Implementing RSVP for MPLS-TE

This module describes how to implement Resource Reservation Protocol (RSVP) for MPLS Traffic Engineering (MPLS-TE) on Cisco ASR 9000 Series Aggregation Services Routers.

The Multiprotocol Label Switching (MPLS) is a standards-based solution, driven by the Internet Engineering Task Force (IETF), devised to convert the Internet and IP backbones from best-effort networks into business-class transport media.

Resource Reservation Protocol (RSVP) is a signaling protocol that enables systems to request resource reservations from the network. RSVP processes protocol messages from other systems, processes resource requests from local clients, and generates protocol messages. As a result, resources are reserved for data flows on behalf of local and remote clients. RSVP creates, maintains, and deletes these resource reservations.

RSVP provides a secure method to control quality-of-service (QoS) access to a network.

MPLS Traffic Engineering (MPLS-TE) uses RSVP to signal label switched paths (LSPs).

Feature History for Implementing RSVP for MPLS-TE

Release

Modification

Release 3.7.2

This feature was introduced.

Release 3.9.0

The RSVP MIB feature was added.

Prerequisites for Implementing RSVP for MPLS-TE

These prerequisites are required to implement RSVP for MPLS-TE :

  • You must be in a user group associated with a task group that includes the proper task IDs. The command reference guides include the task IDs required for each command. If you suspect user group assignment is preventing you from using a command, contact your AAA administrator for assistance.

  • Either a composite mini-image plus an MPLS package, or a full image, must be installed.

Information About Implementing RSVP for MPLS-TE

To implement MPLS RSVP, you must understand the these concepts:

Overview of RSVP for MPLS-TE

RSVP is a network control protocol that enables Internet applications to signal LSPs for MPLS-TE . The RSVP implementation is compliant with the IETF RFC 2205, and RFC 3209.

RSVP is automatically enabled on interfaces on which MPLS-TE is configured. For MPLS-TE LSPs with nonzero bandwidth, the RSVP bandwidth has to be configured on the interfaces. There is no need to configure RSVP, if all MPLS-TE LSPs have zero bandwidth .

RSVP Refresh Reduction, defined in RFC 2961, includes support for reliable messages and summary refresh messages. Reliable messages are retransmitted rapidly if the message is lost. Because each summary refresh message contains information to refresh multiple states, this greatly reduces the amount of messaging needed to refresh states. For refresh reduction to be used between two routers, it must be enabled on both routers. Refresh Reduction is enabled by default.

Message rate limiting for RSVP allows you to set a maximum threshold on the rate at which RSVP messages are sent on an interface. Message rate limiting is disabled by default.

The process that implements RSVP is restartable. A software upgrade, process placement or process failure of RSVP or any of its collaborators, has been designed to ensure Nonstop Forwarding (NSF) of the data plane.

RSVP supports graceful restart, which is compliant with RFC 3473. It follows the procedures that apply when the node reestablishes communication with the neighbor’s control plane within a configured restart time.

It is important to note that RSVP is not a routing protocol. RSVP works in conjunction with routing protocols and installs the equivalent of dynamic access lists along the routes that routing protocols calculate. Because of this, implementing RSVP in an existing network does not require migration to a new routing protocol.

LSP Setup

LSP setup is initiated when the LSP head node sends path messages to the tail node (see the RSVP Operation figure ).

Figure 1. RSVP Operation.


The Path messages reserve resources along the path to each node, creating Path soft states on each node. When the tail node receives a path message, it sends a reservation (RESV) message with a label back to the previous node. When the reservation message arrives at the previous node, it causes the reserved resources to be locked and forwarding entries are programmed with the MPLS label sent from the tail-end node. A new MPLS label is allocated and sent to the next node upstream.

When the reservation message reaches the head node, the label is programmed and the MPLS data starts to flow along the path.

High Availability

RSVP is designed to ensure nonstop forwarding under the following constraints:

  • Ability to tolerate the failure of one RP of a 1:1 redundant pair.

  • Hitless software upgrade.

The RSVP high availability (HA) design follows the constraints of the underlying architecture where processes can fail without affecting the operation of other processes. A process failure of RSVP or any of its collaborators does not cause any traffic loss or cause established LSPs to go down. When RSVP restarts, it recovers its signaling states from its neighbors. No special configuration or manual intervention are required. You may configure RSVP graceful restart, which offers a standard mechanism to recover RSVP state information from neighbors after a failure.

Graceful Restart

RSVP graceful restart provides a control plane mechanism to ensure high availability (HA), which allows detection and recovery from failure conditions while preserving nonstop forwarding services on the systems running Cisco IOS XR software.

RSVP graceful restart provides a mechanism that minimizes the negative effects on MPLS traffic caused by these types of faults:

  • Disruption of communication channels between two nodes when the communication channels are separate from the data channels. This is called control channel failure.

  • Control plane of a node fails but the node preserves its data forwarding states. This is called node failure.

The procedure for RSVP graceful restart is described in the “Fault Handling” section of RFC 3473, Generalized MPLS Signaling, RSVP-TE Extensions. One of the main advantages of using RSVP graceful restart is recovery of the control plane while preserving nonstop forwarding and existing labels.


Note


RSVP graceful restart feature is not supported when TE is running over multiple IGP instances which have different TE router-ids. This causes the TE tunnels to constantly flap.


Graceful Restart: Standard and Interface-Based

When you configure RSVP graceful restart, Cisco IOS XR software sends and expects node-id address based Hello messages (that is, Hello Request and Hello Ack messages). The RSVP graceful restart Hello session is not established if the neighbor router does not respond with a node-id based Hello Ack message.

You can also configure graceful restart to respond (send Hello Ack messages) to interface-address based Hello messages sent from a neighbor router in order to establish a graceful restart Hello session on the neighbor router. If the neighbor router does not respond with node-id based Hello Ack message, however, the RSVP graceful restart Hello session is not established.

Cisco IOS XR software provides two commands to configure graceful restart:

  • signalling hello graceful-restart

  • signalling hello graceful-restart interface-based


Note


By default, graceful restart is disabled. To enable interface-based graceful restart, you must first enable standard graceful restart. You cannot enable interface-based graceful restart independently.


Graceful Restart: Figure

Figure 2. Node Failure with RSVP. This figure illustrates how RSVP graceful restart handles a node failure condition.


RSVP graceful restart requires the use of RSVP hello messages. Hello messages are used between RSVP neighbors. Each neighbor can autonomously issue a hello message containing a hello request object. A receiver that supports the hello extension replies with a hello message containing a hello acknowledgment (ACK) object. This means that a hello message contains either a hello Request or a hello ACK object. These two objects have the same format.

The restart cap object indicates a node’s restart capabilities. It is carried in hello messages if the sending node supports state recovery. The restart cap object has the following two fields:
Restart Time

Time after a loss in Hello messages within which RSVP hello session can be reestablished. It is possible for a user to manually configure the Restart Time.

Recovery Time

Time that the sender waits for the recipient to re-synchronize states after the re-establishment of hello messages. This value is computed and advertised based on number of states that existed before the fault occurred.

