Route policies
Configuring route policies
Nokia’s router supports two databases for routing information. The routing database is composed of the routing information learned by the routing protocols. The forwarding database is composed of the routes actually used to forward traffic through a router. In addition, link state databases are maintained by interior gateway protocols (IGPs) such as IS-IS and OSPF.
Routing protocols calculate the best route to each destination and place these routes in a forwarding table. The routes in the forwarding table are used to forward routing protocol traffic, sending advertisements to neighbors and peers.
A routing policy can be configured that will not place routes associated with a specific origin in the routing table. Those routes will not be used to forward data packets to the intended destinations and the routes are not advertised by the routing protocol to neighbors and peers.
Routing policies control the size and content of the routing tables, the routes that are advertised, and the best route to take to reach a destination. Careful planning is essential to implement route policies that can affect the flow of routing information or packets in and traversing through the router. Before configuring and applying a route policy, develop an overall plan and strategy to accomplish your intended routing actions.
There are no default route policies. Each policy must be created explicitly and applied to a routing protocol or to the forwarding table. Policy parameters are modifiable.
Policy statements
SR OS route policy statements consist of a sequence of ordered rules, or entries. When the policy is applied to a routing adjacency, route table, or some other context, then each route associated with that context is evaluated by the rules of the policy, in the specified order, until a matching entry is found or the end of the policy is reached. If a matching entry is found, then its actions are applied to the route. However, if there is no matching entry, then the policy default-action is applied to the route.
Some of the match criteria that can be used in a policy entry include:
IP prefix-list reference
AS path regular expression
community list reference
route properties such as MED, local-preference, IGP metric, IGP route type, BGP path type, and so on
In classic mode and mixed-mode every policy-statement must have numbered entries.
In full Model-Driven mode, each policy-statement can be configured to be entry-type named or entry-type numbered. Numbered types behave as in classic mode and mixed-mode. In named types, each entry is a specific string-format name up to 255 characters in length, and entries are evaluated in user order (the order they appear in the configuration). MD-CLI and NETCONF management interfaces support insert commands that change the order of the named entries in a policy statement. For example, in the MD-CLI configuration context of a policy-statement X, if a named-entry entry2 needs to be moved so that it is evaluated immediately before an existing named-entry entry1 this can be achieved using the insert named-entry entry2 before entry1 command.
Policy statement chaining and logical expressions
Multiple policy-statement names can be specified in the CLI commands that attach route policies to specific functions. A chain of routing policies is created if a list of two or more policy names is specified in the CLI command. Route policy chaining allows complex route processing logic to be broken into smaller components. This enables the reuse of common functions and facilitates the process of amending and updating route control logic as required.
Each route is evaluated against a policy chain as follows.
The route is evaluated against the first listed policy. If the route matches an entry with action next-policy, or the route matches no entry and the default-action is next-policy (or there is no default-action specified at all), the evaluation continues into the second policy.
The route is evaluated against the second listed policy. If the route matches an entry with action next-policy or a default-action of next-policy applies, the evaluation continues to the third policy.
The sequential evaluation of policies continues until the route is accepted or rejected by an entry or explicit default-action.
In addition to policy chaining, the SR OS also supports policy logical expressions that enable applications to use complex multiple policy statements. A policy logical expression can be used as a standalone expression or as part of a policy chain. Each policy chain supports a maximum of one logical expression. The logical expression is usually the first element of the policy chain; however, it can appear in a non-initial position as long as its length does not exceed 64 characters.
A route policy logical expression is a string composed of logical operators (keywords AND, OR and NOT), up to 16 route policy names (each up to 64 characters in length and delimited by brackets ( ) and square brackets [ ] to group sub-expressions (with up to three levels of nesting)). The total length of the route policy expression cannot exceed 900 characters.
The following are examples of valid logical expressions in the SR OS CLI syntax:
‟NOT [policyA]”
‟[policyA] AND [policyB] OR [policyC]”
‟NOT ([policyA] OR [policyB] OR [policyC])”
The final result of a route policy evaluation against a logical expression is TRUE or FALSE. The SR OS rules for policy evaluation are as follows.
If the expression includes a NOT operator followed by a sub-expression in brackets, the expression is flattened using De Morgan's rule.
For example, the expression ‟NOT ([policyA] OR [policyB] OR [policyC])” is flattened to: ‟(NOT [policyA]) AND (NOT [policyB]) AND (NOT [policyC])”.
The usual rules of precedence apply: NOT is the highest priority, then AND, then OR.
The use of ‟NOT <expression>” negates the TRUE/FALSE result of the expression.
Where the logic is ‟(<expression1>) AND (<expression2>)”, if expression1 is FALSE, the result is FALSE and expression2 is not evaluated. If expression1 is TRUE, expression2 is then evaluated. The final result is TRUE only if both expressions are TRUE.
Where the logic is ‟(<expression1>) OR (<expression2>)”, if expression1 is TRUE, the result is TRUE and expression2 is not evaluated. If expression1 is FALSE, expression2 is then evaluated. The final result is TRUE if either expression is TRUE.
If the evaluation of a policy terminates with an action accept, action next-entry or action next-policy, the result is TRUE. If the evaluation of a policy terminates with an action reject or action drop, then the result is FALSE. If a route matches no entry in a policy and there is no specified default-action, the implied default action is next-policy; if there is no next policy, this translates to the default action for the protocol.
When a route is evaluated against a policy contained in a logical expression, the route property changes (such as MED, local preference, communities) made by the matching entry or default action apply cumulatively to the route. The result of a cumulative change is that a policy evaluated later in the logical expression (or later in the entire policy chain) may undo or reverse prior changes. A later policy in the logical expression (or policy chain) may also match a route on the basis of route properties that were modified by earlier policies.
