JP2004282375A - Bridge device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a bridge device in which the number of lines to be maintained is comparatively small and an MAC frame is transferred at high speed. <P>SOLUTION: Only a specific position out of the destination address information of an MAC frame converted into a core frame is analyzed and whether the MAC frame is a multicast frame is judged. The MAC frame is unidirectionally transferred to a LAN interface part or multidirectionally transferred to logical circuits other than an inputted logical circuit and the LAN interface part in accordance with the judged result. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

以上により、マルチキャストフレームの高速なＶＣ間ＭＡＣフレーム転送処理が可能となる。
【００５７】
また、ＡＴＭスイッチ部２０に以下のＰ−ＭＰコネクションを設定しておくことで、ブロードキャストストームを防止することができる。
【００５８】

上述したような本発明のＡＴＭブリッジ装置は、ユニキャスト／マルチキャスト（ブロードキャスト）混在で通信可能な複数のＰＶＣで対向装置と接続される網構成において、ＡＴＭ網から受信する全ＭＡＣフレームからマルチキャスト（ブロードキャスト）のみをピックアップして、高速に他のＰＶＣへ転送処理させることができる。
【００５９】
また、ＡＴＭブリッジ装置が対向装置と複数のＰＶＣと接続されるようなループ状のネットワーク構成に設置される場合でも、特別なプロトコルを使用することなく、ＰＶＣ間のマルチキャスト設定から指定ＶＣを外すだけの単純な構成でブロードキャストストームを防ぐことが可能である。
【００６０】
図５は、本発明によるＡＴＭブリッジ装置のフローチャートである。
【００６１】
以下、図５を用いて本発明のＡＴＭブリッジ装置におけるＭＡＣアドレス解析部の詳細動作について説明する。
【００６２】
ＡＴＭスイッチ部２０からのセルが入力されると（Ｓ１０１）、セル管理部ＣＥＬＬＭＮＧ３０２で受信したセルがＡＡＬ５フレームの先頭セルか否かが確認される（Ｓ１０２，Ｓ１０３）。先頭セルの場合、宛先ＭＡＣアドレスの先頭オクテットが格納される場所を解析し、最下位ビットに１が設定されているかを判定する（Ｓ１０３）。
【００６３】
上記判定したビットが１に設定されるＭＡＣアドレスはマルチキャストフレームであるため（Ｓ１０４）、受信したセルを各バッファ３０３，３０５経由でそれぞれＬＡＮインタフェース制御部３０６及びＡＴＭインタフェース制御部３０７に向けて送信する（Ｓ１０５〜Ｓ１０８）。
【００６４】
以上の動作を、受信しているＡＡＬ５フレームの最終セルの最終バイトを認識するまで行う（Ｓ１０９）。
【００６５】
最終セルの最終バイトが認識されると、各バッファへの書込が停止される（Ｓ１１０）とともにＬＡＮインタフェース制御部３０６及びＡＴＭインタフェース制御部３０７の起動要求がなされる（Ｓ１１１）。
【００６６】
ＡＴＭインタフェース制御部３０７では、起動要求があるまでバッファからセルを順次読み込み（Ｓ１１２〜Ｓ１１３）、起動要求時にマルチキャスト送信イネーブルであると（Ｓ１１４）、マルチキャストフレームのカプセリングされた全セルをＡＴＭスイッチ部２０へ送信する（Ｓ１１５〜Ｓ１１６）。マルチキャスト送信イネーブルでないとバッファ内のセルは廃棄される（Ｓ１１７）。
【００６７】
ＬＡＮインタフェース制御部３０６では、起動要求があるまでバッファからセルを順次読み込み（Ｓ１１８〜Ｓ１１９）、起動要求時にマルチキャストフレームをデカプセリングしてＬＡＮスイッチ部４０へ送信する（Ｓ１２０〜Ｓ１２１）。
【００６８】
ここで、ＡＴＭスイッチ部２０には、ＣＰＵ６０によって予め入力側のコネクション識別子（ＶＣＩ）毎にＰ−ＭＰコネクションを設定しておくことにより、入力されたコネクション識別子（ＶＣＩ）以外のＰＶＣへマルチキャストフレームを転送することが可能となる。
【００６９】
なお、ネットワークがループ構成となるような場合で、ブロードキャストストームが発生する可能性がある場合には、ＣＰＵ６０が予めＰ−ＭＰコネクションを設定する時に、そのＰＶＣをＰ−ＭＰコネクションのメンバーから外すことにより、簡単に特定のＰＶＣ間のマルチキャスト転送を抑止することができる。
【００７０】
以上説明したように、本発明のＡＴＭブリッジ装置は、ＡＡＬ５フレームの先頭セルについて所定ビットをチェックすることにより宛先ＭＡＣアドレスがマルチキャストであるかどうかだけを判断し、内蔵するＡＴＭスイッチ部２０のマルチキャスト機能を使用することにより、高速にマルチキャストフレームのＰＶＣ間転送処理を行うことが可能である。
