- Read Me First
- Optimizing PIM Sparse Mode in a Large IP Multicast Deployment
- Multicast Subsecond Convergence
- IP Multicast Load Splitting across Equal-Cost Paths
- Configuring Multicast Admission Control
- Per Interface Mroute State Limit
- SSM Channel Based Filtering for Multicast Boundaries
- IPv6 Multicast: Bandwidth-Based Call Admission Control
- PIM Dense Mode State Refresh
- Finding Feature Information
- Prerequisites for Optimizing PIM Sparse Mode in a Large IP Multicast Deployment
- Information About Optimizing PIM Sparse Mode in a Large IP Multicast Deployment
Optimizing PIM Sparse Mode in a Large IP Multicast Deployment
This module describes how to optimize Protocol Independent Multicast (PIM) sparse mode for a large deployment of IP multicast. You can set a limit on the rate of PIM register messages sent in order to limit the load on the designated router and RP, you can reduce the PIM router query message interval to achieve faster convergence, and you can delay or prevent the use of the shortest path tree.
- Finding Feature Information
- Prerequisites for Optimizing PIM Sparse Mode in a Large IP Multicast Deployment
- Information About Optimizing PIM Sparse Mode in a Large IP Multicast Deployment
- How to Optimize PIM Sparse Mode in a Large IP Multicast Deployment
- Configuration Examples for Optimizing PIM Sparse Mode in a Large IP Multicast Deployment
- Additional References
- Feature Information for Optimizing PIM Sparse Mode in a Large IP Multicast Deployment
Finding Feature Information
Your software release may not support all the features documented in this module. For the latest caveats and feature information, see Bug Search Tool and the release notes for your platform and software release. To find information about the features documented in this module, and to see a list of the releases in which each feature is supported, see the feature information table at the end of this module.
Use Cisco Feature Navigator to find information about platform support and Cisco software image support. To access Cisco Feature Navigator, go to www.cisco.com/go/cfn. An account on Cisco.com is not required.
Prerequisites for Optimizing PIM Sparse Mode in a Large IP Multicast Deployment
Information About Optimizing PIM Sparse Mode in a Large IP Multicast Deployment
- PIM Registering Process
- PIM Designated Router
- PIM Sparse-Mode Register Messages
- Preventing Use of Shortest-Path Tree to Reduce Memory Requirement
PIM Registering Process
IP multicast sources do not use a signaling mechanism to announce their presence. Sources just send their data into the attached network, as opposed to receivers that use Internet Group Management Protocol (IGMP) to announce their presence. If a source sends traffic to a multicast group configured in PIM sparse mode (PIM-SM), the Designated Router (DR) leading toward the source must inform the rendezvous point (RP) about the presence of this source. If the RP has downstream receivers that want to receive the multicast traffic (natively) from this source and has not joined the shortest path leading toward the source, then the DR must send the traffic from the source to the RP. The PIM registering process, which is individually run for each (S, G) entry, accomplishes these tasks between the DR and RP.
The registering process begins when a DR creates a new (S, G) state. The DR encapsulates all the data packets that match the (S, G) state into PIM register messages and unicasts those register messages to the RP.
If an RP has downstream receivers that want to receive register messages from a new source, the RP can either continue to receive the register messages through the DR or join the shortest path leading toward the source. By default, the RP will join the shortest path, because delivery of native multicast traffic provides the highest throughput. Upon receipt of the first packet that arrives natively through the shortest path, the RP will send a register-stop message back to the DR. When the DR receives this register-stop message, it will stop sending register messages to the RP.
If an RP has no downstream receivers that want to receive register messages from a new source, the RP will not join the shortest path. Instead, the RP will immediately send a register-stop message back to the DR. When the DR receives this register-stop message, it will stop sending register messages to the RP.
Once a routing entry is established for a source, a periodic reregistering takes place between the DR and RP. One minute before the multicast routing table state times out, the DR will send one dataless register message to the RP each second that the source is active until the DR receives a register-stop message from the RP. This action restarts the timeout time of the multicast routing table entry, typically resulting in one reregistering exchange every 2 minutes. Reregistering is necessary to maintain state, to recover from lost state, and to keep track of sources on the RP. It will take place independently of the RP joining the shortest path.