When evaluation of the logical expression is complete, the final TRUE or FALSE result is translated back to a traditional action. The FALSE value is translated to action reject; the TRUE value is translated to action accept, action next-policy or action next-entry to match the action of the last policy that produced the TRUE result.
Routing policy subroutines
It is possible to reference a routing policy from within another routing policy to construct powerful subroutine based policies.
Up to the three levels of subroutine calls are supported. Policy subroutines produce a final result of TRUE or FALSE through matching and policy entry actions. A policy entry action of ‛accept’ evaluates to TRUE, and a policy entry action of ‛reject’ evaluates to FALSE.
When using next-policy action state in the subroutine, the match value is defined by the default action behavior. The action is protocol-dependent. See Default action behavior for information about the default actions that are applied during packet processing.
If a match is not found during the evaluation of one or more routing policies, the final evaluation returns the accept or the reject provided by the default behavior based on the policy type (import/export) and the destination and/or source protocol.
Policy evaluation command
Operators can evaluate a routing policy against a BGP neighbor, routing context, or individual prefix before applying the policy to the neighbor or routing context. This command displays prefixes that are rejected by a policy and what modifications are made by a policy.
Exclusive editing for policy configuration
Operators can set an exclusive lock on policy edit sessions. When the exclusive flag is set by an operator that is editing policy, other users (console or SNMP) are restricted from being able to begin, edit, commit, or abort policy. An administrative override is made available to reset the exclusive flag in the event of a session failure.
Default action behavior
The default action of a policy applies to a route when the route does not match any of the entries of the policy. If a policy does not have any match entries, all routes are subject to the default action. If no default action is specified and the policy is the last one in a chain of policies, the default action is determined by the protocol that called the policy.
If a default action is defined for one or more of the configured route policies, then the default action is handled as follows.
The default action can be set to all available action states including accept, reject, next-entry, and next-policy.
If the action states accept or reject, then the policy evaluation terminates and the appropriate result is returned.
If a default action is defined and no matches occurred with the entries in the policy, then the default action is used.
If a default action is defined and one or more matches occurred with the entries of the policy, then the default action is not used.
Denied IP unicast prefixes
The Route Table Manager does not inherently restrict any IP prefixes from the forwarding table, but individual routing protocols may not accept prefixes that are not globally routable.
Controlling route flapping
Route damping is a controlled acceptance of unstable routes from BGP peers so that any ripple effect caused by route flapping across BGP AS border routers is minimized. The motive is to delay the use of unstable routes (flapping routes) to forward data and advertisements until the route stabilizes.
Nokia’s implementation of route damping is based on the following parameters:
Figure of merit
A route is assigned a Figure of Merit (FoM), which is proportional to the frequency of flaps. FoM should be able to characterize a route’s behavior over a period of time.
Route flap
A route flap is not limited to the withdrawn route. It also applies to any change in the AS path or the next hop of a reachable route. A change in AS path or next hop indicates that the intermediate AS or the route-advertising peer is not suppressing flapping routes at the source or during the propagation. Even if the route is accepted as a stable route, the data packets destined for the route could experience unstable routing because of the unstable AS path or next hop.
Suppress threshold
The threshold is a configured value that, when exceeded, the route is suppressed and not advertised to other peers. The state is considered to be down from the perspective of the routing protocol.
Reuse threshold
When FoM value falls below a configured reuse threshold and the route is still reachable, the route is advertised to other peers. The FoM value decays exponentially after a route is suppressed. This requires the BGP implementation to decay thousands of routes from a misbehaving peer.
The two events that could trigger the route flapping algorithm are:
Route flapping
If a route flap is detected within a configured maximum route flap history time, the route’s FoM is initialized and the route is marked as a potentially unstable route. Every time a route flaps, the FoM is increased and the route is suppressed if the FoM crosses the suppress threshold.
Route reuse timer trigger
A suppressed route’s FoM decays exponentially. When it crosses the reuse threshold, the route is eligible for advertisement if it is still reachable.
If the route continues to flap, the FoM, with respect to time scale, looks like a sawtooth waveform with the exponential rise and decay of FoM. To control flapping, the following parameters can be configured:
half-life
The half-life value is the time, expressed in minutes, required for a route to remain stable in order for one half of the FoM value to be reduced. For example, if the half-life value is 6 (minutes) and the route remains stable for 6 minutes, then the new FoM value is 3. After another 6 minutes passes and the route remains stable, the new FoM value is 1.5.
max-suppress
The maximum suppression time, expressed in minutes, is the maximum amount of time that a route can remain suppressed.
suppress
If the FoM value exceeds the configured integer value, the route is suppressed for use or inclusion in advertisements.
reuse
If the suppress value falls below the configured reuse value, then the route can be reused.
Regular expressions
The ability to perform a filter match on confederations in the AS path or communities is supported. This filter allows customers to configure match criteria for specific confederation sets and sequences within the AS path so that they can be filtered out before cluttering the service provider’s routing information base (RIB). When matching communities, the filter allows customers to configure match criteria within the community value.
SR OS uses regular expression strings to specify match criteria for:
an AS path string; for example, ‟100 200 300”
a community string; for example, ‟100:200” where 100 is the AS number, and 200 is the community-value
any AS path beginning with a confederation SET or SEQ containing 65001 and 65002 only: for example, ‟< 65001 65002 >.*”
any AS path containing a confederation SET or SEQ, regardless of the contents: for example, ‟.* <.*> .*”
A regular expression is expressed in the form of terms and operators.
A term for an AS path regular expression must meet the following criteria.
Regular expressions should always be enclosed in quotes.
An elementary term; for example, an AS number ‟200”
A range term composed of two elementary terms separated by the ‟-” character, such as ‟200-300”.
The ‟.” dot wild-card character which matches any elementary term.
A regular expression enclosed in parenthesis ‟( )”.
