KR100473803B1 - High speed router system for elevating reliance of IPC message transmission - Google Patents

Abstract

A high speed routing system capable of reliable IPC message transmission is disclosed. The high speed routing system according to the present invention manages an IPC board for switching an IPC message transmission path, a switch board for switching a user data transmission path, and manages the high speed router system and a routing protocol, and performs an IPC message through the IPC board. And an active routing processor board for receiving or transmitting the data, and determining whether the data received from the external network is an IPC message or user data, and transmitting the received data to the IPC board or the switch board according to the determined result. And a plurality of line card boards for receiving an IPC message transmitted from the active routing processor board through the IPC board, and may form an IPC network for transmitting an IPC message using the IPC board. Trusted, unaffected by data congestion or anomalies The IPC consists of messages sent, which may improve the ability to cope with failures of high-speed routers. In addition, through the VLAN function of the IPC board, two RP boards mounted on the high-speed router receive messages from multiple LP boards at the same time, thereby minimizing the redundant data to be transmitted between each RP board.

Description

High speed router system for elevating reliance of IPC message transmission

The present invention relates to a router system, and in particular, a high-speed router system for transmitting a reliable IPC message by forming an IPC network for transmitting a separate IPC message by using an inter-processor communication (IPC) board and a method of transmitting the IPC message thereof It is about.

In a conventional high speed router, the IPC network transmits and receives IPC messages using a switch board that exchanges user data. This simplifies the whole system because there is no need for a separate device for the IPC network, but since the user data and IPC messages use the same network resources within the high-speed router, stable IPC message transmission can be avoided if user data is congested or the switch board fails. There is an impossible problem.

In addition, for the reliability of a high-speed router system generally, two routing processor boards are used and this is called redundancy of the routing processor board. One of the two routing processor boards is an active routing processor board for processing IPC messages, and the other is a standby routing processor board in case an active routing processor behaves abnormally. In order for the standby routing processor board to replace the active router processor board, information must be shared with the active routing processor board. Such shared information is called redundant data. In the meantime, only the active routing processor board receives the IPC message, and the active routing processor board must transmit the received IPC message back to the standby routing processor. Therefore, the conventional high speed router system has a difficulty in that a high speed redundancy channel capable of transmitting a large amount of redundant data to the standby routing processor board in a short time is required for the active routing processor board to be redundant.

The first technical problem to be achieved by the present invention is to provide a high-speed router system capable of transmitting a reliable IPC message regardless of congestion of user data by building an IPC dedicated network in a high-speed router.

A second technical problem to be achieved by the present invention is to provide a recording medium recording a frame format of an IPC message transmitted in the high speed router system.

In order to achieve the first object, the fast routing system according to the present invention manages the IPC board for switching the transmission path of the IPC message, the switch board for switching the transmission path of the user data, and manages and manages the routing protocol for the fast router system. And an active routing processor board for receiving or transmitting an IPC message through the IPC board, and each of the active routing processor board determines whether data received from an external network is an IPC message or user data, and according to the determined result, the IPC board or the switch. It is preferable to include a plurality of line card boards for transmitting the received data to the board, and receiving the IPC message transmitted from the active routing processor board through the IPC board.

In order to achieve the second object, a recording medium recording an IPC message frame format according to the present invention includes a MAC address of a destination board for transmitting an IPC message, a MAC address of a destination board for receiving an IPC message, and one source board. It is desirable to include VLAN header data, IPC data, and data for error detection that configure a virtual LAN (VLAN) to simultaneously transmit IPC messages to multiple destination boards.

Hereinafter, with reference to the accompanying drawings, a high-speed router system capable of transmitting a reliable IPC message and an IPC message transmission method according to the present invention will be described as follows.

1 is a block diagram schematically showing an embodiment of a high-speed router system according to the present invention, including Routing Processor (RP) boards 10 and 11, Linecard Processor (LP) boards 12a to 12d, and an IPC board. And a switch board 14. For convenience of explanation, the RP board 10 is assumed to be an active RP board, and the RP board 11 is assumed to be a standby RP board.

Referring to FIG. 1, the active RP board 10 manages a high speed router system, and processes a routing protocol according to an IPC message related to a routing protocol transmitted from the LP boards 12a to 12d through the IPC board 13. do.

Each of the LP boards 12a to 12d includes a forwarding table for determining whether data received from an external network is an IPC message or user data. The LP boards 12a to 12d refer to the forwarding table and transmit the data to the IPC board 13 so that the data received from the external network is an IPC message to the RP boards 10 and 11. In addition, if the data received from the external network is user data is transmitted to the switch board 14 to be transmitted to the LP board (12a ~ 12d).

