JP2010232996A - Packet transfer method in ethernet network constituting plural redundant routes, switch device, program, and data structure - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a packet transfer method which can constitute a plurality of redundant routes in an Ethernet network. <P>SOLUTION: A first switch device is connected to a second switch device by the plurality of redundant routes in the Ethernet network. A layer 2 packet that the first switch device should transfer to the second switch device is encapsulated in an OAM frame with an MAC address of the second switch device set as a destination MAC address, and the OAM frame packet is sent from a predetermined port connected toward the second switch device to the second switch device via the Ethernet network. The second switch device decapsulates the OAM frame from the OAM frame packet received from the first switch device, and outputs the layer 2 packet from the predetermined port. <P>COPYRIGHT: (C)2011,JPO&INPIT

Description

  The present invention relates to a packet transfer method, a switch device, a program, and a data structure in an Ethernet (registered trademark) network. In particular, the present invention relates to a technique using an operation maintenance management frame.

  As a layer 2 network for a LAN (Local Area Network), an Ethernet (registered trademark) network is widely used. The Ethernet network was developed as a LAN technology based on a bus connection type. Therefore, the plurality of layer 2 switch devices are connected in a tree shape (tree diagram shape).

  In recent years, this Ethernet technology has been applied to FTTH (Fiber To The Home), and an ultrahigh-speed layer 2 network has been constructed. Such a layer 2 network is actually operated in a telecommunications carrier network. A large number of switch devices are connected to the layer 2 network to increase the capacity of the communication network including the core network and the metro network.

  FIG. 1 is a network configuration diagram in the prior art.

  According to FIG. 1, the carrier network is constructed by an Ethernet network, and in the Ethernet network 3, a plurality of layer 2 switch devices 1 are connected in a tree shape. The terminal is connected to a layer 2 switch device as an edge switch of a communication carrier network via a LAN (Local Area Network) and an access network.

  In a telecommunications carrier network constructed with an Ethernet network, it is necessary to remotely operate, maintain, and manage connection lines (OAM: Operation Administration and Maintenance) in order to always provide stable services to subscribers. . Therefore, ITU-T Y.T. Ethernet OAM frames have been defined by 1731 or IEEE802.1ag. In particular, ITU-T Y.M. 1731 is a standard that realizes an operation and maintenance management function almost equivalent to SONET (Synchronous Optical NETwork) in the Ethernet network. The Ethernet OAM frame has functions such as reachability management (CFM: Connectivity Fault Management), error notification, link (line) performance monitor, and the like and a function for transmitting the information.

  There is also a technique for constructing a plurality of paths redundantly in order to improve fault tolerance in a network (see, for example, Patent Document 1). According to this technique, a working line and a protection line are provided, and control information for the working line is transferred to a normally unused protection line. There is also a technique for controlling traffic distribution for a plurality of routes for link aggregation (see, for example, Patent Document 2). According to this technique, traffic flows for a plurality of routes are equalized. Further, there is a technique for copying a packet to be transmitted and transmitting the same packet to a plurality of routes (see, for example, Patent Document 3). According to this technique, the delay in different paths can be reduced and the packet loss can be reduced, but the use efficiency of the network band is sacrificed.

JP 2008-104144 A JP 2006-005437 A WO2006 / 001060

Koichiro Seto, “Standardization Trend of 802.1 / 802.3 (3)”, [online], September 25, 2006, WBB Forum, [Search March 16, 2009], Internet <URL: http: //wbb.forum.impressrd.jp/report/list/29>

  However, in an Ethernet network, switch devices must be connected in a tree shape and cannot be connected in a ring shape. The switch devices are connected by one path, and if a failure occurs in any one of the paths, communication is impossible.

  The header part of the Ethernet frame does not have a TTL (Time To Live) field. For this reason, when the switch devices are connected in a ring shape, they may end up in an infinite loop. In order to deal with such problems, Resilient Packet Ring technology (IEEE 802.17-2004), Ethernet-based protection-related protocols (ITU-T G.8031, G.8032), and vendor-specific redundancy protocol technologies have been devised. Yes.

