GK-Express, and common users including computer professional users are difficult to build an operating environment.

Disclosure of Invention

In view of the above, the main objective of the present invention is to provide an enterprise-level instant messaging interconnection system and a method for implementing enterprise interconnection, which solve the problems in the prior art and improve the extensibility and security of the entire system.

In order to achieve the purpose, the technical scheme of the invention is realized as follows:

the invention provides an enterprise-level instant messaging interconnection system, which comprises more than one RTX enterprise network, an authentication server and at least one transfer server; wherein,

the authentication server is used for verifying the validity of the enterprise user, generating various signatures and returning the signatures and the IP address of the target transit server;

the transfer server is used for supporting the access of the RTX enterprise network, completing the forwarding of data between the enterprise networks and storing each logged-in enterprise user online list;

and the RTX enterprise network is used for completing instant messaging in the enterprise.

In the above solution, the RTX enterprise network further includes an RTX server, a gateway, an internet application, and at least one client, wherein,

the RTX server is used for realizing the instant messaging function among all users in the enterprise;

the gateway logs in the authentication server to authenticate the enterprise to which the gateway belongs, and acquires a signature and an IP address of a target transit server from the authentication server;

and the interconnection application is responsible for the connection between the enterprise network and the public network, establishes communication connection between the transfer server and the RTX server, processes data receiving and transmitting between enterprises, and communicates with the gateway through UDP of the intranet.

The interconnection application further comprises a processing layer, an application layer, an IO layer, a configuration management unit, an external user information management unit and a local user information management unit; wherein,

the processing layer is used for performing local configuration management, application registration management, IO layer management and local user information management and processing network data from the transfer server and the internet application;

the configuration management unit is responsible for reading relevant information including local configuration and permission;

the application layer is responsible for processing the data forwarded by the processing layer;

the IO layer is responsible for network connection with the transfer server;

the local user information management unit is responsible for maintaining the user information opened by the enterprise to the outside and simultaneously saving an external friend list of the local user;

and the external user information management unit is responsible for recording the personal information of the external enterprise users.

In the above scheme, the enterprise network is connected to one transfer server, or multiple enterprise networks are connected to multiple transfer servers, and the number of the enterprise networks is different from the number of the transfer servers.

The invention also provides a method for realizing enterprise network interconnection, which is provided with an authentication server and a transfer server, and sets interconnection application for connecting the transfer server in each enterprise network, and the method comprises the following steps:

A. when an enterprise user initiates an interconnection request, a gateway of an enterprise to which the interconnection request user belongs acquires a signature and an IP address of a target transfer server from an authentication server;

B. the method comprises the steps that an interconnection application of an enterprise to which a user initiating an interconnection request belongs logs on a corresponding target transfer server, and connection between the interconnection application and the target transfer server is established;

C. and the target transit server searches the transit server logged by the target enterprise according to the identification of the target enterprise, forwards the data to the transit server logged by the target enterprise, and sends the data to the internet application of the target enterprise network.

Wherein, before step a, the method further comprises: and initiating an interconnection request to log in a gateway of an enterprise to which the user belongs to an authentication server, authenticating the current enterprise user by the authentication server, and then returning a login result to the gateway.

In the above solution, when the client requests to obtain the buddy enterprise list, the method further includes: and the client sends a request for acquiring a friend enterprise list to the RTX server to which the client belongs after logging in, the RTX server forwards the request to local interconnection application, and the interconnection application judges the authority of the current client, reads local data and returns the local data to the client through the RTX server.

When the user state in any friend enterprise is required to be acquired after the friend list is acquired, the method further comprises the following steps: after the friend list is obtained, the client sends a request for obtaining the user state of the friend enterprise to the RTX server which the client belongs to, the RTX server forwards the request to local interconnection application, the interconnection application judges the authority of the current client, if the authority passes, the request is forwarded to the interconnection application of the friend enterprise through the transfer server, the interconnection application of the friend enterprise obtains the user state information, and the user state information is returned to the client initiating the request through the transfer server, interconnection application equipment and the RTX server.

