Segment Routing Configuration Guide for Cisco NCS 5500 Series Routers, IOS XR Release 7.5.x
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Segment Routing Flexible Algorithm allows operators to customize IGP shortest path computation according to their own needs.
An operator can assign custom SR prefix-SIDs to realize forwarding beyond link-cost-based SPF. As a result, Flexible Algorithm
provides a traffic engineered path automatically computed by the IGP to any destination reachable by the IGP.
The SR architecture associates prefix-SIDs to an algorithm which defines how the path is computed. Flexible Algorithm allows
for user-defined algorithms where the IGP computes paths based on a user-defined combination of metric type and constraint.
This document describes the IS-IS and OSPF extensions to support Segment Routing Flexible Algorithm on an MPLS data-plane.
Prerequisites for Flexible Algorithm
Segment routing must be enabled on the router before the Flexible Algorithm functionality is activated.
Building Blocks of Segment Routing Flexible Algorithm
This section describes the building blocks that are required to support the SR Flexible Algorithm functionality in IS-IS and OSPF.
Flexible Algorithm Definition
Many possible constraints may be used to compute a path over a network. Some networks are deployed with multiple planes. A
simple form of constraint may be to use a particular plane. A more sophisticated form of constraint can include some extended
metric, like delay, as described in [RFC7810]. Even more advanced case could be to restrict the path and avoid links with
certain affinities. Combinations of these are also possible. To provide a maximum flexibility, the mapping between the algorithm
value and its meaning can be defined by the user. When all the routers in the domain have the common understanding what the
particular algorithm value represents, the computation for such algorithm is consistent and the traffic is not subject to
looping. Here, since the meaning of the algorithm is not defined by any standard, but is defined by the user, it is called
a Flexible Algorithm.
Flexible Algorithm Membership
An algorithm defines how the best path is computed by IGP. Routers advertise the support for the algorithm as a node capability.
Prefix-SIDs are also advertised with an algorithm value and are tightly coupled with the algorithm itself.
An algorithm is a one octet value. Values from 128 to 255 are reserved for user defined values and are used for Flexible Algorithm
representation.
Flexible Algorithm Definition Advertisement
To guarantee the loop free forwarding for paths computed for a particular Flexible Algorithm, all routers in the network must
share the same definition of the Flexible Algorithm. This is achieved by dedicated router(s) advertising the definition of
each Flexible Algorithm. Such advertisement is associated with the priority to make sure that all routers will agree on a
single and consistent definition for each Flexible Algorithm.
Definition of Flexible Algorithm includes:
Metric type
Affinity constraints
Exclude SRLG constraint
To enable the router to advertise the definition for the particular Flexible Algorithm, advertise-definition command is used. At least one router in the area, preferably two for redundancy, must advertise the Flexible Algorithm definition.
Without the valid definition being advertised, the Flexible Algorithm will not be functional.
Flexible Algorithm Link Attribute Advertisement
Various link attributes may be used during the Flexible Algorithm path calculation. For example, include or exclude rules
based on link affinities can be part of the Flexible Algorithm definition, as defined in IETF draft draft-ietf-lsr-flex-algo.
Link attribute advertisements used during Flexible Algorithm calculation must use the Application-Specific Link Attribute
(ASLA) advertisements, as defined in RFC8919 (IS-IS) and RFC8920 (OSPF). In the case of IS-IS, if the L-Flag is set in the ASLA advertisement, then legacy advertisements (IS-IS Extended
Reachability TLV) are used instead.
The mandatory use of ASLA advertisements applies to the following link attributes:
Minimum Unidirectional Link Delay
TE Default Metric
Administrative Group
Extended Administrative Group
Shared Risk Link Group
Flexible Algorithm Prefix-SID Advertisement
To be able to forward traffic on a Flexible Algorithm specific path, all routers participating in the Flexible Algorithm will
install a MPLS labeled path for the Flexible Algorithm specific SID that is advertised for the prefix. Only prefixes for which
the Flexible Algorithm specific Prefix-SID is advertised is subject to Flexible Algorithm specific forwarding.
