JP5733473B2 - Interworking apparatus, method, and program - Google Patents

Description

  The present invention relates to interworking between a MAC (Media Access Control) -in-MAC network and a VPLS (Virtual Private LAN Service) network.

  In recent years, in a data center, a corporate network, etc., use of a wide area Ethernet service that enables transmission and reception of Ethernet (registered trademark) frames between LANs at remote bases has been advanced.

  U.S. Patent No. 6,099,077 discloses a hierarchical framing technique that allows a network architecture to recognize a local area network hierarchy within the network. In the technique, a first local area network hierarchy is defined by communication in a first frame format between a first set of network devices and a second set of network devices. The second local area network hierarchy is defined by communication in a second frame format between members of the second set of network devices. The second frame format includes all fields of a frame of the first frame format used for communication between the first set of communication devices and the second set of communication devices.

  Patent Document 2 discloses a network including a plurality of MPLS networks and an Ethernet network interconnected by an Ethernet network. In such a network, the Ethernet network provides a plurality of paths established to interconnect pairs of MPLS networks. An Ethernet encapsulated LSP (Label Switched Path) frame received from one of the MPLS networks at the entrance to the Ethernet network is mapped to a path at the entrance to the Ethernet network according to the classification identifier associated with the Ethernet encapsulated LSP frame. The

  Patent Document 3 discloses a method for enabling a nomadic terminal to access a home network on the layer 2 level. The method comprises the steps of connecting the terminal to a remote access network via an access point, and connecting the remote access network to an operator backbone network via a remote access router. . In order to authenticate the terminal to the authentication server, signaling is exchanged between the access point and the authentication server in the backbone network. After successful authentication, a layer 2 tunnel across the backbone network is established to connect the terminal to the home network.

JP 2005-533445 A Special table 2010-517382 gazette Special table 2010-538554

  In the conventional wide area Ethernet, the high load of the core network LAN switch is regarded as a problem. For example, in order to transmit and receive frames between user bases, the LAN switch in the core network needs to learn the MAC addresses of all terminals at all bases. For this reason, the number of registered MAC addresses becomes enormous, and the load in address search increases.

  Typical techniques for solving such problems include an L2 switch-based MAC-in-MAC technique and an MPLS (Multi-Protocol Label Switching) router-based VPLS technique.

  As the MAC-in-MAC technology, for example, PBB (IEEE802.ah Provider Backbone Bridges), EoE (Ethernet over Ethernet (registered trademark)), and the like are often used. FIG. 7 illustrates a general MAC-in-MAC network 101. The relay apparatus (provider) 102 can conceal the MAC address of the user terminal 103 by encapsulating the packet from the user terminal 103 with the provider MAC frame. Thereby, the wide area Ethernet service can be provided without imposing an excessive load on the relay apparatus 102.

  In the VPLS technique, a user MAC frame is encapsulated with an MPLS frame and transferred. Therefore, the relay apparatus can transfer a frame with low load and high efficiency without being aware of the MAC address of the user terminal.

  The VPLS technology has an advantage of having a traffic management function, a high-speed failure recovery function, and the like compared to the MAC-in-MAC technology. For example, the traffic management function makes it possible to provide a guaranteed bandwidth service that cannot be supported by the MAC-in-MAC technology. The high-speed failure recovery function realizes further improvement in network quality.

  Due to such advantages of the VPLS technology, in recent years, there is an increasing demand for replacing a MAC-in-MAC network with a VPLS network. However, it is usually difficult to rapidly replace an operating MAC-in-MAC network with a VPLS network. Therefore, a migration scenario is important in which the MAC-in-MAC network that has been operated so far is interconnected with the VPLS network, and both networks are gradually replaced while being used flexibly like a single network.