The IPC board 13 relays an IPC message between the RP boards 11 and 12 and the LP boards 12a to 12d, and the switch board 14 relays user data between the LP boards 12a to 12d.

At this time, each board is connected to the board matching backplane 15 through the high-speed signal connector to exchange real / hernia information, inter-board matching signal, and IPC message. All I / O ports of the IPC board 13 are connected to the board matching backplane 15 so that each board is connected to the IPC board 13 without a separate cable, and a radial IPC network centering on the IPC board 13 is provided. Can be built. In addition, an external Ethernet connection port mounted on the IPC board 13 can be used to develop an IPC message processing software by connecting to an external computer. Also, the performance of the IPC board can be connected by connecting a router tester to the external connection port. It can also be used to measure.

2 is a diagram illustrating a process in which data received from an external network is processed in the fast router system according to the present invention.

Referring to FIG. 2, data input from the external network 30 may be largely divided into user data 31 and an IPC message 34. Data input from the external network 30 is divided into user data 31 and an IPC message 34 through a network processor (NP) 32. The user data 31 is transmitted to the external network 38 through the NP 32, the switch board 33, and the output LP board 35b.

The IPC message 34 is configured in the IPC message format via the processor 35 in the LP board 35a and simultaneously transmitted to the active and standby RP boards 37a and 37b via the IPC board 36. As such, since the IPC message is simultaneously transmitted to the active and standby RP boards 37a and 37b through the IPC board 36, the active RP board 37a does not need to separately transmit the IPC message to the standby RP board 37b. Therefore, the redundant data transmitted by the active RP board 37a to the standby RP board 37b for data duplication is reduced accordingly.

3 is a block diagram showing in detail the configuration of the IPC board 36 shown in FIG.

Referring to FIG. 3, the IPC message in the Ethernet frame format reaches the PHY 22, which is the physical layer, via the backplane connection port 20 and the magnetics 21, and is connected to the Ethernet through a reduced media independent interface (RMII) bus. Passed to switch 23, this message is stored in SRAM 24, which is an Ethernet framebuffer memory.

The Ethernet switch 23 checks whether the received IPC message frame is in an error state, and reads the transmit / receive MAC address present in the header of the IPC message frame and transmits the IPC message frame to the receiving processor board. In addition, the Ethernet switch 23 reads the sending MAC address from the IPC message and updates the MAC table using the MAC address. In addition, the IPC board can be tested externally through a separate port 25. The IPC message frame format will be described with reference to FIG.

4 is a block diagram showing the configuration of a virtual LAN (VLAN) when transmitting an IPC message from the LP board to the RP board.

Referring to FIG. 4, in case of transmitting an IPC message from the LP board to the RP board, N (16 embodiments) LP boards and two redundant RP boards are used using the Port-based-VLAN function of the IPC board. N VLANs (example: 16) can be set.

VLAN 1 (46) consists of LP board 1 (42), RP board 1 (40), and RP board 2 (41), and LP board 42 includes VLAN headers for IPC data to be sent to RP boards 40 and 41. After adding to convert the frame (broadcast) of the frame, and transmits to the IPC board (49). Upon receiving the IPC message from the LP board 42, the IPC board refers to the VLAN header and the destination MAC address of the IPC message and transmits the IPC message to all ports designated by the same VLAN. This operation is generally referred to as multicasting, and the present invention implements a multicasting function in Layer 2 by using a port-based VLAN function of the IPC board 49. When sending an IPC message from the LP board 42 to the RP boards 40 and 41, as described, the VLAN binds one LP board 42 and two RP boards 40 and 41, so that The number is N (example: 16). Similarly, VLAN 16 47 is constituted by LP board 16 42b and two RP boards 40 and 41.

5 is a block diagram showing a VLAN configuration when transmitting an IPC message from the RP board to the LP board. For convenience of description, it will be described as 16 LP boards.

Referring to FIG. 5, when transmitting an IPC message from an RP board to an LP board, two VLANs may be configured for 16 LP boards and two RP boards using the port-based-VLAN function of the IPC board. VLAN 17 (46) consists of 16 LP boards 1,2,3, ..., 16 (51, 52, 53, 54) and RP board 1 (50). The RP board 50 adds a VLAN header to data to be transmitted to the 16 LP boards 51 to 54 and transmits the data to the IPC board in a broadcast form. Upon receiving the IPC message from the RP board 50, the IPC board 58 refers to the VLAN header and the destination MAC address of the IPC message and transmits the IPC message to all ports designated by the same VLAN. Since RP board 2 is excluded from VLAN 17, the IPC board does not send IPC messages sent from RP board 1 to RP board 2.

