KR101596140B1 - Apparatus and method for toleranting fault in tcp based on dual structure - Google Patents

Abstract

A TCP-based fault tolerant device and method based on a redundancy structure is disclosed. A TCP-based failure-tolerance device based on a redundant structure includes an interface for receiving a beating signal from a master processor, and a control unit for switching control authority from the master processor to a backup processor when detecting an abnormality with respect to the beating signal And a processor unit for establishing a session between the client and the backup processor connected to the master processor in accordance with the switching of the control authority.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a TCP based fault tolerant apparatus and method based on a redundant structure,

Embodiments of the present invention relate to a technique for establishing a session between a client and a backup processor which are connected to a master processor when an abnormality is detected in the master processor so that network communication at the client is maintained even in the event of a failure.

The fault tolerant device can communicate with a networked client based on TCP and can detect when a fault occurs. At this time, in case of a failure, the fault tolerant device must reset the TCP session with the client as the TCP session is lost.

At this time, there is a need for a technique that can easily reconfigure the TCP session between the fault-tolerant device and the client.

In the present invention, when an abnormality is detected in a beep signal inputted from a master processor, a control right is switched from the master processor to a backup processor, and the control right is transferred to the client connected to the master processor And setting a session between the backup processors to replace the role of the master processor with a backup processor when a failure occurs in the master processor, thereby stably maintaining the network communication in the client.

The present invention replicates a communication state between a master processor and a client (e.g., a transmission or reception state of a packet, a socket information, a routing table entry, and the like) at the time of detecting an abnormality in the master processor, By synchronizing the communication environment, it is possible to easily re-establish a session with a client, thereby reducing the high cost caused by the resetting.

In addition, the present invention restricts connection termination between a master processor and a client within a predetermined period after establishing a session between a client and a backup processor, thereby maintaining the connection for a predetermined period, To prevent them from recognizing.

In order to achieve the above object, a TCP-based failure-tolerance device based on a redundancy structure includes an interface for receiving a beating signal from a master processor, and a control processor for controlling the control authority from the master processor to a backup processor And a processor unit for establishing a session between the client and the backup processor connected to the master processor in accordance with the switching of the control authority.

According to another aspect of the present invention, there is provided a TCP-based fault tolerance method based on a redundant structure, including the steps of receiving a beep signal from a master processor, switching control authority from the master processor to a backup processor And establishing a session between the client and the backup processor that has been connected to the master processor upon switching of the control authority.

According to the embodiment of the present invention, when an abnormality is detected in the beep signal input from the master processor, control authority is switched from the master processor to the backup processor and given to the master processor By establishing a session between the connected client and the backup processor, when a failure occurs in the master processor, the role of the master processor is replaced with the backup processor, so that the network communication in the client can be stably maintained.

According to an embodiment of the present invention, when an abnormality is detected in a master processor, a communication state between the master processor and a client (e.g., transmission or reception state of a packet, socket information, routing table entry, It is possible to easily reset the session with the client by synchronizing the communication environment, thereby reducing the high cost caused by the resetting.

According to the embodiment of the present invention, connection termination between a master processor and a client is restricted within a predetermined period after a session is established between a client and a backup processor, and the connection is maintained for a predetermined period, It is possible to prevent the master processor from recognizing the abnormality.

1 is a diagram illustrating an exemplary configuration of a network including a TCP-based fault tolerance apparatus based on a redundancy structure according to an embodiment of the present invention.
2 is a diagram illustrating a configuration of a TCP-based fault tolerance apparatus based on a redundancy structure according to an embodiment of the present invention.
3 is a diagram illustrating an example of a configuration of a master processor controlled by a TCP-based failure-tolerance device based on a redundancy structure according to an embodiment of the present invention.
4 is a diagram for explaining a synchronization method when a master processor transmits a packet to a client in a TCP-based fault tolerance apparatus based on a redundancy structure according to an embodiment of the present invention.
5 is a diagram for explaining a synchronization method when a master processor receives a packet from a client in a TCP-based fault tolerance apparatus based on a redundancy structure according to an embodiment of the present invention.
6 is a diagram for explaining an example of a method of operating a backup processor controlled by a TCP-based fault tolerance apparatus based on a redundancy structure according to an embodiment of the present invention.
7 is a flowchart illustrating a TCP-based fault tolerance method based on a redundancy structure in accordance with an embodiment of the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, a TCP-based fault tolerance apparatus and method based on a redundancy structure according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings.