A regular expression enclosed in square brackets used to specify a set of choices of elementary or range terms; for example, [100-300 400] matches any AS number between 100 and 300 or the AS number 400.
A term for a community string regular expression is a string that is evaluated character by character and is composed of:
an elementary term, which for a community string, is any single digit, such as ‟4”
A range term composed of two elementary terms separated by the ‛-’ character like ‟2-3”
a colon ‟:” to delimit the AS number from the community value
the ‟.” dot wild-card character which matches any elementary term or ':'
a regular expression enclosed in parenthesis ‟( )”
a regular expression enclosed in square brackets used to specify a set of choices of elementary or range terms; for example, [51-37] matches digit 5 or any single digit between 1 and 3 or the digit 7
extended communities of type route-target and route-origin may embed two regular expressions separated by ONE ampersand ‟'&”) character; the first expression is applied to the as-value of the community string and the second to the local administrative value
large communities may embed three regular expressions separated by two ampersand (‟&”) characters; the first expression is applied to the Global Administrator part of the large community, the second expression is applied to the Local Data part 1 element of the large community, and the third expression is applied to the Local Data part 2 element of the large community
A raw hex format can be keyed to represent all extended communities. For example, "ext:0102:dc0000020032" is the same as ‟target:65530:20”. Hex values ‟ext:” and ‟&” can also be used to filter extended communities. The first expression is applied to the type/subtype of the extended community and the second expression to the value. In this case, hex values can also be used in the operands; for example, the value {3,f} matches a minimum 3 and a maximum 15 repetitions of the term.
The regular expression OPERATORS are listed in Regular expression operators .
Operator | Description |
---|---|
| |
Matches the term on alternate sides of the pipe. |
* |
Matches multiple occurrences of the term. |
? |
Matches 0 or 1 occurrence of the term. |
+ |
Matches 1 or more occurrence of the term. |
( ) |
Used to parenthesize so a regular expression is considered as one term. |
[ ] |
Used to demarcate a set of elementary or range terms. |
- |
Used between the start and end of a range. |
{m,n} |
Matches least m and at most n repetitions of the term. |
{m} |
Matches exactly m repetitions of the term. |
{m,} |
Matches m or more repetitions of the term. |
^ |
Matches the beginning of the string - only allowed for communities. |
$ |
Matches the end of the string - only allowed for communities. |
\ |
An escape character to indicate that the following character is a match criteria and not a grouping delimiter. |
<> |
Matches any AS path numbers containing a confederation SET or SEQ. |
& |
Matches ‟:” between terms of a community string (applicable to extended communities origin, target, bandwidth, ext only). |
Examples of ‟target:”, ‟origin:” and ‟ext:” community strings are listed in Community strings examples .
Example expression | Example matches |
---|---|
"ext:..&f(.*)[af]$" |
Matches the community "ext:0002:fffa0000001a". |
'target:1&22 |
Matches community target:100:221. |
target:^1&^22 |
Matches community target:100:221. |
target:(.*)0$&(.*)1$ |
Matches community target:100:221. |
origin:^1&(.*)1$ |
Matches community origin:100:221. |
Examples of AS path and community string regular expressions are listed in AS path and community regular expression examples .
AS path to match criteria | Regular expression | Example matches |
---|---|---|
Null AS path |
null1 |
Null AS path |
AS path is 11 |
11 |
11 |
AS path is 11 22 33 |
11 22 33 |
11 22 33 |
Zero or more occurrences of AS number 11 |
11* |
Null AS path 11 11 11 11 11 11 11 … 11 |
Path of any length that begins with AS numbers 11, 22, 33 |
11 22 33 .* |
11 22 33 11 22 33 400 500 600 |
Path of any length that ends with AS numbers 44, 55, 66 |
.* 44 55 66 |
44 55 66 100 44 55 66 100 200 44 55 66 100 200 300 44 55 66 100 200 300 … 44 55 66 |
One occurrence of the AS numbers 100 and 200, followed by one or more occurrences of the number 33 |
100 200 33+ |
100 200 33 100 200 33 33 100 200 33 33 33 100 200 33 33 33 … 33 |
One or more occurrences of AS number 11, followed by one or more occurrences of AS number 22, followed by one or more occurrences of AS number 33 |
11+ 22+ 33+ |
11 22 33 11 11 22 33 11 11 22 22 33 11 11 22 22 33 33 11 … 11 22 … 22 33 …33 |
Path whose second AS number must be 11 or 22 |
(. 11) | (. 22) .* or . (11 | 22) .* |
100 11 200 22 300 400 … |
Path of length one or two whose second AS number may be 11 or 22 |
. (11 | 22)? |
100 200 11 300 22 |
Path whose first AS number is 100 and second AS number is either 11 or 22 |
100 (11 | 22) .* |
100 11 100 22 200 300 |
Either AS path 11, 22, or 33 |
[11 22 33] |
11 22 33 |
Range of AS numbers to match a single AS number |
10-14 |
10 or 11 or 12 or 13 or 14 |
[10-12]* |
Null AS path 10 or 11 or 12 10 10 or 10 11 or 10 12 11 10 or 11 11 or 11 12 12 10 or 12 11 or 12 12 … |
|
Zero or one occurrence of AS number 11 |
11? or 11{0,1} |
Null AS path 11 |
One through four occurrences of AS number 11 |
11{1,4} |
11 11 11 11 11 11 11 11 11 11 |
One through four occurrences of AS number 11 followed by one occurrence of AS number 22 |
11{1,4} 22 |
11 22 11 11 22 11 11 11 22 11 11 11 11 22 |
Path of any length, except nonexistent, whose second AS number can be anything, including nonexistent |
. .* or . .{0,} |
100 100 200 11 22 33 44 55 |
AS number is 100. Community value is 200. |
^100:200$ |
100:200 |
AS number is 11 or 22. Community value is any number. |
^((11)|(22)):(.*)$ |
11:100 22:100 11:200 … |
AS number is 11. Community value is any number that starts with 1. |
^11:(1.*)$ |
11:1 11:100 11:1100 … |
AS number is any number. Community value is any number that ends with 1, 2, or 3. |
^(.*):(.*[1-3])$ |
11:1 100:2002 333:55553 … |
AS number is 11 or 22. Community value is any number that starts with 3 and ends with 4, 5 or 9. |
^((11)|(22)):(3.*[459])$ |
11:34 22:3335 11:3777779 … |
AS number is 11 or 22. Community value ends in 33 or 44. |
[^((11|22)):(.*((33)|(44)))$ |
11:33 22:99944 22:555533 … |
Range of Community values |
100&^([1-9][0-9]|[1-9][0-9][0-9]|1[0-9][0-9][0-9]|2000)$" |
100:10 100:11 100: … 100:2000 |
BGP and OSPF route policy support
OSPF and BGP requires route policy support. BGP route policy diagram and OSPF route policy diagram display where route policies are evaluated in the protocol. BGP route policy diagram depicts BGP which applies a route policy as an internal part of the BGP route selection process. OSPF route policy diagram depicts OSPF which applies routing policies at the edge of the protocol, to control only the routes that are announced to or accepted from the Route Table Manager (RTM).
