KR100501320B1 - method for recovery of CR-LSP in Multi Protocol Label Switching system - Google Patents

Abstract

According to the present invention, there is provided a method for restoring a CR-LSP (Constraint-based routing Label switched Path) in a multi-protocol label exchange system. The method includes: storing link-related information of the CR-LSP in a database; In the event of a failure or system restart, recording the fact that the CR-LSP is down in the database, and periodically checking whether an LDP session is established for each link for the downlink CR-LSP link. Checking the link, and if there is a link in which the LDP session is established as a result of the inspection, retrieving link setting information for the corresponding link from the database, and checking the released link according to the link setting related information of the retrieved CR-LSP. Follow the steps to reset.

According to the present invention, when recovering after a link failure, the system recognizes the recovery and resets the CR-LSP without the operator's intervention, so that the CR-LSP can be easily managed even at night when it is difficult for the operator to monitor the system.

Description

Method for recovery of CR-LSP in Multi Protocol Label Switching system

The present invention relates to a method of restoring a contract-based routing label switched path (CR-LSP) in a multi-protocol label switching (MPLS) system. Specifically, the MPLS system is restarted or linked. The present invention relates to a method for restoring a CR-LSP that was previously set in a restoration after a temporary failure of the system.

Constraint-based routing method is a routing method by explicit protocol (designated path, bandwidth, etc.).

1 is a block diagram illustrating a general MPLS system. Referring to FIG. 1, the MPLS system is unconfigured due to a network engineering due to a traffic engineering unit (hereinafter referred to as TE) 1 for controlling the setting and release of the CR-LSP and a system restart or a link disconnection. CR-LDP (2) for resetting the CR-LSP, and a forwarding engine (3) for receiving the CR-LSP ID information and FEC information from the TE (1) for data transmission .

TE (1) can select an explicit path in consideration of traffic information and network resources through the constraint-based routing method.

CR-LDP (2) is an abbreviation of Constraint Routed (or Based) Label Distribution Protocol. It is a signaling protocol for distributing labels to set up a route according to an explicit protocol. The CR-LDP (2) can perform alternative route setting for network recovery. .

FEC stands for Fowarding Equivalence Class and represents a group of destination addresses with the same route.

When MPLS technology is expected to be adopted in most backbone networks in the future, the support of network recovery function in MPLS network is expected to be a very important issue for vendors developing MPLS LER / LSR. Here, LER is an abbreviation of Label Edge Router, which is located at the boundary of the MPLS network and refers to the starting point and end point of the path using MPLS, and LSR is an abbreviation of Label Switch Router, which is an intermediate node located on the MPLS path between LERs.

As the traffic and services using the Internet increased since the late 1990s, the network became a public network rather than a simple data network. Accordingly, the network recovery function became the main operation factor from the viewpoint of the operator who operates the network. In particular, CR-LSP, a connection-oriented network service that guarantees higher quality of service than the best IP (Internet Protocol) service, which is a connectionless network service, should be maintained at all times until a service interruption request is made.

However, if a Label Edge Router (LER) with CR-LSP is required to restart due to system failure or other reasons, or the LSR between the Ingress LER as the entry point of service traffic and the Egress LER as the exit The connection is broken when the link between them is broken. If the system or link is restored afterwards, the CR-LSP must be set again.

However, manually resetting many of the CR-LSPs that have already been set up is not easy and is likely to miss settings. In addition, the recovery method after link disconnection is extremely limited, so even if the link is restored, the operator may not recognize it, so the CR-LSP reset may not be performed until a complaint occurs.

These problems require the ability to reset the CR-LSP during system restart or recovery after a link failure. When MPLS technology is expected to be adopted for most network equipments in the future, whether the MPLS network supports the CR-LSP reset function will be an important consideration for the equipment introduction to the ISP (Internet Service Provider) who adopts and operates the equipment. It is expected.

