JP2005236640A - Vpn multicast packet transfer method, network system using same, and device and program composing network system - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To easily build, maintain, and use a multicast network of the same VPN to a different VPN site via a VPN backbone network from a specified VPN site in a specified VPN, on the VPN backbone network for connecting at least one of VPNs comprising a plurality of VPN sites. <P>SOLUTION: A VPN identifier is set for each VPN by the edge router of the VPN backbone network for connecting the VPN sites. The respective VPN identifiers are set to be a group (FEC) of IP packets to be transferred by the same method. A label for identifying them is used and an MPLS of the packet transfer technology is used for deciding the transfer destination of data, thus transferring a multicast packet. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

  The present invention is a VPN that is constructed on a public data communication network such as the Internet, and that connects a plurality of IP-VPNs (Internet Protocol-Virtual Private Networks) consisting of virtual dedicated lines for communication between specific sites. On a backbone network, a method for transferring multicast packets from one site in a specific VPN to other sites belonging to the same VPN via the VPN backbone network, a network system using the method, and an apparatus and program constituting the same About.

  For multiple VPNs, a multicast packet forwarding network in a VPN packet forwarding network that uses a VPN backbone network that superimposes a network that connects sites that make up each VPN on a single network is connected to the VPN backbone network for each VPN. A VPN multicast packet transfer network was constructed by assigning a multicast address (see, for example, Patent Document 1).

  In the above conventional multicast packet transfer method, in order to realize the superimposition of multiple VPNs on the VPN backbone network, a multicast address is also provided for each VPN for the backbone network separately from the multicast address in the VPN used for actual multicast transfer. Therefore, the construction, maintenance, and operation of a multicast network are complicated in address management.

  In addition, since an IP multicast address is assigned to each VPN, a specific multicast address is used to transfer multicast packets of a specific VPN, so address management with multicast addresses that transfer multicast packets that are not VPNs However, the construction, maintenance, and operation of a multicast network were complicated.

  Furthermore, the conventional method uses MPLS LSP (Multi Protocol Label Switching-Label Switching Path) used to forward VPN unicast packets to assign an IP multicast address for each VPN, and a path method for forwarding VPN multicast packets. It has been difficult to apply as a different transfer path method, and the construction, maintenance, and operation of the VPN backbone network have been complicated.

JP 2002-176436 A

  In view of the above, an object of the present invention is to use information other than a multicast address as address information for setting a VPN multicast packet transfer network, and in the VPN multicast packet transfer network, an MPLS LSP is used as a VPN multicast packet transfer path. It is an object of the present invention to provide a VPN multicast packet transfer method that facilitates the construction, maintenance, and operation of a multicast network, a network system using the same, and an apparatus and program that configure the VPN multicast packet.

  In order to achieve the above object, the invention according to claim 1 is constructed using a VPN backbone network in which, for a plurality of VPNs, a network connecting between sites constituting each VPN is superimposed on one network. In the method of transferring a VPN multicast packet by a VPN packet transfer network, the PE router which is an edge router in the VPN backbone network to which each VPN site is connected has a VPN identifier for each VPN to which the VPN site connected to the PE router belongs. From all PE routers connected to the multicast VPN site that constitutes the VPN multicast in a specific VPN, the P router that connects the PE router is set as the multicast VPN connection information using the set VPN identifier. VPN by advertising to the VPN backbone network via A VPN multicast packet transfer characterized in that a multicast packet transfer network is constructed, and a VPN multicast packet is transferred by MPLS LSP set along the VPN multicast packet transfer network with the VPN identifier set in the VPN as FEC Is in the way.

  Further, the invention of claim 2 is that in claim 1, the VPN identifier is an arbitrary value unique to each VPN in order to identify the VPN in the VPN backbone network, and the same VPN is used in all PE routers. It is characterized by setting the same VPN identifier.

  The invention of claim 3 is characterized in that, in claim 1, the VPN identifier is set only for a VPN that performs multicast packet transfer.