  However, in order to use such a protocol technique, it is necessary to provide a dedicated path switching device. This leads to higher costs and the problem that it cannot be used with existing Ethernet networks. Further, when one route is used as a working route and the other route is used as a backup route, the network utilization efficiency cannot be increased.

  Accordingly, an object of the present invention is to provide a packet transfer method, a switch device, a program, and a data structure that can form a plurality of redundant paths in an Ethernet network.

According to the present invention, in a packet transfer method using a layer 2 switch device capable of transmitting and receiving an operation maintenance management frame,
The first switch device and the second switch device serve as branch points in the Ethernet network and redundantly configure a plurality of paths.
For the destination MAC address and the source MAC address in the layer 2 packet, the first switch device outputs the port number of the port connected to the second switch device and the MAC address of the second switch device that is the opposite destination It has a route table that correlates addresses,
The first switch device refers to the routing table, encapsulates the layer 2 packet to be transferred to the second switch device with an operation and maintenance management header with the MAC address of the second switch device as the destination MAC address, and operates. A first step of generating a maintenance management frame packet;
A second step in which the first switch device refers to the route table and transmits an operation and maintenance management frame packet from the port of the output port number to the second switch device via the Ethernet network;
A second step in which the second switch device decapsulates the operation and maintenance management header from the operation and maintenance management frame packet received from the first switch device;
The second switch device has a fourth step of referring to the route table and outputting the decapsulated layer 2 packet from the port having the output port number.

  According to another embodiment of the packet transfer method of the present invention, the operation and maintenance management header is preferably an Ethernet OAM header.

  According to another embodiment of the packet transfer method of the present invention, the Ethernet OAM header preferably includes a sequence number and TTL (Time To Live) in a vendor-defined message (VSM) area secured by OpCode.

According to the present invention, in a layer 2 switch device capable of transmitting and receiving an operation maintenance management frame,
A plurality of paths are redundantly configured as a branch point in the Ethernet network with the opposite switch device.
A routing table in which the output port number of the port connected to the opposite destination switch device and the MAC address of the opposite destination switch device are associated with the destination MAC address and the source MAC address in the layer 2 packet;
Encapsulation that refers to the route table and encapsulates the layer 2 packet to be transferred to the opposite switch device with an operation and maintenance management header that uses the MAC address of the opposite destination switch device as the destination MAC address and generates an operation and maintenance management frame packet Means,
Decapsulating means for decapsulating the operation and maintenance management header from the operation and maintenance management frame packet received from the opposite switch device;
With reference to the route table, the layer 2 packet to be transferred to the opposite switch device is transferred to the encapsulation means, and the operation maintenance management frame packet output from the encapsulation means is output to the port of the output port number, MAC switch means for transferring an operation / maintenance management frame packet received from the opposite switch device to the decapsulating means and outputting the layer 2 packet output from the decapsulating means to the port of the output port number. And

  According to another embodiment of the layer 2 switching device of the present invention, the operation and maintenance management header is preferably an Ethernet OAM header.

  According to another embodiment of the layer 2 switching device of the present invention, the Ethernet OAM header preferably includes a sequence number and TTL in a vendor specified message (VSM) area reserved by OpCode.

According to the present invention, in a program for causing a computer mounted on a layer 2 switch device capable of transmitting and receiving an operation maintenance management frame to function,
A plurality of paths are redundantly configured as a branch point in the Ethernet network with the opposite switch device.
A routing table in which the output port number of the port connected to the opposite destination switch device and the MAC address of the opposite destination switch device are associated with the destination MAC address and the source MAC address in the layer 2 packet;
Encapsulation that refers to the route table and encapsulates the layer 2 packet to be transferred to the opposite switch device with an operation and maintenance management header that uses the MAC address of the opposite destination switch device as the destination MAC address and generates an operation and maintenance management frame packet Means,
Decapsulating means for decapsulating the operation and maintenance management header from the operation and maintenance management frame packet received from the opposite switch device;
With reference to the route table, the layer 2 packet to be transferred to the opposite switch device is transferred to the encapsulation means, and the operation maintenance management frame packet output from the encapsulation means is output to the port of the output port number, Transfer the operation / maintenance management frame packet received from the opposite switch device to the decapsulation means, and cause the computer to function as a MAC switch means for outputting the layer 2 packet output from the decapsulation means to the port of the output port number It is characterized by.

