Segment Routing Configuration Guide for Cisco NCS 540 Series Routers, IOS XR Release 7.3.x
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This module provides information about segment routing for traffic engineering (SR-TE) policies, how to configure SR-TE policies,
and how to steer traffic into an SR-TE policy.
SR-TE Policy Overview
Segment routing for traffic engineering (SR-TE) uses a “policy” to steer traffic through the network. An SR-TE policy path
is expressed as a list of segments that specifies the path, called a segment ID (SID) list. Each segment is an end-to-end
path from the source to the destination, and instructs the routers in the network to follow the specified path instead of
following the shortest path calculated by the IGP. If a packet is steered into an SR-TE policy, the SID list is pushed on
the packet by the head-end. The rest of the network executes the instructions embedded in the SID list.
An SR-TE policy is identified as an ordered list (head-end, color, end-point):
Head-end – Where the SR-TE policy is instantiated
Color – A numerical value that distinguishes between two or more policies to the same node pairs (Head-end – End point)
End-point – The destination of the SR-TE policy
Every SR-TE policy has a color value. Every policy between the same node pairs requires a unique color value.
An SR-TE policy uses one or more candidate paths. A candidate path is a single segment list (SID-list) or a set of weighted
SID-lists (for weighted equal cost multi-path [WECMP]). A candidate path is either dynamic or explicit. See SR-TE Policy Path Types section for more information.
Usage Guidelines and Limitations
Observe the following guidelines and limitations for the platform.
The ECMP path-set of an IGP route with a mix of SR-TE Policy paths (Autoroute Include) and unprotected native paths is supported.
The ECMP path-set of an IGP route with a mix of SR-TE Policy paths (Autoroute Include) and protected (LFA/TI-LFA) native paths
is not supported.
Before configuring SR-TE policies, use the distribute link-state command under IS-IS or OSPF to distribute the link-state database to external services.
L3VPN BGP PIC over SR-TE is supported.
BGP PIC over SR-TE is supported when both primary and backup paths each resolve into the BSID of an SR policy. BGP PIC over
SR-TE is not supported when primary and backup paths are of different resolution types. For example, when a primary path resolves
into the BSID of an SR policy, the backup path cannot point to a native LSP. When this happens, the backup path will not be
programmed. For information about BGP PIC, refer to the BGP PIC chapter in the BGP Configuration Guide for Cisco NCS 540 Series Routers.
SR-TE over BVI is not supported. An SR-TE policy cannot be resolved over an MPLS-enabled BVI interface.
Counter implications when BVI and SR-TE co-exist in same NPU—Counters for a BVI's logical interface are not allocated when
the same NPU hosts layer-2 (sub)interface(s) associated with the BVI alongside other port(s) used as egress interface(s) for
an SR policy
GRE tunnel as primary interface for an SR policy is not supported.
GRE tunnel as backup interface for an SR policy with TI-LFA protection is not supported.
Head-end computed inter-domain SR policy with Flex Algo constraint and IGP redistribution is not supported. This is supported with Flex Algo-aware path computation at SR-PCE, with or without IGP redistribution. See SR-PCE Flexible Algorithm Multi-Domain Path Computation.
Instantiation of an SR Policy
An SR policy is instantiated, or implemented, at the head-end router.
The following sections provide details on the SR policy instantiation methods:
Segment Routing On-Demand Next Hop (SR-ODN) allows a service head-end router to automatically instantiate an SR policy to
a BGP next-hop when required (on-demand). Its key benefits include:
SLA-aware BGP service – Provides per-destination steering behaviors where a prefix, a set of prefixes, or all prefixes from a service can be associated
with a desired underlay SLA. The functionality applies equally to single-domain and multi-domain networks.
Simplicity – No prior SR Policy configuration needs to be configured and maintained. Instead, operator simply configures a small set
of common intent-based optimization templates throughout the network.
Scalability – Device resources at the head-end router are used only when required, based on service or SLA connectivity needs.
The following example shows how SR-ODN works:
An egress PE (node H) advertises a BGP route for prefix T/t. This advertisement includes an SLA intent encoded with a BGP
color extended community. In this example, the operator assigns color purple (example value = 100) to prefixes that should
traverse the network over the delay-optimized path.
The route reflector receives the advertised route and advertises it to other PE nodes.
Ingress PEs in the network (such as node F) are pre-configured with an ODN template for color purple that provides the node
with the steps to follow in case a route with the intended color appears, for example:
Contact SR-PCE and request computation for a path toward node H that does not share any nodes with another LSP in the same
disjointness group.
At the head-end router, compute a path towards node H that minimizes cumulative delay.
In this example, the head-end router contacts the SR-PCE and requests computation for a path toward node H that minimizes
cumulative delay.
After SR-PCE provides the compute path, an intent-driven SR policy is instantiated at the head-end router. Other prefixes
with the same intent (color) and destined to the same egress PE can share the same on-demand SR policy. When the last prefix
associated with a given [intent, egress PE] pair is withdrawn, the on-demand SR policy is deleted, and resources are freed
from the head-end router.
An on-demand SR policy is created dynamically for BGP global or VPN (service) routes. The following services are supported
with SR-ODN:
IPv4 BGP global routes
IPv6 BGP global routes (6PE)
VPNv4
VPNv6 (6vPE)
EVPN-VPWS (single-homing)
EVPN-VPWS (multi-homing)
EVPN (single-homing/multi-homing)
Note
For EVPN single-homing, you must configure an EVPN Ethernet Segment Identifier (ESI) with a non-zero value.
Note
Colored per-ESI/per-EVI EVPN Ethernet Auto-Discovery route (route-type 1) and Inclusive Multicast Route (route-type 3) are
used to trigger instantiation of ODN SR-TE policies.
Note
The following scenarios involving virtual Ethernet Segments (vES) are also supported with EVPN ODN:
VPLS VFI as vES for single-active Multi-Homing to EVPN
Active/backup Pseudo-wire (PW) as vES for Single-Homing to EVPN
Static Pseudo-wire (PW) as vES for active-active Multi-Homing to EVPN
SR-ODN Configuration Steps
To configure SR-ODN, complete the following configurations:
Define the SR-ODN template on the SR-TE head-end router.
(Optional) If using Segment Routing Path Computation Element (SR-PCE) for path computation:
Configure SR-PCE. For detailed SR-PCE configuration information, see Configure SR-PCE.
Configure the head-end router as Path Computation Element Protocol (PCEP) Path Computation Client (PCC). For detailed PCEP
PCC configuration information, see Configure the Head-End Router as PCEP PCC.
Define BGP color extended communities. Refer to the "Implementing BGP" chapter in the BGP Configuration Guide for Cisco NCS 540 Series Routers.
Define routing policies (using routing policy language [RPL]) to set BGP color extended communities. Refer to the "Implementing
Routing Policy" chapter in the Routing Configuration Guide for Cisco NCS 540 Series Routers.
The following RPL attach-points for setting/matching BGP color extended communities are supported:
Note
The following table shows the supported RPL match operations; however, routing policies are required primarily to set BGP
color extended community. Matching based on BGP color extended communities is performed automatically by ODN's on-demand color
template.
Attach Point
Set
Match
VRF export
X
X
VRF import
–
X
Neighbor-in
X
X
Neighbor-out
X
X
Inter-AFI export
–
X
Inter-AFI import
–
X
Default-originate
X
–
Apply routing policies to a service. Refer to the "Implementing Routing Policy" chapter in the Routing Configuration Guide for Cisco NCS 540 Series Routers.