  FIG. 8 illustrates a communication network 111 that is generally considered when interconnecting the MAC-in-MAC network 112 and the VPLS network 113. In the communication network 111 according to this example, there is no interwork apparatus between both networks 112 and 113, and a MAC-in-MAC apparatus 121 and a VPLS apparatus which are UNI (User Network Interface) of both networks 112 and 113. 131 is connected. The MAC-in-MAC device 121 and the VPLS device 131 perform interworking between the networks 112 and 113.

  For example, when the Ethernet frame 141 is transmitted from the MAC terminal 125 to the VPLS terminal 135, the MAC-in-MAC device 122 connected to the MAC terminal 125 encapsulates the Ethernet frame 141 into the MAC frame 142 and performs the above interworking. To the MAC-in-MAC device 121.

  Upon receiving the MAC frame 142, the MAC-in-MAC device 121 receives the provider MAC address (B-SA) indicating the MAC address of the source provider (MAC-in-MAC device 122) and the source MAC terminal 125. The terminal MAC address (C-SA) indicating the MAC address is learned. Thereafter, the MAC-in-MAC device 121 extracts the internal Ethernet frame 143, generates a VPLS frame 144, and transmits the VPLS frame 144 to the interworking VPLS device 131.

  When the Ethernet frame 145 is transmitted from the VPLS terminal 135 to the MAC terminal 125, the MAC-in-MAC device 121 transmits the MAC address of the transmission source VPLS terminal 135 included in the Ethernet frame 143 inside the VPLS frame 144. C-SA indicating Further, the MAC-in-MAC device 121 encapsulates the provider MAC address B-DA of the provider (MAC-in-MAC device 122) corresponding to C-DA indicating the MAC address of the destination MAC terminal 125 to obtain the MAC. A frame 142 is generated and transmitted to the MAC-in-MAC network 112.

  As described above, in the communication network 111 as shown in FIG. 8, the MAC-in-MAC device 121 and the VPLS device 131 that are arranged between the MAC-in-MAC network 112 and the VPLS network 113 and perform interworking are provided. It is necessary to learn the MAC addresses of all the terminals 125 and 135. Therefore, there is a concern that the number of MAC addresses registered in the MAC-in-MAC device 121 and the VPLS device 131 becomes enormous and the load in address search becomes large.

  Therefore, an object of the present invention is to reduce a load for learning a MAC address of a terminal in interworking between a MAC-in-MAC network and a VPLS network.

  According to a first aspect of the present invention, there is provided a MAC processing unit that transmits / receives a MAC frame to / from a MAC-in-MAC network, a label processing unit that transmits / receives a VPLS frame to / from a VPLS network, and the MAC-in- A provider MAC address indicating an address of a provider connected to a MAC terminal in the MAC network, a virtual provider MAC address indicating an address of a virtual provider connected to the provider in the MAC-in-MAC network, and a path identifier in the VPLS network Included in the received MAC frame with reference to the conversion table when the MAC frame is received from the MAC processing unit. The conversion table is detected when the path identifier corresponding to the provider MAC address of the source is detected, the VPLS frame is generated based on the detected path identifier, and the VPLS frame is received from the label processing means. The provider MAC address and the virtual provider address corresponding to the path identifier included in the received VPLS frame are detected, and the MAC frame is generated based on the detected provider MAC address and virtual provider address. It is an interworking apparatus provided with the frame conversion means to do.

  The second aspect of the present invention provides a MAC processing means for transmitting / receiving a MAC frame to / from a MAC-in-MAC network, a label processing means for transmitting / receiving a VPLS frame to / from a VPLS network, and the MAC- a conversion table holding means for holding a conversion table prepared in advance for associating a virtual provider MAC address indicating a virtual provider address in an in-MAC network with a path identifier in the VPLS network; and the MAC frame from the MAC processing means. When received, a MAC learning table that associates a terminal MAC address indicating the address of the MAC terminal included in the received MAC frame with a provider MAC address indicating the address of the provider connected to the MAC terminal is generated. When the MAC frame including the virtual provider MAC address as the destination provider MAC address is received from the AC address learning unit and the MAC processing unit, the conversion table is referenced to correspond to the virtual provider MAC address. When a path identifier is detected, the VPLS frame is generated based on the detected path identifier, and the VPLS frame is received from the label processing means, it is included in the received VPLS frame with reference to the conversion table And detecting the provider MAC address corresponding to the destination MAC address of the transmission destination included in the received VPLS frame with reference to the MAC learning table. The concerned An interworking unit and a frame conversion means for generating the MAC frame based on the issued virtual provider MAC address and provider MAC address.