PIM Version 1 Compatibility
If an RP is running PIM Version 1, it will not understand dataless register messages. In this case, the DR will not send dataless register messages to the RP. Instead, approximately every 3 minutes after receipt of a register-stop message from the RP, the DR encapsulates the incoming data packets from the source into register messages and sends them to the RP. The DR continues to send register messages until it receives another register-stop message from the RP. The same behavior occurs if the DR is running PIM Version 1.
When a DR running PIM Version 1 encapsulates data packets into register messages for a specific (S, G) entry, the entry is process-switched, not fast-switched or hardware-switched. On platforms that support these faster paths, the PIM registering process for an RP or DR running PIM Version 1 may lead to periodic out-of-order packet delivery. For this reason, we recommend upgrading your network from PIM Version 1 to PIM Version 2.
PIM Designated Router
Devices configured for IP multicast send PIM hello messages to determine which device will be the designated router (DR) for each LAN segment (subnet). The hello messages contain the device’s IP address, and the device with the highest IP address becomes the DR.
The DR sends Internet Group Management Protocol (IGMP) host query messages to all hosts on the directly connected LAN. When operating in sparse mode, the DR sends source registration messages to the rendezvous point (RP).
By default, multicast devices send PIM router query messages every 30 seconds. By enabling a device to send PIM hello messages more often, the device can discover unresponsive neighbors more quickly. As a result, the device can implement failover or recovery procedures more efficiently. It is appropriate to make this change only on redundant devices on the edge of the network.
PIM Sparse-Mode Register Messages
Dataless register messages are sent at a rate of one message per second. Continuous high rates of register messages might occur if a DR is registering bursty sources (sources with high data rates) and if the RP is not running PIM Version 2.
By default, PIM sparse-mode register messages are sent without limiting their rate. Limiting the rate of register messages will limit the load on the DR and RP, at the expense of dropping those register messages that exceed the set limit. Receivers may experience data packet loss within the first second in which packets are sent from bursty sources.
Preventing Use of Shortest-Path Tree to Reduce Memory Requirement
Understanding PIM shared tree and source tree will help you understand how preventing the use of the shortest-path tree can reduce memory requirements.
- PIM Shared Tree and Source Tree - Shortest-Path Tree
- Benefit of Preventing or Delaying the Use of the Shortest-Path Tree
PIM Shared Tree and Source Tree - Shortest-Path Tree
By default, members of a multicast group receive data from senders to the group across a single data distribution tree rooted at the rendezvous point (RP). This type of distribution tree is called shared tree, as shown in the figure. Data from senders is delivered to the RP for distribution to group members joined to the shared tree.
If the data rate warrants, leaf routers on the shared tree may initiate a switch to the data distribution tree rooted at the source. This type of distribution tree is called a shortest-path tree (SPT) or source tree. By default, the software switches to a source tree upon receiving the first data packet from a source.
The following process describes the move from shared tree to source tree in more detail:
Receiver joins a group; leaf Router C sends a Join message toward the RP.
The RP puts the link to Router C in its outgoing interface list.
Source sends data; Router A encapsulates data in a register message and sends it to the RP.
The RP forwards data down the shared tree to Router C and sends a Join message toward the source. At this point, data may arrive twice at Router C, once encapsulated and once natively.
When data arrives natively (through multicast) at the RP, the RP sends a register-stop message to Router A.
By default, reception of the first data packet prompts Router C to send a Join message toward the source.
When Router C receives data on (S, G), it sends a Prune message for the source up the shared tree.
The RP deletes the link to Router C from the outgoing interface of (S, G). The RP triggers a Prune message toward the source.
Join and Prune messages are sent for sources and RPs. They are sent hop-by-hop and are processed by each PIM router along the path to the source or RP. Register and register-stop messages are not sent hop-by-hop. They are sent by the designated router that is directly connected to a source and are received by the RP for the group.