Configure On-Demand Color Template
Use the on-demand colorcolor command to create an ODN template for the specified color value. The head-end router automatically follows the actions defined
in the template upon arrival of BGP global or VPN routes with a BGP color extended community that matches the color value
specified in the template.
The color range is from 1 to 4294967295.
Router(config)# segment-routing traffic-eng
Router(config-sr-te)# on-demand color 10
Note
Matching based on BGP color extended communities is performed automatically via ODN's on-demand color template. RPL routing
policies are not required.
Use the on-demand colorcolordynamic command to associate the template with on-demand SR policies with a locally computed dynamic path (by SR-TE head-end router
utilizing its TE topology database) or centrally (by SR-PCE). The head-end router will first attempt to install the locally
computed path; otherwise, it will use the path computed by the SR-PCE.
Router(config)# segment-routing traffic-eng
Router(config-sr-te)# on-demand color 10dynamic
Use the on-demand colorcolordynamic pcep command to indicate that only the path computed by SR-PCE should be associated with the on-demand SR policy. With this configuration,
local path computation is not attempted; instead the head-end router will only instantiate the path computed by the SR-PCE.
Router(config-sr-te)# on-demand color 10dynamic pcep
Configure Dynamic Path Optimization Objectives
Use the metric type {igp | te | latency} command to configure the metric for use in path computation.
Router(config-sr-te-color-dyn)# metric type te
Use the metric margin {absolutevalue| relativepercent} command to configure the On-Demand dynamic path metric margin. The range for value and percent is from 0 to 2147483647.
Use the disjoint-path group-idgroup-idtype {link | node | srlg | srlg-node} [sub-idsub-id] command to configure the disjoint-path constraints. The group-id and sub-id range is from 1 to 65535.
Router(config-sr-te-color-dyn)# disjoint-path group-id 775 type link
Use the affinity {include-any | include-all | exclude-any} {nameWORD} command to configure the affinity constraints.
Router(config-sr-te-color-dyn)# affinity exclude-any name CROSS
Use the maximum-sid-depthvalue command to customize the maximum SID depth (MSD) constraints advertised by the router.
The default MSD value is equal to the maximum MSD supported by the platform (12).
Use the sid-algorithmalgorithm-number command to configure the SR Flexible Algorithm constraints. The algorithm-number range is from 128 to 255.
Router(config-sr-te-color-dyn)# sid-algorithm 128
Configuring SR-ODN: Examples
Configuring SR-ODN: Layer-3 Services Examples
The following examples show end-to-end configurations used in implementing SR-ODN on the head-end router.
Configuring ODN Color Templates: Example
Configure ODN color templates on routers acting as SR-TE head-end nodes. The following example shows various ODN color templates:
color 10: minimization objective = te-metric
color 20: minimization objective = igp-metric
color 21: minimization objective = igp-metric; constraints = affinity
color 22: minimization objective = te-metric; path computation at SR-PCE; constraints = affinity
color 30: minimization objective = delay-metric
color 128: constraints = flex-algo
segment-routing
traffic-eng
on-demand color 10
dynamic
metric
type te
!
!
!
on-demand color 20
dynamic
metric
type igp
!
!
!
on-demand color 21
dynamic
metric
type igp
!
affinity exclude-any
name CROSS
!
!
!
on-demand color 22
dynamic
pcep
!
metric
type te
!
affinity exclude-any
name CROSS
!
!
!
on-demand color 30
dynamic
metric
type latency
!
!
!
on-demand color 128
dynamic
sid-algorithm 128
!
!
!
end
Configuring BGP Color Extended Community Set: Example
The following example shows how to configure BGP color extended communities that are later applied to BGP service routes via
route-policies.
Note
In most common scenarios, egress PE routers that advertise BGP service routes apply (set) BGP color extended communities.
However, color can also be set at the ingress PE router.
Configuring RPL to Set BGP Color (Layer-3 Services): Examples
The following example shows various representative RPL definitions that set BGP color community.
The first 4 RPL examples include the set color action only. The last RPL example performs the set color action for selected destinations based on a prefix-set.
route-policy SET_COLOR_LOW_LATENCY_TE
set extcommunity color color10-te
pass
end-policy
!
route-policy SET_COLOR_HI_BW
set extcommunity color color20-igp
pass
end-policy
!
route-policy SET_COLOR_LOW_LATENCY
set extcommunity color color30-delay
pass
end-policy
!
route-policy SET_COLOR_FA_128
set extcommunity color color128-fa128
pass
end-policy
!
prefix-set sample-set
88.1.0.0/24
end-set
!
route-policy SET_COLOR_GLOBAL
if destination in sample-set then
set extcommunity color color10-te
else
pass
endif
end-policy
Applying RPL to BGP Services (Layer-3 Services): Example
The following example shows various RPLs that set BGP color community being applied to BGP Layer-3 VPN services (VPNv4/VPNv6)
and BGP global.
The L3VPN examples show the RPL applied at the VRF export attach-point.
The BGP global example shows the RPL applied at the BGP neighbor-out attach-point.
Use the show bgp vrf command to display BGP prefix information for VRF instances. The following output shows the BGP VRF table including a prefix
(88.1.1.0/24) with color 10 advertised by router 10.1.1.8.
RP/0/RP0/CPU0:R4# show bgp vrf vrf_cust1
BGP VRF vrf_cust1, state: Active
BGP Route Distinguisher: 10.1.1.4:101
VRF ID: 0x60000007
BGP router identifier 10.1.1.4, local AS number 100
Non-stop routing is enabled
BGP table state: Active
Table ID: 0xe0000007 RD version: 282
BGP main routing table version 287
BGP NSR Initial initsync version 31 (Reached)
BGP NSR/ISSU Sync-Group versions 0/0
Status codes: s suppressed, d damped, h history, * valid, > best
i - internal, r RIB-failure, S stale, N Nexthop-discard
Origin codes: i - IGP, e - EGP, ? - incomplete
Network Next Hop Metric LocPrf Weight Path
Route Distinguisher: 10.1.1.4:101 (default for vrf vrf_cust1)
*> 44.1.1.0/24 40.4.101.11 0 400 {1} i
*>i55.1.1.0/24 10.1.1.5 100 0 500 {1} i
*>i88.1.1.0/24 10.1.1.8 C:10 100 0 800 {1} i
*>i99.1.1.0/24 10.1.1.9 100 0 800 {1} i
Processed 4 prefixes, 4 paths
The following output displays the details for prefix 88.1.1.0/24. Note the presence of BGP extended color community 10, and
that the prefix is associated with an SR policy with color 10 and BSID value of 24036.
RP/0/RP0/CPU0:R4# show bgp vrf vrf_cust1 88.1.1.0/24
BGP routing table entry for 88.1.1.0/24, Route Distinguisher: 10.1.1.4:101
Versions:
Process bRIB/RIB SendTblVer
Speaker 282 282
Last Modified: May 20 09:23:34.112 for 00:06:03
Paths: (1 available, best #1)
Advertised to CE peers (in unique update groups):
40.4.101.11
Path #1: Received by speaker 0
Advertised to CE peers (in unique update groups):
40.4.101.11
800 {1}
10.1.1.8 C:10 (bsid:24036) (metric 20) from 10.1.1.55 (10.1.1.8)
Received Label 24012
Origin IGP, localpref 100, valid, internal, best, group-best, import-candidate, imported
Received Path ID 0, Local Path ID 1, version 273
Extended community: Color:10 RT:100:1
Originator: 10.1.1.8, Cluster list: 10.1.1.55
SR policy color 10, up, registered, bsid 24036, if-handle 0x08000024
Source AFI: VPNv4 Unicast, Source VRF: default, Source Route Distinguisher: 10.1.1.8:101
Verifying Forwarding (CEF) Table
Use the show cef vrf command to display the contents of the CEF table for the VRF instance. Note that prefix 88.1.1.0/24 points to the BSID label
corresponding to an SR policy. Other non-colored prefixes, such as 55.1.1.0/24, point to BGP next-hop.