According to the present invention, for a layer 2 switch device capable of transmitting and receiving an operation / maintenance management frame, the first switch device and the second switch device serve as branch points in the Ethernet network to form a plurality of paths redundantly. A data structure of a data packet transferred to the path,
The layer 2 packet to be transferred from the first switch device to the second switch device is encapsulated with an Ethernet OAM header whose destination MAC address is the MAC address of the second switch device.
The Ethernet OAM header includes a sequence number and TTL in a vendor specified message (VSM) area secured by OpCode.

  According to the packet transfer method, switch device, program, and data structure of the present invention, a plurality of redundant paths can be configured in an Ethernet network by encapsulating a packet to be transferred with an OAM header.

It is a network block diagram in a prior art. It is a 1st network block diagram in this invention. It is a 2nd network block diagram in this invention. It is a functional block diagram of the switch apparatus in this invention. It is a frame block diagram in this invention. It is explanatory drawing showing the flow of the packet in this invention.

  Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.

  FIG. 2 is a first network configuration diagram according to the present invention.

  According to FIG. 2, in the Ethernet network 3 of the carrier network, a plurality of layer 2 switch devices 1 are connected in a tree shape. The terminal 2 is connected via the LAN 5 and the access network 4 to the layer 2 switch device 1 as an edge switch of the carrier network. Two opposing switch devices are redundantly connected by two paths.

  Further, a redundant route (child route) may be further constructed between two switch devices constructed with a redundant route (parent route). The characteristic switch device of the present invention is arranged at an opposite branch point in a redundant route.

  FIG. 3 is a second network configuration diagram according to the present invention.

  According to FIG. 3, the functional configuration of the layer 2 switch device according to the present invention is mounted on a home gateway (router). The home gateway in the present invention has two WAN side interfaces and is connected to different carrier networks. The data packet of the first application is communicated via the first carrier network, and the data packet of the second application is communicated via the second carrier network. For example, if a failure occurs in the first carrier network, the data packet can be switched to communicate via the second carrier network.

  FIG. 4 is a functional configuration diagram of the switch device according to the present invention.

  Two facing switch devices are redundantly connected by a plurality of paths in an Ethernet network. According to FIG. 4, the first path in which the port 1 of the first switch device and the port 1 of the second switch device are connected, the port 2 of the first switch device and the port of the second switch device 2 and a second path connected to each other. The port 3 of the first switch device is connected to the first terminal via the first LAN, and the port 3 of the second switch device is connected to the second terminal via the second LAN. Is done.

  The switch device 1 includes a plurality of ports 10, a MAC (Media Access Control) switch unit 11, a route table 12, an OAM frame encapsulation unit 13, and an OAM frame decapsulation unit 14. These functional components other than the port are realized by executing a program that causes a computer mounted on the switch device to function.

  The routing table 12 includes the “output port number” of the port connected to the opposite destination switch device and the “MAC address of the opposite destination switch device” for the “destination MAC address” and “source MAC address” in the user packet Are associated with each other. According to this route table 12, since the “output port number” is uniquely determined by the “destination MAC address” and “source MAC address” of the data packet, the route is also determined. When a failure occurs in a route that is in use, the route can be switched by simply switching the “output port number” in the route table 12. It should be noted that the control policy of “whether or not a route is switched when a condition occurs” and “which route is selected when a condition” is assumed by the present invention. Absent.