BGP route policies
Nokia’s implementation of BGP uses route policies extensively. The implied or default route policies can be overridden by customized route policies. The default BGP properties, with no route policies configured, behave as follows:
accept all BGP routes into the RTM for consideration
announce all used BGP learned routes to other BGP peers
announce none of the IGP, static or local routes to BGP peers
Re-advertised route policies
Occasionally, BGP routes may be re advertised from BGP into OSPF, IS-IS, and RIP. OSPF export policies (policies control which routes are exported to OSPF) are not handled by the main OSPF task but are handled by a separate task or an RTM task that filters the routes before they are presented to the main OSPF task.
Triggered policies
With triggered policy enabled, deletion and re-addition of a peer after making changes to export policy causes the new updates sent out to all peers.
Triggered policy is not honored if a new peer added to BGP. Update with the old policy is sent to the newly added peer. New policy does not get applied to the new peer until the peer is flapped.
With triggered policy enabled, if a new BGP/static route comes in, new addition or modification of an export policy causes the updates to send out dynamically to all peers with the new/modified export policy.
When multiple peers, say P1, P2 and P3 share the same export policy, any modifications to export policy followed by clear soft on one of the peer P1, send out routes to P1 only according to newly modified policy.
Though routes with newly modified policy are not sent to other peers (P2, and P3) as no clear soft issues on these peers, RIB-OUT shows that new routes with modified policy are sent to all the peers. RIB-IN on peers P2 and P3 are shown correctly.
The triggered policy is not honored if a new peer is added to BGP. An update with the old policy is sent to the newly added peer. The new policy is not applied to the new peer until the peer is flapped.
With the triggered policy enabled, if a new BGP/static route comes in, the new addition or modification of an export policy causes the updates to be sent out dynamically to all peers with the new/modified export policy.
When multiple peers, such as P1, P2 and P3, share the same export policy, any modifications to the export policy followed by clear soft on one of the peer P1s, send out routes to P1 only according to the newly modified policy. Though routes with the newly modified policy are not sent to other peers (P2 and P3) as there are no clear soft issues on these peers, RIB-OUT shows that the new routes with the modified policy are sent to all the peers. RIB-IN on peers P2 and P3 are shown correctly.
Set MED to IGP cost using route policies
This feature sets MED to the IGP cost of a route exported into BGP as an action in route policies. The med-out command in the bgp, group, and neighbor configuration context supports this option, but this method lacks per-prefix granularity. The enhanced metric command supported as a route policy action supports setting MED to a fixed number, or adding, or subtracting a fixed number from the received MED, and sets IGP cost option. The enhanced metric {set {igp | number1} | {add | subtract} number2} command is under config>router>policy-options>policy-statement>entry>action.
The metric set igp command, when used in a BGP export policy, have the same effect as the current med-out igp command, except that it applies only to the routes matched by the policy entry.
The effect of the metric set igp command depends on the route type and policy type as summarized in Metric set IGP effect.
BGP policy type | Matched route type | Set metric IGP effect |
---|---|---|
Export |
Non-BGP route (static, OSPF, ISIS, and so on) |
Add MED attribute. Set value to M. |
Export |
BGP route w/o MED |
Add MED attribute. Set value to D. |
Export |
BGP route with MED (value A) |
Overwrite MED attribute with value D. |
BGP policy subroutines
A BGP policy can call another policy (subroutine) and that subroutine can call another subroutine, and so on. This facilitates re-usability of common logic and a structured approach to writing BGP policies. Up to three levels of subroutine are supported.
Route policies for BGP next-hop resolution and peer tracking
This feature adds the flexibility to attach a route policy to the BGP next-hop resolution process; it also allows a route policy to be associated with the optional BGP peer-tracking function. BGP next-hop resolution is a fundamental part of BGP protocol operation; it determines the best matching route (or tunnel) for the BGP next-hop address and uses information about this resolving route in the best path selection algorithm and to program the forwarding table. Attaching a policy to BGP next-hop resolution provides more control over which IP routes in the routing table can become resolving routes. Similar flexibility is also available for BGP peer-tracking, which is an optional feature that allows the session with a BGP neighbor to be taken down if there is no IP route to the neighbor address or if the best matching IP route is rejected by the policy.
Routing policy parameterization
Routing policy parameterization allows operators a powerful and flexible configuration approach to routing policies for policies are often reused across BGP peers of a common type (such as, transit, peer, customer).
