R3102-R3103-HP 6600/HSR6600 Routers IP Multicast Configuration Guide
Table Of Contents
- Title Page
- Contents
- Multicast overview
- Configuring IGMP snooping
- Overview
- IGMP snooping configuration task list
- Configuring basic IGMP snooping functions
- Configuring IGMP snooping port functions
- Configuring IGMP snooping querier
- Configuring IGMP snooping proxying
- Configuring IGMP snooping policies
- Configuration prerequisites
- Configuring a multicast group filter
- Configuring multicast source port filtering
- Enabling dropping unknown multicast data
- Enabling IGMP report suppression
- Setting the maximum number of multicast groups that a port can join
- Enabling multicast group replacement
- Setting the 802.1p precedence for IGMP messages
- Enabling the IGMP snooping host tracking function
- Displaying and maintaining IGMP snooping
- IGMP snooping configuration examples
- Troubleshooting IGMP snooping
- Appendix
- Configuring multicast routing and forwarding
- Overview
- Configuration task list
- Enabling IP multicast routing
- Configuring multicast routing and forwarding
- Displaying and maintaining multicast routing and forwarding
- Configuration examples
- Troubleshooting multicast routing and forwarding
- Configuring IGMP
- Overview
- IGMP configuration task list
- Configuring basic IGMP functions
- Adjusting IGMP performance
- Configuring IGMP SSM mapping
- Configuring IGMP proxying
- Displaying and maintaining IGMP
- IGMP configuration examples
- Troubleshooting IGMP
- Configuring PIM
- Overview
- Configuring PIM-DM
- Configuring PIM-SM
- Configuring BIDIR-PIM
- Configuring PIM-SSM
- Configuring common PIM features
- Displaying and maintaining PIM
- PIM configuration examples
- Troubleshooting PIM
- Configuring MSDP
- Overview
- MSDP configuration task list
- Configuring basic MSDP functions
- Configuring an MSDP peer connection
- Configuring SA message related parameters
- Displaying and maintaining MSDP
- MSDP configuration examples
- Troubleshooting MSDP
- Configuring MBGP
- MBGP overview
- Protocols and standards
- MBGP configuration task list
- Configuring basic MBGP functions
- Controlling route advertisement and reception
- Configuration prerequisites
- Configuring MBGP route redistribution
- Configuring default route redistribution into MBGP
- Configuring MBGP route summarization
- Advertising a default route to an IPv4 MBGP peer or peer group
- Configuring outbound MBGP route filtering
- Configuring inbound MBGP route filtering
- Configuring MBGP route dampening
- Configuring MBGP route attributes
- Optimizing MBGP networks
- Configuring a large scale MBGP network
- Displaying and maintaining MBGP
- MBGP configuration example
- Configuring multicast VPN
- Overview
- How MD-VPN works
- Multicast VPN configuration task list
- Configuring MD-VPN
- Configuring BGP MDT
- Specifying the source IP address for multicast across VPNs
- Displaying and maintaining multicast VPN
- Multicast VPN configuration examples
- Troubleshooting MD-VPN
- Configuring IPv6 multicast routing and forwarding
- Overview
- Configuration task list
- Enabling IPv6 multicast routing
- Configuring IPv6 multicast routing and forwarding
- Displaying and maintaining IPv6 multicast routing and forwarding
- IPv6 multicast forwarding over GRE tunnel configuration example
- Troubleshooting abnormal termination of IPv6 multicast data
- Configuring MLD
- Overview
- MLD configuration task list
- Configuring basic MLD functions
- Adjusting MLD performance
- Configuring MLD SSM mapping
- Configuring MLD proxying
- Displaying and maintaining MLD
- MLD configuration examples
- Troubleshooting MLD
- Configuring IPv6 PIM
- Overview
- Configuring IPv6 PIM-DM
- Configuring IPv6 PIM-SM
- Configuring IPv6 BIDIR-PIM
- Configuring IPv6 PIM-SSM
- Configuring common IPv6 PIM features
- Displaying and maintaining IPv6 PIM
- IPv6 PIM configuration examples
- Troubleshooting IPv6 PIM
- Configuring IPv6 MBGP
- Overview
- IPv6 MBGP configuration task list
- Configuring basic IPv6 MBGP functions
- Controlling route distribution and reception
- Configuration prerequisites
- Injecting a local IPv6 MBGP route
- Configuring IPv6 MBGP route redistribution
- Configuring IPv6 MBGP route summarization
- Advertising a default route to a peer or peer group
- Configuring outbound IPv6 MBGP route filtering
- Configuring inbound IPv6 MBGP route filtering
- Configuring IPv6 MBGP route dampening
- Configuring IPv6 MBGP route attributes
- Optimizing IPv6 MBGP networks
- Configuring a large scale IPv6 MBGP network
- Displaying and maintaining IPv6 MBGP
- IPv6 MBGP configuration example
- Configuring PIM snooping
- Configuring multicast VLANs
- Support and other resources
- Index
46
considers the path of the packet that the RPF interface receives from the RPF neighbor as the
shortest path that leads back to the source.