  Another aspect of the present invention is a method and a program based on the same technical idea as the first or second aspect.

  ADVANTAGE OF THE INVENTION According to this invention, the load for learning the MAC address of a terminal can be reduced in the interworking between a MAC-in-MAC network and a VPLS network.

It is a figure which shows the structure of the interworking apparatus which concerns on Embodiment 1 of this invention. 1 is a diagram illustrating a communication network in which a MAC-in-MAC network and a VPLS network are interconnected and an interworking apparatus according to Embodiment 1 is applied. FIG. 6 is a diagram illustrating a conversion table according to Embodiment 1. FIG. It is a figure which shows the structure of the interworking apparatus which concerns on Embodiment 2 of this invention. It is a figure which illustrates the communication network with which the MAC-in-MAC network and the VPLS network were mutually connected and the interworking apparatus which concerns on Embodiment 2 was applied. It is a figure which illustrates the conversion table and MAC learning table which concern on Embodiment 2. It is a figure which illustrates the general structure of a MAC-in-MAC network. 1 is a diagram illustrating a general configuration of a communication network in which a MAC-in-MAC network and a VPLS network are interconnected. FIG.

Embodiment 1
Embodiments of the present invention will be described below with reference to the drawings. FIG. 1 shows a configuration of an interworking apparatus 1 according to Embodiment 1 of the present invention. FIG. 2 illustrates a communication system to which the interworking apparatus 1 is applied.

  The interworking device 1 in the communication system includes the MAC-in-MAC devices 21 and 22 and the VPLS network 12 so that all the MAC-in-MAC devices 21 and 22 and all the VPLS devices 26 are connected in a full mesh. Virtual provider MAC addresses C1 and C2 that connect the path identifiers 1001 and 1002 are set.

  The interworking apparatus 1 includes a MAC processing unit 2, a level processing unit 3, a conversion table holding unit 4, and a frame conversion unit 5. Each of these functional units 2 to 5 includes a computer including a central processing unit, a storage device, an input / output device, a program for controlling the computer, various databases used for the control, and a logic configured by a combination of various semiconductor devices. This is realized by cooperation of a circuit or the like.

  The MAC processing unit 2 is an interface that transmits and receives MAC frames to and from the MAC-in-MAC network 11. The MAC processing unit 2 determines whether or not the MAC frame received from the MAC-in-MAC network 11 is to be processed by itself. When the MAC processing unit 2 determines that the received MAC frame is to be processed by itself, the MAC processing unit 2 transfers the MAC frame to the frame conversion unit 5, and when it determines that the received MAC frame is not to be processed, Discard the frame. The case where it is determined that it should be processed by itself is, for example, that the destination provider MAC address (B-DA) included in the received MAC frame is included in the list of virtual provider MAC addresses handled by the own device. This is the case. If the B-DA is a broadcast address, a multicast address, etc., transfer or discard is performed according to the network operation policy.

  The level processing unit 3 is an interface that transmits and receives VPLS frames to and from the VPLS network 12. Similarly to the MAC processing unit 2, the level processing unit 3 also receives the received VPLS frame based on whether or not the path identifier included in the received VPLS frame is included in the list of path identifiers handled by the own device. It is determined whether or not it should be processed by itself.