The following output displays CEF details for prefix 88.1.1.0/24. Note that the prefix is associated with an SR policy with
BSID value of 24036.
RP/0/RP0/CPU0:R4# show cef vrf vrf_cust1 88.1.1.0/24
88.1.1.0/24, version 51, internal 0x5000001 0x0 (ptr 0x98c60ddc) [1], 0x0 (0x0), 0x208 (0x98425268)
Updated May 20 09:23:34.216
Prefix Len 24, traffic index 0, precedence n/a, priority 3
via local-label 24036, 5 dependencies, recursive [flags 0x6000]
path-idx 0 NHID 0x0 [0x97091ec0 0x0]
recursion-via-label
next hop VRF - 'default', table - 0xe0000000
next hop via 24036/0/21
next hop srte_c_10_ep labels imposed {ImplNull 24012}
Verifying SR Policy
Use the show segment-routing traffic-eng policy command to display SR policy information.
The following outputs show the details of an on-demand SR policy that was triggered by prefixes with color 10 advertised by
node 10.1.1.8.
RP/0/RP0/CPU0:R4# show segment-routing traffic-eng policy color 10 tabular
Color Endpoint Admin Oper Binding
State State SID
------ -------------------- ------ ------ --------------------
1010.1.1.8upup24036
The following outputs show the details of the on-demand SR policy for BSID 24036.
Note
There are 2 candidate paths associated with this SR policy: the path that is computed by the head-end router (with preference
200), and the path that is computed by the SR-PCE (with preference 100). The candidate path with the highest preference is
the active candidate path (highlighted below) and is installed in forwarding.
Configuring RPL to Set BGP Color (EVPN Services): Examples
The following examples shows various representative RPL definitions that set BGP color community.
The following RPL examples match on EVPN route-types and then set the BGP color extended community.
route-policy sample-export-rpl
if evpn-route-type is 1 then
set extcommunity color color-44
endif
if evpn-route-type is 3 then
set extcommunity color color-55
endif
end-policy
route-policy sample-import-rpl
if evpn-route-type is 1 then
set extcommunity color color-77
elseif evpn-route-type is 3 then
set extcommunity color color-88
else
pass
endif
end-policy
The following RPL example sets BGP color extended community while matching on the following:
Route Distinguisher (RD)
Ethernet Segment Identifier (ESI)
Ethernet Tag (ETAG)
EVPN route-types
route-policy sample-bgpneighbor-rpl
if rd in (10.1.1.1:3504) then
set extcommunity color color3504
elseif rd in (10.1.1.1:3505) then
set extcommunity color color3505
elseif rd in (10.1.1.1:3506) then
set extcommunity color color99996
elseif esi in (0010.0000.0000.0000.1201) and rd in (10.1.1.1:3508) then
set extcommunity color color3508
elseif etag in (30509) and rd in (10.1.1.1:3509) then
set extcommunity color color3509
elseif etag in (0) and rd in (10.1.1.1:2001) and evpn-route-type is 1 then
set extcommunity color color82001
elseif etag in (0) and rd in (10.1.1.1:2001) and evpn-route-type is 3 then
set extcommunity color color92001
endif
pass
end-policy
Applying RPL to BGP Services (EVPN Services): Example
The following examples show various RPLs that set BGP color community being applied to EVPN services.
The following 2 examples show the RPL applied at the EVI export and import attach-points.
Note
RPLs applied under EVI import or export attach-point also support matching on the following:
This use case shows how to set up a pair of ELINE services using EVPN-VPWS between two sites. Services are carried over SR
policies that must not share any common links along their paths (link-disjoint). The SR policies are triggered on-demand based
on ODN principles. An SR-PCE computes the disjoint paths.
This use case uses the following topology with 2 sites: Site 1 with nodes A and B, and Site 2 with nodes C and D.
Table 1. Use Case Parameters
IP Addresses of Loopback0 (Lo0) Interfaces
SR-PCE Lo0: 10.1.1.207
Site 1:
Node A Lo0: 10.1.1.5
Node B Lo0: 10.1.1.6
Site 2:
Node C Lo0: 10.1.1.2
Node D Lo0: 10.1.1.4
EVPN-VPWS Service Parameters
ELINE-1:
EVPN-VPWS EVI 100
Node A: AC-ID = 11
Node C: AC-ID = 21
ELINE-2:
EVPN-VPWS EVI 101
Node B: AC-ID = 12
Node D: AC-ID = 22
ODN BGP Color Extended Communities
Site 1 routers (Nodes A and B):
set color 10000
match color 11000
Site 2 routers (Nodes C and D):
set color 11000
match color 10000
Note
These colors are associated with the EVPN route-type 1 routes of the EVPN-VPWS services.
PCEP LSP Disjoint-Path Association Group ID
Site 1 to Site 2 LSPs (from Node A to Node C/from Node B to Node D):
group-id = 775
Site 2 to Site 1 LSPs (from Node C to Node A/from Node D to Node B):
group-id = 776
The use case provides configuration and verification outputs for all devices.
For cases when PCC nodes support, or signal, PCEP association-group object to indicate the pair of LSPs in a disjoint set,
there is no extra configuration required at the SR-PCE to trigger disjoint-path computation.
Note
SR-PCE also supports disjoint-path computation for cases when PCC nodes do not support PCEP association-group object. See
Configure the Disjoint Policy (Optional) for more information.
Configuration: Site 1 Node A
This section depicts relevant configuration of Node A at Site 1. It includes service configuration, BGP color extended community,
and RPL. It also includes the corresponding ODN template required to achieve the disjointness SLA.
Nodes in Site 1 are configured to set color 10000 on originating EVPN routes, while matching color 11000 on incoming EVPN
routes from routers located at Site 2.
Since both nodes in Site 1 request path computation from SR-PCE using the same disjoint-path group-id (775), the PCE will
attempt to compute disjointness for the pair of LSPs originating from Site 1 toward Site 2.
/* EVPN-VPWS configuration */
interface GigabitEthernet0/0/0/3.2500 l2transport
encapsulation dot1q 2500
rewrite ingress tag pop 1 symmetric
!
l2vpn
xconnect group evpn_vpws_group
p2p evpn_vpws_100
interface GigabitEthernet0/0/0/3.2500
neighbor evpn evi 100 target 21 source 11
!
!
!
!
/* BGP color community and RPL configuration */
extcommunity-set opaque color-1000010000
end-set
!
route-policy SET_COLOR_EVPN_VPWS
if evpn-route-type is 1 and rd in (ios-regex '.*..*..*..*:(100)') then
set extcommunity color color-10000
endif
pass
end-policy
!
router bgp 65000
neighbor 10.1.1.253
address-family l2vpn evpn
route-policy SET_COLOR_EVPN_VPWS out
!
!
!
/* ODN template configuration */
segment-routing
traffic-eng
on-demand color 11000
dynamic
pcep
!
metric
type igp
!
disjoint-path group-id 775 type link
!
!
!
!
Configuration: Site 1 Node B
This section depicts relevant configuration of Node B at Site 1.
/* EVPN-VPWS configuration */
interface TenGigE0/3/0/0/8.2500 l2transport
encapsulation dot1q 2500
rewrite ingress tag pop 1 symmetric
!
l2vpn
xconnect group evpn_vpws_group
p2p evpn_vpws_101
interface TenGigE0/3/0/0/8.2500
neighbor evpn evi 101 target 22 source 12
!