In the above solution, when the user list is updated among the interconnected enterprises, the method further includes:

a1, a timer set by the interconnection application in each enterprise network, checking whether the local user list information changes, if yes, informing the version information of the modified user list to the interconnection application of the corresponding friend enterprise, and selecting to update the user list information after the friend enterprise compares.

Before step a1, the method further includes:

the internet application reports the version numbers of the external users stored in the local to each friend enterprise through the transfer server; and the interconnection application of the receiver judges whether the two received version numbers are consistent, if not, the interconnection application of the receiver acquires the version number information of the user list from the interconnection application reporting the version number, and then downloads the user list information to the local.

In the above scheme, the method further comprises: and the internet application detects whether the user state changes, and if so, the internet application informs the online friend enterprise of updating the external user state information through the transit server. And the user state change information is actively reported to the interconnection application of the user by the client.

The enterprise-level instant messaging interconnection system and the method for realizing enterprise interconnection provided by the invention are provided with the authentication server specially used for authenticating enterprise users; in each RTX enterprise network, the function of completing enterprise authentication and the function of completing the connection with the public network are separately completed by different devices; the interconnection between different RTX enterprise networks is completed by the transfer server, so the invention has the following advantages and characteristics:

1) independence and safety of enterprise users are fully guaranteed:

each enterprise has an independent account system, RTX servers in the enterprises can realize basic functions without depending on any public network server, and meanwhile, interconnection and intercommunication among the enterprises are uniformly managed by a B2B server, so that great convenience is brought to user deployment;

after RTX remote login is established, enterprises needing to start public network interconnection can realize information transmission among the enterprises only by starting an independent service to be connected to a transfer server on the basis of the established RTX remote login, when the public network interconnection is not needed, the service can be stopped, and other enterprise users cannot find the enterprises stopping the service;

when RTX remote login is established, the number of an enterprise switchboard and an enterprise password are authenticated, and an automatic IP limiting function is also arranged, so that the safety of an RTX server is guaranteed; when the enterprises are interconnected, the signature is required to be acquired from the public network channel which is subjected to security authentication, and then the signature is verified on the transfer server, so that the security of the enterprise interconnection service is ensured;

data transmitted between the enterprise internal server and the public network server use a strict digital signature technology and an encryption technology, so that others cannot crack network data by intercepting a network packet, and the safety of user network data is guaranteed;

the RTX enterprise network server does not need to open any port to the outside, so that illegal external attack can be avoided, meanwhile, the public network service can configure the switchboard number of an external friend enterprise, and other harassment information can be avoided.

2) The great convenience of users uses the public network function of RTX:

an administrator of the RTX enterprise network only needs to configure the switchboard number of the friend enterprise and a local user list opened for the corresponding enterprise, meanwhile, the other enterprise also configures the enterprise as the friend enterprise, and users opened by the two enterprises can communicate with each other;

at the client, the function of enterprise interconnection exists in the form of plug-in, the basic interface is basically the same as the internal user, and special training is not needed.

3) Good expansibility and compatibility:

by adopting a relatively advanced server cluster technology and a load balancing strategy, under the condition that enterprise users are gradually increased, a large number of users can be smoothly supported by simply adding a transfer server, and the intercommunication of the users of different enterprises is supported;

according to the invention, an independent service is added in the RTX server and is responsible for transferring network data, special change is not required for specific network service, and bottleneck does not exist in the expansion of various services;

for the RTX client and the server, the RTX client and the server both exist in plug-in logically, so that the stability of the whole RTX system architecture is maintained, and various services which exist before are compatible.

Drawings

Fig. 1 is a schematic structural diagram of a composition of an enterprise-level instant messaging interconnection system in the prior art;

FIG. 2 is a schematic diagram of a component structure of an enterprise-level instant messaging interconnection system according to an embodiment of the present invention;

FIG. 3 is a schematic diagram of the internal components of the interconnect application of the present invention;

FIG. 4 is a schematic flow chart of a system-side method according to the present invention;

FIG. 5 is a schematic processing flow diagram of a client in the present invention;

FIG. 6 is a schematic view of a process flow for updating a user list according to the present invention;

FIG. 7 is a schematic view of a user state synchronization process according to the present invention.