1 is a diagram illustrating an exemplary configuration of a network including a TCP-based fault tolerance apparatus based on a redundancy structure according to an embodiment of the present invention.

Referring to FIG. 1, the network 100 may include a client 101 and a fault tolerant system 103.

The client 101 may communicate with the fault tolerant system 103. Specifically, the client 101 can communicate with the master processor 105 in the fault tolerant system 103 on the basis of TCP (Transmission Control Protocol). If an error occurs in the master processor 105, Based communication with the backup processor 107 in the fault tolerant system 103 under the control of the TCP based fault tolerant device 109 based on the redundant structure in the system 103. [

The fault tolerant system 103 may include a master processor 105, a backup processor 107 and a TCP-based fault tolerance device 109 based on a redundancy structure.

The master processor 105 and the backup processor 107 may be of the same structure and may communicate with the client 101 on a TCP basis if the control authority is granted by the TCP based fault tolerance device 109 based on the redundancy structure .

The TCP-based fail-safe device 109 based on the redundancy structure can be, for example, but is not limited to a routing device. The TCP-based failure-tolerant device 109 based on the redundant structure first grants control to the master processor 105 and establishes and connects a session between the master processor 105 and the client 101, 105) and the client (101).

At this time, the TCP-based fault tolerant device 109 based on the redundant structure can maintain the communication state (e.g., transmission or reception state of the packet, socket information, routing table entry, etc.) between the master processor and the client.

That is, the TCP-based failure-tolerant device 109 based on the redundant structure can collect TCP session information and packet information for recovery in a normal state (before communication is smooth between the master processor and the client) .

Here, the TCP-based fault tolerant device 109 based on the redundant structure is set up between the master processor 105 and the client 101 in accordance with the connection between the master processor 105 and the client 101 Receives session information related to a TCP session, and maintains the session information in the storage in consideration of the input time of the session information. Further, the TCP-based failure-tolerant device 109 based on the redundant structure further receives packet information regarding a packet exchanged between the master processor 105 and the client 101, receives the packet information in response to the session information And can be kept in the storage. At least one of the session information and the packet information may be transmitted to the master processor 105 and the client 101 by the master processor 105 when an abnormality is detected in the TCP session, / RTI >

Thereafter, the TCP-based fault tolerance device 109 based on the redundancy structure can recover the TCP session based on the TCP session information collected in the storage when the master processor 105 fails.

Specifically, the TCP-based failure-tolerant device 109 based on the redundant structure switches control authority from the master processor 105 to the backup processor 107 when it detects an abnormality in the master processor 105, It is possible to support communication between the backup processor 107 and the client 101 by establishing and connecting a session between the client 101 and the backup processor 107 which have been connected to the master processor 105 have. At this time, the TCP-based failure-tolerant device 109 based on the redundancy structure can synchronize the communication environment by applying the communication state between the master processor and the client, which is maintained in the storage, between the backup processor and the client, Can be reset.

The TCP-based failure-tolerant device 109 based on the redundant structure replaces the role of the master processor 105 with the backup processor 107 when a failure occurs in the master processor 105, To be maintained stably.

2 is a diagram illustrating a configuration of a TCP-based fault tolerance apparatus based on a redundancy structure according to an embodiment of the present invention.

2, a TCP-based failure-tolerant device 200 based on a redundancy structure according to an embodiment of the present invention includes an interface unit 201, a provision unit 203, a processor unit 205, a storage controller 207 And a storage 209.

i) Collecting TCP session information and packet information for recovery in a normal state

The interface unit 201 can receive session information related to a TCP session established between the master processor and the client from the master processor according to the connection with the client. Here, the session information can be maintained in the repository, taking into account the input time, by the repository control section.

In addition, the interface unit 201 may further receive packet information regarding packets exchanged between the master processor and the client. Here, the packet information may be maintained by the storage control unit in the storage corresponding to the session information.