!
!
!
/* BGP color community and RPL configuration */
extcommunity-set opaque color-1000010000
end-set
!
route-policy SET_COLOR_EVPN_VPWS
if evpn-route-type is 1 and rd in (ios-regex '.*..*..*..*:(101)') then
set extcommunity color color-10000
endif
pass
end-policy
!
router bgp 65000
neighbor 10.1.1.253
address-family l2vpn evpn
route-policy SET_COLOR_EVPN_VPWS out
!
!
!
/* ODN template configuration */
segment-routing
traffic-eng
on-demand color 11000
dynamic
pcep
!
metric
type igp
!
disjoint-path group-id 775 type link
!
!
!
!
Configuration: Site 2 Node C
This section depicts relevant configuration of Node C at Site 2. It includes service configuration, BGP color extended community,
and RPL. It also includes the corresponding ODN template required to achieve the disjointness SLA.
Nodes in Site 2 are configured to set color 11000 on originating EVPN routes, while matching color 10000 on incoming EVPN
routes from routers located at Site 1.
Since both nodes on Site 2 request path computation from SR-PCE using the same disjoint-path group-id (776), the PCE will
attempt to compute disjointness for the pair of LSPs originating from Site 2 toward Site 1.
/* EVPN-VPWS configuration */
interface GigabitEthernet0/0/0/3.2500 l2transport
encapsulation dot1q 2500
rewrite ingress tag pop 1 symmetric
!
l2vpn
xconnect group evpn_vpws_group
p2p evpn_vpws_100
interface GigabitEthernet0/0/0/3.2500
neighbor evpn evi 100 target 11 source 21
!
!
!
!
/* BGP color community and RPL configuration */
extcommunity-set opaque color-1100011000
end-set
!
route-policy SET_COLOR_EVPN_VPWS
if evpn-route-type is 1 and rd in (ios-regex '.*..*..*..*:(100)') then
set extcommunity color color-11000
endif
pass
end-policy
!
router bgp 65000
neighbor 10.1.1.253
address-family l2vpn evpn
route-policy SET_COLOR_EVPN_VPWS out
!
!
!
/* ODN template configuration */
segment-routing
traffic-eng
on-demand color 10000
dynamic
pcep
!
metric
type igp
!
disjoint-path group-id 776 type link
!
!
!
!
Configuration: Site 2 Node D
This section depicts relevant configuration of Node D at Site 2.
/* EVPN-VPWS configuration */
interface GigabitEthernet0/0/0/1.2500 l2transport
encapsulation dot1q 2500
rewrite ingress tag pop 1 symmetric
!
l2vpn
xconnect group evpn_vpws_group
p2p evpn_vpws_101
interface GigabitEthernet0/0/0/1.2500
neighbor evpn evi 101 target 12 source 22
!
!
!
!
/* BGP color community and RPL configuration */
extcommunity-set opaque color-1100011000
end-set
!
route-policy SET_COLOR_EVPN_VPWS
if evpn-route-type is 1 and rd in (ios-regex '.*..*..*..*:(101)') then
set extcommunity color color-11000
endif
pass
end-policy
!
router bgp 65000
neighbor 10.1.1.253
address-family l2vpn evpn
route-policy SET_COLOR_EVPN_VPWS out
!
!
!
/* ODN template configuration */
segment-routing
traffic-eng
on-demand color 10000
dynamic
pcep
!
metric
type igp
!
disjoint-path group-id 776 type link
!
!
!
!
Verification: SR-PCE
Use the show pce ipv4 peer command to display the SR-PCE’s PCEP peers and session status. SR-PCE performs path computation for the 4 nodes depicted
in the use-case.
RP/0/0/CPU0:SR-PCE# show pce ipv4 peer
Mon Jul 15 19:41:43.622 UTC
PCE's peer database:
--------------------
Peer address: 10.1.1.2State: Up
Capabilities: Stateful, Segment-Routing, Update, Instantiation
Peer address: 10.1.1.4State: Up
Capabilities: Stateful, Segment-Routing, Update, Instantiation
Peer address: 10.1.1.5State: Up
Capabilities: Stateful, Segment-Routing, Update, Instantiation
Peer address: 10.1.1.6State: Up
Capabilities: Stateful, Segment-Routing, Update, Instantiation
Use the show pce association group-id command to display information for the pair of LSPs assigned to a given association group-id value.
Based on the goals of this use case, SR-PCE computes link-disjoint paths for the SR policies associated with a pair of ELINE
services between site 1 and site 2. In particular, disjoint LSPs from site 1 to site 2 are identified by association group-id
775. The output includes high-level information for LSPs associated to this group-id:
At Node A (10.1.1.5): LSP symbolic name = bgp_c_11000_ep_10.1.1.2_discr_100
At Node B (10.1.1.6): LSP symbolic name = bgp_c_11000_ep_10.1.1.4_discr_100
In this case, the SR-PCE was able to achieve the desired disjointness level; therefore the Status is shown as "Satisfied".
RP/0/0/CPU0:SR-PCE# show pce association group-id 775
Thu Jul 11 03:52:20.770 UTC
PCE's association database:
----------------------
Association: Type Link-Disjoint, Group 775, Not Strict
Associated LSPs:
LSP[0]:
PCC 10.1.1.6, tunnel name bgp_c_11000_ep_10.1.1.4_discr_100, PLSP ID 18, tunnel ID 17, LSP ID 3, Configured on PCC
LSP[1]:
PCC 10.1.1.5, tunnel name bgp_c_11000_ep_10.1.1.2_discr_100, PLSP ID 18, tunnel ID 18, LSP ID 3, Configured on PCC
Status: Satisfied
Use the show pce lsp command to display detailed information of an LSP present in the PCE's LSP database. This output shows details for the LSP
at Node A (10.1.1.5) that is used to carry traffic of EVPN VPWS EVI 100 towards node C (10.1.1.2).
Based on the goals of this use case, SR-PCE computes link-disjoint paths for the SR policies associated with a pair of ELINE
services between site 1 and site 2. In particular, disjoint LSPs from site 2 to site 1 are identified by association group-id
776. The output includes high-level information for LSPs associated to this group-id:
At Node C (10.1.1.2): LSP symbolic name = bgp_c_10000_ep_10.1.1.5_discr_100
At Node D (10.1.1.4): LSP symbolic name = bgp_c_10000_ep_10.1.1.6_discr_100
In this case, the SR-PCE was able to achieve the desired disjointness level; therefore, the Status is shown as "Satisfied".
RP/0/0/CPU0:SR-PCE# show pce association group-id 776
Thu Jul 11 03:52:24.370 UTC
PCE's association database:
----------------------
Association: Type Link-Disjoint, Group 776, Not Strict
Associated LSPs:
LSP[0]:
PCC 10.1.1.4, tunnel name bgp_c_10000_ep_10.1.1.6_discr_100, PLSP ID 16, tunnel ID 14, LSP ID 1, Configured on PCC
LSP[1]:
PCC 10.1.1.2, tunnel name bgp_c_10000_ep_10.1.1.5_discr_100, PLSP ID 6, tunnel ID 21, LSP ID 3, Configured on PCC
Status: Satisfied
Use the show pce lsp command to display detailed information of an LSP present in the PCE's LSP database. This output shows details for the LSP
at Node C (10.1.1.2) that is used to carry traffic of EVPN VPWS EVI 100 towards node A (10.1.1.5).
This section depicts verification steps at Node A.