  The OAM frame encapsulation unit 13 inputs a layer 2 packet to be transferred from the MAC switch unit 11 to the opposite switch device. The OAM frame encapsulation unit 13 refers to the route table 12 and encapsulates the layer 2 packet to be transferred to the opposite destination switch device with an OAM header having the “MAC address of the opposite destination switch device” as the destination MAC address, and OAM. Generate a frame packet. The OAM frame packet is output to the MAC switch unit 11.

  The OAM frame decapsulation unit 14 inputs the layer 2 packet received from the opposite switch device from the MAC switch unit 11. The OAM frame decapsulation unit 14 decapsulates the OAM header from the OAM frame packet. The decapsulated layer 2 packet is output to the MAC switch unit 11.

  Assume that the MAC switch unit 11 receives a layer 2 packet to be transferred to the opposite switch device from the port. At this time, the route table 12 is referred to items corresponding to the “destination MAC address” and “source MAC address” of the layer 2 packet. Here, if “the MAC address of the opposite switch device” is registered, it is determined that a plurality of redundant paths are set. In this case, the MAC switch unit 11 outputs the layer 2 packet to the encapsulation unit 13.

  On the other hand, the MAC switch unit 11 inputs an OAM frame packet from the encapsulation unit 13. At this time, with respect to the route table 12, “output port number” corresponding to “destination MAC address” and “source MAC address” of the user packet portion of the OAM frame packet is referred to. Then, the MAC switch unit 11 outputs the OAM frame packet to the port having the output port number.

  Assume that the MAC switch unit 11 receives an OAM frame packet received from the opposite switch device from a port. At this time, when the “destination MAC address” of the OAM header is the MAC address of the switch device, the MAC switch unit 11 outputs the OAM frame packet to the decapsulation unit 14.

  On the other hand, the MAC switch unit 11 inputs a layer 2 packet from the decapsulation unit 14. At this time, the “output port number” corresponding to the “destination MAC address” and “source MAC address” of the layer 2 packet is referred to for the route table 12. Then, the MAC switch unit 11 outputs the layer 2 packet to the port having the output port number.

  FIG. 5 is a frame configuration diagram in the present invention.

  FIG. 5A shows an Ethernet frame. The header of the Ethernet frame includes a destination MAC address, a transmission source MAC address, and a Type code. The MAC address is a 48-bit identification number that is unique to the layer 2 switch device or the network interface card that is the target of operation and maintenance management. The layer 2 switch device has one device MAC address (CPU-MAC address) that identifies the device itself. The Ethernet frame transmitted from the terminal is received by the layer 2 switch device.

  FIG. 1731 is a standard Ethernet OAM frame specified by 1731. The Ethernet OAM frame includes a destination MAC address, a transmission source MAC address, an Ethernet OAM TLV (Type Length Value), and an FCS (Frame Check Sequence).

  According to FIG.5 (b), VLAN (Virtual LAN) is designated as Type and a VLAN tag is included. A VLAN is a group that is virtually configured independently of a virtual connection form. It is preferable to attach different VLAN tags to the first route and the second route in the Ethernet network. However, when the first route and the second route are via different Ethernet networks in completely different carrier networks, the same VLAN tag may be used.

  Further, according to FIG. 5B, EtherOAM is specified as Type, and specific fields are specified by OpCode.

  FIG. 5C shows an Ethernet OAM frame extended according to the present invention. By describing 0x33 in the OpCode field, it is defined as a VSM (Vender Specific Message) frame. This allows subsequent fields to be extended independently. For the existing Ethernet switch, the transfer is controlled by the outermost destination MAC address without changing from the normal frame processing process. Also, the Ethernet switch refers to the EtherType field “0x8902” and the OpCode field, and if it determines that the process on its own switch is not necessary, it will transfer transparently, so it is compatible with sending and transferring frames to the existing Ethernet network. Have sex.

  FIG. 6 is an explanatory diagram showing a packet flow in the present invention.