  Further, the invention of claim 4 is the invention according to claim 1, wherein the multicast connection information includes information indicating that a PE router of the VPN backbone network is connected to a multicast VPN site in a specific VPN to the router. It is also information indicating that the connection of the multicast VPN site in the specific VPN is lost.

  In addition, when the multicast VPN connection information is advertised to the VPN backbone network, the invention of claim 5 also advertises by adding the IP address of the PE router that generated the multicast VPN connection information. It is characterized by that.

  The invention of claim 6 is the VPN multicast packet transfer network for generating a VPN multicast packet transfer network according to claim 5 by using the IP address information of the router that generated the information as the multicast connection information. The VPN multicast packet transfer network is set without transmitting the multicast packet to be used.

  The invention of claim 7 is the invention according to claim 1, wherein each of the routers constituting the VPN backbone network activates LDP to set an MPLS LSP, assigns a label with the VPN identifier as FEC, It is characterized by notifying neighboring routers using LDP.

  The invention according to claim 8 is the invention according to claim 7, wherein when a PE router in the VPN backbone network receives a multicast packet from a multicast VPN site connected to the PE router, the PE router is set to a VPN to which the multicast VPN site belongs. The destination is determined from the direction in which the same VPN identifier as the VPN identifier has been advertised to the VPN backbone network from other PE routers, and among the labels notified from the transmission direction, the VPN identifier set for the VPN is FEC. A multicast packet is encapsulated by a label to be transmitted and transmitted.

  Further, the invention of claim 9 is that, in claim 8, when the PE router on the outgoing side of the VPN backbone network receives the encapsulated packet, the packet is obtained from the FEC information of the label used for encapsulation. When there is a VPN having the same VPN identifier, the packet is transmitted to the multicast VPN site based on the route table of the VPN.

  The invention according to claim 10 is the invention according to claim 1, wherein a PE router that connects a VPN site having a source for transmitting a multicast packet to the VPN multicast packet transfer network to the VPN backbone network is connected to the PE router. By advertising to the VPN backbone network that the VPN site that has the source to send is connected, each PE router that connects the other site of the same VPN as the VPN to which the VPN site belongs from the PE router. Only the VPN multicast packet transfer network to be connected is constructed.

  The invention of claim 11 is a VPN packet transfer network system constructed by using a VPN backbone network in which a network connecting sites constituting each VPN is superimposed on a single network for a plurality of VPNs. The VPN backbone network consists of PE routers, which are edge routers connecting each VPN site, and P routers connecting these PE routers. Each PE router has a VPN site connected to the PE router. A VPN identifier is set for each belonging VPN, and the PE router is set as the multicast VPN connection information from all the PE routers connected to the multicast VPN site constituting the VPN multicast in the specific VPN. Advertising to the VPN backbone network via each P router connecting In VPN packet transfer network system is characterized in that so as to construct the VPN multicast packet transfer network by.

  Further, the invention of claim 12 is the invention of claim 11, wherein each router in the VPN backbone network uses a VPN multicast by MPLS LSP set along the VPN multicast packet forwarding network with the VPN identifier set in the VPN as FEC. It is characterized in that packets are transferred.

  Further, the invention of claim 13 is the invention according to claim 12, wherein each router constituting the VPN backbone network activates LDP to set an MPLS LSP, assigns a label with a VPN identifier as FEC, and It is characterized by notifying neighboring routers using LDP.

  Further, the invention of claim 14 is the invention according to claim 12, wherein the PE router on the outgoing side of the VPN backbone network receives the packet from the FEC information of the label used for encapsulation when receiving the encapsulated packet. When there is a VPN with the same VPN identifier set, a packet is transmitted to the multicast VPN site based on the route table of the VPN.

  Further, the invention of claim 15 is that, in claim 12, when the PE router on the outgoing side of the VPN backbone network receives the encapsulated packet, the packet is obtained from the FEC information of the label used for encapsulation. When there is a VPN with the same VPN identifier set, a packet is transmitted to the multicast VPN site based on the route table of the VPN.