Use the show bgp l2vpn evpn command to display BGP prefix information for EVPN-VPWS EVI 100 (rd 10.1.1.5:100). The output includes an EVPN route-type
1 route with color 11000 originated at Node C (10.1.1.2).
RP/0/RSP0/CPU0:Node-A# show bgp l2vpn evpn rd 10.1.1.5:100
Wed Jul 10 18:57:57.704 PST
BGP router identifier 10.1.1.5, local AS number 65000
BGP generic scan interval 60 secs
Non-stop routing is enabled
BGP table state: Active
Table ID: 0x0 RD version: 0
BGP main routing table version 360
BGP NSR Initial initsync version 1 (Reached)
BGP NSR/ISSU Sync-Group versions 0/0
BGP scan interval 60 secs
Status codes: s suppressed, d damped, h history, * valid, > best
i - internal, r RIB-failure, S stale, N Nexthop-discard
Origin codes: i - IGP, e - EGP, ? - incomplete
Network Next Hop Metric LocPrf Weight Path
Route Distinguisher: 10.1.1.5:100 (default for vrf VPWS:100)
*> [1][0000.0000.0000.0000.0000][11]/120
0.0.0.0 0 i
*>i[1][0000.0000.0000.0000.0000][21]/12010.1.1.2 C:11000 100 0 i
The following output displays the details for the incoming EVPN RT1. Note the presence of BGP extended color community 11000,
and that the prefix is associated with an SR policy with color 11000 and BSID value of 80044.
RP/0/RSP0/CPU0:Node-A# show bgp l2vpn evpn rd 10.1.1.5:100 [1][0000.0000.0000.0000.0000][21]/120
Wed Jul 10 18:57:58.107 PST
BGP routing table entry for [1][0000.0000.0000.0000.0000][21]/120, Route Distinguisher: 10.1.1.5:100
Versions:
Process bRIB/RIB SendTblVer
Speaker 360 360
Last Modified: Jul 10 18:36:18.369 for 00:21:40
Paths: (1 available, best #1)
Not advertised to any peer
Path #1: Received by speaker 0
Not advertised to any peer
Local
10.1.1.2 C:11000 (bsid:80044) (metric 40) from 10.1.1.253 (10.1.1.2)
Received Label 80056
Origin IGP, localpref 100, valid, internal, best, group-best, import-candidate, imported, rib-install
Received Path ID 0, Local Path ID 1, version 358
Extended community: Color:11000 RT:65000:100
Originator: 10.1.1.2, Cluster list: 10.1.1.253
SR policy color 11000, up, registered, bsid 80044, if-handle 0x00001b20
Source AFI: L2VPN EVPN, Source VRF: default, Source Route Distinguisher: 10.1.1.2:100
Use the show l2vpn xconnect command to display the state associated with EVPN-VPWS EVI 100 service.
RP/0/RSP0/CPU0:Node-A# show l2vpn xconnect group evpn_vpws_group
Wed Jul 10 18:58:02.333 PST
Legend: ST = State, UP = Up, DN = Down, AD = Admin Down, UR = Unresolved,
SB = Standby, SR = Standby Ready, (PP) = Partially Programmed
XConnect Segment 1 Segment 2
Group Name ST Description ST Description ST
------------------------ ----------------------------- -----------------------------
evpn_vpws_group
evpn_vpws_100UP Gi0/0/0/3.2500 UP EVPN 100,21,10.1.1.2 UP
----------------------------------------------------------------------------------------
The following output shows the details for the service. Note that the service is associated with the on-demand SR policy with
color 11000 and end-point 10.1.1.2 (node C).
RP/0/RSP0/CPU0:Node-A# show l2vpn xconnect group evpn_vpws_group xc-name evpn_vpws_100 detail
Wed Jul 10 18:58:02.755 PST
Group evpn_vpws_group, XC evpn_vpws_100, state is up; Interworking none
AC: GigabitEthernet0/0/0/3.2500, state is up
Type VLAN; Num Ranges: 1
Rewrite Tags: []
VLAN ranges: [2500, 2500]
MTU 1500; XC ID 0x120000c; interworking none
Statistics:
packets: received 0, sent 0
bytes: received 0, sent 0
drops: illegal VLAN 0, illegal length 0
EVPN: neighbor 10.1.1.2, PW ID: evi 100, ac-id 21, state is up ( established )
XC ID 0xa0000007
Encapsulation MPLS
Source address 10.1.1.5
Encap type Ethernet, control word enabled
Sequencing not set
Preferred path Active : SR TE srte_c_11000_ep_10.1.1.2, On-Demand, fallback enabled
Tunnel : Up
Load Balance Hashing: src-dst-mac
EVPN Local Remote
------------ ------------------------------ -----------------------------
Label 80040 80056
MTU 1500 1500
Control word enabled enabled
AC ID 11 21
EVPN type Ethernet Ethernet
------------ ------------------------------ -----------------------------
Create time: 10/07/2019 18:31:30 (1d17h ago)
Last time status changed: 10/07/2019 19:42:00 (1d16h ago)
Last time PW went down: 10/07/2019 19:40:55 (1d16h ago)
Statistics:
packets: received 0, sent 0
bytes: received 0, sent 0
Use the show segment-routing traffic-eng policy command with tabular option to display SR policy summary information.
The following output shows the on-demand SR policy with BSID 80044 that was triggered by EVPN RT1 prefix with color 11000
advertised by node C (10.1.1.2).
RP/0/RSP0/CPU0:Node-A# show segment-routing traffic-eng policy color 11000 tabular
Wed Jul 10 18:58:00.732 PST
Color Endpoint Admin Oper Binding
State State SID
------ -------------------- ------ ------ --------------------
1100010.1.1.2upup80044
The following output shows the details for the on-demand SR policy. Note that the SR policy's active candidate path (preference
100) is computed by SR-PCE (10.1.1.207).
Based on the goals of this use case, SR-PCE computes link-disjoint paths for the SR policies associated with a pair of ELINE
services between site 1 and site 2. Specifically, from site 1 to site 2, LSP at Node A (srte_c_11000_ep_10.1.1.2) is link-disjoint
from LSP at Node B (srte_c_11000_ep_10.1.1.4).
This section depicts verification steps at Node B.
Use the show bgp l2vpn evpn command to display BGP prefix information for EVPN-VPWS EVI 101 (rd 10.1.1.6:101). The output includes an EVPN route-type
1 route with color 11000 originated at Node D (10.1.1.4).
RP/0/RSP0/CPU0:Node-B# show bgp l2vpn evpn rd 10.1.1.6:101
Wed Jul 10 19:08:54.964 PST
BGP router identifier 10.1.1.6, local AS number 65000
BGP generic scan interval 60 secs
Non-stop routing is enabled
BGP table state: Active
Table ID: 0x0 RD version: 0
BGP main routing table version 322
BGP NSR Initial initsync version 7 (Reached)
BGP NSR/ISSU Sync-Group versions 0/0
BGP scan interval 60 secs
Status codes: s suppressed, d damped, h history, * valid, > best
i - internal, r RIB-failure, S stale, N Nexthop-discard
Origin codes: i - IGP, e - EGP, ? - incomplete
Network Next Hop Metric LocPrf Weight Path
Route Distinguisher: 10.1.1.6:101 (default for vrf VPWS:101)
*> [1][0000.0000.0000.0000.0000][12]/120
0.0.0.0 0 i
*>i[1][0000.0000.0000.0000.0000][22]/120 10.1.1.4 C:11000 100 0 i
Processed 2 prefixes, 2 paths
The following output displays the details for the incoming EVPN RT1. Note the presence of BGP extended color community 11000,
and that the prefix is associated with an SR policy with color 11000 and BSID value of 80061.