Calculation of Flexible Algorithm Path
Table 1. Feature History Table
Feature Name
Release Information
Feature Description
OSPF: Microloop Avoidance for Flexible Algorithm
Release 7.4.1
This feature extends the current OSPF Flexible Algorithm functionality to support Microloop Avoidance.
Table 2. Feature History Table
Feature Name
Release Information
Feature Description
OSPF: Microloop Avoidance for Flexible Algorithm
Release 7.3.2
This feature extends the current OSPF Flexible Algorithm functionality to support Microloop Avoidance.
OSPF: TI-LFA for Flexible Algorithm
Release 7.3.1
This feature extends the current OSPF Flexible Algorithm functionality to support TI-LFA.
A router may compute path for multiple Flexible Algorithms. A router must be configured to support particular Flexible Algorithm
before it can compute any path for such Flexible Algorithm. A router must have a valid definition of the Flexible Algorithm
before Flexible Algorithm is used.
The router uses the following rules to prune links from the topology during the Flexible Algorithm computation:
All nodes that don't advertise support for Flexible Algorithm are pruned from the topology.
Affinities:
Check if any exclude affinity rule is part of the Flexible Algorithm Definition. If such exclude rule exists, check if any
color that is part of the exclude rule is also set on the link. If such a color is set, the link must be pruned from the computation.
Check if any include-any affinity rule is part of the Flexible Algorithm Definition. If such include-any rule exists, check
if any color that is part of the include-any rule is also set on the link. If no such color is set, the link must be pruned
from the computation.
Check if any include-all affinity rule is part of the Flexible Algorithm Definition. If such include-all rule exists, check
if all colors that are part of the include-all rule are also set on the link. If all such colors are not set on the link,
the link must be pruned from the computation
Router uses the metric that is part of the Flexible Algorithm definition. If the metric isn't advertised for the particular
link, the link is pruned from the topology.
Loop Free Alternate (LFA) paths, TI-LFA backup paths, and Microloop Avoidance paths for particular Flexible Algorithm are
computed using the same constraints as the calculation of the primary paths for such Flexible Algorithm. These paths use Prefix-SIDs
advertised specifically for such Flexible Algorithm in order to enforce a backup or microloop avoidance path.
Configuring Microloop Avoidance for Flexible Algorithm
By default, Microloop Avoidance per Flexible Algorithm instance follows Microloop Avoidance configuration for algo-0. For
information about configuring Microloop Avoidance, see Configure Segment Routing Microloop Avoidance.
You can disable Microloop Avoidance for Flexible Algorithm using the following commands:
Installation of Forwarding Entries for Flexible Algorithm Paths
Flexible Algorithm path to any prefix must be installed in the forwarding using the Prefix-SID that was advertised for such
Flexible Algorithm. If the Prefix-SID for Flexible Algorithm is not known, such Flexible Algorithm path is not installed in
forwarding for such prefix..
Only MPLS to MPLS entries are installed for a Flexible Algorithm path. No IP to IP or IP to MPLS entries are installed. These
follow the native IPG paths computed based on the default algorithm and regular IGP metrics.
Flexible Algorithm Prefix-SID Redistribution
Table 3. Feature History Table
Feature Name
Release Information
Feature Description
Flexible Algorithm Prefix-SID Redistribution for External Route Propagation
Release 7.5.2
You can now propagate flexible algorithm prefix-SIDs and their algorithm-specific metric between different IGP domains, such
as OSPF to IS-IS RIP to OSPF. With this functionality enabling interdomain traffic engineering, you can export flexible algorithm
labels from the OSPF domain to other domains and import the labels from other domains into OSPF.
The show ospf route flex-algo command has been modified to include additional attributes to indicate the external routes.