{ The router searches its MBGP routing table by using the IP address of the packet source as the
destination address and automatically chooses an optimal MBGP route. The outgoing interface
of the route is the RPF interface and the next hop is the RPF neighbor.
{ The router searches its static multicast routing table by using the IP address of the packet source
as the source address and automatically chooses an optimal static multicast route. The route
explicitly defines the RPF interface and the RPF neighbor.
2. The router selects one of the optimal routes as the RPF route according to the following principles:
{ If the router uses the longest match principle, it selects the longest matching route as the RPF
route. If the routes have the same mask, the router selects the route that has the highest priority
as the RPF route. If the routes have the same priority, the router selects a route as the RPF route
in the order of static multicast route, MBGP route, and unicast route.
{ If the router does not use the longest match principle, it selects the route that has the highest
priority as the RPF route. If the routes have the same priority, the router selects a route as the RPF
route in the order of static multicast route, MBGP route, and unicast route.
The term "packet source" means different things in different situations:
• For a packet traveling along the SPT from the multicast source to the receivers or the RP, the packet
source for RPF check is the multicast source.
• For a packet traveling along the RPT from the RP to the receivers, or along the source-side RPT from
the multicast source to the RP, the packet source for RPF check is the RP.
• For a bootstrap message from the BSR, the packet source for RPF check is the BSR.
For more information about the concepts of SPT, RPT, source-side RPT, RP, and BSR, see "Configuring
PIM." For more information about multicast across VPNs, see "Configuring multicast VPN."
RPF check implementation in multicast
Implementing an RPF check on each received multicast packet would bring a big burden to the router.
The use of a multicast forwarding table is the solution to this issue. When the router creates a multicast
routing entry and a multicast forwarding entry for a multicast packet, it sets the RPF interface of the packet
as the incoming interface of the forwarding entry. After the router receives a multicast packet, it searches
its multicast forwarding table:
• If no forwarding entry matches the packet, the packet undergoes an RPF check. The router creates
a multicast routing entry with the RPF interface as the incoming interface and adds the entry into the
multicast forwarding table.
{ If the interface that received the packet is the RPF interface, the RPF check succeeds and the
router forwards the packet out of all the outgoing interfaces.
{ If the interface that received the packet is not the RPF interface, the RPF check fails and the
router discards the packet.
• If a forwarding entry matches the packet and the interface that received the packet is the incoming
interface of the forwarding entry, the router forwards the packet out of all outgoing interfaces.
• If a forwarding entry matches the packet but the interface that received the packet is not the
incoming interface of the forwarding entry, the multicast packet undergoes an RPF check.
{ If the RPF interface is the incoming interface, it indicates that the forwarding entry is correct but
the packet traveled along a wrong path. The router discards the packet.
{ If the RPF interface is not the incoming interface, it indicates that the forwarding entry has
expired, and the router replaces the incoming interface with the RPF interface. If the interface