RP/0/RSP0/CPU0:Node-B# show bgp l2vpn evpn rd 10.1.1.6:101 [1][0000.0000.0000.0000.0000][22]/120
Wed Jul 10 19:08:55.039 PST
BGP routing table entry for [1][0000.0000.0000.0000.0000][22]/120, Route Distinguisher: 10.1.1.6:101
Versions:
Process bRIB/RIB SendTblVer
Speaker 322 322
Last Modified: Jul 10 18:42:10.408 for 00:26:44
Paths: (1 available, best #1)
Not advertised to any peer
Path #1: Received by speaker 0
Not advertised to any peer
Local
10.1.1.4 C:11000 (bsid:80061) (metric 40) from 10.1.1.253 (10.1.1.4)
Received Label 80045
Origin IGP, localpref 100, valid, internal, best, group-best, import-candidate, imported, rib-install
Received Path ID 0, Local Path ID 1, version 319
Extended community: Color:11000 RT:65000:101
Originator: 10.1.1.4, Cluster list: 10.1.1.253
SR policy color 11000, up, registered, bsid 80061, if-handle 0x00000560
Source AFI: L2VPN EVPN, Source VRF: default, Source Route Distinguisher: 10.1.1.4:101
Use the show l2vpn xconnect command to display the state associated with EVPN-VPWS EVI 101 service.
RP/0/RSP0/CPU0:Node-B# show l2vpn xconnect group evpn_vpws_group
Wed Jul 10 19:08:56.388 PST
Legend: ST = State, UP = Up, DN = Down, AD = Admin Down, UR = Unresolved,
SB = Standby, SR = Standby Ready, (PP) = Partially Programmed
XConnect Segment 1 Segment 2
Group Name ST Description ST Description ST
------------------------ ----------------------------- -----------------------------
evpn_vpws_group
evpn_vpws_101UP Te0/3/0/0/8.2500 UP EVPN 101,22,10.1.1.4 UP
----------------------------------------------------------------------------------------
The following output shows the details for the service. Note that the service is associated with the on-demand SR policy with
color 11000 and end-point 10.1.1.4 (node D).
RP/0/RSP0/CPU0:Node-B# show l2vpn xconnect group evpn_vpws_group xc-name evpn_vpws_101
Wed Jul 10 19:08:56.511 PST
Group evpn_vpws_group, XC evpn_vpws_101, state is up; Interworking none
AC: TenGigE0/3/0/0/8.2500, state is up
Type VLAN; Num Ranges: 1
Rewrite Tags: []
VLAN ranges: [2500, 2500]
MTU 1500; XC ID 0x2a0000e; interworking none
Statistics:
packets: received 0, sent 0
bytes: received 0, sent 0
drops: illegal VLAN 0, illegal length 0
EVPN: neighbor 10.1.1.4, PW ID: evi 101, ac-id 22, state is up ( established )
XC ID 0xa0000009
Encapsulation MPLS
Source address 10.1.1.6
Encap type Ethernet, control word enabled
Sequencing not set
Preferred path Active : SR TE srte_c_11000_ep_10.1.1.4, On-Demand, fallback enabled
Tunnel : Up
Load Balance Hashing: src-dst-mac
EVPN Local Remote
------------ ------------------------------ -----------------------------
Label 80060 80045
MTU 1500 1500
Control word enabled enabled
AC ID 12 22
EVPN type Ethernet Ethernet
------------ ------------------------------ -----------------------------
Create time: 10/07/2019 18:32:49 (00:36:06 ago)
Last time status changed: 10/07/2019 18:42:07 (00:26:49 ago)
Statistics:
packets: received 0, sent 0
bytes: received 0, sent 0
Use the show segment-routing traffic-eng policy command with tabular option to display SR policy summary information.
The following output shows the on-demand SR policy with BSID 80061 that was triggered by EVPN RT1 prefix with color 11000
advertised by node D (10.1.1.4).
RP/0/RSP0/CPU0:Node-B# show segment-routing traffic-eng policy color 11000 tabular
Wed Jul 10 19:08:56.146 PST
Color Endpoint Admin Oper Binding
State State SID
------ -------------------- ------ ------ --------------------
1100010.1.1.4upup80061
The following output shows the details for the on-demand SR policy. Note that the SR policy's active candidate path (preference
100) is computed by SR-PCE (10.1.1.207).
Based on the goals of this use case, SR-PCE computes link-disjoint paths for the SR policies associated with a pair of ELINE
services between site 1 and site 2. Specifically, from site 1 to site 2, LSP at Node B (srte_c_11000_ep_10.1.1.4) is link-disjoint
from LSP at Node A (srte_c_11000_ep_10.1.1.2).
This section depicts verification steps at Node C.
Use the show bgp l2vpn evpn command to display BGP prefix information for EVPN-VPWS EVI 100 (rd 10.1.1.2:100). The output includes an EVPN route-type
1 route with color 10000 originated at Node A (10.1.1.5).
RP/0/RSP0/CPU0:Node-C# show bgp l2vpn evpn rd 10.1.1.2:100
BGP router identifier 10.1.1.2, local AS number 65000
BGP generic scan interval 60 secs
Non-stop routing is enabled
BGP table state: Active
Table ID: 0x0 RD version: 0
BGP main routing table version 21
BGP NSR Initial initsync version 1 (Reached)
BGP NSR/ISSU Sync-Group versions 0/0
BGP scan interval 60 secs
Status codes: s suppressed, d damped, h history, * valid, > best
i - internal, r RIB-failure, S stale, N Nexthop-discard
Origin codes: i - IGP, e - EGP, ? - incomplete
Network Next Hop Metric LocPrf Weight Path
Route Distinguisher: 10.1.1.2:100 (default for vrf VPWS:100)
*>i[1][0000.0000.0000.0000.0000][11]/12010.1.1.5 C:10000 100 0 i
*> [1][0000.0000.0000.0000.0000][21]/120
0.0.0.0 0 i
The following output displays the details for the incoming EVPN RT1. Note the presence of BGP extended color community 10000,
and that the prefix is associated with an SR policy with color 10000 and BSID value of 80058.
RP/0/RSP0/CPU0:Node-C# show bgp l2vpn evpn rd 10.1.1.2:100 [1][0000.0000.0000.0000.0000][11]/120
BGP routing table entry for [1][0000.0000.0000.0000.0000][11]/120, Route Distinguisher: 10.1.1.2:100
Versions:
Process bRIB/RIB SendTblVer
Speaker 20 20
Last Modified: Jul 10 18:36:20.503 for 00:45:21
Paths: (1 available, best #1)
Not advertised to any peer
Path #1: Received by speaker 0
Not advertised to any peer
Local
10.1.1.5 C:10000 (bsid:80058) (metric 40) from 10.1.1.253 (10.1.1.5)
Received Label 80040
Origin IGP, localpref 100, valid, internal, best, group-best, import-candidate, imported, rib-install
Received Path ID 0, Local Path ID 1, version 18
Extended community: Color:10000 RT:65000:100
Originator: 10.1.1.5, Cluster list: 10.1.1.253
SR policy color 10000, up, registered, bsid 80058, if-handle 0x000006a0
Source AFI: L2VPN EVPN, Source VRF: default, Source Route Distinguisher: 10.1.1.5:100
Use the show l2vpn xconnect command to display the state associated with EVPN-VPWS EVI 100 service.