  The invention of claim 16 is the PE router according to claim 11, wherein the PE router that connects a VPN site having a source for transmitting a multicast packet to the VPN multicast packet transfer network to the VPN backbone network includes a multicast packet. By advertising to the VPN backbone network that the VPN site that has the source to send is connected, each PE router that connects the other site of the same VPN as the VPN to which the VPN site belongs from the PE router. Only the VPN multicast packet transfer network to be connected is constructed.

  The invention of claim 17 relates to the VPN in a VPN packet transfer network system constructed using a VPN backbone network in which a network connecting sites constituting each VPN is superimposed on a single network for a plurality of VPNs. The router that configures the backbone network sets the VPN identifier for each VPN to which the VPN site connected to the router belongs, and from all the routers that connect the multicast VPN site that configures the VPN multicast in a specific VPN, A router for constructing a VPN multicast packet transfer network by advertising the set VPN identifier as multicast VPN connection information to the VPN backbone network via another router connecting the router .

  Further, the invention of claim 18 is the invention of claim 17, wherein the VPN multicast packet is forwarded by the MPLS LSP set along the VPN multicast packet transfer network using the VPN identifier set for the VPN as FEC, and the MPLS LSP is set. In order to do this, LDP is started, a VPN identifier is assigned as a FEC, and a label is given to notify an adjacent router using the LDP.

  The invention according to claim 19 is the VPN multicast packet by the VPN packet transfer network constructed by using the VPN backbone network in which the networks connecting the sites constituting each VPN are superimposed on one network for a plurality of VPNs. For each VPN to which a VPN site connected to the PE router belongs to a PE router that is an edge router in the VPN backbone network to which each VPN site is connected. Connects the PE router using the set VPN identifier as multicast VPN connection information from all PE routers connected to the multicast VPN site that constitutes the VPN multicast in the process of setting the VPN identifier and the VPN multicast. VPN backbone network via the P router Processing to construct a VPN multicast packet forwarding network by advertising to the network, and processing to forward VPN multicast packets by MPLS LSP set along the VPN multicast packet forwarding network with the VPN identifier set in the VPN as FEC Is in a program that causes a computer to execute.

  The invention according to claim 20 resides in a storage medium storing the program according to claim 19.

  According to the present invention as described above, by adopting a VPN multicast packet transfer method in which MPLS LSP is applied to a VPN multicast packet transfer path in the VPN backbone network, the same method as the path used for VPN unicast packet transfer is used. Since a path can be used, it is easy to construct, maintain, and operate a network.

  Further, by adopting a VPN multicast packet transfer method that uses information other than the multicast address as address information for setting the VPN multicast packet transfer network, it is possible to facilitate the management, maintenance, and operation of the VPN backbone network.

  Embodiments of the present invention will be described below with reference to the drawings. FIG. 1 is a schematic configuration diagram of a network model constructed by using a VPN backbone network in which a network connecting sites constituting each VPN for a plurality of VPNs is superimposed on one network.

  VPN1-site 1, VPN1-site 2 and VPN1-site 3 are VPN sites belonging to VPN1, VPN2-site 1 and VPN2-site 2 are VPN sites belonging to VPN2, VPN3-site 1 and VPN3-site 2 are VPN3 VPN sites belonging to each are shown, and VPN sites of the same VPN are mutually connected by a VPN backbone network. The edge router of the VPN backbone network that connects each VPN site is the PE router (PE1, PE2, PE3), and the router in the VPN backbone network that connects these PE routers is the P router (P1, P2, P3, ...). .)

  The PE router of the VPN backbone network to which the VPN site is connected sets a VPN identifier having an arbitrary value for each VPN to which the VPN site connected to the PE router belongs. For example, as shown in FIG. 1, router PE1 sets VPN identifier 1 for VPN1, VPN identifier 2 for VPN2, and router PE2 sets VPN identifier 1 for VPN1 and VPN identifier 3 for VPN3. PE3 sets VPN identifier 1 for VPN1, VPN identifier 2 for VPN2, and VPN identifier 3 for VPN3.