  According to FIG. 6, the transmission source terminal transmits packet 1 to destination terminal A, and transmits packet 2 and packet 3 to destination terminal B. The packet 1 includes a destination MAC address [00: A0: 12: 19: 8E: 10] indicating the destination terminal A, and a source MAC address [50: 7B: 66: 34: 5E: 20] indicating the source terminal. including. The packet 2 and the packet 3 include a destination MAC address [00: A0: 12: 19: 8E: 11] indicating the destination terminal B and a source MAC address [50: 7B: 66: 34: 5E: indicating the source terminal. 20].

  The layer 2 switch device 1 receives the packets 1 to 3 from the port 2 on the LAN side. The layer 2 switch device 1 refers to the routing table, includes the MAC address [20: 4A: 32: 22: 6B: 40] of the destination switch device in the destination MAC address of the OAM header of the packet 1, and the source MAC address Includes the MAC address [20: 53: 28: 7B: 3A: 60] of the transmission source switch device. Then, the packet 1 with the OAM header added is output from the port 1.

  Further, the layer 2 switch device 1 refers to the route table, includes the MAC address [20: 4A: 32: 22: 6B: 40] of the destination switch device in the destination MAC address of the OAM header of the packet 2, and the source The MAC address [20: 53: 28: 7B: 3A: 60] of the transmission source switch device is included in the MAC address. Then, the packet 2 with the OAM header added is output from the port 2.

  Further, the layer 2 switching device 1 refers to the route table and outputs the packet 3 to which the OAM header is added from the port 2 in the same manner as the packet 2.

  Thereby, the packets 1 to 3 are transferred from the transmission source switch device to the destination switch device via the two paths. The destination switch device removes the OAM header from the received packets 1 to 3, refers to the route table, and outputs these packets 1 to 3 from a predetermined port.

  As described above in detail, according to the packet transfer method, the switch device, the program, and the data structure of the present invention, by encapsulating the packet to be transferred with the OAM header, a loop does not occur in the Ethernet network. A plurality of redundant paths can be configured.

  According to the present invention, it is not necessary to provide a dedicated path switching device, and a plurality of paths can be configured redundantly at low cost on an Ethernet network. In addition, since a plurality of routes can be used normally without being distinguished between the working route and the backup route, it is not necessary to secure useless backup routes. According to the present invention, there is no influence on the existing switch device arranged in the Ethernet network.

  Furthermore, according to the present invention, it can be applied to the standard of the Ethernet network, regardless of the bandwidth and media in a plurality of paths. For example, one path may be ADSL (Asymmetric Digital Subscriber Line) and the other path may be PON (Passive Optical Network). Also, one route may be a wired network and the other route may be a radio access network. That is, as long as it conforms to the Ethernet network standard, a plurality of paths can be configured redundantly.

  The packet transfer method of the present invention can be applied to high reliability in an existing Ethernet network, particularly a private network for enterprises.

  Various changes, modifications, and omissions of the above-described various embodiments of the present invention can be easily made by those skilled in the art. The above description is merely an example, and is not intended to be restrictive. The invention is limited only as defined in the following claims and the equivalents thereto.

DESCRIPTION OF SYMBOLS 1 Switch apparatus, layer 2 switch apparatus 10 Port 11 MAC switch part 12 Routing table 13 OAM frame encapsulation part 14 OAM frame decapsulation part 2 Terminal 3 Ethernet network 4 Access network 5 LAN

Claims (8)