RP/0/RSP0/CPU0:Node-C# show l2vpn xconnect group evpn_vpws_group
Legend: ST = State, UP = Up, DN = Down, AD = Admin Down, UR = Unresolved,
SB = Standby, SR = Standby Ready, (PP) = Partially Programmed
XConnect Segment 1 Segment 2
Group Name ST Description ST Description ST
------------------------ ----------------------------- -----------------------------
evpn_vpws_group
evpn_vpws_100UP Gi0/0/0/3.2500 UP EVPN 100,11,10.1.1.5 UP
----------------------------------------------------------------------------------------
The following output shows the details for the service. Note that the service is associated with the on-demand SR policy with
color 10000 and end-point 10.1.1.5 (node A).
RP/0/RSP0/CPU0:Node-C# show l2vpn xconnect group evpn_vpws_group xc-name evpn_vpws_100
Group evpn_vpws_group, XC evpn_vpws_100, state is up; Interworking none
AC: GigabitEthernet0/0/0/3.2500, state is up
Type VLAN; Num Ranges: 1
Rewrite Tags: []
VLAN ranges: [2500, 2500]
MTU 1500; XC ID 0x1200008; interworking none
Statistics:
packets: received 0, sent 0
bytes: received 0, sent 0
drops: illegal VLAN 0, illegal length 0
EVPN: neighbor 10.1.1.5, PW ID: evi 100, ac-id 11, state is up ( established )
XC ID 0xa0000003
Encapsulation MPLS
Source address 10.1.1.2
Encap type Ethernet, control word enabled
Sequencing not set
Preferred path Active : SR TE srte_c_10000_ep_10.1.1.5, On-Demand, fallback enabled
Tunnel : Up
Load Balance Hashing: src-dst-mac
EVPN Local Remote
------------ ------------------------------ -----------------------------
Label 80056 80040
MTU 1500 1500
Control word enabled enabled
AC ID 21 11
EVPN type Ethernet Ethernet
------------ ------------------------------ -----------------------------
Create time: 10/07/2019 18:36:16 (1d19h ago)
Last time status changed: 10/07/2019 19:41:59 (1d18h ago)
Last time PW went down: 10/07/2019 19:40:54 (1d18h ago)
Statistics:
packets: received 0, sent 0
bytes: received 0, sent 0
Use the show segment-routing traffic-eng policy command with tabular option to display SR policy summary information.
The following output shows the on-demand SR policy with BSID 80058 that was triggered by EVPN RT1 prefix with color 10000
advertised by node A (10.1.1.5).
RP/0/RSP0/CPU0:Node-C# show segment-routing traffic-eng policy color 10000 tabular
Color Endpoint Admin Oper Binding
State State SID
------ -------------------- ------ ------ --------------------
1000010.1.1.5upup80058
The following output shows the details for the on-demand SR policy. Note that the SR policy's active candidate path (preference
100) is computed by SR-PCE (10.1.1.207).
Based on the goals of this use case, SR-PCE computes link-disjoint paths for the SR policies associated with a pair of ELINE
services between site 1 and site 2. Specifically, from site 2 to site 1, LSP at Node C (srte_c_10000_ep_10.1.1.5) is link-disjoint
from LSP at Node D (srte_c_10000_ep_10.1.1.6).
This section depicts verification steps at Node D.
Use the show bgp l2vpn evpn command to display BGP prefix information for EVPN-VPWS EVI 101 (rd 10.1.1.4:101). The output includes an EVPN route-type
1 route with color 10000 originated at Node B (10.1.1.6).
RP/0/RSP0/CPU0:Node-D# show bgp l2vpn evpn rd 10.1.1.4:101
BGP router identifier 10.1.1.4, local AS number 65000
BGP generic scan interval 60 secs
Non-stop routing is enabled
BGP table state: Active
Table ID: 0x0 RD version: 0
BGP main routing table version 570
BGP NSR Initial initsync version 1 (Reached)
BGP NSR/ISSU Sync-Group versions 0/0
BGP scan interval 60 secs
Status codes: s suppressed, d damped, h history, * valid, > best
i - internal, r RIB-failure, S stale, N Nexthop-discard
Origin codes: i - IGP, e - EGP, ? - incomplete
Network Next Hop Metric LocPrf Weight Path
Route Distinguisher: 10.1.1.4:101 (default for vrf VPWS:101)
*>i[1][0000.0000.0000.0000.0000][12]/12010.1.1.6 C:10000 100 0 i
*> [1][0000.0000.0000.0000.0000][22]/120
0.0.0.0 0 i
Processed 2 prefixes, 2 paths
The following output displays the details for the incoming EVPN RT1. Note the presence of BGP extended color community 10000,
and that the prefix is associated with an SR policy with color 10000 and BSID value of 80047.
RP/0/RSP0/CPU0:Node-D# show bgp l2vpn evpn rd 10.1.1.4:101 [1][0000.0000.0000.0000.0000][12]/120
BGP routing table entry for [1][0000.0000.0000.0000.0000][12]/120, Route Distinguisher: 10.1.1.4:101
Versions:
Process bRIB/RIB SendTblVer
Speaker 569 569
Last Modified: Jul 10 18:42:12.455 for 00:45:38
Paths: (1 available, best #1)
Not advertised to any peer
Path #1: Received by speaker 0
Not advertised to any peer
Local
10.1.1.6 C:10000 (bsid:80047) (metric 40) from 10.1.1.253 (10.1.1.6)
Received Label 80060
Origin IGP, localpref 100, valid, internal, best, group-best, import-candidate, imported, rib-install
Received Path ID 0, Local Path ID 1, version 568
Extended community: Color:10000 RT:65000:101
Originator: 10.1.1.6, Cluster list: 10.1.1.253
SR policy color 10000, up, registered, bsid 80047, if-handle 0x00001720
Source AFI: L2VPN EVPN, Source VRF: default, Source Route Distinguisher: 10.1.1.6:101
Use the show l2vpn xconnect command to display the state associated with EVPN-VPWS EVI 101 service.
RP/0/RSP0/CPU0:Node-D# show l2vpn xconnect group evpn_vpws_group
Legend: ST = State, UP = Up, DN = Down, AD = Admin Down, UR = Unresolved,
SB = Standby, SR = Standby Ready, (PP) = Partially Programmed
XConnect Segment 1 Segment 2
Group Name ST Description ST Description ST
------------------------ ----------------------------- -----------------------------
evpn_vpws_group
evpn_vpws_101UP Gi0/0/0/1.2500 UP EVPN 101,12,10.1.1.6 UP
----------------------------------------------------------------------------------------
The following output shows the details for the service. Note that the service is associated with the on-demand SR policy with
color 10000 and end-point 10.1.1.6 (node B).
RP/0/RSP0/CPU0:Node-D# show l2vpn xconnect group evpn_vpws_group xc-name evpn_vpws_101
Group evpn_vpws_group, XC evpn_vpws_101, state is up; Interworking none
AC: GigabitEthernet0/0/0/1.2500, state is up
Type VLAN; Num Ranges: 1
Rewrite Tags: []
VLAN ranges: [2500, 2500]
MTU 1500; XC ID 0x120000c; interworking none
Statistics:
packets: received 0, sent 0
bytes: received 0, sent 0
drops: illegal VLAN 0, illegal length 0
EVPN: neighbor 10.1.1.6, PW ID: evi 101, ac-id 12, state is up ( established )
XC ID 0xa000000d
Encapsulation MPLS
Source address 10.1.1.4
Encap type Ethernet, control word enabled
Sequencing not set
Preferred path Active : SR TE srte_c_10000_ep_10.1.1.6, On-Demand, fallback enabled
Tunnel : Up
Load Balance Hashing: src-dst-mac
EVPN Local Remote
------------ ------------------------------ -----------------------------
Label 80045 80060
MTU 1500 1500
Control word enabled enabled
AC ID 22 12
EVPN type Ethernet Ethernet
------------ ------------------------------ -----------------------------
Create time: 10/07/2019 18:42:07 (00:45:49 ago)
Last time status changed: 10/07/2019 18:42:09 (00:45:47 ago)
Statistics:
packets: received 0, sent 0
bytes: received 0, sent 0
Use the show segment-routing traffic-eng policy command with tabular option to display SR policy summary information.