  The conversion table holding unit 4 includes a provider MAC address (A, B) indicating the addresses of the MAC-in-MAC devices 21 and 22 connected to the MAC terminals 31 and 32 in the MAC-in-MAC network 11, and MAC-in- A conversion table prepared in advance that associates virtual provider addresses (C1, C2) indicating the addresses of virtual providers in the MAC network 11 with path identifiers in the VPLS network 12 is held.

  FIG. 3 illustrates the conversion tables 41 and 42. The first conversion table 41 is a table used when data is transmitted from the MAC terminals 31 and 32 connected to the MAC-in-MAC network 11 to the VPLS terminal 36 connected to the VPLS network 12. Conversely, the second conversion table 42 is a table used when data is transmitted from the VPLS terminal 36 to the MAC terminals 31 and 32.

  In the first conversion table 41, B-SA is a source provider MAC address (A, B) in the MAC-in-MAC network 11, and B-DA is a destination virtual provider MAC address (C1, C1). C2). In the second conversion table 42, B-DA is a destination provider MAC address (A, B), and B-SA is a source virtual provider MAC address (C1, C2).

  When the frame conversion unit 5 receives the MAC frame 52 from the MAC processing unit 2, the frame conversion unit 5 refers to the first conversion table 41 and transmits the provider MAC address B-SA (A of the transmission source included in the received MAC frame 52 , B), the path identifier (1001, 1002) is detected. Thereafter, the frame conversion unit 5 generates a VPLS frame 53 based on the detected path identifier.

  Further, when the frame conversion unit 5 receives the VPLS frame 53 from the label processing unit 3, the frame conversion unit 5 refers to the second conversion table 42 and corresponds to the path identifiers (1001 and 1002) included in the received VPLS frame 53. The transmission destination provider MAC address B-DA (A, B) and the transmission source virtual provider MAC address B-SA (C1, C2) are detected. Thereafter, the frame conversion unit 5 generates a MAC frame 52 based on the detected MAC address.

  Hereinafter, an operation of transmitting a frame from the MAC terminal 31 to the VPLS terminal 36 will be exemplified. As shown in FIG. 2, the MAC terminal 31 generates an Ethernet frame 51 in which the MAC address of the VPLS terminal 36 is C-DA and the MAC address of the own device is C-SA, and is transmitted to the MAC-in-MAC device 21. Send.

  Since the MAC-in-MAC device 21 does not know to which provider the C-DA is initially connected, the MAC frame 52 having the broadcast MAC address as B-DA and its own MAC address as B-SA (A). Generate and send.

  When the interworking apparatus 1 receives the broadcast MAC frame 52 from the MAC-in-MAC network 11, the interworking apparatus 1 refers to the first conversion table 41 shown in FIG. 3 and refers to the path identifier (B-SA (A)). 1001) is detected. At this time, if the B-SA included in the received MAC frame is not in the first conversion table 41, the MAC frame is discarded.

  Subsequently, the interworking apparatus 1 decapsulates the B-DA and B-SA of the MAC frame 52 to extract the internal Ethernet frame, and encapsulates the detected path identifier (1001), thereby encapsulating the VPLS frame 53. It is generated and transmitted to the VPLS device 26.

  When receiving the VPLS frame 53 from the VPLS network 12, the VPLS device 26 learns the path identifier (1001) and C-SA (the MAC address of the MAC terminal 31 that is the transmission source) as usual. Thereafter, the VPLS device 26 decapsulates the VPLS frame 53 to generate an Ethernet frame 54 and transmits it to the VPLS terminal 36.

  Next, an operation of transmitting a frame from the VPLS terminal 36 to the MAC terminal 31 is illustrated. The VPLS terminal 36 generates an Ethernet frame 54 in which the MAC address of the MAC terminal 31 is C-DA and the MAC address of its own device is C-SA, and transmits the Ethernet frame 54 to the VPLS apparatus 26.