【００７１】
また、ネットワークのループ構成に対しても、特別なプロトコルを使用することなく、ＰＶＣ間のマルチキャスト設定から、指定ＰＶＣを外すだけの単純な設定を行うことでブロードキャストストームを防ぐことができる。
【００７２】
なお、上述の説明ではＡＴＭ網に設定される拠点間の回線をＰＶＣとしたが、ＰＮＮＩによってルートが選択されるソフト相手先固定回線接続（ＳＰＶＣ）であっても良く、また相手選択接続による仮想回線（ＳＶＣ）であっても良いことは明らかである。
【００７３】
また、本発明のブリッジ装置と接続するコアネットワークとして、上記説明ではＡＴＭを用いたが、本発明はこれに限定されることはなく、ＭＰＬＳやＧＭＰＬＳなどについても同様の効果を奏するものである。
【００７４】
【発明の効果】
本発明によれば、維持すべき回線が比較的少なく、ＭＡＣフレームを高速に転送処理することが可能なブリッジ装置を提供することができる。
【図面の簡単な説明】
【図１】ＡＴＭブリッジ装置の構成を示す図である。
【図２】ＭＡＣアドレス解析部の構造を示す図である。
【図３】ＭＡＣフレームのＡＴＭへのカプセリングを説明する図である。
【図４】ＭＡＣアドレスの構成を示す図である。
【図５】ＡＴＭブリッジ装置のフローチャートを示す図である。
【図６】ＡＴＭ網を介したＬＡＮ間接続を示す図である。
【符号の説明】
１０ …ＡＴＭインタフェース部
２０ …ＡＴＭスイッチ部
３０ …ＭＡＣアドレス解析部
４０ …ＬＡＮスイッチ部
５０−１，５０−２，…５０−ｎ …ＬＡＮインタフェース
６０ …ＣＰＵ[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention is based on RFC2684 and RFC1483 Multiprotocol Encapsulation over ATM Adaptation Layer 5 and IEEE 802.1D MAC Bridges and IEEE802.3 MAC and ATM Forum and ITU-T standards based on two or more networks. In particular, a core network using a network such as an ATM (Asynchronous Transfer Mode), an MPLS (Multiprotocol Label Switching), a GMPLS (generalized multiprotocol switching), a local network using a core network and the like, and an IP (Internet Protocol) using a local area network such as an IP (Internet Protocol) and an Internet Protocol (IP) network Over click (hereinafter, LAN) and relates bridge device for interconnecting.
[0002]
In recent years, an ATM leased line service provided by a telecommunications carrier has been widely used as one form of the interconnection. As an ATM dedicated line service, for example, an ATM share link service of East Nippon Telegraph and Telephone Corporation is known.
[0003]
In addition, as a technology for constructing a core network, there are MPLS and GMPLS including ATM in those defined by IETF. These are defined by RFCs 3031 to 3032, RFCs 3471 to 473, respectively.
[0004]
These core networks convert a native format data frame (MAC frame) from a connected network such as a LAN into a core frame of a format suitable for the own network and transfer the frame on a virtual transmission path (logical line). The present invention provides a wide area network (WAN) function or an interwork function that can transparently communicate with each other.