  The VPN identifier is a unique value for each VPN in order to identify the VPN in the VPN backbone network, and the same VPN identifier is set for the same VPN in all PE routers. However, VPN identifiers can be set only for VPNs that perform multicast packet forwarding.

  As shown in FIG. 2, when the router PE1 determines that VPN1-site 1, which is a VPN site connected to the router, desires connection to the multicast packet transfer network, the VPN1 to which the VPN site belongs. The router identifier P1 is set as information (hereinafter referred to as multicast VPN connection information) indicating that a VPN site that performs VPN multicast (hereinafter referred to as a multicast VPN site) is connected to the VPN backbone network. , Advertise on VPN backbone network via P2. Similarly, when router PE2 determines that VPN1-site 3 and VPN3-site 2, which are VPN sites connected to the router, wish to connect to the multicast packet forwarding network, these VPN sites The VPN identifier 1 and VPN identifier 3 set to the respective VPN1 and VPN3 belong to the VPN backbone network via the routers P5 and P6 as multicast VPN connection information, and the router PE3 similarly sends the multicast VPN connection information to the router P4, Advertise on VPN backbone network via P6. In this way, the VPN identifier is advertised as multicast VPN connection information from all PE routers connected to the multicast VPN site in a specific VPN.

  The multicast VPN connection information is information indicating that the PE router of the VPN backbone network is connected to the multicast VPN site in the specific VPN, and the connection of the multicast VPN site in the specific VPN is It is also information indicating that the connection is lost when it is lost.

  When advertising the multicast VPN connection information in the VPN backbone network via the P router, the IP address of the PE router that generated the multicast VPN connection information is added to the multicast VPN connection information and advertised.

  The routers that make up the VPN backbone network activate LDP (Label distribution protocol) to set MPLS LSP, assign the VPN identifier a label as FEC (Forwarding Equivalence Class), and notify the neighboring routers using LDP To do.

  FIG. 3 shows how the label information is advertised from the router PE2 in the VPN backbone network. In this case, the router PE2 is FEC as the VPN identifier 1, Label2-1, VPN identifier 2, Label2-2, and VPN identifier 3, Label2. -3 is assigned and notified to neighboring routers P5 and P6 using LDP. Accordingly, each router holds the label information generated by its own router and the label information generated by the adjacent router.

  Routers that make up the VPN backbone network use the advertised VPN identifier as multicast VPN connection information equivalent to the destination multicast address used in the multicast routing protocol when constructing a general multicast packet forwarding network. As with the construction of a general multicast packet forwarding network, the construction of a VPN multicast forwarding network can also be implemented when a multicast packet is actually received and transmitted. .

  As shown in FIG. 4, when the router PE1 receives the multicast packet from VPN1-site 1, the same VPN identifier as the VPN identifier set for the VPN is selected from the direction in which the other router has advertised the VPN backbone network. Determine and send a multicast packet. At this time, the router PE1 encapsulates and transmits the multicast packet with the label notified from the transmission direction with the VPN identifier set for the VPN as FEC. In the example of FIG. 4, the router PE1 determines the router P2 that has been advertised to the VPN backbone network as the VPN identifier 1 that is the same as the VPN identifier 1 set in the VPN1-site 1 that is the multicast VPN site, and this router Label 20-1 generated by P2 encapsulates and transmits the VPN identifier as FEC of the multicast packet from VPN1-site 1.

  Next, as shown in FIG. 5, the P router (P2) that has received the encapsulated MPLS packet determines the VPN identifier of the packet from the FEC information of the label used for encapsulation. Then, the P router determines the transmission destination from the direction in which the VPN identifier as the same multicast VPN connection information as the VPN identifier has been advertised, and transmits the multicast packet. At this time, the label notified from the transmission direction is encapsulated with a label in which the VPN identifier set for the VPN is FEC and transmitted. At this point, the P router (P2) combines the received label and the label used for transmission so that the label switch can be performed. If transfer using the Label switch is already possible, transfer using the Label switch is performed. Thereafter, packet transfer at each P router is performed in the same manner.