At least one of the session information and the packet information may be used by the master processor to recover the TCP session between the clients when an abnormality is detected in the TCP session.

Ⅱ) TCP session recovery based on TCP session information collected in the repository in the event of a failure

The interface unit 201 can receive a signal, for example, a heartbeat signal, from the master processor.

In addition, the interface unit 201 can receive session information on a TCP session between the master processor and the client, and packet information on packets exchanged between the master processor and the client, from the master processor. The session information and the packet information may be maintained in the storage 209 by the storage control unit 207. [

In addition, the interface unit 201 may receive the packet from the client, which has been retained in the storage 209 after a session is established between the client and the backup processor, which has been connected to the master processor, And transmits the ACK message to the client through the backup processor, thereby allowing the client to confirm completion of the reception of the packet.

The interface unit 201 retransmits the packet held in the storage 209 to the client via the backup processor when the ACK message is not received from the client for the packet transmitted to the client within the predetermined period So that the packet whose transmission completion is not confirmed can be provided again.

The control unit 203 may change the control authority from the master processor to the backup processor when detecting an abnormality with respect to the pulse signal.

The processor unit 205 can establish and connect a session between the client and the backup processor connected to the master processor upon switching of the control right from the master processor to the backup processor. At this time, the processor unit 205 replicates any one of the session information about the TCP session and the packet information about the packet in the storage 209, and the session between the backup processor and the client , It is possible to easily restore the TCP session between the backup processor and the client.

In addition, when the backup processor and the client are connected, the processor unit 205 collects socket information used for connection with the client from the master processor, and, using the socket specified in the socket information, And the client so that the communication environment between the master processor and the client can be directly applied between the backup processor and the client.

After establishing a session between the client and the backup processor, the processor unit 205 may process the Flush message associated with the packet through the backup processor to generate update packet information for the packet.

In addition, the processor unit 205 restricts the termination of connection between the master processor and the client within a predetermined period of time after setting up a session between the client and the backup processor, thereby preventing the client from recognizing the abnormality of the master processor can do. That is, the processor unit 205 maintains a connection between the master processor and the client for a predetermined period until the connection between the client and the backup processor is stabilized, thereby preventing the master processor from experiencing a failure So that the communication can be maintained.

Meanwhile, the processor unit 205 recovers the master processor according to the switching of the control authority from the master processor to the backup processor, and enters the standby state of the master processor. When an error occurs in the backup processor An environment for supporting the re-communication between the master processor and the client can be provided by re-switching the control right from the backup processor to the master processor.

The storage control unit 207 may maintain an ACK message on reception of the packet when an abnormality is detected in the heartbeat signal of the master processor while receiving the packet from the client. When the processor unit 205 generates update packet information on the received packet, the storage control unit 207 periodically updates the packet information on the packet by keeping the update packet information in the storage 209 , And keep up-to-date information.

When an abnormality is detected in the heartbeat signal of the master processor while the packet is being transmitted to the client, the storage control unit 207 holds the packet in the storage 209, and after the setting of the session, , And if an ACK message is received from the client, the packet held in the storage can be deleted. That is, the storage control unit 207 stores the packet sent to the client in the storage 209, successfully receives the packet from the client, and can delete the packet from the storage when the packet is transmitted.

The repository 209 may store at least one of session information about a TCP session, an ACK message about packet reception from a client, packet information about a packet, and a packet sent to a client.

3 is a diagram illustrating an example of a configuration of a master processor controlled by a TCP-based failure-tolerance device based on a redundancy structure according to an embodiment of the present invention.

Referring to FIG. 3, the master processor 300 controlled by the TCP-based fault tolerance device based on the redundancy structure includes APP_B 301, TCP Session Synchronizing Block (TSS_B) 303, TSH_B (TCP Session Handling Block) 305, an ASW_B (Application Side Wrapper Block) 307, and an IP Side Wrapper Block (ISW_B) 309.

The APP_B 301 may provide application information to the TSS_B 303.