  Since the VPLS device 26 has learned the MAC address of the MAC terminal 31, it can detect the path identifier (1001) corresponding to C-DA. Based on the path identifier (1001) corresponding to the C-DA, the VPLS device 26 encapsulates the Ethernet frame 54 to generate a VPLS frame 53, and transmits this to the interworking device 1.

  When the interworking apparatus 1 receives the VPLS frame 53 from the VPLS network 12, the interworking apparatus 1 refers to the second conversion table 42 shown in FIG. 3 and refers to the B-DA (A) and B- corresponding to the path identifier (1001). SA (C1) is detected. At this time, when the path identifier included in the received VPLS frame is not in the second conversion table 42, the VPLS frame is discarded.

  Subsequently, the interworking apparatus 1 decapsulates the path identifier (1001) of the VPLS frame 53, extracts the internal Ethernet frame, and encapsulates the detected B-DA and B-SA, thereby encapsulating the MAC frame 52. It is generated and transmitted to the MAC-in-MAC device 21.

  When receiving the MAC frame 52 from the MAC-in-MAC network 11, the MAC-in-MAC device 21 learns B-SA and C-SA as before, decapsulates the MAC frame 52, and Ethernet frame 51 Is transmitted to the MAC terminal 31.

  With the above configuration, learning of the MAC addresses of the terminals 31 and 32 by the interwork apparatus 1 is not necessary, and it is possible to prevent a problem that the number of registered MAC addresses becomes enormous.

Embodiment 2
FIG. 4 shows the configuration of the interworking device 61 according to Embodiment 2 of the present invention. FIG. 5 illustrates a communication system to which the interwork apparatus 61 is applied.

  The interworking device 1 according to the first embodiment connects all the MAC-in-MAC devices 21 and 22 and all the VPLS devices 26 with END-to-END and full mesh, so that the terminals 31, 32, 36 MAC address learning is completely unnecessary.

  On the other hand, the interworking device 61 according to the second embodiment learns only the MAC addresses of the MAC terminals 31 and 32 connected to the MAC-in-MAC network 11, thereby enabling END-to-END and full mesh. Even if it is not a connection, it is possible to provide a service. According to the second embodiment, the load for learning the MAC address is increased as compared with the first embodiment, but the MAC addresses of all the terminals of the MAC-in-MAC network 11 and the VPLS network 12 are set as in the conventional case. The load can be greatly reduced compared to the case of learning.

  The interworking device 61 includes a MAC processing unit 62, a level processing unit 63, a conversion table holding unit 64, a MAC learning unit 65, and a frame conversion unit 66. These function units 62 to 66 are realized by the cooperation of a computer, a program, a database, a logic circuit, and the like, as in the first embodiment.

  The MAC processing unit 62 transmits and receives MAC frames to and from the MAC-in-MAC network 11. The label processing means 62 transmits and receives VPLS frames to and from the VPLS network 12.

  The conversion table holding unit 64 is prepared in advance to associate the virtual provider MAC address (C, D) indicating the address of the virtual provider in the MAC-in-MAC network 11 with the path identifier (1001, 1003) in the VPLS network 12. Hold the conversion table.

  When the MAC address learning unit 65 receives a MAC frame from the MAC processing unit 62, the MAC address learning unit 65 is connected to the terminal MAC address indicating the address of the MAC terminal 31, 32 included in the received MAC frame, and to the MAC terminal 31, 32. A MAC learning table for associating the provider MAC addresses (A, B) indicating the addresses of the MAC-in-MAC devices (providers) 21 and 22 to be generated is generated.

  FIG. 6 illustrates the conversion tables 81 and 82 and the MAC learning table 83. The first conversion table 81 is a table used when data is transmitted from the MAC terminals 31 and 32 connected to the MAC-in-MAC network 11 to the VPLS terminals 36 and 37 connected to the VPLS network 12. Conversely, the second conversion table 42 is a table used when data is transmitted from the VPLS terminals 36 and 37 to the MAC terminals 31 and 32. In the first conversion table 81, B-DA is a destination virtual provider MAC address (C, D). In the second conversion table 82, B-SA is the source virtual provider MAC address (C, D).