[0005]
[Prior art]
FIG. 6 is a diagram for explaining the outline of the connection between LANs via the ATM network. In the network shown in FIG. 6, an ATM bridge device (not shown) having an ATM interface is installed at each site, and each ATM bridge device is communicably connected to an ATM network. The ATM bridge devices are also connected to the LANs at the respective sites via LAN interfaces, and devices (not shown) such as information communication terminals that transmit and receive IP packets and the like by MAC frames are connected to the LANs. Under such a device configuration, a MAC frame between LANs extending over each base is transmitted and received via an ATM network.
[0006]
That is, the ATM bridge device converts (disassembles / assembles) the MAC frame into an ATM cell (hereinafter, simply referred to as a cell) of a format that can be transmitted in the ATM network according to a predetermined method, and transmits and receives the ATM frame. The MAC frames are transparently transmitted to each other.
[0007]
Here, when a mesh network configuration is adopted as a network configuration for connecting a plurality of bases, the number of lines to be maintained increases as the number of bases increases. Therefore, in order to suppress the number of lines to be maintained, a star-shaped network configuration in which each site is connected around a specific site is often used.
[0008]
When such a star-shaped network configuration is adopted, a MAC frame transmitted from each location is once sent to a specific location serving as a center, and then transferred to each location. In FIG. 6, the base A corresponds to the center.
[0009]
A plurality of fixed ATM logical lines (hereinafter, PVC) respectively corresponding to the other sites B, C, and D are logically multiplexed on the ATM interface of the ATM bridge device installed at the site A. At this time, if the MAC frame received from one of the logically multiplexed PVCs is a broadcast frame or a multicast frame, the ATM bridge device transmits the MAC frame to the logically multiplexed other PVC and its own LAN interface. Transfer processing (or flooding) to
[0010]
In order to perform the above-described frame transfer processing, the following method has been considered.
[0011]
In the first method, a MAC frame is once received / terminated by a CPU of an ATM bridge, a destination MAC address is inspected, and after it is recognized as a broadcast frame or a multicast frame, logical multiplexing other than the received PVC is performed. An operation of performing transfer processing to the PVC and LAN interfaces is performed.
[0012]
In the second method, each site is connected with a unicast PVC and a plurality of multicast PVCs corresponding to each site, and a MAC frame transfer type is determined from a received cell connection identifier and an address table. Then, the multicast MAC frame is transmitted to a multicast PVC connected to another site (for example, see Patent Document 1).
[0013]
[Patent Document 1]
Japanese Patent Application Laid-Open No. 2002-354047
[Problems to be solved by the invention]
However, in the first method, the CPU once receives the MAC frame received from the PVC, recognizes the multicast frame or the broadcast frame from the destination MAC address of the assembled MAC frame, and then receives the re-disassembled cell again. Therefore, it is difficult to transfer the MAC frame at a high speed due to the limitation of the CPU processing capacity.
[0015]
Further, in the second method, since each site is connected with a unicast PVC and a different multicast PVC between the respective sites, a large number of PVCs to be set are required.
[0016]
SUMMARY OF THE INVENTION It is an object of the present invention to solve the above-mentioned problems and to provide a bridge device which has a relatively small number of lines to be maintained and can transfer a MAC frame at high speed.
[0017]
[Means for Solving the Problems]
In order to solve the above-described problems, the present invention provides a bridge device that transmits a MAC frame converted to a core frame,
A core interface unit for transmitting and receiving the core frame,
A LAN interface unit for transmitting and receiving the MAC frame;
A core switch unit for selectively outputting a core frame obtained by converting the MAC frame input from a first logical line logically multiplexed to the core interface unit;
Only the specific part of the destination address information of the MAC frame converted into the core frame is analyzed to determine whether the analyzed MAC frame is a multicast frame, and in response to the determination, to the LAN interface unit. An address analysis unit that transfers the MAC frame in one direction, or transfers the MAC frame in multiple directions toward a second logical line logically multiplexed to the core interface unit and the LAN interface unit;
A LAN switch unit that learns address information of a MAC frame from the LAN interface unit and selectively outputs the MAC frame to the core interface unit or the LAN interface unit according to the learned address information. It is characterized by having.