Prefix redistribution from IS-IS to another IS-IS instance or protocol was limited to SR algorithm 0 (regular SPF) prefix
SIDs; SR algorithm 1 (Strict SPF) and SR algorithms 128-255 (Flexible Algorithm) prefix SIDs were not redistributed along
with the prefix. The Segment Routing IS-IS Flexible Algorithm Prefix SID Redistribution feature allows redistribution of strict
and flexible algorithms prefix SIDs from IS-IS to another IS-IS instance or protocols. This feature is enabled automatically
when you configure redistribution of IS-IS Routes with strict or flexible algorithm SIDs.
Prefix redistribution from OSPF to another AS was limited to SR algorithm 0 (regular SPF) prefix SIDs; SR algorithm 1 (Strict
SPF) and SR algorithms 128-255 (Flexible Algorithm) prefix SIDs were not redistributed along with the prefix. Starting from
Cisco IOS XR Release 7.5.2, the Flexible Algorithm Prefix-SID Redistribution for External Route Propagation feature allows redistribution of strict
and flexible algorithm prefixes SIDs from OSPF to another AS and also from another AS into OSPF.
Configuration Example
The following example shows how to configure redistribute and flexible algorithm to enable external routes.
This following show output displays the route-type as 'Extern' for the external routes.
Router#show ospf routes flex-algo 240 route-type external detail
Route Table of ospf-1 with router ID 192.168.0.2 (VRF default)
Algorithm 240
Route entry for 192.168.4.3/32, Metric 220, SID 536, Label 16536
Priority : Medium
Route type : Extern Type 1
Last updated : Apr 25 14:30:12.718
Flags: Inuse
Prefix Contrib Algo 240 SID 536
From 192.168.0.4 Route-type 5
Total Metric : 220 Base metric 20 FAPM 20
Contrib Flags : Inuse, Reachable
SID Flags : PHP off, Index, Global, Valid
Path: 10.1.1.3, from 192.168.0.4, via GigabitEthernet0/2/0/2
Out Label : 16536
Weight : 0
Area : 0
Path: 10.1.2.3, from 192.168.0.4, via GigabitEthernet0/2/0/3
Out Label : 16536
Weight : 0
Area : 0
Path: 10.2.1.5, from 192.168.0.4, via GigabitEthernet0/2/0/4
Out Label : 16536
Weight : 0
Area : 0
Route entry for 192.168.4.5/32, Metric 120, SID 556, Label 16556
Priority : Medium
Route type : Extern Type 1
Last updated : Apr 25 14:30:12.724
Flags: Inuse
Prefix Contrib Algo 240 SID 556
From 192.168.0.3 Route-type 5
Total Metric : 120 Base metric 1 FAPM 20
Contrib Flags : Inuse, Reachable
SID Flags : PHP off, Index, Global, Valid
Path: 10.1.1.3, from 192.168.0.3, via GigabitEthernet0/2/0/2
Out Label : 16556
Weight : 0
Area : 0
Path: 10.1.2.3, from 192.168.0.3, via GigabitEthernet0/2/0/3
Out Label : 16556
Weight : 0
Area : 0
The following show output displays label information for flexible algorithm and its corresponding metric as added in RIB:
RP/0/RP0/CPU0:ios# show route 192.168.0.2/32 detail
Wed Apr 6 16:24:46.021 IST
Routing entry for 192.168.0.2/32
Known via "ospf 1", distance 110, metric 2, labeled SR, type intra area
Installed Apr 6 15:51:57.973 for 00:32:48
Routing Descriptor Blocks
10.10.10.2, from 192.168.0.2, via GigabitEthernet0/2/0/0, Protected
Route metric is 2
Label: 0x3 (3)
Tunnel ID: None
Binding Label: None
Extended communities count: 0
Path id:1 Path ref count:0
NHID:0x1(Ref:1)
Backup path id:65
OSPF area: 1
10.11.11.2, from 192.168.0.2, via GigabitEthernet0/2/0/1, Backup (Local-LFA)
Route metric is 6
Label: 0x3 (3)
Tunnel ID: None
Binding Label: None
Extended communities count: 0
Path id:65 Path ref count:1
NHID:0x2(Ref:1)
OSPF area:
Route version is 0x12 (18)
Local Label: 0x3ee6 (16102)
Local Label Algo Set (ID, Label, Metric): (1, 16202, 0),(128, 17282, 2)
IP Precedence: Not Set
QoS Group ID: Not Set
Flow-tag: Not Set
Fwd-class: Not Set
Route Priority: RIB_PRIORITY_NON_RECURSIVE_MEDIUM (7) SVD Type RIB_SVD_TYPE_LOCAL
Download Priority 1, Download Version 38
No advertising protos.