  In the MAC learning table 83, C-SA (DA) is the MAC address (31, 32) of the MAC terminal 31, 32 of the transmission source (transmission destination), and B-SA (DA) is the transmission source (transmission destination). MAC-in-MAC devices (providers) 21 and 22 of MAC addresses (A and B).

  The frame conversion unit 66 refers to the first conversion table 81 when receiving the MAC frame 72 including the virtual provider MAC address (C, D) as the transmission destination provider MAC address B-DA from the MAC processing unit 62. The path identifier (1001, 1003) corresponding to the virtual provider MAC address (C, D) is detected. Thereafter, the frame conversion unit 66 generates a VPLS frame 73 based on the detected path identifier.

  Further, when the frame conversion unit 66 receives the VPLS frame 73 from the label processing unit 63, the frame conversion unit 66 refers to the second conversion table 82 and corresponds to the path identifiers (1001, 1003) included in the received VPLS frame 73. The virtual provider MAC address (C, D) to be detected is detected. Thereafter, the frame conversion unit 66 refers to the MAC learning table 83 and detects the provider MAC address (A, B) corresponding to the destination terminal MAC address (31, 32) included in the received VPLS frame 73. The MAC frame 72 is generated based on the detected provider MAC address.

  Hereinafter, an operation of transmitting a frame from the MAC terminal 32 to the VPLS terminal 37 will be exemplified. As shown in FIG. 5, the MAC terminal 32 generates an Ethernet frame 71 having the MAC address of the VPLS terminal 37 as C-DA and the MAC address of its own device as C-SA (32) to generate MAC-in-MAC. To the device 21.

  Since the MAC-in-MAC device 21 does not know to which provider the C-DA is initially connected, the MAC frame 72 having the broadcast MAC address as B-DA and its own MAC address as B-SA (A). Generate and send.

  When the interworking device 61 receives the broadcast MAC frame 72 from the MAC-in-MAC network 11, it refers to the first MAC learning table 83 shown in FIG. Here, when the C-SA (32) included in the MAC frame 72 is not registered in the MAC learning table 83, the C-SA (32) and B-SA (B) are associated and registered. .

  In this example, since B-DA is a broadcast address, all path identifiers (1001, 1003) registered in the first conversion table 81 are encapsulated, and a VPLS frame 73 is generated.

  Even when the MAC frame 72 is a unicast frame and the C-SA (32) is not registered in the MAC learning table 83, C-SA (32) and B-SA (B) are displayed. Registered in association. If B-DA is not a broadcast address and is not registered in the first conversion table 81, the MAC frame 72 is discarded.

  The VPLS device 26 that has received the VPLS frame 73 does not have a connection with the C-DA (37) included in the VPLS frame 73, and therefore discards the VPLS frame 73. Upon receiving the VPLS frame 73, the VPLS device 27 learns the path identifier (1003) and C-SA (32) as usual, and then decapsulates the VPLS frame 73 to generate an Ethernet frame 74. Transmit to the VPLS terminal 37.

  Next, an operation of transmitting a frame from the VPLS terminal 37 to the MAC terminal 32 is illustrated. The VPLS terminal 37 generates an Ethernet frame 74 having the MAC address of the MAC terminal 32 as C-DA (32) and its own MAC address as C-SA (37), and transmits the Ethernet frame 74 to the VPLS apparatus 27.

  Since the VPLS device 27 has learned the MAC address of the MAC terminal 32, the VPLS device 27 can detect the path identifier (1003) corresponding to the C-DA (32). The VPLS device 27 encapsulates the path identifier (1003) in the Ethernet frame 74 to generate a VPLS frame 73, and transmits this to the interworking device 61.