[0018]
That is, the present invention implements a MAC frame transfer process using the function of the core switch unit according to the above configuration. Further, according to the present invention, it is sufficient to analyze only a specific portion of the destination address information of the MAC frame encapsulated in the core frame, and the transfer process of the multicast frame is simplified and the speed can be remarkably increased.
[0019]
[Embodiment of the present invention]
Hereinafter, an embodiment of the present invention will be described with reference to the drawings. In the following description, an ATM network is used as a core network, and an ATM cell is used as a core frame. Therefore, an ATM bridge device will be described as an embodiment of the present invention.
[0020]
FIG. 1 shows a configuration of an ATM bridge device according to the present invention. Reference numerals 10 in the figure indicate an ATM interface unit, an ATM switch unit 20, a MAC address analysis unit 30, a LAN switch unit 40, 50-1, 50-2,. A LAN interface is denoted by 50) and 60 denotes a device control unit.
[0021]
The ATM bridge device shown in FIG. 1 has a function of converting a MAC frame input / output via a LAN interface into cells input / output via an ATM interface as a core interface.
[0022]
That is, the MAC frame is converted into an intermediate data frame format called an AAL5 frame of a predetermined length by a predetermined conversion process (described later) of the ATM bridge device (this is referred to as encapsulation / decapsulation), and then converted to a fixed-length cell. The data is transmitted / received while being divided / combined, and transmitted in the ATM network.
[0023]
The ATM interface unit 1 is a part directly connected to the ATM network as a physical / logical interface, and is used for transmitting and receiving cells whose MAC frames have been converted between the ATM network and the apparatus.
[0024]
The ATM switch unit 20 corresponds to a core switch unit, and has a function of transferring a MAC frame from a single PVC toward the LAN interface 50 side, and conversely, a function to transfer a MAC frame from the LAN interface 50 to a single PVC. Has a function to transfer a MAC frame from point to point. In addition, it has a function of transferring a MAC frame from the LAN interface 50 or the MAC address analysis unit 30 to a plurality of PVCs from point to multipoint (Point to Multipoint).
[0025]
The MAC address analysis unit 30 has a function of analyzing only a specific portion of a destination address (Destination MAC address) of a MAC frame received from the ATM network side by the ATM interface 10 and determining whether the frame is a multicast frame.
[0026]
The LAN switch unit 40 has a function of learning a MAC address of a passing MAC frame and switching a received MAC frame to the ATM interface 10 side or an arbitrary LAN interface 50 according to the learned MAC address.
[0027]
The LAN interface 50 is a portion directly connected to a LAN interface of another device (not shown) as a physical / logical interface by a predetermined LAN cable, and is used for transmitting and receiving a MAC frame via the LAN cable.
[0028]
The CPU 60 has a function of performing necessary settings for the ATM switch unit 20 and the LAN switch unit 40 at the time of starting the apparatus, and performing a predetermined MAC frame transfer process.
[0029]
A point-to-multipoint connection is set in the ATM switch unit 20 in advance, and a MAC frame transfer process using the function of the ATM switch unit 20 is performed.
[0030]
FIG. 2 shows a configuration of the MAC address analysis unit.
[0031]
Hereinafter, the configuration of the MAC address analysis unit will be described with reference to FIG. 2, reference numerals 301 in FIG. 2 denote an ATM interface control unit P1ATMinfCTL, 302 a cell management unit CELLMNG, 304 a MAC frame management unit SDUMNG, 303 a buffer DWNFIFO, 305 a buffer BCFIFO, and 306 a LAN interface control unit. LANinfCTL, 307 denotes an ATM interface control unit P2ATMinfCTL.
[0032]
The ATM interface control unit P1ATMinfCTL301 has a function of continuously monitoring cell reception and transmitting a cell to "CELLMNG" when one cell has been received.