For graceful restart, the hello messages are sent with an IP Time to Live (TTL) of 64. This is because the destination of the hello messages can be multiple hops away. If graceful restart is enabled, hello messages (containing the restart cap object) are send to an RSVP neighbor when RSVP states are shared with that neighbor.

Restart cap objects are sent to an RSVP neighbor when RSVP states are shared with that neighbor. If the neighbor replies with hello messages containing the restart cap object, the neighbor is considered to be graceful restart capable. If the neighbor does not reply with hello messages or replies with hello messages that do not contain the restart cap object, RSVP backs off sending hellos to that neighbor. If graceful restart is disabled, no hello messages (Requests or ACKs) are sent. If a hello Request message is received from an unknown neighbor, no hello ACK is sent back.

ACL-based Prefix Filtering

RSVP provides for the configuration of extended access lists (ACLs) to forward, drop, or perform normal processing on RSVP router-alert (RA) packets. Prefix filtering is designed for use at core access routers in order that RA packets (identified by a source/destination address) can be seamlessly forwarded across the core from one access point to another (or, conversely to be dropped at this node). RSVP applies prefix filtering rules only to RA packets because RA packets contain source and destination addresses of the RSVP flow.


Note


RA packets forwarded due to prefix filtering must not be sent as RSVP bundle messages, because bundle messages are hop-by-hop and do not contain RA. Forwarding a Bundle message does not work, because the node receiving the messages is expected to apply prefix filtering rules only to RA packets.


For each incoming RSVP RA packet, RSVP inspects the IP header and attempts to match the source/destination IP addresses with a prefix configured in an extended ACL. The results are as follows:

  • If an ACL does not exist, the packet is processed like a normal RSVP packet.

  • If the ACL match yields an explicit permit (and if the packet is not locally destined), the packet is forwarded. The IP TTL is decremented on all forwarded packets.

  • If the ACL match yields an explicit deny, the packet is dropped.

If there is no explicit permit or explicit deny, the ACL infrastructure returns an implicit (default) deny. RSVP can be configured to drop the packet. By default, RSVP processes the packet if the ACL match yields an implicit (default) deny.

RSVP MIB

RFC 2206, RSVP Management Information Base Using SMIv2 defines all the SNMP MIB objects that are relevant to RSVP. By implementing the RSVP MIB, you can perform these functions:

  • Specifies two traps (NetFlow and LostFlow) which are triggered when a new flow is created or deleted.

  • Lets you use SNMP to access objects belonging to RSVP.

Bandwidth Reservation Percentage

The Bandwidth Reservation Percentage allows the RSVP interface bandwidth to be specified as percentages of the link's physical bandwidth.

MPLS-TE LSP OOR

MPLS-TE LSP OOR

The MPLS-TE LSP OOR function adds capability for the RSVP-TE control plane to track the LSP scale of transit routers, so that it can take a specific set of (pre-configured) actions when threshold limits are crossed, and inform other routers in the network. MPLS-TE keeps track of the number of transit LSPs set up through the router. The limits do not apply to ingress and egress LSP routers since they are driven by explicit configuration. In other words, the configuration determines how many egress or ingress LSPs a router has. For midpoint routers, the number is a function of the topology, the links metrics, and links’ bandwidth.

State Transition Triggers - The LSP OOR state transition is triggered by checking the total transit LSP count and the unprotected count. If either count crosses the threshold, the state transition is triggered. If both counts cross the limit, the more critical state is chosen. Each limit will have a value for the Yellow threshold and a value for the Red threshold. When these thresholds are crossed, the configured MPLS-TE LSP OOR actions take effect. Similarly, the transition to Green state occurs when the LSP numbers drop.

LSP OOR State Dampening - The reason for LSP OOR State Dampening is that the number of accepted LSPs would be at the threshold and once an LSP is deleted, the state goes back from Red to Yellow, and a new LSP is setup and the state goes back to Red.

The solution is to introduce dampening when there is a state transition from Red to Yellow or from Yellow to Green. Whenever the transit number of LSPs crosses down a threshold, a timer is started for 10 seconds. After the timer expires, the new state is computed and moved to it. The timer is stopped if the transit number threshold is crossed (up) again. The transition from a state to a more severe state is not dampened.

Low and High Priority LSPs - When the LSP OOR is in yellow or red state, new high priority LSPs will not preempt low priority LSPs. Preemption can still occur but only for bandwidth reasons. In other words, if the router is in Red state where one of the actions is to reject any new LSP, the new high-priority LSPs are rejected even if there is an established low-priority LSP. The low-priority LSP is not removed to make room for the high-priority one.

Configuration Limit - Setting the configured limit to a value that is smaller than the current number of LSPs will trigger state transition but will not cause existing LSPs to be deleted or preempted. Setting the configured limit to a value that is larger than the current number of LSPs takes the node out of LSP OOR state. When an LSP cannot be admitted due to LSP OOR, the LSRs send Path Error messages to the LERs.

Event Logging - This is generated when the system transitions across OOR states, such as a resource change into an yellow or red state. Reporting level for Red is critical (1), and for yellow is warning (4). The following example shows that the count has crossed the threshold of 5000.

RP/0/RP1/CPU0:May 15 17:05:48 PDT: te_control[1034]: %ROUTING-MPLS_TE-4-LSP_OOR : 

Transit LSP resources changed to Yellow. 
Total transit: configured threshold 5000; actual count 5001; 
Unprotected transit: configured threshold 4294967295; actual count 0

When the resource comes out of OOR, it will report as green.

Configuration Example

mpls traffic-eng
 lsp-oor
  green 
   action accept reopt-lsp
   action flood available-bw 20  
   recovery-duration 
   action admit lsp-min-bw   X   -- > (in kbps, a lower limit than yellow and red state)
 
  yellow 
   transit-all threshold 75000
   action accept reopt-lsp
   action flood available-bw 0
   action admit lsp-min-bw  Y 

  red 
   transit-all threshold 90000
   action flood available-bw 0
   action admit lsp-min-bw Z

The LSP OOR threshold values are set to yellow as 75000 and red as 90000. When these thresholds are crossed, corresponding actions are applied to all the TE interfaces.


Note


The default values of the above thresholds are infinite.


When the LSP OOR yellow state is reached, the accept reopt-lsp action, flood available-bw 0 action and admit lsp-min-bw actions are activated. This allows headend routers to reoptimize existing LSPs through, but doesn’t allow new LSPs to get established. Also, MPLS-TE advertises zero bandwidth out of all interfaces, making this transit router less preferable for new LSPs. To handle a sudden burst of new LSPs that get signaled, the action admit lsp-min-bw function ensures only a small number of high bandwidth LSPs get provisioned through the affected router. When the red threshold state is crossed, the flood available-bw 0 and admit lsp-min-bw actions prevent any additional or reoptimized transit LSPs from getting set up through the affected router.