The TSS_B 303 may store application information transmitted from the APP_B 301 and TCP session information and packet information transmitted from the TSH_B 305 in a TSR_B (TCP Session Repository Block) 313. Here, the TSR_B 313 may be located in the TCP-based fault tolerant device 311 based on the redundancy structure, and may store at least one of application information, TCP session information, and packet information.

The TSH_B 305 operates in the kernel layer and manages TCP session information and packet information, and can transmit updated TCP session information and packet information to the TSR_B 313 via the TSS_B 303. Here, TSH_B 305 may communicate with TSS_B 303 of the user area using a Netlink, according to an internally defined stack.

Upon failover due to a failure in the master processor, the TSH_B 305 receives the TCP session information stored in the TSR_B 313 via the TSS_B 303 and restores the TCP session with the client , The packet stored in the TSR_B 313 can be received through the TSS_B 303 and retransmitted to the client in response to the ACK message being not received for the packet (Send packet) transmitted to the client.

The ASW_B 307 operates in the kernel layer and may be located between the TCP layer and the APP_B 301.

The ASW_B 307 can provide an API (Application Programming Interface) for socket processing. When the ASW_B 307 detects packet reception (reception of a receive packet) from the client, until the APP_B 301 processes the TCP data for synchronization, After the TCP session update is suspended, the Flush message generated after the data processing in the APP_B 301 is received, the TSH_B 305 is informed to store the updated TCP session information in the TSR_B 313 for session synchronization have. Here, the TSH_B 305 can store the updated TCP session information in the TSR_B 313 via the TSS_B 303. Here, after the Flush message is processed, for the packet received from the client, the held ACK message can be transmitted to the client.

In addition, the ASW_B 307 suspends the data processing when transmitting a packet to the client, and after completing the processing procedure of storing the packet in the TSR_B 313 via the TSH_B 305, Lt; / RTI >

ISW_B 309 operates in the kernel layer and may be located between the TCP layer and IP.

The ISW_B 309 can delete a packet stored in the TSR_B 313 via the TSH_B 305 when an ACK message for a packet transmitted to the client is detected.

In addition, the backup processor controlled by the TCP-based fault tolerant device based on the redundant structure may have the same structure as the master processor 300. [

4 is a diagram for explaining a synchronization method when a master processor transmits a packet to a client in a TCP-based fault tolerance apparatus based on a redundancy structure according to an embodiment of the present invention. Here, the master processor 401 may include APP_B, TSS_B, TSH_B, ASW_B, and ISW_B. In addition, the TCP-based failure-tolerance device 403 based on the redundancy structure may include TSR_B.

Referring to FIG. 4, when ASW_B receives a send packet from APP_B, it can transmit TCP session information and packet information to TSH_B.

TSH_B can transmit TCP session information and packet information received from ASW_B to TSS_B and store TCP session information and packet information in TSR_B through TSS_B to update information.

The ASW_B may transmit the send packet to the ISW_B located between the TCP and the IP layer when it is confirmed that the TCP session information and the packet information update from the TSS_B to the TSR_B are completed through the TSH_B.

ISW_B sends a send packet to the client, and if an ACK message for the send packet is detected, it can forward an ACK message to TSH_B.

When TSH_B receives an ACK message from TSH_B, it forwards the Flush message to TSR_B via TSS_B, allowing TSR_B to update the TCP session information associated with the Flush message.

5 is a diagram for explaining a synchronization method when a master processor receives a packet from a client in a TCP-based fault tolerance apparatus based on a redundancy structure according to an embodiment of the present invention. Here, the master processor 501 may include APP_B, TSS_B, TSH_B, ASW_B, and ISW_B. In addition, the TCP-based fail-safe device 503 based on the redundancy structure may include TSR_B.

Referring to FIG. 5, if ASW_B detects a receive packet received from a client via ISW_B, the ASW_B temporarily holds session information on a packet received from the ASW_B and suspends the processing until receiving a Flush message of APP_B through the ioctl have.

Upon receiving the Flush message from APP_B, ASW_B can inform TSH_B to store updated TCP session information in TSR_B for session synchronization. TSH_B may store the updated TCP session information in TSR_B 313 via TSS_B.