  As shown in FIG. 6, when PE2 and PE3 which are PE routers on the outgoing side of the VPN backbone network receive the encapsulated packet, the VPN identifier of the packet is obtained from the FEC information of the label used for encapsulation. If there is a VPN with the same VPN identifier set, the packet is transmitted to the multicast VPN site based on the VPN route table. Each PE router has an independent route table for each VPN.

  The VPN multicast forwarding network can also be configured before sending actual multicast packets.

  As shown in FIG. 7, a multicast packet whose destination is the VPN identifier included in the multicast VPN connection information with the IP address of the PE router that generated the multicast VPN connection information included in the multicast VPN connection information as a transmission source address. Assuming that the arrival interface is predicted in advance by SPF calculation, the forwarding destination of the multicast packet can be determined in advance using the VPN identifier as a key, and the MPLS LSP can be generated by combining the labels.

  The VPN multicast packet transfer network generated in this way is generated for each VPN and for each PE router that connects the VPN site of the VPN as shown in FIG.

  It is preferable to suppress the VPN multicast packet transfer network to the required number. Therefore, as shown in FIG. 9, it is assumed that VPN1-site 1 which is a VPN site connected to router PE1 is a VPN site including a source for transmitting multicast packets (hereinafter referred to as a source VPN site). The router PE1 advertises information indicating that the source VPN site is connected (hereinafter referred to as source connection information) by adding it to the multicast VPN connection information.

  The routers that make up the VPN backbone network use source connection information or decide beforehand by setting.

  If the router that configures the VPN backbone network is set to use source connection information, the router from the PE router that generated the multicast VPN connection information advertised in the multicast VPN connection information to which the source connection information is added is used. By generating only the VPN multicast packet transfer network, only the VPN multicast packet transfer network from the source VPN site to another multicast VPN site is constructed.

  Even if the information to which the source site is connected is advertised, it is possible to construct a transfer network other than the VPN multicast transfer network that transmits multicast packets from the source site to other sites.

  Next, a specific embodiment of the method for transferring a VPN multicast packet according to the present invention will be further described.

  FIG. 10 shows an IP-VPN network using MPLS / BGP IP-VPN. In this case as well, the VPN backbone network is composed of PE routers (PE1, PE2, PE3) that connect VPN sites and P routers that connect these PE routers. (P1, P2, P3, ...).

  In order to advertise the site information connected to the VPN multicast packet transfer network in the router constituting the VPN backbone network, the extended MOSPF (hereinafter referred to as extended MOSPF) is operated.

  Extended MOSPF uses an extended group membership LSA that advertises a VPN identifier instead of a destination group advertised by group membership LSA in MOSPF. The VPN identifier advertised by the extended group membership LSA is used in the same way as the group membership LSA to construct a multicast packet forwarding network. The extended MOSPF uses the router ID of the PE router as the advertising router that advertises with the extended group membership LSA.

  The extended MOSPF advertises source information indicating that the PE router that advertises the extended group membership LSA is connected to a source that transmits multicast packets to the multicast packet forwarding network.

  When MOSPF receives a multicast packet, it builds a multicast packet forwarding network from the source address of the multicast packet and the destination group, whereas extended MOSPF uses the advertising router of the extended group membership LSA as the source address and Assuming that a multicast packet for a destination group advertised by LSA is received, a multicast packet transfer network can be constructed without actually receiving the multicast packet.

  In the extended MOSPF, when the extended group membership LSA advertises the source information, the multicast packet forwarding network is operated by the above-mentioned operation using only the advertising router advertised by the extended group membership LSA including the source information as the source address. It can be constructed.

Whether or not the extended MOSPF uses the source information of the extended group membership LSA is determined by setting the extended MOSPF in a router that operates. LDP is used as a control protocol for generating MPLS LSP.
The VPN information to which the VPN site belongs is registered in the PE router of the VPN backbone network. VPN information consists of a VPN name, a route identifier <RD> that identifies the route, and VPN route import information (RT).