In current modes of operation as shown in Route policy past mode of operation, an operator must create individual routing policies, prefix-lists, AS-Path lists, community lists, and so on for each peer despite many times the policy ultimately being the same. In this case, should an operator with 100 peers with a common policy behavior but unique policies have to make a change to entry 135 in the policy, they must do it on all policies – a significant amount of work that can result in incorrect/inconsistent policy behavior.
Using a parameter based system allows an operator to have a single policy that is consistent across all peers of a type, while retaining the flexibility to reference different policy functions (such as, prefixes, prefix-lists, community lists) with unique names if required, by defining variables and the variable value.
Additionally, instead of policies being fixed and requiring many statements, the use of parameters and variables may be passed to simplify policy configuration. This reduces the number of policies required on a peering edge router with large numbers of peers where only small amounts of configuration changes between peers, such as the ASN and prefix-list name.
The following two types of policy variables are supported.
-
Global policy variables are configured using the global-variables command and can be referenced from any policy. Use global policy variables when the variables are used by multiple policies.
-
Local policy variables are configured using the policy-variables command in each policy, and can be referenced in a sub-policy. Use local policy variables when the variables are specific to a policy and are not used in any other policies.
Variables expansion can use two formats, with the variable name delimited by at-signs (@) at the beginning and the end:
-
standard variables must start and end with at-signs (@), for example: @variable@
-
midstring variables must be enclosed with at-signs (@) and may be midstring, for example: @variable@, start@variable@end, @variable@end, start@variable@
Route policy variable support in policy parameters lists route policy variables supported in policy parameters.
Parameter name | Variable in policy ‟from” statement | Variable in policy ‟action” statement | Variable format | Standard format release | Midstring format release |
---|---|---|---|---|---|
aigp-metric |
No |
Yes |
Standard |
13.0.R4 |
— |
as-path |
Yes |
Yes |
Midstring |
12.0.R1 |
13.0.R1 |
as-path expression |
Yes |
No |
Midstring |
12.0.R4 |
13.0.R1 |
as-path-group |
Yes |
No |
Midstring |
12.0.R1 |
13.0.R1 |
as-path-group expression |
Yes |
No |
Midstring |
12.0.R4 |
13.0.R1 |
as-path-length |
Yes |
— |
Standard |
15.0.R1 |
— |
as-path-prepend |
— |
Yes |
Standard |
13.0.R4 |
— |
cluster-id |
No |
— |
— |
— |
— |
community |
Yes |
Yes |
Midstring |
12.0.R1 |
13.0.R1 |
community-count |
Yes |
— |
Standard |
15.0.R1 |
N/A |
damping |
No |
Yes |
Midstring |
13.0.R4 |
13.0.R4 |
local-preference |
Yes (15.0.R1) |
Yes (13.0.R4) |
Standard |
13.0.R4 |
— |
metric |
Yes (15.0.R1) |
Yes (13.0.R4) |
Standard |
13.0.R4 |
— |
next-hop |
No |
Yes |
Standard |
13.0.R4 |
— |
origin |
No |
Yes |
Standard |
13.0.R4 |
— |
path-type |
No |
— |
— |
— |
— |
preference |
No |
Yes |
Standard |
13.0.R4 |
— |
prefix-list |
Yes |
No |
Midstring |
12.0.R1 |
13.0.R1 |
route-distinguisher-list |
Yes |
No |
Midstring |
23.3.R1 |
23.3.R1 |
tag |
No |
Yes |
Standard |
13.0.R4 |
— |
type |
No |
Yes |
Standard |
13.0.R4 |
— |
For the definition of the variables, there are three different possible types:
-
name name-string value value-string
-
name name-string address ip-address
-
name name-string number value-number
Depending on the parameter referenced, specify the correct type as follows:
-
value-string: as-path, as-path-group, community, prefix-list, damping
-
ip-address: next-hop
-
value-number: aigp-metric, as-path-length, as-path-prepend, community-count, local-preference, metric, origin, origin-validation, preference, tag, type
The logical flow of this is to configure a per-peer policy in which the variable names and values are defined. Using Route policy parameterization using sub-policies as the example, the following configuration would be applied:
prefix-list "pfx-as63535"
prefix 6.3.5.0/24 through 32
exit
prefix-list "pfx-as64535"
prefix 6.4.5.0/24 through 32
exit
prefix-list "pfx-as65535"
prefix 6.5.5.0/24 through 32
exit
community "cm-as63535" members "7750:63535"
community "cm-as65535" members "7750:65535"
community "cm-as64535-rejects" members "64535:14"
community "cm-as65535-rejects" members "65535:14"
community "cm-as64535-highpref" members "7777:64535"
as-path "as63535" expression "^63535$"
as-path "as64535" expression "^64535$"
as-path "as65535" expression "^65535$"
policy-statement "peer1"
entry 5
from
policy-variables
name "@cm-reject@" value "cm-as65535-rejects"
exit
policy "std-peering-inbound-drop"
exit
action reject
entry 10
from
policy-variables
name "@localcm@" value "cm-as65535"
name "@peer-as@" value "as65535"
name "@cm-highpref@" value "cm-as65535-highpref"
name "@peer-prefix@" value "pfx-as65535"
exit
policy "std-peering-inbound-main"
exit
action accept
exit
exit
exit
policy-statement "peer2"
entry 5
from
policy-variables
name "@cm-reject@" value "cm-as64535-rejects"
exit
policy "std-peering-inbound-drop"
exit
action reject
entry 10
from
policy-variables
name "@localcm@" value "cm-as64535"
name "@peer-as@" value "as64535"
name "@cm-highpref@" value "cm-as64535-highpref"
name "@peer-prefix@" value "pfx-as64535"
exit
policy "std-peering-inbound-main"
exit
action accept
exit
exit
exit
policy-statement "peer3"
entry 5
from
policy-variables
name "@cm-reject@" value "cm-as63535-rejects"
exit
policy "std-peering-inbound-drop"
exit
action reject
entry 10
from
policy-variables
name "@localcm@" value "cm-as63535"
name "@peer-as@" value "as63535"
name "@cm-highpref@" value "cm-as63535-highpref"
name "@peer-prefix@" value "pfx-as63535"
exit
policy "std-peering-inbound-main"
exit
action accept
exit
exit
exit
policy-statement "std-peering-inbound-drop"
default-action reject
entry 10
from
community "@cm-reject@"
exit
action accept
policy-statement "std-peering-inbound-main"
default-action reject
entry 10
from
prefix-list "@peer-prefix@"
as-path "@peer-as@"
exit
action accept
community add "@localcm@"
local-preference 400
exit
exit
entry 20
from
community "@cm-highpref@"
exit
action accept
community add "@localcm@"
local-preference 4000
exit
exit
exit
This configuration would take slightly different actions depending on the peer.