Information About Implementing RSVP Authentication

Before implementing RSVP authentication, you must configure a keychain first. The name of the keychain must be the same as the one used in the keychain configuration. For more information about configuring keychains, see System Security Configuration Guide for Cisco ASR 9000 Series Routers.


Note


RSVP authentication supports only keyed-hash message authentication code (HMAC) type algorithms.


To implement RSVP authentication on Cisco IOS XR software, you must understand the following concepts:

RSVP Authentication Functions

You can carry out these tasks with RSVP authentication:

  • Set up a secure relationship with a neighbor by using secret keys that are known only to you and the neighbor.

  • Configure RSVP authentication in global, interface, or neighbor configuration modes.

  • Authenticate incoming messages by checking if there is a valid security relationship that is associated based on key identifier, incoming interface, sender address, and destination address.

  • Add an integrity object with message digest to the outgoing message.

  • Use sequence numbers in an integrity object to detect replay attacks.

RSVP Authentication Design

Network administrators need the ability to establish a security domain to control the set of systems that initiates RSVP requests.

The RSVP authentication feature permits neighbors in an RSVP network to use a secure hash to sign all RSVP signaling messages digitally, thus allowing the receiver of an RSVP message to verify the sender of the message without relying solely on the sender's IP address.

The signature is accomplished on a per-RSVP-hop basis with an RSVP integrity object in the RSVP message as defined in RFC 2747. This method provides protection against forgery or message modification. However, the receiver must know the security key used by the sender to validate the digital signature in the received RSVP message.

Network administrators manually configure a common key for each RSVP neighbor on the shared network.

The following reasons explain how to choose between global, interface, or neighbor configuration modes:

  • Global configuration mode is optimal when a router belongs to a single security domain (for example, part of a set of provider core routers). A single common key set is expected to be used to authenticate all RSVP messages.

  • Interface, or neighbor configuration mode, is optimal when a router belongs to more than one security domain. For example, a provider router is adjacent to the provider edge (PE), or a PE is adjacent to an edge device. Different keys can be used but not shared.

Global configuration mode configures the defaults for interface and neighbor interface modes. These modes, unless explicitly configured, inherit the parameters from global configuration mode, as follows:

  • Window-size is set to 1.

  • Lifetime is set to 1800.

  • key-source key-chain command is set to none or disabled.

Global, Interface, and Neighbor Authentication Modes

You can configure global defaults for all authentication parameters including key, window size, and lifetime. These defaults are inherited when you configure authentication for each neighbor or interface. However, you can also configure these parameters individually on a neighbor or interface basis, in which case the global values (configured or default) are no longer inherited.


Note


RSVP uses the following rules when choosing which authentication parameter to use when that parameter is configured at multiple levels (interface, neighbor, or global). RSVP goes from the most specific to least specific; that is, neighbor, interface, and global.


Global keys simplify the configuration and eliminate the chances of a key mismatch when receiving messages from multiple neighbors and multiple interfaces. However, global keys do not provide the best security.

Interface keys are used to secure specific interfaces between two RSVP neighbors. Because many of the RSVP messages are IP routed, there are many scenarios in which using interface keys are not recommended. If all keys on the interfaces are not the same, there is a risk of a key mismatch for the following reasons:

  • When the RSVP graceful restart is enabled, RSVP hello messages are sent with a source IP address of the local router ID and a destination IP address of the neighbor router ID. Because multiple routes can exist between the two neighbors, the RSVP hello message can traverse to different interfaces.

  • When the RSVP fast reroute (FRR) is active, the RSVP Path and Resv messages can traverse multiple interfaces.

  • When Generalized Multiprotocol Label Switching (GMPLS) optical tunnels are configured, RSVP messages are exchanged with router IDs as the source and destination IP addresses. Since multiple control channels can exist between the two neighbors, the RSVP messages can traverse different interfaces.

Neighbor-based keys are particularly useful in a network in which some neighbors support RSVP authentication procedures and others do not. When the neighbor-based keys are configured for a particular neighbor, you are advised to configure all the neighbor’s addresses and router IDs for RSVP authentication.

Security Association

A security association (SA) is defined as a collection of information that is required to maintain secure communications with a peer to counter replay attacks, spoofing, and packet corruption.

This table lists the main parameters that define a security association.

Table 1. Security Association Main Parameters

Parameter

Description

src

IP address of the sender.

dst

IP address of the final destination.

interface

Interface of the SA.

direction

Send or receive type of the SA.

Lifetime

Expiration timer value that is used to collect unused security association data.

Sequence Number

Last sequence number that was either sent or accepted (dependent of the direction type).

key-source

Source of keys for the configurable parameter.

keyID

Key number (returned form the key-source) that was last used.

digest

Algorithm last used (returned from the key-source).

Window Size

Specifies the tolerance for the configurable parameter. The parameter is applicable when the direction parameter is the receive type.

Window

Specifies the last window size value sequence number that is received or accepted. The parameter is applicable when the direction parameter is the receive type.

An SA is created dynamically when sending and receiving messages that require authentication. The neighbor, source, and destination addresses are obtained either from the IP header or from an RSVP object, such as a HOP object, and whether the message is incoming or outgoing.

When the SA is created, an expiration timer is created. When the SA authenticates a message, it is marked as recently used. The lifetime timer periodically checks if the SA is being used. If so, the flag is cleared and is cleaned up for the next period unless it is marked again.

This table shows how to locate the source and destination address keys for an SA that is based on the message type.

Table 2. Source and Destination Address Locations for Different Message Types

Message Type

Source Address Location

Destination Address Location

Path

HOP object

SESSION object

PathTear

HOP object

SESSION object

PathError

HOP object

IP header

Resv

HOP object

IP header

ResvTear

HOP object

IP header

ResvError

HOP object

IP header

ResvConfirm

IP header

CONFIRM object

Ack

IP header

IP header

Srefresh

IP header

IP header

Hello

IP header

IP header

Bundle

Key-source Key-chain

The key-source key-chain is used to specify which keys to use.

You configure a list of keys with specific IDs and have different lifetimes so that keys are changed at predetermined intervals automatically, without any disruption of service. Rollover enhances network security by minimizing the problems that could result if an untrusted source obtained, deduced, or guessed the current key.

RSVP handles rollover by using the following key ID types:

  • On TX, use the youngest eligible key ID.

  • On RX, use the key ID that is received in an integrity object.

For more information about implementing keychain management, see System Security Configuration Guide for Cisco ASR 9000 Series Routers.

Guidelines for Window-Size and Out-of-Sequence Messages

These guidelines are required for window-size and out-of-sequence messages:

  • Default window-size is set to 1. If a single message is received out-of-sequence, RSVP rejects it and displays a message.

  • When RSVP messages are sent in burst mode (for example, tunnel optimization), some messages can become out-of-sequence for a short amount of time.

  • Window size can be increased by using the window-size command. When the window size is increased, replay attacks can be detected with duplicate sequence numbers.

Caveats for Out-of-Sequence

These caveats are listed for out-of-sequence:

  • When RSVP messages traverse multiple interface types with different maximum transmission unit (MTU) values, some messages can become out-of-sequence if they are fragmented.