  The RD of VPN information is used as a VPN identifier as connection information of a VPN site used for construction of a VPN multicast packet transfer network. In VPN backbone network, RD is set for each VPN.

  In FIG. 10, routers PE1, PE2, and PE3 connect VPN1-site 1, VPN1-site 3, and VPN1-site 2, which are VPN sites belonging to VPN1, respectively. At this time, each PE router sets RD1 as the RD of VPN information of VPN1.

  As shown in FIG. 11, each VPN site, VPN1-site 1, VPN1-site 2, and VPN1-site 3 belonging to VPN1 shown in FIG. 10 desires to participate in the VPN multicast packet forwarding network of VPN1 to which it belongs. In this case, the routers PE1, PE2, and PE3 are configured to indicate that VPN1-site 1, VPN1-site 3, and VPN1-site 2 participate in the VPN multicast packet forwarding network, respectively. PE2 and PE3 advertise RD1 to the VPN backbone network using extended MOSPF as information on sites connected to the VPN multicast packet transfer network.

  By the operation of the extended MOSPF, a VPN multicast packet transfer network for VPN1 is constructed as shown in FIG.

  The routers that make up the VPN backbone network attach MPLS Labels to RD1, which is connection information of VPN sites to VPN1's VPN multicast packet transfer network, and advertise them to neighboring routers.

  Neighboring routers can set MPLS LSP by combining MPLS Labels along the VPN multicast packet transfer network, and can construct a VPN multicast packet transfer network using MPLS LSP as a transfer path.

  If the source site is clearly known, set the source information to be used when setting up the operation of extended MOSPF in the routers that make up the VPN backbone network.

  As shown in FIG. 13, when VPN1-site 1 connected to the VPN multicast packet transfer network is a site that is a source for sending multicast packets, as shown in FIG. 14, the router PE1 connecting the VPN1-site 1 is connected to the router PE1. Set to indicate that VPN1-site 1 is the source site connected to the VPN multicast packet transfer network, and using this setting, router PE1 uses the extended MOSPF along with RD1 as source information to connect to the VPN multicast packet transfer network. Advertise

  By the operation of generating the multicast packet transfer network using the source information of the extended MOSPF, only the VPN multicast packet transfer network connecting the router PE1 to the router PE2 and the router PE3 is set as shown in FIG.

  The routers that make up the VPN backbone network attach MPLS Labels to RD1, which is connection information of VPN sites to VPN1's VPN multicast packet transfer network, and advertise them to neighboring routers. The adjacent router sets an MPLS LSP by combining MPLS labels along the VPN multicast packet transfer network 1.

  The method of the present invention as described above is a program that can be executed by a computer as a storage medium such as a magnetic disk (floppy (registered trademark) disk, hard disk, etc.), optical disk (CD-ROM, DVD, etc.), semiconductor memory, etc. It can also be stored and distributed.

FIG. 2 is a diagram showing a VPN network model constructed using a VPN network in which networks connecting sites constituting each VPN are superimposed on one network. FIG. 5 is a network diagram when advertising a VPN identifier as multicast VPN connection information to a VPN backbone network. FIG. 3 is a network diagram when label information is advertised from a router PE2. FIG. 5 is a network diagram when encapsulating and transferring with a label having a VPN identifier as FEC when receiving a multicast packet. It is a network diagram for demonstrating the packet transfer in P router. FIG. 3 is a network diagram for explaining transmission of packets from a PE router on the outgoing side of a VPN backbone network to a VPN site. FIG. 2 is an explanatory diagram for configuring a VPN multicast packet transfer network before transferring an actual multicast packet. FIG. 3 is a network diagram when a VPN multicast packet transfer network is generated for each VPN and for each PE router that connects the VPN site of the VPN. FIG. 3 is a network diagram in the case where a necessary number of VPN multicast packet transfer networks are generated. It is a figure which shows the IP-VPN network by MPLS / BGP IP-VPN. It is explanatory drawing which shows the process sequence which produces | generates a VPN multicast packet transfer network by operation | movement of extended MOSPF. It is a network diagram of a VPN multicast packet transfer network constructed by the operation of extended MOSPF. It is a figure which shows the VPN packet transfer network in case VPN1-site 1 is a site used as the source which transmits a multicast packet. It is explanatory drawing which shows the process sequence which produces | generates the multicast packet transfer network using the source information of extended MOSPF. FIG. 3 is a network diagram of a VPN multicast transfer network set using extended MOSPF source information.