Flexible Algorithm Prefix Metric
Table 4. Feature History Table
Feature Name
Release Information
Feature Description
Prefix Metric support for OSPF Flexible Algorithm
Release 7.5.1
This feature extends the current OSPF Flexible Algorithm functionality to introduce a Flexible Algorithm-specific prefix-metric
in the OSPF prefix advertisement. The prefix-metric provides a way to compute the best end-to-end Flexible Algorithm optimized
paths across multiple areas or domains.
A limitation of the existing Flexible Algorithm functionality in IS-IS and OSPF is the inability to compute the best path to a prefix in a remote area or remote IGP domain. Prefixes are advertised between
IS-IS areas, OSPF processes, or between protocol domains, but the existing prefix metric does not reflect any of the constraints used for Flexible Algorithm
path. Although the best Flexible Algorithm path can be computed to the inter-area or redistributed prefix inside the area,
the path may not represent the overall best path through multiple areas or IGP domains.
The Flexible Algorithm Prefix Metric feature introduces a Flexible Algorithm-specific prefix-metric in the IS-IS and OSPF prefix advertisement. The prefix-metric provides a way to compute the best end-to-end Flexible Algorithm optimized paths across
multiple areas or domains.
Flexible Algorithm allows for user-defined algorithms where the IGP computes paths based on a user-defined combination of
metric type (path optimization objective) and constraint.
This feature adds support for TE metric as a metric type for IS-IS Flexible Algorithm. This allows the TE metric, along with
IGP and delay metrics, to be used when running shortest path computations.
The following IS-IS and OSPF configuration sub-mode is used to configure Flexible Algorithm:
By default the IGP metric is used. If delay or TE metric is enabled, the advertised delay or TE metric on the link is used
as a metric for Flexible Algorithm computation.
The following command is used for defining the affinity-map. Affinity-map associates the name with the particular bit positions
in the Extended Admin Group bitmask.
router isisinstanceflex-algoalgoaffinity-mapnamebit-positionbit numberrouter ospfprocessflex-algoalgoaffinity-mapnamebit-positionbit number
name—name of the affinity-map
Configuring Prefix-SID Advertisement
The following command is used to advertise prefix-SID for default and strict-SPF algorithm:
Flexible Algorithm Link Attribute Advertisement Behavior
Table 6. Feature History Table
Feature Name
Release Information
Feature Description
Advertisement of Link Attributes for IS-IS Flexible Algorithm
Release 7.4.1
Link attribute advertisements used during Flexible Algorithm path calculation must use the Application-Specific Link Attribute
(ASLA) advertisements, as defined in IETF draft draft-ietf-lsr-flex-algo.
This feature introduces support for ASLA advertisements during IS-IS Flexible Algorithm path calculation.
The following tables explain the behaviors for advertising (transmitting) and processing (receiving) Flexible Algorithm link
attributes.
Table 7. OSPF
Link Attribute
Transmit
Receive
Link Delay Metric
IOS XR OSPF Flex Algo implementation advertises the link delay metric value using the OSPF ASLA sub-TLV with the F-bit set.
IOS XR OSPF only uses the link delay metric advertised in the ASLA sub-TLV for Flex Algo.