6 is a diagram for explaining an example of a method of operating a backup processor controlled by a TCP-based fault tolerance apparatus based on a redundancy structure according to an embodiment of the present invention.

Referring to FIG. 6, when the TSS_B detects an abnormality with respect to a heart beat in the TSS_RECOVERY_M, it can execute APP_B and switch to a failover mode.

APP_B can request TSS_B session information to be restored after executing the initialization routine for applying the failed TCP stack and failover mode. TSS_B can receive session information from TSR_B and forward it to TSH_B.

In addition, APP_B can transmit the fd information in a listening state, which is server socket information to be restored, to TSH_B through TSS_B.

TSH_B restores the established TCP session from the master processor based on the received TCP session information. After performing the session restoration, TSH_B transmits the ACK message stored in TSR_B It is possible to proceed with the retransmission for the packet (i.e., the packet transmitted to the client).

In addition, TSH_B can transfer the restored fd to the APP_B through the accept API when the retransmission of the Send packet is completed.

The APP_B (301) resumes communication with the client connected to the master processor through the received fd, thereby enabling the client to maintain the communication in a state in which the client can not detect an abnormality with respect to the master processor.

7 is a flowchart illustrating a TCP-based fault tolerance method based on a redundancy structure in accordance with an embodiment of the present invention.

Referring to FIG. 7, in step 701, a TCP-based failure-tolerance device based on a redundancy structure receives, from a master processor, session information regarding a TCP session established between the client and the master processor, At least one of packet information regarding a packet exchanged between clients can be input.

At this time, the TCP-based failure-tolerance device based on the redundancy structure can keep the session information in the storage in consideration of the input time of the session information. In addition, the TCP-based failure-tolerance device based on the redundancy structure can keep the packet information in the storage corresponding to the session information. At least one of the session information and the packet information may be used by the master processor to recover the TCP session between the clients when an abnormality is detected in the TCP session.

In step 703, the TCP-based failure-tolerance device based on the redundancy structure can transfer control authority from the master processor to the backup processor when detecting an abnormality in the beating signal input from the master processor.

The TCP-based failure-tolerance device based on the redundancy structure can maintain an ACK message on reception of the packet when an abnormality is detected in the beep signal of the master processor while receiving the packet from the client.

In addition, the TCP-based failure-tolerance device based on the redundancy structure can maintain the packet in the storage when an abnormality is detected in the heartbeat signal of the master processor during transmission of the packet to the client.

In step 705, a TCP-based failure-tolerance device based on the redundancy structure can establish a session between the client and the backup processor that has been connected to the master processor upon switching of the control authority.

A TCP-based failure-tolerance device based on a redundant structure replicates any one of session information and packet information regarding a TCP session in the repository, and generates a duplication structure between the backup processor and the client By establishing a session, a TCP session can be easily restored between the backup processor and the client.

In addition, when the backup processor and the client are connected, the TCP-based failure-tolerance device based on the redundancy structure collects socket information used for connection with the client from the master processor, and uses the socket specified by the socket information By connecting the backup processor and the client, the communication environment between the master processor and the client can be directly applied between the backup processor and the client.

After the session is established between the client and the backup processor, the TCP-based failure-tolerance device based on the redundancy structure transmits an ACK message, which has been held in the repository, to the client through the backup processor, ≪ / RTI >

In addition, after the establishment of the session, the TCP-based failure-tolerance device based on the redundancy structure processes the Flush message associated with the packet received from the client through the backup processor to generate update packet information on the packet, Lt; RTI ID = 0.0 > update packet information. ≪ / RTI >

On the other hand, the TCP-based failure-tolerance device based on the redundancy structure can delete a packet held in the storage when an ACK message is received from the client through the backup processor after establishing a session between the client and the backup processor. At this time, if the ACK message is not received from the client within a predetermined period, the TCP-based failure-tolerant device based on the redundant structure can retransmit the packet held in the repository to the client through the backup processor.

In addition, the TCP-based failure-tolerance device based on the redundancy structure limits connection termination between the master processor and the client within a predetermined period after the session between the client and the backup processor is established, Thereby making it impossible to recognize the abnormality of the master processor.