  When receiving the VPLS frame 73, the interworking device 61 refers to the second conversion table 82 and detects B-SA (D) corresponding to the path identifier (1003). At this time, when the path identifier included in the received VPLS frame is not in the second conversion table 72, the VPLS frame is discarded.

  Subsequently, the interworking device 61 decapsulates the path identifier (1003) of the VPLS frame 73, extracts the internal Ethernet frame, and refers to the MAC learning table 83 to the destination terminal MAC address C-DA (32). The corresponding destination provider MAC address B-DA (B) is detected. Thereafter, the interworking device 61 encapsulates the destination provider MAC address B-DA (B) and the corresponding virtual provider MAC address B-SA (D) in the internal Ethernet frame to generate a MAC frame 72 This is transmitted to the MAC-in-MAC device 22.

  Upon receiving the MAC frame 72, the MAC-in-MAC device 22 learns B-SA (D) and C-SA (32) as usual, and then decapsulates the MAC frame 72 to generate an Ethernet frame 71. This is transmitted to the MAC terminal 32.

  According to the second embodiment, the load for learning the MAC address is increased as compared with the first embodiment, but the MAC addresses of all the terminals of the MAC-in-MAC network 11 and the VPLS network 12 as in the past. The load can be greatly reduced as compared with the case of learning. In addition, by learning only the MAC addresses of the MAC terminals 31 and 32 connected to the MAC-in-MAC network 11, an interworking service is provided even if the connection is not END-to-END and full mesh. It becomes possible to do.

  Further, according to the first and second embodiments, since only the header of the MAC-in-MAC network 11 or the VPLS network 12 is added to the frame overhead, the frame overhead can be minimized. . This is because the header of the frame is switched depending on whether the frame is transmitted from the MAC-in-MAC network 11 to the VPLS network 12 or the frame is transmitted from the VPLS network 12 to the MAC-in-MAC network 11.

  Note that the present invention is not limited to the above-described embodiment, and can be changed as appropriate without departing from the spirit of the present invention.

In the above-described embodiments, the present invention has been described as a hardware configuration, but the present invention is not limited to this. The present invention can also realize arbitrary processing by causing a CPU (Central Processing Unit) to execute a computer program.
Further, the above-described program can be stored using various types of non-transitory computer readable media and supplied to a computer. Non-transitory computer readable media include various types of tangible storage media. Examples of non-transitory computer-readable media include magnetic recording media (for example, flexible disks, magnetic tapes, hard disk drives), magneto-optical recording media (for example, magneto-optical disks), CD-ROM (Read Only Memory) CD-R, CD -R / W, semiconductor memory (for example, mask ROM, PROM (Programmable ROM), EPROM (Erasable PROM), flash ROM, RAM (Random Access Memory)). The program may also be supplied to the computer by various types of transitory computer readable media. Examples of transitory computer readable media include electrical signals, optical signals, and electromagnetic waves. The temporary computer-readable medium can supply the program to the computer via a wired communication path such as an electric wire and an optical fiber, or a wireless communication path.

  Although the present invention has been described with reference to the exemplary embodiments, the present invention is not limited to the above. Various changes that can be understood by those skilled in the art can be made to the configuration and details of the present invention within the scope of the invention.

  This application claims the priority on the basis of Japanese application Japanese Patent Application No. 2012-094852 for which it applied on April 18, 2012, and takes in those the indications of all here.