Detailed Description

The basic idea of the invention is: setting an authentication server specially used for authenticating enterprise users; in each RTX enterprise network, the enterprise authentication function and the public network connection function are respectively completed by different devices; the interconnection between different RTX enterprise networks is uniformly managed and completed by the transfer server. When the enterprises are interconnected, the gateway of the enterprise initiating the interconnection firstly acquires the signature and the IP address of the target transit server from the authentication server, then the gateway of the enterprise initiating the interconnection logs on the corresponding target transit server by the interconnection application of the enterprise initiating the interconnection, and establishes the connection with the public network, the target transit server searches the transit server logged on by the target enterprise according to the identification of the target enterprise, and forwards the data to the transit server logged on by the target enterprise, and the transit server logged on by the target enterprise sends the data to the interconnection application of the target enterprise network.

In the enterprise-level instant messaging interconnection system, one transfer server or a plurality of transfer servers can be used. That is, a plurality of intranets may be connected to one relay server, one intranet may be connected to one relay server, or the intranet may be shared by a plurality of relay servers when the number of intranets is large, that is, a plurality of intranets are connected to a plurality of relay servers and the number of intranets is different from the number of relay servers.

Fig. 2 shows a composition structure of an embodiment of the enterprise-level instant messaging interconnection unification in the present invention, and as shown in fig. 2, the system in this embodiment includes more than one enterprise network, an authentication server WanServer, two transit servers B2BServer1 and B2BServer2, and B2BServer1 and B2BServer2 are respectively deployed in different network operators, such as telecommunications and internet communications, to provide better services for enterprise interconnection applications deployed in different network operators. In practical applications, there may be one or more transit servers, which may be deployed as required.

The WanServer is used for verifying the validity of enterprise users, generating various signatures, returning digital signatures and IP addresses of target transit servers required by corresponding services according to the types and load conditions of the services, and realizing the scheduling of the servers of various services.

B2BServer, which supports the access of the enterprise network and is responsible for the forwarding of data between the enterprise networks; b2BServer reports the load condition to the WanServer periodically; and B2BServer saves all logged-in online lists of enterprise users, when a new enterprise user logs in by using a signature, the B2BServer broadcasts a new enterprise login to other B2 BServers according to local configuration, and the other B2 BServers automatically update the local online lists of the enterprise users. When a plurality of B2 BServers exist, the B2 BServers forward data through a User Data Protocol (UDP), and the data of other interconnected applications are transferred without analyzing specific protocol contents in a network packet.

In fig. 2, each enterprise network at least includes an RTX server, a Gateway (GW), an internet application AppB2B, and a plurality of clients, where the RTX server is an enterprise-level instant messaging platform and is used to implement an instant messaging function between users in an enterprise. The GW is used as an external unified interface of the enterprise network and provides authentication support and redirection functions for other applications of RTX enterprise network users; specifically, the GW logs in the WanServer to authenticate the enterprise to which the GW belongs, and acquires the signature and the IP address of the target B2BServer from the WanServer. The AppB2B is an application in an RTX Server, the AppB2B in each enterprise network is responsible for the connection between the enterprise network and a public network, communication connection is established between the B2BServer and the RTX Server, data receiving and transmitting between enterprises are processed, and the AppB2B and GW communicate through UDP of an intranet.

Further, as shown in fig. 3, the App B2B further includes a processing layer (handler layer), an application layer (App layer), an IO layer (IOLayer), a configuration management (confighandle) unit, an external user information management unit, and a local user information management unit, where the processing layer is a core logic layer of the App B2B, and processes network data from the B2BServer and the App Server in addition to local configuration management, application registration management, IO layer management, and local user information management; the configuration management unit is responsible for reading related information such as local configuration, permission and the like; the application layer is responsible for processing the data forwarded by the processing layer and is concentrated with application logic; the IO layer is responsible for network connection with the B2BServer and comprises mechanisms such as login, disconnection reconnection and the like; the local user information management unit is responsible for maintaining user information such as open levels, online states, personal data and the like which are open to the outside of the enterprise, and simultaneously storing an external friend list of the local user; and the external user information management unit is responsible for recording the personal information of the external enterprise users.