6 illustrates a frame format of an IPC message.

Referring to FIG. 6, the IPC message includes a destination MAC address DA 60, a destination MAC address 61, a TPID 62 as a tag protocol identifier, a TCI 63 indicating tag control information, and an IPC message. Data 67, FCS 68, which is an error check field. The TCI 63 representing the tag control information is composed of a Priority 64 representing a priority, a CFI 65 representing a standard Ethernet format, and a Virtual LAN Identifier (VID) 66 which is a VLAN identifier. The VLAN header TCI 63 is attached only to the IPC network, and when the IPC message goes out to the external network, the TCI 63 removes the VLAN header TCI 63.

The invention may also be embodied as computer readable code or as data on a computer readable recording medium. The computer-readable recording medium includes all kinds of recording devices in which data that can be read by a computer system is stored. Examples of computer-readable recording media include ROM, RAM, CD-ROM, magnetic tape, floppy disk, optical data storage, and the like, which are also implemented in the form of a carrier wave (for example, transmission over the Internet). It also includes. The computer readable recording medium can also be distributed over network coupled computer systems so that the computer readable code is stored and executed in a distributed fashion.

The best embodiments have been disclosed in the drawings and specification above. Although specific terms have been used herein, they are used only for the purpose of describing the present invention and are not used to limit the scope of the present invention as defined in the meaning or claims. Therefore, those skilled in the art will understand that various modifications and equivalent other embodiments are possible from this. Therefore, the true technical protection scope of the present invention will be defined by the technical spirit of the appended claims.

As described above, according to the present invention, it is possible to form an IPC network for transmitting IPC messages by using an IPC board, so that reliable IPC message transmission is performed without being affected by congestion or abnormality of user data. Can be improved. In addition, through the VLAN function of the IPC board, two RP boards mounted on the high-speed router receive messages from multiple LP boards at the same time, thereby minimizing the redundant data to be transmitted between each RP board.

1 is a block diagram schematically showing an embodiment of a fast router system according to the present invention;

2 is a diagram illustrating a process in which data received from an external network is processed in the fast router system according to the present invention.

3 is a block diagram showing in detail the configuration of the IPC board 36 shown in FIG.

4 is a block diagram showing the configuration of a virtual LAN (VLAN) when transmitting an IPC message from the LP board to the RP board.

5 is a block diagram showing a VLAN configuration when transmitting an IPC message from the RP board to the LP board.

6 illustrates a frame format of an IPC message.

Claims (8)

In a high speed router system, An IPC board for switching the transmission path of the IPC message; A switch board for switching a transmission path of user data; An active routing processor board for managing the high speed router system, processing a routing protocol, and receiving or transmitting an IPC message through the IPC board; And Each determines whether the data received from the external network is an IPC message or user data, and transmits the received data to the IPC board or the switch board according to the determined result, and through the IPC board the active routing processor A high speed routing system comprising a plurality of line card boards for receiving IPC messages sent from the board. The method of claim 1, Setting at least one standby routing processor board to replace the active routing processor board when the active routing processor board malfunctions using the port-based VLAN function of the IPC board, And the IPC board simultaneously transmits IPC messages transmitted from the plurality of line card boards to the active routing processor board and the standby routing processor board set to VLAN. The method of claim 2, The active routing processor inserts a VLAN header into the response message for the received IPC message, sets the receiving address of the response message to the MAC address of the line card board that sent the IPC message, The standby routing processors do not transmit a response message to the received IPC message. 3. The active routing processor board of claim 2, wherein the active routing processor board inserts a VLAN header in the response message for the received IPC message, and sets the receiving address of the response message to the MAC address of the line card board transmitting the IPC message. High-speed routing system. The method of claim 2, The line card board refers to the destination MAC (MAC) address of the received data to determine whether the destination is a routing processor board, And if the received data is data received from an external network, adding a VLAN header to a destination address of the received data. The method of claim 5, The line card board modifies the receiving side address into a broadcast frame and transmits it to the IPC board. And the IPC board simultaneously transmits data to routing processor boards belonging to the same VLAN by referring to a receiving header address and a VLAN header of the frame. The method of claim 1, By using the port-based VLAN function of the IPC board, one routing processor is configured with at least one line card board and a VLAN, The routing processor is a fast routing system, characterized in that for transmitting the IPC message to the line cards set to the VLAN at the same time. The method of claim 1, wherein the IPC message, A MAC address of a source board sending the IPC message; A MAC address of a destination board receiving the IPC message; VLAN header data for setting a virtual LAN (VLAN) to simultaneously transmit the IPC message from one source board to a plurality of destination boards; IPC data; And Fast routing system comprising a; data for error detection.