ASLA sub-TLV is supported with non-zero-length or with zero-length Application Identifier Bit Masks.
Link TE Metric
IOS XR OSPF Flex Algo implementation advertises the link TE metric value using the OSPF ASLA sub-TLV with the F-bit set.
The link TE metric values advertised are configured under SR-TE.
IOS XR OSPF only uses the TE metric advertised in the ASLA sub-TLV for Flex Algo.
ASLA sub-TLV is supported with non-zero-length or with zero-length Application Identifier Bit Masks.
Link Admin Group/Extended Admin Group
IOS XR OSPF Flex Algo implementation advertises the link admin group value using both link admin group (AG) and link extended
admin group (EAG) encoding using the OSPF ASLA sub-TLV with the F-bit set.
The link admin group values advertised can be configured directly under the IGP and are therefore FA-specific. Otherwise,
they will be derived from the link admin group values configured under SR-TE.
IOS XR OSPF only uses the AG/EAG (either one or both) advertised in the ASLA sub-TLV for Flex Algo.
ASLA sub-TLV is supported with non-zero-length or with zero-length Application Identifier Bit Masks.
Table 8. IS-IS
Link Attribute
Transmit
Receive
Link Delay Metric
IOS XR IS-IS Flex Algo implementation advertises the link delay metric value using both the IS-IS Extended Reachability TLV and the IS-IS ASLA.
By default, IOS XR IS-IS Flex Algo implementation prefers the link delay metric value received in the IS-IS ASLA. Otherwise,
it will use link delay metric value received in the IS-IS Extended Reachability TLV.
ASLA sub-TLV is supported with non-zero-length or with zero-length Application Identifier Bit Masks.
If the incoming ASLA includes the L-Flag, implementation derives the link delay metric value from the IS-IS Extended Reachability
TLV.
You can configure the IOS XR IS-IS Flex Algo implementation to strictly use the link delay metric value received in the IS-IS
ASLA. See Strict IS-IS ASLA Link Attribute.
Link TE Metric
IOS XR IS-IS Flex Algo implementation advertises the link TE metric value using the IS-IS ASLA.
The link TE metric values advertised can be configured directly under the IGP and are therefore FA-specific. Otherwise, they
will be derived from the link TE metric values configured under SR-TE.
IOS XR IS-IS Flex Algo implementation processes the link TE metric value received in the IS-IS ASLA.
ASLA sub-TLV is supported with non-zero-length or with zero-length Application Identifier Bit Masks.
If incoming ASLA includes the L-Flag, implementation derives the link TE metric value from the IS-IS Extended Reachability
TLV.
Link Admin Group/Extended Admin Group
IOS XR IS-IS Flex Algo implementation advertises the affinity value as both the link admin group (AG) TLV and the link extended
admin group (EAG) TLV using the IS-IS ASLA when its value falls within the first 32 bits. Otherwise, the affinity value is
advertised only as link EAG TLV using the IS-IS ASLA.
The admin group values advertised are configured directly under the IGP and are therefore FA-specific.
IOS XR IS-IS Flex Algo implementation processes the affinity value received as either the link admin group TLV or link extended
admin group TLV in the IS-IS ASLA.
ASLA sub-TLV is supported with non-zero-length or with zero-length Application Identifier Bit Masks.
If incoming ASLA includes the L-Flag, implementation derives the affinity value from the IS-IS Extended Reachability TLV.
Link SRLG
IOS XR IS-IS LFA implementation advertises the link SRLG value in the IS-IS ASLA.
IOS XR IS-IS LFA implementation processes the link SRLG value received in the IS-IS ASLA.
If incoming ASLA includes the L-Flag, implementation derives the link SRLG value from the IS-IS Extended Reachability TLV.
Strict IS-IS ASLA Link Attribute
Use the following command to configure the IOS XR IS-IS Flex Algo implementation to strictly use the link delay metric value
received in the IS-IS ASLA:
You can now configure the flexible algorithm to exclude any link belonging to the Shared Risk Link Groups (SRLGs) from the
path computation for OSPF. The ability to exclude the at-risk links ensures that the rest of the links in the network remain
unaffected.