The AppB2B has a separate database file for recording various information, including a list of users open to the outside by the enterprise, basic information of the external users, basic information of the external enterprise, blacklisted enterprises and the like; the internal timer reads the version information at regular time to decide whether to operate a specific table or not so as to improve the efficiency. Also deployed on the same machine as AppB2B is an enterprise interconnection manager, which mainly configures the enterprise open level and user list to the outside.

In order to complete the B2B function, each client further includes a B2B function module, which is an application of the client. In order to support the development of the SDK interface for the third party, the client side adopts a module form.

The method for realizing the enterprise network interconnection comprises the following steps:

step A: when an enterprise user initiates an interconnection request, a gateway of an enterprise to which the interconnection request user belongs acquires a signature and an IP address of a target transfer server from an authentication server;

and B: the method comprises the steps that an interconnection application of an enterprise to which a user initiating an interconnection request belongs logs on a corresponding target transfer server, and connection between the interconnection application and the target transfer server is established;

and C: and the target transit server searches the transit server logged by the target enterprise according to the identification of the target enterprise, forwards the data to the transit server logged by the target enterprise, and sends the data to the internet application of the target enterprise network.

Before the internet application logs in the transit server, the corresponding gateway needs to be informed, information such as an IP address and a signature of the transit server needs to be acquired, the gateway can be used for authenticating the acquisition of the server and then returning the information to the internet application, and then the internet application is connected and logs in the transit server. The process of obtaining the signature and the IP address is specifically: before the step A, a gateway of an enterprise to which the user initiates the interconnection request logs in an authentication server, the authentication server authenticates the current enterprise user, and then a login result is returned to the gateway. If the authentication is passed, the returned result comprises the signature and the IP address of the transit server, and the step A is directly executed; if the authentication fails, the authentication process is repeated until the authentication is successful.

Here, there may be one or more transit servers, and when there is only one transit server, the transit server corresponding to the enterprise to which the user initiating the interconnection request belongs is the same as the destination transit server, in this case, one transit server corresponds to a plurality of intranets.

For example, suppose that an enterprise a sends data to an enterprise B, and the enterprise a only needs to inform a transit server connected to the enterprise a and an enterprise identifier of the enterprise B, then the transit server connected to the enterprise a acquires the transit server connected to the enterprise B according to the enterprise identifier, and then forwards the data to the enterprise B via the transit server connected to the enterprise B; if the transit server connected with the enterprise A finds that the enterprise B is also connected with the enterprise A, the transit server directly forwards the information without forwarding the information to other transit servers.

Based on the system structure of fig. 2, a specific processing flow for implementing enterprise network interconnection of the present invention is shown in fig. 4, and includes the following steps:

step 401-403: GW1 logs in to WanServer by using TCP, and the WanServer authenticates the current enterprise user and then returns a login result to GW 1; and B2BServer registers the relevant information to the WanServer, and after the completion of the WanServer registration, the registration result is returned to the B2 BServer.

Here, the reported information includes: what service (B2B) the transit server belongs to, what network is deployed and operated on, for example: over telecommunications, internet or educational networks, and the like.

Step 404-407: AppB2B1 sends a signature requesting a B2B service to GW1, GW1 sends a request for acquiring the signature of B2B and a destination service address to WanServer, WanServer returns the signature and the destination transit server address to GW1 and GW1 returns the signature and the destination transit server address to AppB2B1 according to the network of the enterprise and the load information of each current transit server. Here, GW1 interworks with AppB2B1 via UDP protocol.

Step 408-411: AppB2B1 logs in B2BServer, establishes connection with the B2BServer, and the B2BServer returns login results and notifies all B2BServer of changes of online enterprises.

Here, the B2 bservers notify each other through UDP broadcasting. Meanwhile, the B2BServer also needs to report its own load condition to the WanServer, for example: and the information of the number of online enterprises, CPU occupation, network bandwidth occupation and the like is provided, so that the WanServer can distribute the B2BServer with lighter load for the next enterprise needing to be logged in.