[0033]
The cell management unit CELLMNG 302 analyzes whether the received cell is the first, middle, or last in the encapsulated AAL5 frame of the MAC frame, and determines a cell from the first cell to the last cell so as to be a MAC frame unit. It has a function of controlling queuing to the buffer DWNFIFO 303 and the buffer BCFOFIFO 305. Also, when the received cell is the head of the MAC frame, it has a function of transmitting the cell to the MAC frame management unit SDUMNG 304.
[0034]
The MAC frame management unit SDUMNG 304 determines whether the value of the lower 1 bit of the first byte of the destination MAC address (DA: Destination Address) in the received head cell is 1 and determines whether the received MAC frame is a multicast frame. It has a function of determining whether or not there is.
[0035]
The buffer DWNFIFO 303 has a function of accumulating cells in which MAC frames for the LAN interface 50 from the ATM switch unit 20 are encapsulated in the order of arrival.
[0036]
The buffer BCFIFO 305 has a function of accumulating, in the order of arrival, cells in which a MAC frame for another PVC has been encapsulated from a PVC to which cells have been input.
[0037]
The LAN interface control unit LANinfCTL 306 keeps monitoring whether or not the MAC frame for the LAN interface 50 from the ATM switch unit 20 has arrived from the first cell to the last cell for the encapsulated cell group, and can store one MAC frame in the buffer DWNFIFO 303. At the point of time, it has a function of decapsulating the received AAL5 frame and transmitting it to the LAN switch unit 40 as a MAC frame.
[0038]
The ATM interface control unit P2ATMinfCTL 307 keeps monitoring whether the MAC frame from the ATM switch unit 20 to the ATM switch unit 20 has arrived from the beginning to the end of the encapsulated cell group, and when the MAC frame for one MAC frame can be stored in the buffer BCCD FIFO 305. And has a function of selecting only the PVCs for which the multicast transfer function between PVCs is enabled and transmitting the received multicast MAC frame.
[0039]
FIG. 3 is a diagram illustrating details of conversion of a MAC frame into an ATM cell. FIG. 4 is a diagram showing a configuration of a MAC address.
[0040]
Hereinafter, the conversion of the MAC frame into the ATM cell will be described in detail with reference to FIGS.
[0041]
The conversion of a MAC frame into ATM cells is also called encapsulation / decapsulation. Here, the method will be described assuming Bridged MAC / 802.3 PDUs of RFC 2684.
[0042]
In the ATM (asynchronous transfer mode), a function of dividing a data frame input from a higher-level application into 48-byte lengths as a pre-process for converting the data into an ATM cell, and conversely, restoring data in the cell to the original frame format. Layers. This functional layer is an ITU-T Recommendation I. 363, and is called an AAL (ATM adaptation layer).
[0043]
The AAL is divided into two sublayers, CS (convergence sublayer) and SAR (segmentation and reassembly sublayer), and the upper CS has a function of identifying a data segment and reproducing a transmission timing clock. , The lower SAR has the function of dividing the data frame into a series of cell groups and performing the reverse process. Among the AALs, the AAL5 is the most widespread practical system as a simple burst data cell division system.
[0044]
The MAC frame (4) shown in FIG. 3 includes a plurality of parts including information such as a destination MAC address, a source MAC address, and a MAC payload. A frame (3) in which intermediate processing information (LLC, OUI, PID, PAD, etc.) is added to this MAC frame is called an AAL5 PDU. The AAL5 PDU is further divided into a predetermined length in the state (2) to which the AAL5 trailer is added, added with a header (not shown), and converted into a series of ATM cells (1). This series of transformations is called encapsulation, and the reverse process is called decapsulation. In this specification, the data frame in the state (2) is referred to as an AAL5 frame.
[0045]
As shown in FIG. 4, the MAC address is composed of 48 bits (6 octets). The first three octets are a vendor identifier (OUI: Organizationally Unique Identifier), and the last three octets are address information unique to each vendor. ing. Among these, 0 / unicast address or 1: multicast address is indicated by the value of the I / G (Individual / Group) bit, which is the LSB (Least Significant Bit: Least Significant Bit) of the first octet, depending on its value. .