IS-IS Flexible Algorithm: Exclude-SRLG Constraint
Release 7.5.1
This feature allows the Flexible Algorithm definition to specify Shared Risk Link Groups (SRLGs) that the operator wants to
exclude during the Flex-Algorithm path computation. The ability to exclude the at-risk links ensures that the rest of the
links in the network remain unaffected.
This allows the setup of disjoint paths between two or more Flex Algos by leveraging deployed SRLG configurations.
This feature allows the Flexible Algorithm definition to specify Shared Risk Link Groups (SRLGs) that the operator wants to
exclude during the Flex-Algorithm path computation. A set of links that share a resource whose failure can affect all links
in the set constitute a SRLG. An SRLG provides an indication of which links in the network might be at risk from the same
failure.
This allows the setup of disjoint paths between two or more Flex Algos by leveraging deployed SRLG configurations. For example,
multiple Flex Algos could be defined by excluding all SRLGs except one. Each FA will prune the links belonging to the excluded
SRLGs from its topology on which it computes its paths.
This provides a new alternative to creating disjoint paths with FA, in addition to leveraging FA with link admin group (affinity)
constraints.
The Flexible Algorithm definition (FAD) can advertise SRLGs that you want to exclude during the Flexible Algorithm path computation.
The IS-IS Flexible Algorithm Exclude SRLG Sub-TLV (FAESRLG) is used to advertise the exclude rule that is used during the
Flexible Algorithm path calculation, as specified in IETF draft https://datatracker.ietf.org/doc/draft-ietf-lsr-flex-algo/
The Flexible Algorithm path computation checks if an “exclude SRLG” rule is part of the FAD. If an “exclude SRLG” rule exists,
it then checks if the link is part of an SRLG that is also part of the “exclude SRLG” rule. If the link is part of an excluded
SRLG, the link is pruned from the path computation.
The figure below shows a topology configured with the following flex algos:
Flex algo 128: metric IGP and exclude SRLG X constraint
Flex algo 129: metric IGP and exclude SRLG Y constraint
The horizontal links between nodes 3 and 4 and between 2 and 5 are part of SRLG group X. The diagonal links between nodes
3 and 5 and between 2 and 4 are part of SRLG group Y. As a result, traffic from node 1 to node 6's FA 128 prefix SID (16806)
avoids interfaces part of SRLG X. While traffic from node 1 to node 6's FA 129 prefix SID (16906) avoids interfaces part of
SRLG Y.
Note
See Constraints section in the Configure SR-TE Policies chapter for information about configuring SR policies with Flex-Algo constraints.
Figure 1. Flex Algo with Exclude SRLG Constraint
Configuration
Use the router isisinstanceaddress-family ipv4 unicast advertise application flex-algo link-attributes srlg command to enable the Flexible Algorithm ASLA-specific advertisement of SRLGs.
Use the router isisinstanceflex-algoalgosrlg exclude-anysrlg-name . . . srlg-name command to configure the SRLG constraint which is advertised in the Flexible Algorithm definition (FAD) if the FAD advertisement
is enabled under the flex-algo sub-mode. You can specify up to 32 SRLG names.