Step 412 to 413: the AppB2B1 sends the instant messaging information to the B2B server, and the B2B server forwards the instant messaging information to the AppB2B2 of the destination enterprise network, and then the B2B server simultaneously returns a result to the AppB2B1, for example, notifies whether the forwarding is successful.

In the flow of fig. 4, enterprise 1 and enterprise 2 share the same B2BServer, and if enterprise 1 and enterprise 2 correspond to different B2 bservers, the two B2 bservers may transfer the transmitted information through the UDP protocol.

Correspondingly, within the enterprise network, the processing flow of the client is as shown in fig. 5, and includes:

steps 501a to 501 d: after logging in, the client C1 sends a request to the RTXServer1 to obtain a list of buddy enterprises, and then downloads user information of each enterprise, the RTXServer1 forwards the request to the AppB2B1, the AppB2B1 determines the authority of the current client and reads local data, and the result is returned to the client C1 via the RTXServer 1.

Here, since AppB2B1 already holds the relevant information of the external contacts, there is no need to forward data to the buddy enterprise for repeated retrieval.

After obtaining the buddy list of a certain enterprise, the client may further obtain the statuses of all users, including:

steps 502a to 502 f: the client C1 sends a request to RTXServer1, to acquire user states of all contacts of a friend enterprise, RTXServer1 forwards the request to AppB2B1, AppB2B1 judges the authority of the current client, if the authority passes, the request is continuously forwarded to AppB2B2 of the friend enterprise through B2BServer, AppB2B2 acquires user state information from a memory, and all user states are returned to the client C1 which initiates the request through B2BServer, AppB2B1 and RTXServer 1.

Generally, acquiring the states of all users occurs when logging in for the first time or when a friend list of a certain enterprise is modified.

The client acquires the user state and specifically comprises the following steps when sending IM information to a certain user of a friend enterprise:

step 502 g-502 m: the client C1 forwards the IM information through RTXServer1 and AppB2B1, AppB2B1 judges the client right, if the client right passes through the RTXServer1 and the AppB2B2 of the friend enterprise, AppB2B2 judges the client right, if the client right passes through the AppB2B2 of the friend enterprise, the client C1 forwards the IM information to RTXServer2, and RTXServer2 forwards the IM information to the client C2 or stores the offline information; meanwhile, AppB2B2 returns the sending result to the client C1 through B2BServer, AppB2B1 and RTXServer 1.

Wherein the receiving party's AppB2B supports the forwarding of offline messages.

In the present invention, when the user list between the interconnected enterprises is updated, the operation flow is specifically shown in fig. 6, and fig. 6 includes three parts: steps 601a to 601e are login registration part; steps 602a to 602i are user information updating parts; steps 603a to 603j are portions for periodically detecting whether the user list has changed. Wherein, the login registration part comprises the registration of two AppB2B respectively. The method specifically comprises the following steps:

steps 601a to 601 b: after AppB2B is started, registering a message type needing attention to RTXServer, wherein the message type comprises a message type B2B and state attention;

step 601 c: when the AppB2B is initialized, it needs to read an external contact list inside an enterprise and the online status of each user, which are used as the basis for subsequent permission determination and online status determination, and the AppB2B defines and reads some locally stored version information to determine whether the external user information of the enterprise is changed.

Steps 601d to 601 e: the AppB2B needs to acquire a digital signature (not shown) from the GW, start to connect to the B2BServer after the acquisition is successful, and register the relevant information after the connection is successful.

Steps 602a to 602 i: the AppB2B1 reports the version number of the external user stored locally to each friend enterprise through the B2Bserver, where the version number includes: the version number of the user list (Verlocal) opened by the enterprise to the friend enterprise, and the version number of the user list (VerRemote) opened by the friend enterprise to the enterprise.