  • Packets with some IP options may be reordered.

  • Change in QoS configurations may lead to a transient reorder of packets.

  • QoS policies can cause a reorder of packets in a steady state.

Because all out-of-sequence messages are dropped, the sender must retransmit them. Because RSVP state timeouts are generally long, out-of-sequence messages during a transient state do not lead to a state timeout.

How to Implement RSVP

RSVP requires coordination among several routers, establishing exchange of RSVP messages to set up LSPs. Depending on the client application, RSVP requires some basic configuration, as described in these topics:

Configuring Traffic Engineering Tunnel Bandwidth

To configure traffic engineering tunnel bandwidth, you must first set up TE tunnels and configure the reserved bandwidth per interface (there is no need to configure bandwidth for the data channel or the control channel).

Cisco IOS XR software supports two MPLS DS-TE modes: Prestandard and IETF.


Note


For prestandard DS-TE you do not need to configure bandwidth for the data channel or the control channel. There is no other specific RSVP configuration required for this application. When no RSVP bandwidth is specified for a particular interface, you can specify zero bandwidth in the LSP setup if it is configured under RSVP interface configuration mode or MPLS-TE configuration mode.


Confirming DiffServ-TE Bandwidth

Perform this task to confirm DiffServ-TE bandwidth.

In RSVP global and subpools, reservable bandwidths are configured per interface to accommodate TE tunnels on the node. Available bandwidth from all configured bandwidth pools is advertised using IGP. RSVP signals the TE tunnel with appropriate bandwidth pool requirements.

SUMMARY STEPS

  1. configure
  2. rsvp
  3. interface type interface-path-id
  4. bandwidth total-bandwidth max-flow sub-pool sub-pool-bw
  5. commit

DETAILED STEPS

  Command or Action Purpose

Step 1

configure

Step 2

rsvp

Example:


RP/0/RSP0/CPU0:router(config)# rsvp

Enters RSVP configuration mode.

Step 3

interface type interface-path-id

Example:


RP/0/RSP0/CPU0:router(config-rsvp)# interface pos 0/2/0/0

Enters interface configuration mode for the RSVP protocol.

Step 4

bandwidth total-bandwidth max-flow sub-pool sub-pool-bw

Example:


RP/0/RSP0/CPU0:router(config-rsvp-if)# bandwidth 1000 100 sub-pool 150

Sets the reservable bandwidth, the maximum RSVP bandwidth available for a flow and the sub-pool bandwidth on this interface.

Step 5

commit

Enabling Graceful Restart

Perform this task to enable graceful restart for implementations using both node-id and interface-based hellos.

RSVP graceful restart provides a control plane mechanism to ensure high availability, which allows detection and recovery from failure conditions while preserving nonstop forwarding services.

SUMMARY STEPS

  1. configure
  2. rsvp
  3. signalling graceful-restart
  4. signalling graceful-restart interface-based
  5. commit

DETAILED STEPS

  Command or Action Purpose

Step 1

configure

Step 2

rsvp

Example:


RP/0/RSP0/CPU0:router(config)# rsvp

Enters the RSVP configuration mode.

Step 3

signalling graceful-restart

Example:


RP/0/RSP0/CPU0:router(config-rsvp)# signalling graceful-restart

Enables the graceful restart process on the node.

Step 4

signalling graceful-restart interface-based

Example:


RP/0/RSP0/CPU0:router(config-rsvp)# signalling graceful-restart interface-based

Enables interface-based graceful restart process on the node.

Step 5

commit

Configuring ACL-based Prefix Filtering

Two procedures are provided to show how RSVP Prefix Filtering is associated:

Configuring ACLs for Prefix Filtering

Perform this task to configure an extended access list ACL that identifies the source and destination prefixes used for packet filtering.


Note


The extended ACL needs to be configured separately using extended ACL configuration commands.


SUMMARY STEPS

  1. configure
  2. rsvp
  3. signalling prefix-filtering access-list
  4. commit

DETAILED STEPS

  Command or Action Purpose

Step 1

configure

Step 2

rsvp

Example:

RP/0/RSP0/CPU0:router(config)# rsvp

Enters the RSVP configuration mode.

Step 3

signalling prefix-filtering access-list

Example:

RP/0/RSP0/CPU0:router(config-rsvp)# signalling prefix-filtering access-list banks

Enter an extended access list name as a string.

Step 4

commit

Configuring RSVP Packet Dropping

Perform this task to configure RSVP to drop RA packets when the ACL match returns an implicit (default) deny.

The default behavior performs normal RSVP processing on RA packets when the ACL match returns an implicit (default) deny.

SUMMARY STEPS

  1. configure
  2. rsvp
  3. signalling prefix-filtering default-deny-action
  4. commit

DETAILED STEPS

  Command or Action Purpose

Step 1

configure

Step 2

rsvp

Example:

RP/0/RSP0/CPU0:router(config)# rsvp

Enters the RSVP configuration mode.

Step 3

signalling prefix-filtering default-deny-action

Example:

RP/0/RSP0/CPU0:router(config-rsvp)# signalling prefix-filtering default-deny-action

Drops RA messages.

Step 4

commit

Configuring Refresh Reduction

RSVP Refresh Reduction improves the reliability of Resource Reservation Protocol (RSVP) signaling to enhance network performance and message delivery and it is enabled by default. Refresh reduction is used with a neighbor only if the neighbor supports it. You can also disable refresh reduction on an interface if you want.

This feature ensures reliable delivery of RSVP messages when network traffic is disrupted. To ensure that its message is delivered to its neighbor, RSVP requests the neighbor to send an acknowledgment message by a given time duration. If it doesn’t receive the acknowledgment, it resends the message and doubles its current wait time. After 5 attempts, RSVP stops retransmitting the message to the neighbor.

Verifying RSVP Configuration

Figure 3. Sample Topology. This figure illustrates the topology.


Perform the following steps to verify RSVP configuration.

SUMMARY STEPS

  1. show rsvp session
  2. show rsvp counters messages summary
  3. show rsvp counters events
  4. show rsvp interface type interface-path-id [detail ]
  5. show rsvp graceful-restart
  6. show rsvp graceful-restart [neighbors ip-address | detail ]
  7. show rsvp interface
  8. show rsvp neighbor

DETAILED STEPS


Step 1

show rsvp session

Verifies that all routers on the path of the LSP are configured with at least one Path State Block (PSB) and one Reservation State Block (RSB) per session.

Example:


RP/0/RSP0/CPU0:routershow rsvp session 

Type Destination Add DPort Proto/ExtTunID PSBs RSBs Reqs
 ---- --------------- ----- --------------- ----- ----- ----- LSP4
 172.16.70.70 6 10.51.51.51 1 1 0

In the example , the output represents an LSP from ingress (head) router 10.51.51.51 to egress (tail) router 172.16.70.70. The tunnel ID (also called the destination port) is 6.

Example:


If no states can be found for a session that should be up, verify the
      application (for example, MPLS-TE ) to see if
      everything is in order. If a session has one PSB but no RSB, this indicates
      that either the Path message is not making it to the egress (tail) router or
      the reservation message is not making it back to the router R1 in question.