In addition, a TCP-based failure-tolerance device based on a redundant structure may restore the master processor upon switching of the control authority from the master processor to the backup processor to enter the standby state of the master processor, If an error occurs, make the master processor available again.

In an embodiment of the present invention, when an abnormality is detected in a beep signal input from a master processor, a control right is switched from the master processor to a backup processor, and the controller is connected to the master processor And establishes a session between the client and the backup processor, thereby replacing the role of the master processor with the backup processor in the event of a failure in the master processor, so that the network communication in the client can be stably maintained.

The embodiment of the present invention replicates a communication state (e.g., transmission or reception state of a packet, socket information, routing table entry, and the like) between a master processor and a client when an error is detected in the master processor, , It is possible to easily reset the session with the client by synchronizing the communication environment, thereby reducing the high cost caused by the resetting.

In addition, the embodiment of the present invention restricts connection termination between the master processor and the client within a predetermined period after establishing a session between the client and the backup processor, thereby maintaining the connection for a predetermined period, Can not be recognized.

The apparatus described above may be implemented as a hardware component, a software component, and / or a combination of hardware components and software components. For example, the apparatus and components described in the embodiments may be implemented within a computer system, such as, for example, a processor, a controller, an arithmetic logic unit (ALU), a digital signal processor, a microcomputer, a field programmable array (FPA) A programmable logic unit (PLU), a microprocessor, or any other device capable of executing and responding to instructions. The processing device may execute an operating system (OS) and one or more software applications running on the operating system. The processing device may also access, store, manipulate, process, and generate data in response to execution of the software. For ease of understanding, the processing apparatus may be described as being used singly, but those skilled in the art will recognize that the processing apparatus may have a plurality of processing elements and / As shown in FIG. For example, the processing unit may comprise a plurality of processors or one processor and one controller. Other processing configurations are also possible, such as a parallel processor.

The software may include a computer program, code, instructions, or a combination of one or more of the foregoing, and may be configured to configure the processing device to operate as desired or to process it collectively or collectively Device can be commanded. The software and / or data may be in the form of any type of machine, component, physical device, virtual equipment, computer storage media, or device , Or may be permanently or temporarily embodied in a transmitted signal wave. The software may be distributed over a networked computer system and stored or executed in a distributed manner. The software and data may be stored on one or more computer readable recording media.

The method according to an embodiment may be implemented in the form of a program command that can be executed through various computer means and recorded in a computer-readable medium. The computer-readable medium may include program instructions, data files, data structures, and the like, alone or in combination. The program instructions to be recorded on the medium may be those specially designed and configured for the embodiments or may be available to those skilled in the art of computer software. Examples of computer-readable media include magnetic media such as hard disks, floppy disks and magnetic tape; optical media such as CD-ROMs and DVDs; magnetic media such as floppy disks; Includes hardware devices specifically configured to store and execute program instructions such as magneto-optical media and ROM, RAM, flash memory, and the like. Examples of program instructions include machine language code such as those produced by a compiler, as well as high-level language code that can be executed by a computer using an interpreter or the like. The hardware devices described above may be configured to operate as one or more software modules to perform the operations of the embodiments, and vice versa.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments. For example, it is to be understood that the techniques described may be performed in a different order than the described methods, and / or that components of the described systems, structures, devices, circuits, Lt; / RTI > or equivalents, even if it is replaced or replaced.

Therefore, other implementations, other embodiments, and equivalents to the claims are also within the scope of the following claims.

100: Network 101: Client
103: Fault tolerance system 105: Master processor
107: Backup Processor
109: TCP-based fault tolerance based on redundancy structure