CR-LSP, which is set up using CR-LDP, maintains its connection by a session maintained by LDP. There are two reasons why the CR-LSP that was established even though this LDP session was not requested by the Ingress LER was released. First, there is a problem with the LER system that sets up the CR-LSP. In this case, the physical link for which the CR-LSP is set is disconnected so that no data flows physically, and the session for setting the CR-LSP, which has been set because the LDP session hold timer expires, ends. In the case of the LSP set by the LDP, the LSP is set based on the FEC information transmitted by the routing protocol. Therefore, even if the system is restarted or the link is temporarily recovered after disconnection, the LSP can be set again with reference to the routing entry. However, in case of CR-LSP set by CR-LDP, CR-LSP is set using Explicit Route, so that CR-LDP can reset CR-LSP that was set by itself even if system or link is restored. There is no function. Therefore, in order to set the CR-LSP, the CR-LSP setting must be triggered by some external means.

In general, the CR-LSP is manually set by the operator. After the failure, the CR-LSP can be reset only after receiving information from the system. However, if the operator turns off the CR-LSP setting from the system console and the situation is recovered, but it is not recognized and cannot reset the CR-LSP, the subscriber who used the CR-LSP until the CR-LSP is reset again. There is a problem that they do not receive services.

The present invention has been made to solve such a conventional problem, and when the system is restarted, the CR-LSP that is previously set, and the CR-LSP which is released due to a network failure such as link disconnection, fails over. It is an object of the present invention to provide a recovery method that can be reset immediately without a separate operator operation.

CR-LSP recovery method in a multi-protocol label exchange system according to the present invention for achieving this object, storing the link-related information of the CR-LSP in the database, and any CR-LSP link failure occurs Recording the fact that the CR-LSP is down when the system restart or the system restart occurs in the database, and periodically checking whether an LDP session is established for each link for the downlink CR-LSP link. And if there is a link in which the LDP session is established as a result of the checking, detecting link setting information for the link from the database, and resetting the released link according to the link setting related information of the detected CR-LSP. Perform the steps.

Hereinafter, with reference to the accompanying drawings to describe the present invention.

In the present invention, the information of the CR-LSP set by the CR-LDP (2) is stored in its own database in the TE (1), and whenever information change occurs in the corresponding CR-LSP link, information about the CR-LSP is displayed. In case of changing and saving, restoring the link or restarting the system, the CR-LSP link is restored by referring to the CR-LSP information stored in the database.

In this case, the link setting related information of the CR-LSP stored in the database of the TE 1 may include at least one of the ID, the subscriber information key, and the path information key information of the CR-LSP.

First, the procedure of setting the CR-LSP in the MPLS system will be described with reference to FIG. 2.

First, the operator checks whether an LDP session is established with a peer 4 of the system he wants to manage, and uses an index key that can refer to information of a registered subscriber in advance. This will require the system to set up a CR-LSP.

The TE (1) determines whether there is a request for such a CR-LSP setting from the operator (S1), and if there is a request for setting the CR-LSP from the operator, referring to the index key of the received subscriber information, the relevant FEC Then, the information needed by the CR-LDP 2 is extracted and transferred to the CR-LDP 2 to make a CR-LSP setting request (S2).

Accordingly, the CR-LDP 2 sends a label request message to its peer 4 with reference to the LDP session information, and sends a label request message to the TE 1. Inform the dispatcher (S3).

On the other hand, CR-LDP (2) receives the label mapping (Label Mapping) for the label request from its peer (4) (S4) and delivers the channel information for the set CR-LSP to the FE (3) ( S5) An LDP setting event for notifying that the label mapping message has been received is transmitted to TE (1) (S6).

Upon receiving the LDP setting event from the CR-LDP 2, the TE 1 transfers the FEC information for the set CR-LSP to the FE 3 (S7).

TE (1) and CR-LDP (2) maintain independent processes. Event transmission and information transfer between both functional blocks is done through IPC (Inter Process Communication) interface.