Go to the downstream router R2 and display the session information:

Example:


If R2 has no PSB, either the path message is not making it to the
      router or the path message is being rejected (for example, due to lack of
      resources). If R2 has a PSB but no RSB, go to the next downstream router R3
      to investigate. If R2 has a PSB and an RSB, this means the reservation is
      not making it from R2 to R1 or is being rejected.

Step 2

show rsvp counters messages summary

Verifies whether the RSVP message is being transmitted and received.

Example:


RP/0/RSP0/CPU0:routershow rsvp counters messages summary 

All RSVP Interfaces Recv Xmit Recv Xmit Path 0 25
      Resv 30 0 PathError 0 0 ResvError 0 1 PathTear 0 30 ResvTear 12 0
      ResvConfirm 0 0 Ack 24 37 Bundle 0 Hello 0 5099 SRefresh 8974 9012
      OutOfOrder 0 Retransmit 20 Rate Limited 0 

Step 3

show rsvp counters events

Verifies how many RSVP states have expired. Because RSVP uses a soft-state mechanism, some failures will lead to RSVP states to expire due to lack of refresh from the neighbor.

Example:


RP/0/RSP0/CPU0:routershow rsvp counters events 

mgmtEthernet0/0/0/0 tunnel6 Expired Path states 0 Expired
      Path states 0 Expired Resv states 0 Expired Resv states 0 NACKs received 0
      NACKs received 0 POS0/3/0/0                              POS0/3/0/1 Expired
      Path states 0 Expired Path states 0 Expired Resv states 0 Expired Resv
      states 0 NACKs received 0 NACKs received 0 POS0/3/0/2
                                   POS0/3/0/3 Expired Path states 0 Expired Path
      states 0 Expired Resv states 0 Expired Resv states 1 NACKs received 0 NACKs
      received 1 

Step 4

show rsvp interface type interface-path-id [detail ]

Verifies that refresh reduction is working on a particular interface.

Example:


RP/0/RSP0/CPU0:routershow rsvp interface pos0/3/0/3 detail 

INTERFACE: POS0/3/0/3 (ifh=0x4000D00). BW
      (bits/sec): Max=1000M. MaxFlow=1000M. Allocated=1K (0%). MaxSub=0.
      Signalling: No DSCP marking. No rate limiting. States in: 1. Max missed
      msgs: 4. Expiry timer: Running (every 30s). Refresh interval: 45s. Normal
      Refresh timer: Not running. Summary refresh timer: Running. Refresh
      reduction local: Enabled. Summary Refresh: Enabled (4096 bytes max).
      Reliable summary refresh: Disabled. Ack hold: 400 ms, Ack max size: 4096
      bytes. Retransmit: 900ms. Neighbor information: Neighbor-IP Nbor-MsgIds
      States-out Refresh-Reduction Expiry(min::sec) -------------- --------------
      ---------- ------------------ ---------------- 64.64.64.65 1 1 Enabled
      14::45 

Step 5

show rsvp graceful-restart

Verifies that graceful restart is enabled locally.

Example:


RP/0/RSP0/CPU0:routershow rsvp graceful-restart

Graceful restart: enabled Number of global
      neighbors: 1 Local MPLS router id: 10.51.51.51 Restart time: 60 seconds
      Recovery time: 0 seconds Recovery timer: Not running Hello interval: 5000
      milliseconds Maximum Hello miss-count: 3 

Step 6

show rsvp graceful-restart [neighbors ip-address | detail ]

Verifies that graceful restart is enabled on the neighbor(s). These examples show that neighbor 192.168.60.60 is not responding to hello messages.

Example:


RP/0/RSP0/CPU0:routershow rsvp graceful-restart neighbors 192.168.60.60

Neighbor App State Recovery Reason
      Since LostCnt --------------- ----- ------ -------- ------------
      -------------------- -------- 192.168.60.60 MPLS INIT DONE N/A 12/06/2003
      19:01:49 0 
RP/0/RSP0/CPU0:routershow rsvp graceful-restart neighbors detail

Neighbor: 192.168.60.60 Source: 10.51.51.51
      (MPLS) Hello instance for application MPLS Hello State: INIT (for 3d23h)
      Number of times communications with neighbor lost: 0 Reason: N/A Recovery
      State: DONE Number of Interface neighbors: 1 address: 10.64.64.65 Restart
      time: 0 seconds Recovery time: 0 seconds Restart timer: Not running Recovery
      timer: Not running Hello interval: 5000 milliseconds Maximum allowed missed
      Hello messages: 3

Step 7

show rsvp interface

Verifies the available RSVP bandwidth.

Example:


RP/0/RSP0/CPU0:routershow rsvp interface 

Interface MaxBW MaxFlow Allocated MaxSub -----------
      -------- -------- --------------- -------- Et0/0/0/0 0 0 0 ( 0%) 0 PO0/3/0/0
      1000M 1000M 0 ( 0%) 0 PO0/3/0/1 1000M 1000M 0 ( 0%) 0 PO0/3/0/2 1000M 1000M
      0 ( 0%) 0 PO0/3/0/3 1000M 1000M 1K ( 0%) 0 

Step 8

show rsvp neighbor

Verifies the RSVP neighbors.

Example:


RP/0/RSP0/CPU0:router# show rsvp neighbor detail 
Global Neighbor: 40.40.40.40 Interface Neighbor: 10.0.0.1
      Interface: POS0/0/0/0 Refresh Reduction: "Enabled" or "Disabled". Remote
      epoch: 0xXXXXXXXX Out of order messages: 0 Retransmitted messages: 0
      Interface Neighbor: 172.16.0.1 Interface: POS0/1/0/0 Refresh Reduction:
      "Enabled" or "Disabled". Remote epoch: 0xXXXXXXXX Out of order messages: 0
      Retransmitted messages: 0 


Enabling RSVP Traps

With the exception of the RSVP MIB traps, no action is required to activate the MIBs. This MIB feature is automatically enabled when RSVP is turned on; however, RSVP traps must be enabled.

Perform this task to enable all RSVP MIB traps, NewFlow traps, and LostFlow traps.

SUMMARY STEPS

  1. configure
  2. snmp-server traps rsvp lost-flow
  3. snmp-server traps rsvp new-flow
  4. snmp-server traps rsvp all
  5. commit

DETAILED STEPS

  Command or Action Purpose

Step 1

configure

Step 2

snmp-server traps rsvp lost-flow

Example:


RP/0/RSP0/CPU0:router(config)# snmp-server traps rsvp lost-flow

Sends RSVP notifications to enable RSVP LostFlow traps.

Step 3

snmp-server traps rsvp new-flow

Example:


RP/0/RSP0/CPU0:router(config)# snmp-server traps rsvp new-flow

Sends RSVP notifications to enable RSVP NewFlow traps.

Step 4

snmp-server traps rsvp all

Example:


RP/0/RSP0/CPU0:router(config)# snmp-server traps rsvp all

Sends RSVP notifications to enable all RSVP MIB traps.