Multiple sources sending to groups use the shared tree.
Benefit of Preventing or Delaying the Use of the Shortest-Path Tree
The switch from shared to source tree happens upon the arrival of the first data packet at the last hop device (Router C in Benefit of Preventing or Delaying the Use of the Shortest-Path Tree). This switch occurs because the ip pim spt-threshold command controls that timing, and its default setting is 0 kbps.
The shortest-path tree requires more memory than the shared tree, but reduces delay. You might want to prevent or delay its use to reduce memory requirements. Instead of allowing the leaf device to move to the shortest-path tree immediately, you can prevent use of the SPT or specify that the traffic must first reach a threshold.
You can configure when a PIM leaf device should join the shortest-path tree for a specified group. If a source sends at a rate greater than or equal to the specified kbps rate, the device triggers a PIM Join message toward the source to construct a source tree (shortest-path tree). If the infinity keyword is specified, all sources for the specified group use the shared tree, never switching to the source tree.
How to Optimize PIM Sparse Mode in a Large IP Multicast Deployment
Optimizing PIM Sparse Mode in a Large Deployment
Consider performing this task if your deployment of IP multicast is large.
Steps 3, 5, and 6 in this task are independent of each other and are therefore considered optional. Any one of these steps will help optimize PIM sparse mode. If you are going to perform Step 5 or 6, you must perform Step 4. Step 6 applies only to a designated router; changing the PIM query interval is only appropriate on redundant routers on the edge of the PIM domain.
1.
enable
2.
configure
terminal
3.
ip
pim
register-rate-limit
rate
4.
ip
pim
spt-threshold
{kbps| infinity}[group-list access-list]
5.
interface
type
number
6.
ip
pim
query-interval
period
[msec]
DETAILED STEPS
Configuration Examples for Optimizing PIM Sparse Mode in a Large IP Multicast Deployment
Optimizing PIM Sparse Mode in a Large IP Multicast Deployment Example
The following example shows how to:
Set the query interval to 1 second for faster convergence.
Configure the router to never move to the SPT but to remain on the shared tree.
Set a limit of 10 PIM sparse mode register messages sent per second for each (S, G) routing entry.
interface ethernet 0 ip pim query-interval 1 . . . ! ip pim spt-threshold infinity ip pim register-rate-limit 10 !
Additional References
Related Documents
Related Topic |
Document Title |
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Cisco IOS commands |
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Cisco IOS IP SLAs commands |
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PIM Sparse Mode concepts and configuration |
“Configuring Basic IP Multicast” module or “Configuring IP Multicast in IPv6 Networks” module |
MIBs
MIB |
MIBs Link |
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No new or modified MIBs are supported by these features, and support for existing MIBs has not been modified by these features. |
To locate and download MIBs for selected platforms, Cisco IOS XE releases, and feature sets, use Cisco MIB Locator found at the following URL: |
Technical Assistance
Description |
Link |
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The Cisco Support and Documentation website provides online resources to download documentation, software, and tools. Use these resources to install and configure the software and to troubleshoot and resolve technical issues with Cisco products and technologies. Access to most tools on the Cisco Support and Documentation website requires a Cisco.com user ID and password. |
Feature Information for Optimizing PIM Sparse Mode in a Large IP Multicast Deployment
The following table provides release information about the feature or features described in this module. This table lists only the software release that introduced support for a given feature in a given software release train. Unless noted otherwise, subsequent releases of that software release train also support that feature.
Use Cisco Feature Navigator to find information about platform support and Cisco software image support. To access Cisco Feature Navigator, go to www.cisco.com/go/cfn. An account on Cisco.com is not required.
Feature Name |
Releases |
Feature Configuration Information |
---|---|---|
PIM Version 2 |
12.2(4)T |
Protocol Independent Multicast (PIM) version 2 builds upon the success of the existing PIMv1 base, has two basic operating modes: sparse-mode and dense-mode, and is suitable for large networks with heterogeneous links and devices. |