[0046]
In the ATM bridge device of the present invention, in order to switch a multicast frame between ATM logical circuits (PVC) at high speed, an AAL5 frame is assembled by an ATM-SAR, and then a MAC 2 capsulated according to RFC 2684 is applied. It is determined whether the lower 1 bit of the first byte of the destination MAC address of the frame is 1. If this bit is 1, the MAC frame is a broadcast frame or a multicast frame, and the cell is transmitted to another port connecting the ATM switch unit 20 and the ATM-SAR.
[0047]
Hereinafter, the MAC frame transfer process according to the present embodiment will be described with reference to FIGS. 2 and 6 in addition to FIGS.
[0048]
Here, an example in which a multicast frame is distributed from the LAN under the site D in FIG. 6 to each LAN under the other sites A, B, and C will be described.
[0049]
The multicast MAC frame from the site D is divided into cells in the format shown in FIG. 3 and transmitted to the ATM bridge device at the site A through the ATM-VC set between the site and the site A.
[0050]
The cell received by the ATM bridge at the point A is sent to the MAC address analysis unit 30 in FIG. 2 via the ATM switch unit 20 built in the ATM bridge. The cell management unit CELLMNG 302 of the MAC address analysis unit 30 stores the received cells in the buffer DWNFIFO 303 and the buffer BCFIFO 305 at the same time.
[0051]
When the received cell is the first cell of the AAL5 frame, the cell management unit CELLMNG 302 determines whether the least significant bit (the above-described I / G bit) of the first octet of the destination MAC address is 1. If this bit is 1, the MAC frame can be determined to be a broadcast frame or a multicast frame. Therefore, the LAN interface control unit LANinfCTL 306 is activated to store received cells, and the ATM interface control unit P2AINTintCTL 307 is activated simultaneously. Store the received cells. The above operation is performed until a cell corresponding to the last cell of the AAL5 frame arrives.
[0052]
When the last cell of the AAL5 frame arrives, the LAN interface control unit LANinfCTL 306 is activated to transmit the decapsulated MAC frame from the cells stored in the LAN switch unit 40, and at the same time, the ATM interface control unit P2AINTintCTL307 is activated to activate the ATM switch. The series of cells stored in the unit 20 are transmitted.
[0053]
Here, in the ATM switch unit 20, for each ATM connection identifier received from the MAC address analysis unit 30, a point-to-multipoint connection (hereinafter referred to as a P-MP connection) for multicasting to a device other than the received ATM connection identifier. Yes) is set.
[0054]
The ATM switch unit 20 converts the cell having the ATM connection identifier from the site D into the cell having the ATM connection identifier for the site B and the cell having the ATM connection identifier for the site C according to the set P-MP connection. To multicast transmission.
[0055]
Specifically, the following P-MP connection is set.
[0056]

As described above, a high-speed inter-VC MAC frame transfer process of a multicast frame becomes possible.
[0057]
By setting the following P-MP connection in the ATM switch unit 20, a broadcast storm can be prevented.
[0058]

The above-described ATM bridge device of the present invention performs multicast (broadcast) from all MAC frames received from the ATM network in a network configuration in which a plurality of PVCs capable of communicating in a unicast / multicast (broadcast) mixture are connected to the opposite device. ) Can be picked up and transferred to another PVC at high speed.
[0059]
Further, even when the ATM bridge device is installed in a loop network configuration in which the opposite device and a plurality of PVCs are connected, only the designated VC is removed from the multicast setting between PVCs without using a special protocol. It is possible to prevent a broadcast storm with a simple configuration of.
[0060]
FIG. 5 is a flowchart of the ATM bridge device according to the present invention.
[0061]
Hereinafter, the detailed operation of the MAC address analysis unit in the ATM bridge device of the present invention will be described with reference to FIG.
[0062]
When a cell is input from the ATM switch unit 20 (S101), it is checked whether the cell received by the cell management unit CELLMNG 302 is the first cell of the AAL5 frame (S102, S103). In the case of the first cell, the location where the first octet of the destination MAC address is stored is analyzed, and it is determined whether 1 is set in the least significant bit (S103).