Step 5

commit

How to Implement RSVP Authentication

There are three types of RSVP authentication modes—global, interface, and neighbor. These topics describe how to implement RSVP authentication for each mode:

Configuring Global Configuration Mode RSVP Authentication

These tasks describe how to configure RSVP authentication in global configuration mode:

Enabling RSVP Authentication Using the Keychain in Global Configuration Mode

Perform this task to enable RSVP authentication for cryptographic authentication by specifying the keychain in global configuration mode.


Note


You must configure a keychain before completing this task (see System Security Configuration Guide for Cisco ASR 9000 Series Routers).


SUMMARY STEPS

  1. configure
  2. rsvp authentication
  3. key-source key-chain key-chain-name
  4. commit

DETAILED STEPS

  Command or Action Purpose

Step 1

configure

Step 2

rsvp authentication

Example:

RP/0/RSP0/CPU0:router(config)# rsvp authentication
RP/0/RSP0/CPU0:router(config-rsvp-auth)#

Enters RSVP authentication configuration mode.

Step 3

key-source key-chain key-chain-name

Example:

RP/0/RSP0/CPU0:router(config-rsvp-auth)# key-source key-chain mpls-keys

Specifies the source of the key information to authenticate RSVP signaling messages.

key-chain-name

Name of the keychain. The maximum number of characters is 32.

Step 4

commit

Configuring a Lifetime for RSVP Authentication in Global Configuration Mode

Perform this task to configure a lifetime value for RSVP authentication in global configuration mode.

SUMMARY STEPS

  1. configure
  2. rsvp authentication
  3. life-time seconds
  4. commit

DETAILED STEPS

  Command or Action Purpose

Step 1

configure

Step 2

rsvp authentication

Example:

RP/0/RSP0/CPU0:router(config)# rsvp authentication
RP/0/RSP0/CPU0:router(config-rsvp-auth)#

Enters RSVP authentication configuration mode.

Step 3

life-time seconds

Example:

RP/0/RSP0/CPU0:router(config-rsvp-auth)# life-time 2000

Controls how long RSVP maintains security associations with other trusted RSVP neighbors.

seconds

Length of time (in seconds) that RSVP maintains idle security associations with other trusted RSVP neighbors. Range is from 30 to 86400. The default value is 1800.

Step 4

commit

Configuring the Window Size for RSVP Authentication in Global Configuration Mode

Perform this task to configure the window size for RSVP authentication in global configuration mode.

SUMMARY STEPS

  1. configure
  2. rsvp authentication
  3. window-size N
  4. commit

DETAILED STEPS

  Command or Action Purpose

Step 1

configure

Step 2

rsvp authentication

Example:

RP/0/RSP0/CPU0:router(config)# rsvp authentication
RP/0/RSP0/CPU0:router(config-rsvp-auth)#

Enters RSVP authentication configuration mode.

Step 3

window-size N

Example:

RP/0/RSP0/CPU0:router(config-rsvp-auth)# window-size 33

Specifies the maximum number of RSVP authenticated messages that can be received out-of-sequence.

N

Size of the window to restrict out-of-sequence messages. The range is from 1 to 64. The default value is 1, in which case all out-of-sequence messages are dropped.

Step 4

commit

Configuring an Interface for RSVP Authentication

These tasks describe how to configure an interface for RSVP authentication:

Specifying the RSVP Authentication Keychain in Interface Mode

Perform this task to specify RSVP authentication keychain in interface mode.

You must configure a keychain first (see System Security Configuration Guide for Cisco ASR 9000 Series Routers).

SUMMARY STEPS

  1. configure
  2. rsvp interface type interface-path-id
  3. authentication
  4. key-source key-chain key-chain-name
  5. commit

DETAILED STEPS

  Command or Action Purpose

Step 1

configure

Step 2

rsvp interface type interface-path-id

Example:

RP/0/RSP0/CPU0:router(config)# rsvp interface POS 0/2/1/0
RP/0/RSP0/CPU0:router(config-rsvp-if)# 

Enters RSVP interface configuration mode.

Step 3

authentication

Example:

RP/0/RSP0/CPU0:router(config-rsvp-if)# authentication
RP/0/RSP0/CPU0:router(config-rsvp-if-auth)#

Enters RSVP authentication configuration mode.

Step 4

key-source key-chain key-chain-name

Example:

RP/0/RSP0/CPU0:router(config-rsvp-if-auth)# key-source key-chain mpls-keys

Specifies the source of the key information to authenticate RSVP signaling messages.

key-chain-name

Name of the keychain. The maximum number of characters is 32.

Step 5

commit

Configuring a Lifetime for an Interface for RSVP Authentication

Perform this task to configure a lifetime for the security association for an interface.

SUMMARY STEPS

  1. configure
  2. rsvp interface type interface-path-id
  3. authentication
  4. life-time seconds
  5. commit

DETAILED STEPS

  Command or Action Purpose

Step 1

configure

Step 2

rsvp interface type interface-path-id

Example:

RP/0/RSP0/CPU0:router(config)# rsvp interface POS 0/2/1/0
RP/0/RSP0/CPU0:router(config-rsvp-if)# 

Enters RSVP interface configuration mode.

Step 3

authentication

Example:

RP/0/RSP0/CPU0:router(config-rsvp-if)# authentication
RP/0/RSP0/CPU0:router(config-rsvp-if-auth)#

Enters RSVP authentication configuration mode.

Step 4

life-time seconds

Example:

RP/0/RSP0/CPU0:router(config-rsvp-if-auth)# life-time 2000

Controls how long RSVP maintains security associations with other trusted RSVP neighbors.

seconds

Length of time (in seconds) that RSVP maintains idle security associations with other trusted RSVP neighbors. Range is from 30 to 86400. The default value is 1800.

Step 5

commit

Configuring the Window Size for an Interface for RSVP Authentication

Perform this task to configure the window size for an interface for RSVP authentication to check the validity of the sequence number received.

SUMMARY STEPS

  1. configure
  2. rsvp interface type interface-path-d
  3. authentication
  4. window-size N
  5. commit

DETAILED STEPS

  Command or Action Purpose

Step 1

configure

Step 2

rsvp interface type interface-path-d

Example:

RP/0/RSP0/CPU0:router(config)# rsvp interface POS 0/2/1/0
RP/0/RSP0/CPU0:router(config-rsvp-if)# 

Enters RSVP interface configuration mode.

Step 3

authentication

Example:

RP/0/RSP0/CPU0:router(config-rsvp-if)# authentication
RP/0/RSP0/CPU0:router(config-rsvp-if-auth)#

Enters RSVP interface authentication configuration mode.

Step 4

window-size N

Example:

RP/0/RSP0/CPU0:router(config-rsvp-if-auth)# window-size 33

Specifies the maximum number of RSVP authenticated messages that can be received out-of-sequence.

N

Size of the window to restrict out-of-sequence messages. The range is from 1 to 64. The default value is 1, in which case all out-of-sequence messages are dropped.