Explanation of symbols

VPN1-site 1 to VPN1-site 3 Sites belonging to VPN1
VPN2-site 1 to VPN2-site 2 Sites belonging to VPN2
VPN3-site 1 to VPN3-site 2 Sites belonging to VPN3
PE1, PE2, PE3 VPN backbone network edge router
P1 to P6 VPN backbone network core router

Claims (20)

  Each VPN site in the VPN multicast packet transfer method using a VPN packet transfer network constructed using a VPN backbone network that superimposes the networks connecting the sites that make up each VPN on a single network for multiple VPNs Multicast VPN site in which a PE router, which is an edge router in the VPN backbone network to which is connected, sets a VPN identifier for each VPN to which the VPN site connected to the PE router belongs, and constitutes a VPN multicast in a specific VPN VPN multicast packet forwarding network by advertising the set VPN identifier as multicast VPN connection information to the VPN backbone network via the P router connecting the PE router from all PE routers connected to And set it to the VPN Method of transferring VPN multicast packets and wherein the transfer of VPN multicast packet by MPLS LSP set along a VPN identifier to the VPN multicast packet transfer network as FEC was.   The VPN identifier is an arbitrary value unique to each VPN in order to identify the VPN in the VPN backbone network, and the same VPN identifier is set for the same VPN in all PE routers. VPN multicast packet forwarding method as described in.   The VPN multicast packet transfer method according to claim 1, wherein the VPN identifier is set only for a VPN that performs multicast packet transfer.   The multicast connection information indicates that there is no connection to the multicast VPN site in the specific VPN other than information indicating that the PE router of the VPN backbone network is connected to the multicast VPN site in the specific VPN. The method for transferring a VPN multicast packet according to claim 1, wherein the information is also information indicating.   The VPN multicast packet according to claim 1, wherein when the multicast VPN connection information is advertised to the VPN backbone network, the IP address of the PE router that generated the multicast VPN connection information is also added and advertised. Transfer method.   By using the IP address information of the router that generated the information as the multicast connection information, a VPN multicast packet transfer network is generated without transmitting a multicast packet using the VPN multicast packet transfer network. The VPN multicast packet transfer method according to claim 5, wherein the setting is performed.   Each router constituting the VPN backbone network activates LDP to set MPLS LSP, assigns a VPN identifier as a FEC, and notifies the neighboring router using the LDP. The method for transferring a VPN multicast packet according to claim 1.   When a PE router in the VPN backbone network receives a multicast packet from a multicast VPN site connected to the PE router, the same VPN identifier as the VPN identifier set for the VPN to which the multicast VPN site belongs is sent from the other PE router to the VPN. The destination is determined from the direction advertised to the backbone network, and the multicast packet is encapsulated with the label notified from the transmission direction with the VPN identifier set for the VPN as FEC and transmitted. The method of transferring a VPN multicast packet according to claim 7.   When the PE router on the outgoing side of the VPN backbone network receives the encapsulated packet, it determines the VPN identifier of the packet from the FEC information of the label used for encapsulation, and the same VPN identifier is set. 9. The method of transferring a VPN multicast packet according to claim 8, wherein when there is a VPN, the packet is transmitted to the multicast VPN site based on the route table of the VPN.   A PE router that connects a VPN site having a source for transmitting multicast packets to the VPN multicast packet transfer network to the VPN backbone network, and a VPN site having a source for transmitting multicast packets is connected to the PE router. Only to construct a VPN multicast packet transfer network that connects each PE router that connects another site to the same VPN as the VPN to which the VPN site belongs from the PE router by advertising to the VPN backbone network The method of transferring a VPN multicast packet according to claim 1.   