In a packet transfer method using a layer 2 switch device capable of transmitting and receiving an operation and maintenance management frame,
The first switch device and the second switch device serve as branch points in the Ethernet network and redundantly configure a plurality of paths.
For the destination MAC address and the source MAC address in the layer 2 packet, the first switch device outputs the port number of the port connected to the second switch device and the MAC address of the second switch device that is the opposite destination It has a route table that correlates addresses,
The first switch device refers to the route table, encapsulates the layer 2 packet to be transferred to the second switch device with an operation and maintenance management header with the MAC address of the second switch device as the destination MAC address, A first step of generating an operation and maintenance management frame packet;
A first step in which the first switch device refers to the route table and transmits the operation and maintenance management frame packet from the port of the output port number to the second switch device via the Ethernet network;
A third step in which a second switch device decapsulates the operation and maintenance management header from the operation and maintenance management frame packet received from the first switch device;
A packet transfer method comprising: a fourth step in which the second switch device refers to the route table and outputs the decapsulated layer 2 packet from the port of the output port number.   The packet transfer method according to claim 1, wherein the operation maintenance management header is an Ethernet OAM (Operation Administration and Maintenance) header.   3. The packet transfer method according to claim 2, wherein the Ethernet OAM header includes a sequence number and TTL (Time To Live) in a vendor specified message (VSM) area secured by OpCode. In a layer 2 switch device capable of transmitting and receiving an operation and maintenance management frame,
A plurality of paths are configured redundantly as a branch point in the Ethernet network with the opposite switch device,
A routing table in which the output port number of the port connected to the opposite destination switch device and the MAC address of the opposite destination switch device are associated with the destination MAC address and the source MAC address in the layer 2 packet;
A capsule that refers to the path table and encapsulates a layer 2 packet to be transferred to the opposite switch device with an operation and maintenance management header with the MAC address of the opposite switch device as the destination MAC address, and generates an operation and maintenance management frame packet And
Decapsulating means for decapsulating the operation and maintenance management header from the operation and maintenance management frame packet received from the opposite switch device;
Referring to the route table, the layer 2 packet to be transferred to the opposite switch device is transferred to the encapsulation unit, and the operation maintenance management frame packet output from the encapsulation unit is transferred to the port of the output port number. MAC that outputs the operation / maintenance management frame packet received from the opposite switch device to the decapsulating unit and outputs the layer 2 packet output from the decapsulating unit to the port of the output port number A layer 2 switch device comprising switch means.   The layer 2 switch device according to claim 4, wherein the operation and maintenance management header is an Ethernet OAM header.   6. The layer 2 switching apparatus according to claim 5, wherein the Ethernet OAM header includes a sequence number and TTL (Time To Live) in a vendor-defined message (VSM) area secured by OpCode. In a program for causing a computer mounted on a layer 2 switch device capable of transmitting and receiving an operation and maintenance management frame to function,
A plurality of paths are configured redundantly as a branch point in the Ethernet network with the opposite switch device,
A routing table in which the output port number of the port connected to the opposite destination switch device and the MAC address of the opposite destination switch device are associated with the destination MAC address and the source MAC address in the layer 2 packet;
A capsule that refers to the path table and encapsulates a layer 2 packet to be transferred to the opposite switch device with an operation and maintenance management header with the MAC address of the opposite switch device as the destination MAC address, and generates an operation and maintenance management frame packet And
Decapsulating means for decapsulating the operation and maintenance management header from the operation and maintenance management frame packet received from the opposite switch device;
Referring to the route table, the layer 2 packet to be transferred to the opposite switch device is transferred to the encapsulation unit, and the operation maintenance management frame packet output from the encapsulation unit is transferred to the port of the output port number. MAC that outputs the operation / maintenance management frame packet received from the opposite switch device to the decapsulating unit and outputs the layer 2 packet output from the decapsulating unit to the port of the output port number A program for a layer 2 switch device, which causes a computer to function as switch means. Regarding the layer 2 switch device capable of transmitting and receiving an operation and maintenance management frame, the first switch device and the second switch device form a plurality of paths redundantly as branch points in the Ethernet network. The data structure of the data packet transferred to
The layer 2 packet to be transferred from the first switch device to the second switch device is encapsulated with an Ethernet OAM header whose destination MAC address is the MAC address of the second switch device.
The Ethernet OAM header includes a sequence number and a TTL in a vendor-defined message (VSM) area secured by OpCode.

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