Step 5

commit

Configuring RSVP Neighbor Authentication

These tasks describe how to configure the RSVP neighbor authentication:

Specifying the Keychain for RSVP Neighbor Authentication

Perform this task to specify the keychain RSVP neighbor authentication.

You must configure a keychain first (see System Security Configuration Guide for Cisco ASR 9000 Series Routers).

SUMMARY STEPS

  1. configure
  2. rsvp neighbor IP-address authentication
  3. key-source key-chain key-chain-name
  4. commit

DETAILED STEPS

  Command or Action Purpose

Step 1

configure

Step 2

rsvp neighbor IP-address authentication

Example:

RP/0/RSP0/CPU0:router(config)# rsvp neighbor 10.0.0.1 authentication
RP/0/RSP0/CPU0:router(config-rsvp-nbor-auth)#

Enters neighbor authentication configuration mode. Use the rsvp neighbor command to activate RSVP cryptographic authentication for a neighbor.

IP address

IP address of the neighbor. A single IP address for a specific neighbor; usually one of the neighbor's physical or logical (loopback) interfaces.

authentication

Configures the RSVP authentication parameters.

Step 3

key-source key-chain key-chain-name

Example:

RP/0/RSP0/CPU0:router(config-rsvp-nbor-auth)# key-source key-chain mpls-keys

Specifies the source of the key information to authenticate RSVP signaling messages.

key-chain-name

Name of the keychain. The maximum number of characters is 32.

Step 4

commit

Configuring a Lifetime for RSVP Neighbor Authentication

Perform this task to configure a lifetime for security association for RSVP neighbor authentication mode.

SUMMARY STEPS

  1. configure
  2. rsvp neighbor IP-address authentication
  3. life-time seconds
  4. commit

DETAILED STEPS

  Command or Action Purpose

Step 1

configure

Step 2

rsvp neighbor IP-address authentication

Example:

RP/0/RSP0/CPU0:router(config)# rsvp neighbor 10.0.0.1 authentication
RP/0/RSP0/CPU0:router(config-rsvp-nbor-auth)#

Enters RSVP neighbor authentication configuration mode. Use the rsvp neighbor command to specify a neighbor under RSVP.

IP address

IP address of the neighbor. A single IP address for a specific neighbor; usually one of the neighbor's physical or logical (loopback) interfaces.

authentication

Configures the RSVP authentication parameters.

Step 3

life-time seconds

Example:

RP/0/RSP0/CPU0:router(config-rsvp-nbor-auth)# life-time 2000

Controls how long RSVP maintains security associations with other trusted RSVP neighbors. The argument specifies the

seconds

Length of time (in seconds) that RSVP maintains idle security associations with other trusted RSVP neighbors. Range is from 30 to 86400. The default value is 1800.

Step 4

commit

Configuring the Window Size for RSVP Neighbor Authentication

Perform this task to configure the RSVP neighbor authentication window size to check the validity of the sequence number received.

SUMMARY STEPS

  1. configure
  2. rsvp neighbor IP address authentication
  3. window-size N
  4. commit

DETAILED STEPS

  Command or Action Purpose

Step 1

configure

Step 2

rsvp neighbor IP address authentication

Example:

RP/0/RSP0/CPU0:router(config)# rsvp neighbor 10.0.0.1 authentication
RP/0/RSP0/CPU0:router(config-rsvp-nbor-auth)#
  

Enters RSVP neighbor authentication configuration mode. Use the rsvp neighbor command to specify a neighbor under RSVP.

IP address

IP address of the neighbor. A single IP address for a specific neighbor; usually one of the neighbor's physical or logical (loopback) interfaces.

authentication

Configures the RSVP authentication parameters.

Step 3

window-size N

Example:

RP/0/RSP0/CPU0:router(config-rsvp-nbor-auth)# window-size 33

Specifies the maximum number of RSVP authenticated messages that is received out-of-sequence.

N

Size of the window to restrict out-of-sequence messages. The range is from 1 to 64. The default value is 1, in which case all out-of-sequence messages are dropped.

Step 4

commit

Verifying the Details of the RSVP Authentication

To display the security associations that RSVP has established with other RSVP neighbors, use the show rsvp authentication command.

Eliminating Security Associations for RSVP Authentication

To eliminate RSVP authentication SA’s, use the clear rsvp authentication command. To eliminate RSVP counters for each SA, use the clear rsvp counters authentication command.

Configuration Examples for RSVP

Sample RSVP configurations are provided for some of the supported RSVP features.

Bandwidth Configuration (Prestandard): Example

The example shows the configuration of bandwidth on an interface using prestandard DS-TE mode. The example configures an interface for a reservable bandwidth of 7500, specifies the maximum bandwidth for one flow to be 1000 and adds a sub-pool bandwidth of 2000.


  rsvp interface hundredGigE 0/0/0/0
   bandwidth 7500 1000 sub-pool 2000
  

Bandwidth Configuration (MAM): Example

The example shows the configuration of bandwidth on an interface using MAM. The example shows how to limit the total of all RSVP reservations on the hundredGigE 0/0/0/0 interface to 7500 kbps, and allow each single flow to reserve no more than 1000 kbps.


  rsvp interface hundredGigE 0/0/0/0
   bandwidth mam 7500 1000
  

Bandwidth Configuration (RDM): Example

The example shows the configuration of bandwidth on an interface using RDM. The example shows how to limit the total of all RSVP reservations on the hundredGigE 0/0/0/0 interface to 7500 kbps, and allows each single flow to reserve no more than 1000 kbps.


  rsvp interface hundredGigE 0/0/0/0
   bandwidth rdm 7500 1000
  

Refresh Reduction and Reliable Messaging Configuration: Examples

Refresh reduction feature as defined by RFC 2961 is supported and enabled by default. The examples illustrate the configuration for the refresh reduction feature. Refresh reduction is used with a neighbor only if the neighbor supports it also.

Refresh Interval and the Number of Refresh Messages Configuration: Example

The example shows how to configure the refresh interval to 30 seconds on POS 0/3/0/0 and how to change the number of refresh messages the node can miss before cleaning up the state from the default value of 4 to 6.


  rsvp interface pos 0/3/0/0
   signalling refresh interval 30
   signalling refresh missed 6

Retransmit Time Used in Reliable Messaging Configuration: Example

The example shows how to set the retransmit timer to 2 seconds. To prevent unnecessary retransmits, the retransmit time value configured on the interface must be greater than the ACK hold time on its peer.


  rsvp interface pos 0/4/0/1
   signalling refresh reduction reliable retransmit-time 2000 

Acknowledgement Times Configuration: Example

The example shows how to change the acknowledge hold time from the default value of 400 ms, to delay or speed up sending of ACKs, and the maximum acknowledgment message size from default size of 4096 bytes. The example shows how to change the acknowledge hold time from the default value of 400 ms and how to delay or speed up sending of ACKs. The maximum acknowledgment message default size is from 4096 bytes.


  rsvp interface pos 0/4/0/1
   signalling refresh reduction reliable ack-hold-time 1000
  rsvp interface pos 0/4/0/1
   signalling refresh reduction reliable ack-max-size 1000

Note


Ensure retransmit time on the peers’ interface is at least twice the amount of the ACK hold time to prevent unnecessary retransmissions.