The two version numbers need to be judged by the corresponding AppB2B2 of the receiver, if the received Verlocal is not equal to the local VerRemote, the AppB2B2 needs to send a command to the AppB2B1 to acquire the version number information of the user list, and then the version number information is compared with the local to download the user list information to the local in batch; similarly, if the VerRemote of AppB2B1 is not equal to the local Verlocal, the version information of the local user list is sent to AppB2B1, and the AppB2B1 downloads the user detailed information;

steps 603a to 603 j: each AppB2B is provided with a timer for checking whether the local user list information changes, if so, the modified version information of the user list is notified to the AppB2B2 of the online friend enterprise, and the friend enterprise selects to update the user list information after comparison;

after each time AppB2B is disconnected, if the reconnection registration is successful, steps 602a to 602i and 603a to 603j are repeated to synchronize the friend data. When there is a change in the user list, all online users open to the enterprise should be notified.

For the synchronization of the user status, as shown in fig. 7, the method specifically includes:

step 701 a-701 g: AppB2B focuses on the state change of the contact opened outside the enterprise itself, and stores the state information of each user opened outside the enterprise itself in the memory. The user state change information is actively reported to the AppB2B to which the client C1 belongs.

The client side needs to acquire the contact state of the friend enterprise in two ways:

a. after the client logs in successfully, the states of all external contacts are pulled from AppB 2B;

b. the state of the contact needing the conversation is pulled independently, and the local AppB2B needs to acquire the state of a single user through the B2Bserver to the AppB2B of the other party.

After the AppB2B updates the internal contact list of the enterprise each time, the states of the contacts need to be acquired from the AppServer as initial state values.

After the AppB2B successfully logs in the B2Bserver each time, the state of the external user stored locally needs to be acquired, and meanwhile, the always-on AppB2B also needs to update the user state information of the opposite enterprise stored locally.

The above description is only a preferred embodiment of the present invention, and is not intended to limit the scope of the present invention.

Claims

1. An enterprise-level instant messaging interconnection system is characterized by comprising more than one RTX enterprise network, an authentication server and at least one transfer server; wherein,

2. The system of claim 1, wherein the RTX enterprise network further comprises an RTX server, a gateway, an Internet application, and at least one client, wherein,

3. The system according to claim 2, wherein the interconnection application further comprises a processing layer, an application layer, an IO layer, a configuration management unit, an external user information management unit, and a local user information management unit; wherein,

the IO layer is responsible for network connection with the transfer server;

4. The system of claim 1, 2 or 3, wherein one enterprise network is connected to one transit server, or a plurality of enterprise networks are connected to a plurality of transit servers, and the number of enterprise networks is different from the number of transit servers.

5. A method for realizing enterprise network interconnection is characterized in that an authentication server and a transfer server are arranged, and interconnection application for connecting the transfer server is arranged in each enterprise network, and the method comprises the following steps:

6. The method of claim 5, wherein prior to step A, the method further comprises: and initiating an interconnection request to log in a gateway of an enterprise to which the user belongs to an authentication server, authenticating the current enterprise user by the authentication server, and then returning a login result to the gateway.

7. The method of claim 5 or 6, wherein when the client requests to obtain the list of friend enterprises, the method further comprises:

and the client sends a request for acquiring a friend enterprise list to the RTX server to which the client belongs after logging in, the RTX server forwards the request to local interconnection application, and the interconnection application judges the authority of the current client, reads local data and returns the local data to the client through the RTX server.

8. The method of claim 7, wherein when the user status in any friend enterprise is required to be obtained after obtaining the friend list, the method further comprises:

after the friend list is obtained, the client sends a request for obtaining the user state of the friend enterprise to the RTX server which the client belongs to, the RTX server forwards the request to local interconnection application, the interconnection application judges the authority of the current client, if the authority passes, the request is forwarded to the interconnection application of the friend enterprise through the transfer server, the interconnection application of the friend enterprise obtains the user state information, and the user state information is returned to the client initiating the request through the transfer server, interconnection application equipment and the RTX server.

9. The method of claim 5 or 6, wherein when updating the user list between the interconnected enterprises, the method further comprises:

10. The method of claim 9, wherein prior to step a1, the method further comprises:

11. The method of claim 5 or 6, further comprising:

and the internet application detects whether the user state changes, and if so, the internet application informs the online friend enterprise of updating the external user state information through the transit server.

12. The method according to claim 11, wherein the user state change information is actively reported to the internet application to which the user belongs by the client.