In a VPN packet transfer network system constructed using a VPN backbone network that superimposes a network connecting between sites constituting each VPN on a single network for a plurality of VPNs, the VPN backbone network is connected to each VPN site. PE routers that are edge routers that connect the PE routers and P routers that connect these PE routers, and each PE router sets a VPN identifier for each VPN to which the VPN site connected to the PE router belongs. In a specific VPN, from all the PE routers connected to the multicast VPN site that constitutes the VPN multicast, the set VPN identifier is used as the multicast VPN connection information via the respective P routers connecting the PE routers. And advertising to the VPN backbone network VPN packet transfer network system is characterized in that so as to build the Tsu-forwarding network.   The respective routers in the VPN backbone network are configured to transfer VPN multicast packets by MPLS LSP set along the VPN multicast packet transfer network using the VPN identifier set in the VPN as FEC. 11. The VPN packet transfer network system according to 11.   Each router configuring the VPN backbone network activates LDP to set MPLS LSP, assigns a VPN identifier as a FEC, and notifies the neighboring router using the LDP. The VPN packet transfer network system according to claim 12,   When a PE router in the VPN backbone network receives a multicast packet from a multicast VPN site connected to the PE router, the same VPN identifier as the VPN identifier set for the VPN to which the multicast VPN site belongs is sent from the other PE router to the VPN. Destination is determined from the direction advertised to the backbone network, and multicast packets are encapsulated and transmitted with the label notified from the transmission direction with the VPN identifier set for the VPN as FEC. The VPN packet transfer network system according to claim 12, wherein:   When the PE router on the outgoing side of the VPN backbone network receives the encapsulated packet, it determines the VPN identifier of the packet from the FEC information of the label used for encapsulation, and the same VPN identifier is set. 13. The VPN packet transfer network system according to claim 12, wherein when there is a VPN, the packet is transmitted to the multicast VPN site based on the route table of the VPN.   A PE router that connects a VPN site having a source for sending multicast packets to the VPN multicast packet transfer network to the VPN backbone network, and that the PE router is connected to a VPN site having a source for sending multicast packets By advertising to the VPN backbone network, only the VPN multicast packet forwarding network that connects each PE router that connects other sites that connect the same VPN as the VPN to which the VPN site belongs from the corresponding PE router was constructed. The VPN packet transfer network system according to claim 11.   For a plurality of VPNs, a router that constitutes the VPN backbone network in a VPN packet transfer network system constructed using a VPN backbone network that superimposes a network that connects sites that constitute each VPN on a single network, A VPN identifier is set for each VPN to which the VPN site connected to the router belongs, and the set VPN identifier is multicast VPN from all routers connected to the multicast VPN site constituting the VPN multicast in a specific VPN. A router that constructs a VPN multicast packet transfer network by advertising to the VPN backbone network via other routers connecting the router as connection information.   VPN multicast packet is forwarded by MPLS LSP set along the VPN multicast packet transfer network with VPN identifier set for VPN as FEC, LDP is started to set MPLS LSP, and VPN identifier is set as FEC The router according to claim 17, wherein a label is given and notified to an adjacent router using the LDP.   To allow a computer to execute a VPN multicast packet transfer process by a VPN packet transfer network constructed using a VPN backbone network that superimposes a network connecting the sites that make up each VPN on a single network. A process for setting a VPN identifier for each VPN to which a VPN site connected to the PE router belongs to a PE router that is an edge router in the VPN backbone network to which each VPN site is connected In all the VPN routers in the VPN, from all the PE routers connected to the multicast VPN site that constitutes the VPN multicast, the VPN is set via the P router that connects the PE router, using the set VPN identifier as multicast VPN connection information. VPN by advertising on backbone network To cause a computer to execute a process of constructing a multicast packet transfer network and a process of transferring a VPN multicast packet by means of an MPLS LSP set along the VPN multicast packet transfer network using the VPN identifier set in the VPN as an FEC Program.   A storage medium recording the program according to claim 19.

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