DESCRIPTION OF SYMBOLS 1,61 Interwork apparatus 2,62 MAC processing part 3,63 Level processing part 4,64 Conversion table holding part 5,66 Frame conversion part 11 MAC-in-MAC network 12 VPLS network 21,22 MAC-in-MAC apparatus 26, 27 VPLS device 31, 32 MAC terminal 36 VPLS terminal 41, 81 First conversion table 42, 82 Second conversion table 51, 54, 71, 74 Ethernet frame 52, 72 MAC frame 53, 73 VPLS frame 65 MAC Address learning unit 83 MAC learning table

Claims (5)

MAC processing means for transmitting and receiving MAC frames to and from a MAC-in-MAC network;
Label processing means for transmitting and receiving VPLS frames to and from the VPLS network;
Conversion table holding means for holding a conversion table prepared in advance for associating a virtual provider MAC address indicating a virtual provider address in the MAC-in-MAC network and a path identifier in the VPLS network;
When the MAC frame is received from the MAC processing means, the terminal MAC address indicating the address of the MAC terminal included in the received MAC frame is associated with the provider MAC address indicating the address of the provider connected to the MAC terminal MAC address learning means for generating a MAC learning table;
When the MAC frame including the virtual provider MAC address as a destination provider MAC address is received from the MAC processing means, the path identifier corresponding to the virtual provider MAC address is detected with reference to the conversion table; When the VPLS frame is generated based on the detected path identifier and the VPLS frame is received from the label processing means, the path identifier included in the received VPLS frame is referenced with reference to the conversion table And detecting the provider MAC address corresponding to the destination MAC address of the destination included in the received VPLS frame with reference to the MAC learning table, and detecting the detected virtual provider MAC address Provider M A frame conversion unit configured to generate the MAC frame based on the C address and provider MAC address,
An interworking device comprising: The MAC processing means receives the reception when the provider MAC address of the transmission destination included in the MAC frame received from the MAC-in-MAC network is not included in the list of virtual provider MAC addresses of the conversion table. Discard the MAC frame
The interworking apparatus according to claim 1 . The label processing means discards the received VPLS frame when the path identifier included in the VPLS frame received from the VPLS network is not included in the list of path identifiers of the conversion table;
The interworking apparatus according to claim 2 . When a MAC frame is received from a MAC-in-MAC network, a terminal MAC address indicating an address of a MAC terminal included in the received MAC frame, a provider MAC address indicating an address of a provider connected to the MAC terminal, Generating a MAC learning table for associating
From the MAC-in-MAC network, when receiving the MAC frame containing the virtual provider MAC address indicating the address of the virtual provider in the MAC-in-MAC network as a provider MAC address of a destination, before Kikari virtual provider The path identifier corresponding to the virtual provider MAC address is detected by referring to a conversion table prepared in advance for associating the MAC address with the path identifier in the VPLS network, and the VPLS frame is determined based on the detected path identifier. Generating step;
When a VPLS frame is received from a VPLS network, the virtual provider MAC address corresponding to the path identifier included in the received VPLS frame is detected with reference to the conversion table, and the MAC learning table is referred to Detecting the provider MAC address corresponding to the terminal MAC address of the transmission destination included in the received VPLS frame, and generating the MAC frame based on the detected virtual provider MAC address and provider MAC address;
An interworking method comprising: On the computer,
When a MAC frame is received from a MAC-in-MAC network, a terminal MAC address indicating the address of the MAC terminal included in the received MAC frame and a provider MAC address indicating the address of the provider connected to the MAC terminal A process of generating a MAC learning table to be associated;
From the MAC-in-MAC network, when receiving the MAC frame containing the virtual provider MAC address indicating the address of the virtual provider in the MAC-in-MAC network as a provider MAC address of a destination, before Kikari virtual provider The path identifier corresponding to the virtual provider MAC address is detected by referring to a conversion table prepared in advance for associating the MAC address with the path identifier in the VPLS network, and a VPLS frame is detected based on the detected path identifier. Processing to generate
When a VPLS frame is received from a VPLS network, the virtual provider MAC address corresponding to the path identifier included in the received VPLS frame is detected with reference to the conversion table, and the MAC learning table is referred to Processing for detecting the provider MAC address corresponding to the terminal MAC address of the transmission destination included in the received VPLS frame, and generating the MAC frame based on the detected virtual provider MAC address and provider MAC address;
Interworking program that executes

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