The following example shows how to enable the Flexible Algorithm ASLA-specific advertisement of SRLGs and to exclude SRLG
groups from Flexible Algorithm path computation:
The following example shows how to enable the Flexible Algorithm ASLA-specific advertisement of SRLGs and to exclude SRLG
groups from Flexible Algorithm path computation for OSPF:
RP/0/RP0/CPU0:router(config)# srlg
RP/0/RP0/CPU0:router(config-srlg)# interface HunGigE0/0/0/0
RP/0/RP0/CPU0:router(config-srlg-if)# name groupX
RP/0/RP0/CPU0:router(config-srlg-if)# exit
RP/0/RP0/CPU0:router(config-srlg)# interface TenGigE0/0/0/1
RP/0/RP0/CPU0:router(config-srlg-if)# name groupX
RP/0/RP0/CPU0:router(config-srlg-if)# exit
RP/0/RP0/CPU0:router(config-srlg)# interface HunGigE0/0/1/0
RP/0/RP0/CPU0:router(config-srlg-if)# name groupY
RP/0/RP0/CPU0:router(config-srlg-if)# exit
RP/0/RP0/CPU0:router(config-srlg)# interface TenGigE0/0/1/1
RP/0/RP0/CPU0:router(config-srlg-if)# name groupY
RP/0/RP0/CPU0:router(config-srlg-if)# exit
RP/0/RP0/CPU0:router(config-srlg)# name groupX value 100
RP/0/RP0/CPU0:router(config-srlg)# name groupY value 200
RP/0/RP0/CPU0:router(config-srlg)# exit
RP/0/0/CPU0:r1(config)#router ospf 1
RP/0/0/CPU0:r1(config-ospf)#flex-algo 128
RP/0/0/CPU0:r1(config-ospf-flex-algo)#srlg exclude-any
RP/0/0/CPU0:r(config-ospf-flex-algo-srlg-exclude-any)#groupX
RP/0/0/CPU0:r(config-ospf-flex-algo-srlg-exclude-any)#groupY
RP/0/0/CPU0:r(config-ospf-flex-algo-srlg-exclude-any)#commit
Verification
The following example shows how to verify the number of SRLGs excluded for OSPF:
RP/0/RP0/CPU0:router# show ospf topology summary
Process ospf-1
Instance default
Router ID : 192.168.0.1
Number of Areas : 1
Number of Algos : 1
Max Path count : 16
Route count : 10
SR Global Block : 16000 - 23999
Area 0
Number of Nodes : 6
Algo 128
FAD Advertising Router : 192.168.0.1
FAD Area ID : 0
Algo Type : 0
Metric Type : 0
Number of Exlclude SRLGs : (2)
[1]: 100 [2]: 200
FAPM supported : No
Example: Configuring IS-IS Flexible Algorithm
router isis 1
affinity-map red bit-position 65
affinity-map blue bit-position 8
affinity-map green bit-position 201
flex-algo 128
advertise-definition
affinity exclude-any red
affinity include-any blue
!
flex-algo 129
affinity exclude-any green
!
!
address-family ipv4 unicast
segment-routing mpls
!
interface Loopback0
address-family ipv4 unicast
prefix-sid algorithm 128 index 100
prefix-sid algorithm 129 index 101
!
!
interface GigabitEthernet0/0/0/0
affinity flex-algo red
!
interface GigabitEthernet0/0/0/1
affinity flex-algo blue red
!
interface GigabitEthernet0/0/0/2
affinity flex-algo blue
!
Example: Configuring OSPF Flexible Algorithm
router ospf 1
flex-algo 130
priority 200
affinity exclude-any
red
blue
!
metric-type delay
!
flex-algo 140
affinity include-all
green
!
affinity include-any
red
!
!
interface Loopback0
prefix-sid index 10
prefix-sid strict-spf index 40
prefix-sid algorithm 128 absolute 16128
prefix-sid algorithm 129 index 129
prefix-sid algorithm 200 index 20
prefix-sid algorithm 210 index 30
!
!
interface GigabitEthernet0/0/0/0
flex-algo affinity
color red
color blue
!
!
affinity-map
color red bit-position 10
color blue bit-position 11
!
Example: Traffic Steering to Flexible Algorithm Paths
BGP Routes on PE – Color Based Steering
SR-TE On Demand Next-Hop (ODN) feature can be used to steer the BGP traffic towards the Flexible Algorithm paths.
The following example configuration shows how to setup BGP steering local policy, assuming two router: R1 (2.2.2.2) and R2
(4.4.4.4), in the topology.
Feedback