 Data name Explanation  FEC  FEC information for CR-LSP  ErHop-List  Node information constituting CR-LSP  T_SPEC  TE parameters carried by the CR-LDP  ATM_Traff  ATM TE Parameters Applied to CR-LSP  Preemp  CR-LSP preemption function  CRLSPID  ID information of the set CR-LSP

Table 1 describes the IPC messages between TE (1) and CR-LDP (2). As such, the interface between the traffic engineering unit 1 and the forwarding engine unit 3 uses an API provided by the resource manager. Arguments passed to the API include FEC information for the CR-LSP, node information constituting the CR-LSP, TE parameters passed by the CR-LDP, ATM TE parameters applied to the CR-LSP, as described in Table 1, It may be a CR-LSP preemption function or ID information of the set CR-LSP.

In general, to release the set CR-LSP, the request of the operator is required. If the set CR-LSP is released in the absence of the operator's request, this is the release of the CR-LSP that occurred in an abnormal situation. The restored CR-LSP must be restored.

3 shows a procedure for restoring a CR-LSP released due to a link failure according to the present invention.

First, TE 1 receives an event from the CR-LDP 2 that any CR-LSP is released due to a link failure (S11). Such an event is called a link down event.

The TE (1) receiving the link down event searches for its own DB that manages CR-LSP information (S12). It is determined whether the corresponding CR-LSP exists in the DB (S13), and if there is the corresponding information, the record indicates that the corresponding CR-LSP is down, and then deletes the FEC information for the corresponding CR-LSP from the forwarding engine unit 3. (S14).

On the other hand, when the link is restored, the CR-LDP 2 checks whether the LDP session is reestablished and informs the TE (1) that the link has lived again when the LDP session is established (S15). This is called an LDP Session Up event.

Upon receiving the LDP session up event, the TE 1 checks the state of the corresponding CR-LSP in the DB and performs a procedure for setting the CR-LSP as shown in FIG. 2 (S16).

4 shows a procedure for restoring a CR-LSP upon system restart according to the present invention.

After system restart, the CR-LDP (2) checks whether or not an LDP session is established for each link (S21) to determine whether an LDP session is established (S22). 1) (S23).

Upon receiving the LDP session up event, the TE 1 searches its DB to retrieve information of a previously set CR-LSP (S24).

It is determined whether the previously set CR-LSP information is searched (S25), and if found, the procedure for CR-LSP setting as shown in FIG. 2 is performed (S26).

According to the present invention, when recovering after a link failure, the system recognizes the recovery and resets the CR-LSP without the operator's intervention, so that the CR-LSP can be easily managed even at night when it is difficult for the operator to monitor the system.

In addition, the system automatically resets the previously set CR-LSP after the system restart, thereby reducing the effort of manually setting all the CR-LSPs.

1 is a configuration block diagram of a typical MPLS system.

2 is a procedure of setting a CR-LSP in the MPLS system.

3 is a flowchart illustrating a procedure for recovering a CR-LSP released due to a link failure according to the present invention.

4 is a flowchart illustrating a procedure for restoring a CR-LSP upon system restart according to the present invention.

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

1: Traffic Engineering Department (TE) 2: CR-LDP Department

30: forwarding engine unit (FE)

Claims (3)

In the CR-LSP recovery method in a multi-protocol label exchange system comprising a traffic engineering unit for controlling the setting and release of the CR-LSP, and a CR-LDP unit for resetting the CR-LSP which has been released. Storing link setting information of the CR-LSP in a database; Recording down to the database the fact that the CR-LSP is down when any CR-LSP link fails or the system restart occurs; Periodically checking whether an LDP session is established for each link of the downlink CR-LSP link; If there is a link for which an LDP session is established as a result of the checking, detecting link setting information for the link from the database; And resetting the link according to the detected link establishment related information of the CR-LSP. The method of claim 1, wherein the storing step A method for recovering a CR-LSP in a multi-protocol label switching system comprising storing link setting related information of the CR-LSP including at least one of an ID, a subscriber information key, and route information key information of the CR-LSP. The method of claim 1 or 2, wherein the database, CR-LSP recovery method in a multi-protocol label exchange system, characterized in that located in the traffic engineering.