[0063]
Since the MAC address in which the determined bit is set to 1 is a multicast frame (S104), the received cell is transmitted to the LAN interface control unit 306 and the ATM interface control unit 307 via the buffers 303 and 305, respectively. (S105 to S108).
[0064]
The above operation is performed until the last byte of the last cell of the received AAL5 frame is recognized (S109).
[0065]
When the last byte of the last cell is recognized, writing to each buffer is stopped (S110), and a request to start the LAN interface control unit 306 and the ATM interface control unit 307 is made (S111).
[0066]
The ATM interface control unit 307 sequentially reads cells from the buffer until there is a start request (S112 to S113). If multicast transmission is enabled at the time of the start request (S114), all the cells encapsulated in the multicast frame are transferred to the ATM switch unit 20. (S115 to S116). If multicast transmission is not enabled, the cells in the buffer are discarded (S117).
[0067]
The LAN interface control unit 306 sequentially reads cells from the buffer until a start request is issued (S118 to S119), decapsulates the multicast frame at the time of the start request, and transmits it to the LAN switch unit 40 (S120 to S121).
[0068]
Here, in the ATM switch unit 20, by setting a P-MP connection for each input connection identifier (VCI) in advance by the CPU 60, a multicast frame is transmitted to a PVC other than the input connection identifier (VCI). It becomes possible to transfer.
[0069]
In a case where a broadcast storm is likely to occur in a case where a network has a loop configuration, when the CPU 60 sets a P-MP connection in advance, the PVC is removed from the members of the P-MP connection. Accordingly, it is possible to easily suppress the multicast transfer between specific PVCs.
[0070]
As described above, the ATM bridge device of the present invention checks only a predetermined bit for the first cell of the AAL5 frame to determine whether or not the destination MAC address is multicast. Is used, it is possible to perform a multicast frame transfer process between PVCs at high speed.
[0071]
Also, for a network loop configuration, a broadcast storm can be prevented by performing a simple setting that removes a designated PVC from a multicast setting between PVCs without using a special protocol.
[0072]
In the above description, PVC is used as a line between bases set in the ATM network. However, a soft permanent line connection (SPVC) in which a route is selected by PNNI may be used. Obviously, it may be a line (SVC).
[0073]
Further, although the ATM is used as the core network connected to the bridge device of the present invention in the above description, the present invention is not limited to this, and the same effects can be obtained for MPLS and GMPLS.
[0074]
【The invention's effect】
According to the present invention, it is possible to provide a bridge device capable of relatively few lines to be maintained and capable of transferring a MAC frame at a high speed.
[Brief description of the drawings]
FIG. 1 is a diagram showing a configuration of an ATM bridge device.
FIG. 2 is a diagram illustrating a structure of a MAC address analysis unit.
FIG. 3 is a diagram illustrating encapsulation of a MAC frame into an ATM.
FIG. 4 is a diagram showing a configuration of a MAC address.
FIG. 5 is a diagram showing a flowchart of the ATM bridge device.
FIG. 6 illustrates a connection between LANs via an ATM network.
[Explanation of symbols]
10 ATM interface unit 20 ATM switch unit 30 MAC address analysis unit 40 LAN switch units 50-1, 50-2,... 50-n LAN interface 60 CPU

Claims (1)

In a bridge device that transmits a MAC frame converted to a core frame,
A core interface unit for transmitting and receiving the core frame,
A LAN interface unit for transmitting and receiving the MAC frame;
A core switch unit for selectively outputting a core frame obtained by converting the MAC frame input from a first logical line logically multiplexed to the core interface unit;
Only the specific part of the destination address information of the MAC frame converted into the core frame is analyzed to determine whether the analyzed MAC frame is a multicast frame, and in response to the determination, to the LAN interface unit. An address analysis unit that transfers the MAC frame in one direction, or transfers the MAC frame in multiple directions toward a second logical line logically multiplexed to the core interface unit and the LAN interface unit;
A LAN switch unit that learns address information of a MAC frame from the LAN interface unit and selectively outputs the MAC frame to the core interface unit or the LAN interface unit according to the learned address information. A bridge device.

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