Peer 1
-
Routes that have a community matching ‟cm-as65535-rejects” are dropped.
-
Routes matching the prefix list ‟pfx-as65535” that originated in the peer AS=65535 are accepted with a local preference of 400.
-
Community ‟7750:65535” is added to accepted prefixes.
-
As community-list ‟cm-65535-highpref” does not exist, no routes are modified with a local preference of 4000.
Peer 2
-
Routes that have a community matching ‟cm-as64535-rejects” are dropped.
-
Routes matching the prefix list ‟pfx-as65535” that originated in the peer AS=65535 are accepted with a local preference of 400.
-
Prefixes matching ‟cm-as64535-highpref” are set to a local-preference of 4000.
Peer 3
-
As community-list ‟cm-as63535-rejects” does not exist, no routes are dropped by the first entry.
-
Routes matching the prefix list ‟pfx-as63535” that originated in the peer AS=63535 are accepted with a local preference of 400.
-
Community ‟7750:63535” is added to accepted prefixes.
-
As community-list ‟cm-63535-highpref” does not exist, no routes are modified with a local preference of 4000.
When to use route policies
The following are examples of circumstances of when to configure and apply unique route policies.
When you want to control the protocol to allow all routes to be imported into the routing table. This enables the routing table to learn about particular routes to enable packet forwarding and redistributing packets into other routing protocols.
When you want to control the exporting of a protocol’s learned active routes.
When you want a routing protocol to announce active routes learned from another routing protocol, which is sometimes called route redistribution.
When you want unique behaviors to control route characteristics. For example, change the route preference.
When you want unique behaviors to control route characteristics. For example, change the route preference, AS path, or community values to manipulate the control the route selection.
When you want to control BGP route flapping (damping).
Route policy configuration process overview
Route policy configuration and implementation flow displays the process to provision basic route policy parameters.
Configuration notes
This section describes route policy configuration restrictions.
General
When configuring policy statements, the policy statement name must be unique.
Policy reference checks
The policy reference checks functionality can be enabled with config>router>policy-reference-checks to indicate policies and policy objects in policy statements that are referenced but do not exist. An INFO or WARNING message is displayed in the CLI.
If a policy is referenced which has not yet been configured, and no policy-reference-checks is set, the configuration line succeeds with the CLI message:
WARNING: CLI Policy "bar" does not exist
If a policy is referenced which has not yet been configured, and policy-reference-checks is set, the configuration line errors and fails with the CLI message:
MINOR: CLI Policy "foo" does not exist
Policy reference checks are required in router configuration contexts that reference a policy name, including the following:
configure router bgp export
configure router bgp group export
configure router bgp group import
configure router bgp group neighbor export
configure router bgp group neighbor import
configure router bgp import
configure service vprn bgp export
configure service vprn bgp group export
configure service vprn bgp group import
configure service vprn bgp group neighbor export
configure service vprn bgp group neighbor import
configure service vprn bgp import
configure service vprn vrf-export
configure service vprn vrf-import
Policy reference checks are required in policy configuration contexts that reference a policy element, including the following:
entry from flow-spec-dest prefix-list-name
entry from flow-spec-source prefix-list-name
entry from group-address prefix-list-name
entry from host-ip prefix-list-name
entry from neighbor {ip-address | prefix-list-name}
entry from next-hop prefix-list-name
entry from prefix-list name [name]
entry from source-address prefix-list prefix-list-name
entry to neighbor {ip-address | prefix-list-name}
entry to prefix-list name [name]
as-path
as-path-group
community
damping
policy statements used in sub-policies
Known limitations
Policy elements must be entered in the correct order to resolve references. For example, if a prefix-list is referenced in a policy statement, the prefix-list must be entered first. This feature does not order policy statements so that references to policy elements exist.
Variable expansion is not supported with the policy reference checks feature. Variables that reference policy elements that do not exist are not checked and are permitted.
This feature is available only for configuring policies. If a policy is deleted, the command succeeds with no info or warning messages displayed. Information from the show router policy-edits command can be used to see warnings about which elements do not exist.
The policy reference checks functionality is not supported with policy expressions.
Configuring route policies with CLI
This section provides information to configure route policies.
Route policy configuration overview
Route policies allow you to configure routing according to specifically defined policies. You can create policies and entries to allow or deny paths based on various parameters such as destination address, protocol, packet size, and community list.
Policies can be as simple or complex as required. A simple policy can block routes for a specific location or IP address. More complex policies can be configured using numerous policy statement entries containing matching conditions to specify whether to accept or reject the route, control how a series of policies are evaluated, and manipulate the characteristics associated with a route.
When to create routing policies
Route policies are created in the config>router context. There are no default route policies. Each route policy must be explicitly created and applied. Applying route policies can introduce more efficiency as well as more complexity to routers.