Claims (21)

delete delete delete Receiving a beep signal from a master processor that transmits a packet to a client through a TCP session;
Establishing a session between the client and the backup processor when detecting an anomaly for the beep signal;
Limiting connection termination between the master processor and the client within a predetermined period after the setting of the session;
Transferring only control authority from the master processor to the backup processor while maintaining connection between the master processor and the client;
Retransmitting, to the client through the session, a packet in which an ACK message is not received from the client, among the packets transmitted to the client through the TCP session; And
When the master processor is restored, transferring the control right from the backup processor to the master processor so as to resume communication with the client connected to the master processor through the TCP session
Based fault tolerant method based on a redundant structure including at least one redundant structure. 5. The method of claim 4,
Receiving session information about a TCP session between the clients and packet information about packets exchanged between the clients from the master processor; And
Maintaining the session information and the packet information in a storage
Further comprising:
Wherein the establishing of the session comprises:
Duplicating any one of the session information and the packet information in the storage; And
Establishing a session between the backup processor and the client based on the replicated information
Based fault tolerant method based on a redundant structure including at least one redundant structure. 5. The method of claim 4,
When an abnormality is detected in the heartbeat signal of the master processor,
Maintaining a packet in which the ACK message is not received in the storage
Further comprising:
Wherein retransmitting to the client comprises:
After the establishment of the session, retransmitting, to the client via the backup processor, a packet in which the ACK message held in the repository is not received
Based fault tolerant method based on a redundant structure including at least one redundant structure. 5. The method of claim 4,
When packet information regarding packets exchanged between the master processor and the client is maintained in the repository,
Processing the Flush message associated with the packet through the backup processor after generating the session to generate update packet information for the packet; And
Maintaining the update packet information in the repository
Based fault tolerance based on a redundancy structure. 5. The method of claim 4,
Maintaining in the repository a packet sent to the client over the TCP session; And
After the establishment of the session, if an ACK message is received from the client through the backup processor, deleting the packet held in the repository
Based fault tolerance based on a redundancy structure. delete 5. The method of claim 4,
Wherein the establishing of the session comprises:
Collecting, from the master processor, socket information used for connection with the client; And
Establishing the session between the client and the backup processor using a socket specified in the socket information
Based fault tolerant method based on a redundant structure including at least one redundant structure. 5. The method of claim 4,
Recovering the master processor
Based fault tolerance based on a redundancy structure. delete An interface unit for receiving a beating signal from a master processor for transmitting a packet to a client through a TCP session;
A processor unit for establishing a session between the client and the backup processor when detecting an abnormality with respect to the beating signal; And
Wherein the master processor and the client are connected to each other via a network,
Lt; / RTI >
The interface unit includes:
Wherein the server retransmits, to the client through the session, a packet in which an ACK message is not received from the client, among the packets transmitted to the client through the TCP session,
[0027]
And when the master processor is restored, transferring the control right from the backup processor to the master processor, thereby allowing the communication with the client connected to the master processor to be resumed through the TCP session
TCP - based fault tolerance based on redundancy structure. 14. The method of claim 13,
When the session information about the TCP session between the clients and the packet information about the packet exchanged between the clients are inputted from the master processor,
The fault-
A storage control unit for storing the session information and the packet information in a storage,
Further comprising:
The processor unit,
Replicating any one of the session information and the packet information in the repository, and establishing a session between the backup processor and the client based on the replicated information
TCP - based fault tolerance based on redundancy structure. 14. The method of claim 13,
When an abnormality is detected in the heartbeat signal of the master processor,
The fault-
A storage control unit for holding a packet in which the ACK message is not received,
Further comprising:
The interface unit includes:
After the establishment of the session, a packet that does not receive the ACK message held in the storage is retransmitted to the client through the backup processor
TCP - based fault tolerance based on redundancy structure. 14. The method of claim 13,
When packet information regarding packets exchanged between the master processor and the client is maintained in the repository,
The processor unit,
After setting up the session, a Flush message associated with the packet is processed through the backup processor to generate update packet information for the packet
TCP - based fault tolerance based on redundancy structure. 14. The method of claim 13,
The fault-
A storage controller for maintaining a packet transmitted to the client through the TCP session in a storage and deleting a packet held in the storage when an ACK message is received from the client through the backup processor after setting up the session;
Based fault tolerant device based on a redundant structure. delete 14. The method of claim 13,
The processor unit,
Collecting socket information used for connection with the client from the master processor and establishing the session between the client and the backup processor using a socket specified in the socket information
TCP - based fault tolerance based on redundancy structure. 14. The method of claim 13,
The processor unit,
The master processor
TCP - based fault tolerance based on redundancy structure. delete

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