Summary Refresh Message Size Configuration: Example

The example shows how to set the summary refresh message maximum size to 1500 bytes.


  rsvp interface pos 0/4/0/1
   signalling refresh reduction summary max-size 1500

Disable Refresh Reduction: Example

If the peer node does not support refresh reduction, or for any other reason you want to disable refresh reduction on an interface, the example shows how to disable refresh reduction on that interface.


  rsvp interface pos 0/4/0/1
   signalling refresh reduction disable

Configure Graceful Restart: Examples

RSVP graceful restart is configured globally or per interface (as are refresh-related parameters). These examples show how to enable graceful restart, set the restart time, and change the hello message interval.

Enable Interface-Based Graceful Restart: Example

The example shows how to enable the RSVP graceful restart feature on an interface.


RP/0/RSP0/CPU0:router#configure
RP/0/RSP0/CPU0:router(config-rsvp)#interface bundle-ether 17
RP/0/RSP0/CPU0:router(config-rsvp-if)#signalling hello graceful-restart ?
  interface-based  Configure Interface-based Hello
RP/0/RSP0/CPU0:router(config-rsvp-if)#signalling hello graceful-restart interface-based
RP/0/RSP0/CPU0:router(config-rsvp-if)# 

Change the Restart-Time: Example

The example shows how to change the restart time that is advertised in hello messages sent to neighbor nodes.

rsvp signalling graceful-restart restart-time 200

Change the Hello Interval: Example

The example shows how to change the interval at which RSVP graceful restart hello messages are sent per neighbor, and change the number of hellos missed before the neighbor is declared down.


  rsvp signalling hello graceful-restart refresh interval 4000
  rsvp signalling hello graceful-restart refresh misses 4

Configure ACL-based Prefix Filtering: Example

The example shows when RSVP receives a Router Alert (RA) packet from source address 10.0.0.1 and 10.0.0.1 is not a local address. The packet is forwarded with IP TTL decremented. Packets destined to 172.16.0.1 are dropped. All other RA packets are processed as normal RSVP packets.


  show run ipv4 access-list
    ipv4 access-list rsvpacl
    10 permit ip host 10.0.0.1 any
    20 deny ip any host 172.16.0.1
    !
  show run rsvp
    rsvp
    signalling prefix-filtering access-list rsvpacl
    !
  

Enable RSVP Traps: Example

The example enables the router to send all RSVP traps:


configure
 snmp-server traps rsvp all

The example enables the router to send RSVP LostFlow traps:


configure
 snmp-server traps rsvp lost-flow

The example enables the router to send RSVP RSVP NewFlow traps:


configure
 snmp-server traps rsvp new-flow

Configuration Examples for RSVP Authentication

These configuration examples are used for RSVP authentication:

RSVP Authentication Global Configuration Mode: Example

The configuration example enables authentication of all RSVP messages and increases the default lifetime of the SAs.


  rsvp
   authentication
    key-source key-chain default_keys
    life-time 3600
   !
  !
  

Note


The specified keychain (default_keys) must exist and contain valid keys, or signaling will fail.


RSVP Authentication for an Interface: Example

The configuration example enables authentication of all RSVP messages that are being sent or received on one interface only, and sets the window-size of the SAs.


  rsvp
   interface GigabitEthernet0/6/0/0
    authentication
     window-size 64
    !
   !
  

Note


Because the key-source keychain configuration is not specified, the global authentication mode keychain is used and inherited. The global keychain must exist and contain valid keys or signaling fails.


RSVP Authentication by Using All the Modes: Example

The configuration example shows how to perform the following functions:

  • Authenticates all RSVP messages.

  • Authenticates the RSVP messages to or from 10.0.0.1 by setting the keychain for the key-source key-chain command to nbr_keys, SA lifetime is set to 3600, and the default window-size is set to 1.

  • Authenticates the RSVP messages not to or from 10.0.0.1 by setting the keychain for the key-source key-chain command to default_keys, SA lifetime is set to 3600, and the window-size is set 64 when using GigabitEthernet0/6/0/0; otherwise, the default value of 1 is used.


  rsvp
   interface GigabitEthernet0/6/0/0
    authentication
     window-size 64
    !
   !
   neighbor 10.0.0.1
    authentication
     key-source key-chain nbr_keys
    !
   !
   authentication
    key-source key-chain default_keys
    life-time 3600
   !
  !
  

Note


If a keychain does not exist or contain valid keys, this is considered a configuration error because signaling fails. However, this can be intended to prevent signaling. For example, when using the above configuration, if the nbr_keys does not contain valid keys, all signaling with 10.0.0.1 fails.


Additional References

Related Documents

For additional information related to implementing GMPLS UNI, refer to the following references:

Related Topic Document Title

GMPLS UNI commands

GMPLS UNI Commands module in MPLS Command Reference for Cisco ASR 9000 Series Routers

MPLS Traffic Engineering commands

MPLS Traffic Engineering commands module in MPLS Command Reference for Cisco ASR 9000 Series Routers

RSVP commands

RSVP commands module in MPLS Command Reference for Cisco ASR 9000 Series Routers

Getting started material

Cisco ASR 9000 Series Aggregation Services Router Getting Started Guide

Information about user groups and task IDs

Configuring AAA Services module in System Security Configuration Guide for Cisco ASR 9000 Series Routers

Standards

Standard Title

No new or modified standards are supported by this feature, and support for existing standards has not been modified by this feature.

MIBs

MIBs MIBs Link

To locate and download MIBs using Cisco IOS XR software, use the Cisco MIB Locator found at the following URL and choose a platform under the Cisco Access Products menu:

http://cisco.com/public/sw-center/netmgmt/cmtk/mibs.shtml

RFCs

RFCs Title

RFC 3471

Generalized Multi-Protocol Label Switching (GMPLS) Signaling Functional Description

RFC 3473

Generalized Multi-Protocol Label Switching (GMPLS) Signaling Resource ReserVation Protocol-Traffic Engineering (RSVP-TE) Extensions

RFC 4208

Generalized Multiprotocol Label Switching (GMPLS) User-Network Interface (UNI): Resource ReserVation Protocol-Traffic Engineering (RSVP-TE) Support for the Overlay Model

RFC 4872

RSVP-TE Extensions in Support of End-to-End Generalized Multi-Protocol Label Switching (GMPLS) Recovery

RFC 4874

Exclude Routes - Extension to Resource ReserVation Protocol-Traffic Engineering (RSVP-TE)

RFC 6205

Generalized Labels for Lambda-Switch-Capable (LSC) Label Switching Routers

Technical Assistance

Description Link

The Cisco Technical Support website contains thousands of pages of searchable technical content, including links to products, technologies, solutions, technical tips, and tools. Registered Cisco.com users can log in from this page to access even more content.

http://www.cisco.com/techsupport