A route policy impacts the flow of routing information or packets within and through the router. A routing policy can be specified to prevent a particular customer’s routes to be placed in the route table which causes those routes to not forward traffic to various destinations and the routes are not advertised by the routing protocol to neighbors.
Route policies can be created to control:
a protocol to export all the active routes learned by that protocol
route characteristics to control which route is selected to act as the active route to reach a destination and advertise the route to neighbors
protocol to import all routes into the routing table. A routing table must learn about particular routes to be able to forward packets and redistribute to other routing protocols
damping
Before a route policy is applied, analyze the policy’s purpose and be aware of the results (and consequences) when packets match the specified criteria and the associated actions and default actions, if specified, are executed. Membership reports can be filtered based on a specific source address.
Default route policy actions
Each routing protocol has default behaviors for the import and export of routing information. Default route policy actions shows the default behavior for each routing protocol.
Protocol | Import | Export |
---|---|---|
OSPF |
Not applicable. All OSPF routes are accepted from OSPF neighbors and cannot be controlled via route policies. |
|
IS-IS |
Not applicable. All IS-IS routes are accepted from IS-IS neighbors and cannot be controlled via route policies |
|
RIP |
By default, all RIP-learned routes are accepted. |
External routes: By default, all non-RIP learned routes are not advertised to RIP peers. |
BGP |
By default, all routes from BGP peers are accepted and passed to the BGP route selection process. |
|
Policy evaluation
Routing policy statements can consist of as few as one or several entries. The entries specify the matching criteria. A route is compared to the first entry in the policy statement. If it matches, the specified entry action is taken, either accepted or rejected. If the action is to accept or reject the route, that action is taken and the evaluation of the route ends.
If the route does not match the first entry, the route is compared to the next entry (if more than one is configured) in the policy statement. If there is a match with the second entry, the specified action is taken. If the action is to accept or reject the route, that action is taken and the evaluation of the route ends, and so on.
Each route policy statement can have a default-action clause defined. If a default-action is defined for one or more of the configured route policies, then the default actions should be handled in the following ways.
The process stops when the first complete match is found and executes the action defined in the entry.
If the packet does not match any of the entries, the system executes the default action specified in the policy statement.
Route policy process example depicts an example of the route policy process.
Route policies can also match a specific route policy entry and continue to search for other entries within either the same route policy or the next route policy by specifying the next-entry or next-policy option in the entry’s action command. Policies can be constructed to support multiple states to the evaluation and setting of various route attributes.
Next policy logic example depicts the next-policy and next-entry route processes.
For the default route policy actions, see Default route policy actions.
Damping
Damping initiates controls when routes flap. Route flapping can occur when an advertised route between nodes alternates (flaps) back and forth between two paths because of network problems which cause intermittent route failures. It is necessary to reduce the amount of routing state change updates propagated to limit processing requirements. Thus, when a route flaps beyond a configured value (the suppress value), then that route is removed from the routing tables and routing protocols until the value falls below the reuse value.
A route can be suppressed according to the Figure of Merit (FoM) value. The FoM is a value that is added to a route each time it flaps. A new route begins with an FoM value of 0.
Damping is optional. If damping is configured, the following parameter values must be explicitly specified as there are no default values:
suppress
half-life
reuse
max-suppress
When a route's FoM value exceeds the suppress value, then the route is removed from the routing table. The route is considered to be stable when the FoM drops below the reuse value by means of the specified half-life parameter. The route is returned to the routing tables. When routes have higher FoM and half-life values, they are suppressed for longer periods of time. Damping example depicts an example of a flapping route, the suppress threshold, the half-life decay (time), and reuse threshold. The peaks represent route flaps, the slopes represent half-life decay.
Basic configurations
This section provides information to configure route policies and configuration examples of common tasks. The minimal route policy parameters that need to be configured are described below.
Policy statement with the following parameters specified:
-
at least one entry
-
entry action
Following is an example route policy configuration:
A:ALA-B>config>router>policy-options# info
----------------------------------------------
community "all-types" members "5000:[1-6][1-9][0-9]"
community "all-normal" members "5000:[1-5][1-9][0-9]"
. . .
as-path "Outside madeup paths" ".* 5001 .*"
as-path "Outside Internet paths" ".* 5002 .*"
policy-statement "RejectOutsideASPaths"
entry 1
from
protocol bgpospf
as-path "Outside madeup paths"
exit
action reject
exit
exit
entry 2
from
protocol bgpospf
as-path "Outside Internet paths"
exit
action reject
exit
exit
entry 3
from
protocol ospf
exit
to
protocol bgpospf
exit
action reject
exit
exit
entry 4
from
protocol isis
exit
to
protocol bgpospf
exit
action reject
exit
exit
default-action accept
exit
exit
policy-statement "aggregate-customer-peer-only"
entry 1
from
community "all-customer-announce"
exit
action accept
exit
exit
default-action reject
exit
exit
----------------------------------------------
A:ALA-B>config>router>policy-options#
Configuring route policy components
This section describes information to configure route policy components using the Classic CLI engine.
Beginning the policy statement
Use the following CLI syntax to begin a policy statement configuration. In order for a policy statement to be complete an entry must be specified (see Configuring an entry).
config>router>policy-options
begin
policy-statement name
description text
The following error message displays when you try to modify a policy options command without entering begin first.
A:ALA-B>config>router>policy-options# policy-statement ‟allow all”
MINOR: CLI The policy-options must be in edit mode by calling begin before
any changes can be made.
The following example displays policy statement configuration command usage. These commands are configured in the config>router context.
Example:
config>router# policy-options
policy-options# begin
There are no default policy statement options. All parameters must be explicitly configured.
Creating a route policy
To enter the mode to create or edit route policies, you must enter the begin keyword at the config>router>policy-options prompt. Other editing commands include:
the commit command saves changes made to route policies during a session
the abort command discards changes that have been made to route policies during a session
The following error message displays when you try to modify a policy options command without entering begin first.
A:ALA-B>config>router>policy-options# policy-statement ‟allow all”
MINOR: CLI The policy-options must be in edit mode by calling begin before any
changes can be made.
A:ALA-B>config>router>policy-options# info
#------------------------------------------
# Policy
#------------------------------------------
policy-options
begin
policy-statement "allow all"
description "General Policy"
...
exit
exit
----------------------------------------------
A:ALA-B>config>router>policy-options#
Configuring a default action
Specifying a default action is optional. The default action controls those packets not matching any policy statement entries. If no default action is specified for the policy, then the action associated with the protocol to which the routing policy was applied is performed. The default action is applied only to those routes that do not match any policy entries.
A policy statement must include at least one entry (see Configuring an entry).
To enter the mode to create or edit route policies, you must enter the begin keyword at the config>router>policy-options prompt. Other editing commands include:
the commit command saves changes made to route policies during a session
the abort command discards changes that have been made to route policies during a session
The following example displays the default action configuration:
A:ALA-B>config>router>policy-options# info
----------------------------------------------
policy-statement "1"
default-action accept
as-path add "test"
community add "365"
damping "flaptest"
next-hop 10.10.10.104
exit
exit
----------------------------------------------
A:ALA-B>config>router>policy-options#
Configuring an entry
An entry action must be specified. The other parameters in the entry action context are optional.
The following example displays entry parameters and includes the default action parameters which were displayed in the previous section.
A:ALA-B>config>router>policy-options# info
----------------------------------------------
policy-statement "1"
entry 1
to
neighbor 10.10.10.104
exit
action accept
exit
exit
entry 2
from
protocol ospf 1
exit
to
protocol ospf
neighbor 10.10.0.91
exit
action accept
exit
exit
default-action accept
. . .
exit
exit
The following example displays entry parameters and includes the default action parameters which were displayed in the previous section.
A:ALA-B>config>router>policy-options# info
----------------------------------------------
policy-statement "1"
entry 1
to
protocol bgp
neighbor 10.10.10.104
exit
action accept
exit
exit
entry 2
from
protocol ospf 1
exit
to
protocol ospf
neighbor 10.10.0.91
exit
action accept
exit
exit
default-action accept
. . .
exit
exit
Configuring a community list
Community lists are composed of a group of destinations which share a common property. Community lists allow you to administer actions on a configured group instead of having to execute identical commands for each member.
The following example displays a community list configuration:
A:ALA-B>config>router>policy-options# info
----------------------------------------------
community "eastern" members "100:200"
community "western" members "100:300"
community "northern" members "100:400"
community "southern" members "100:500"
community "headquarters" members "100:1000"
policy-statement "1"
entry 1
to
protocol bgp
neighbor 10.10.10.104
exit
action accept
. . .
----------------------------------------------
A:ALA-B>config>router>policy-options#
Configuring damping
The following considerations apply.
For each damping profile, all parameters must be configured.
The suppress value must be greater than the reuse value (see Damping example).
Damping can be enabled in the config>router>bgp context on the BGP global, group, and neighbor levels. If damping is enabled, but route policy does not specify a damping profile, the default damping profile is used. This profile is always present and consists of the following parameters:
half-life: 15 minutes
max-suppress: 60 minutes
suppress: 3000
reuse: 750
The following example displays a damping configuration:
*A:cses-A13>config>router>policy-options# info
----------------------------------------------
damping "damptest123"
half-life 15
max-suppress 60
reuse 750
suppress 1000
exit
----------------------------------------------
*A:cses-A13>config>router>policy-options#
Configuring a prefix list
The following example displays a prefix list configuration:
A:ALA-B>config>router>policy-options# info
----------------------------------------------
prefix-list "western"
prefix 10.10.0.1/32 exact
prefix 10.10.0.2/32 exact
prefix 10.10.0.3/32 exact
prefix 10.10.0.4/32 exact
exit
damping "damptest123"
half-life 15
max-suppress 60
reuse 750
exit
----------------------------------------------
A:ALA-B>config>router>policy-options#
Route policy configuration management tasks
This section discusses route policy configuration management tasks.
Editing policy statements and parameters
Route policy statements can be edited to modify, add, or delete parameters. To enter the mode to edit route policies, you must enter the begin keyword at the config>router> policy-options prompt. Other editing commands include:
the commit command saves changes made to route policies during a session
the abort command discards changes that have been made to route policies during a session
The following example displays a changed configuration:
A:ALA-B>config>router>policy-options>policy-statement# info
----------------------------------------------
description "Level 1"
entry 1
to
protocol bgp
neighbor 10.10.10.104
exit
action accept
exit
exit
entry 2
from
protocol ospf
exit
to
protocol ospf
neighbor 10.10.0.91
exit
action accept
exit
exit
entry 4
description "new entry"
from
protocol isis
area 0.0.0.20
exit
action reject
exit
default-action accept
as-path add "test"
community add "365"
damping "flapper"
next-hop 10.10.10.104
exit
----------------------------------------------
Deleting an entry
Use the following CLI syntax to delete a policy statement entry.
CLI syntax
config>router>policy-options
begin
commit
abort
policy-statement name
no entry entry-id
The following example displays the commands required to delete a policy statement entry.
Example
config>router>policy-options# begin
policy-options# policy-statement "1"
policy-options>policy-statement# no entry 4
policy-options>policy-statement# commit
Deleting a policy statement
Use the following CLI syntax to delete a policy statement.
CLI syntax
config>router>policy-options
begin
commit
abort
no policy-statement name
The following example displays the commands required to delete a policy statement.
Example
config>router>policy-options# begin
policy-options# no policy-statement 1
policy-options# commit