The following output shows the on-demand SR policy with BSID 80047 that was triggered by EVPN RT1 prefix with color 10000
advertised by node B (10.1.1.6).
RP/0/RSP0/CPU0:Node-D# show segment-routing traffic-eng policy color 10000 tabular
Color Endpoint Admin Oper Binding
State State SID
------ -------------------- ------ ------ --------------------
1000010.1.1.6upup80047
The following output shows the details for the on-demand SR policy. Note that the SR policy's active candidate path (preference
100) is computed by SR-PCE (10.1.1.207).
Based on the goals of this use case, SR-PCE computes link-disjoint paths for the SR policies associated with a pair of ELINE
services between site 1 and site 2. Specifically, from site 2 to site 1, LSP at Node D (srte_c_10000_ep_10.1.1.6) is link-disjoint
from LSP at Node C (srte_c_10000_ep_10.1.1.5).
Manually provisioned SR policies are configured on the head-end router. These policies can use dynamic paths or explicit paths.
See the SR-TE Policy Path Types section for information on manually provisioning an SR policy using dynamic or explicit paths.
PCE-Initiated SR Policy
An SR-TE policy can be configured on the path computation element (PCE) to reduce link congestion or to minimize the number
of network touch points.
The PCE collects network information, such as traffic demand and link utilization. When the PCE determines that a link is
congested, it identifies one or more flows that are causing the congestion. The PCE finds a suitable path and deploys an SR-TE
policy to divert those flows, without moving the congestion to another part of the network. When there is no more link congestion,
the policy is removed.
To minimize the number of network touch points, an application, such as a Network Services Orchestrator (NSO), can request
the PCE to create an SR-TE policy. PCE deploys the SR-TE policy using PCC-PCE communication protocol (PCEP).
With this feature, SRTE calculates a shortest path that satisfies multiple metric bounds.
This feature provides flexibility for finding paths within metric bounds, for parameters such as latency, hop count, IGP and
TE.
SRTE can calculate a shortest path with cumulative metric bounds. For example, consider these metric bounds:
IGP metric <= 10
TE metric <= 60
Hop count <= 4
Latency <= 55
When an SR policy is configured on a head-end node with these metric bounds, a path is finalized towards the specified destination
only if it meets each of these criteria.
You can set the maximum number of attempts for computing a shortest path that satisfies the cumulative metric bounds criteria,
by using the kshortest-paths command in SR-TE configuration mode.
Restrictions
PCE-based cumulative metric bounds computations are not supported. You must use non-PCE (SR-TE topology) based configuration
for path calculation, for cumulative bounds.
If you use PCE dynamic computation configuration with cumulative bounds, the PCE computes a path and validates against cumulative
bounds. If it is valid, then the policy is created with this path on PCC. If the initial path doesn't respect the bounds,
then the path is not considered, and no further K-shortest path algorithm is executed to find the path.
Configuring SRTE Shortest Path Calculation For Cumulative Metric Bounds
You can enable this feature for SR, and ODN SR policy configurations, as shown below.
SR Policy
SR Policy - A policy called fromAtoB_XTC is created towards destination IP address 192.168.0.2. Also, the candidate-paths preference, and other attributes are enabled.
Router# configure terminal
Router(config)# segment-routing traffic-eng policy fromAtoB_XTC
Router(config-sr-te-policy)# color 2 end-point ipv4 192.168.0.2
Router(config-sr-te-policy)# candidate-paths preference 100
Router(config-sr-te-policy-path-pref)# dynamic metric type te
Cumulative Metric bounds – IGP, TE, hop count, and latency metric bounds are set. SRTE calculates paths only when each criterion is satisfied.
Router(config-sr-te-policy-path-pref)# constraints bounds cumulative
Router(config-sr-te-pref-const-bounds-type)# type igp 10
Router(config-sr-te-pref-const-bounds-type)# type te 60
Router(config-sr-te-pref-const-bounds-type)# type hopcount 4
Router(config-sr-te-pref-const-bounds-type)# type latency 55
Router(config-sr-te-pref-const-bounds-type)# commit
ODN SR Policy
SR ODN Policy – An SR ODN policy with color 1000 is created. Also, the candidate-paths value is on-demand.
Router# configure terminal
Router(config)# segment-routing traffic-eng
Router(config-sr-te)# on-demand color 1000 dynamic metric type te
Router(config-sr-te)# candidate-paths on-demand
Router(config-sr-te-candidate-path-type)# exit
Router(config-sr-te-candidate-path)# exit
Cumulative Metric bounds – IGP, TE, hop count, and latency metric bounds are set for the policy. SRTE calculates paths, only when each criterion is
satisfied.
Router(config-sr-te)# on-demand color 1000 dynamic bounds cumulative
Router(config-sr-te-odc-bounds-type)# type igp 100
Router(config-sr-te-odc-bounds-type)# type te 60
Router(config-sr-te-odc-bounds-type)# type hopcount 6
Router(config-sr-te-odc-bounds-type)# type latency 1000
Router(config-sr-te-odc-bounds-type)# commit
To set the maximum number of attempts for computing paths that satisfy the cumulative metric bounds criteria, use the kshortest-paths command.
Use this command to view SR policy configuration details. Pointers:
The Number of K-shortest-paths field displays 4. It means that the K-shortest path algorithm took 4 computations to find the right path. The 4 shortest
paths that are computed using K-shortest path algorithm did not respect the cumulative bounds. The fifth shortest path is
valid against the bounds.
The values for the metrics of the actual path (TE, IGP, Cumulative Latency and Hop count values in the Dynamic section) are within the configured cumulative metric bounds.
Router# show segment-routing traffic-eng policy color 2
Color: 2, End-point: 192.168.0.2
Name: srte_c_2_ep_192.168.0.2
Status:
Admin: up Operational: up for 3d02h (since Dec 15 12:13:21.993)
Candidate-paths:
Preference: 100 (configuration) (active)
Name: fromAtoB_XTC
Requested BSID: dynamic
Constraints:
Protection Type: protected-preferred
Affinity:
exclude-any:
red
Maximum SID Depth: 10
IGP Metric Bound: 10
TE Metric Bound: 60
Latency Metric Bound: 55
Hopcount Metric Bound: 4
Dynamic (valid)
Metric Type: TE, Path Accumulated Metric: 52
Number of K-shortest-paths: 4
TE Cumulative Metric: 52
IGP Cumulative Metric: 3
Cumulative Latency: 52
Hop count: 3
16004 [Prefix-SID, 192.168.0.4]
24003 [Adjacency-SID, 16.16.16.2 - 16.16.16.5]
24001 [Adjacency-SID, 14.14.14.5 - 14.14.14.4]
Attributes:
Binding SID: 24011
Forward Class: Not Configured
Steering labeled-services disabled: no
Steering BGP disabled: no
IPv6 caps enable: yes
Invalidation drop enabled: no
SR-TE BGP Soft Next-Hop Validation For ODN Policies
Table 3. Feature History Table
Feature Name
Release Information
Feature Description
SR-TE BGP Soft Next-Hop Validation For ODN Policies
Release 7.3.2
This feature addresses BGP Next-Hop reachability issues through BGP Next-Hop soft validation, and also enhances BGP best path selection.
New commands:
nexthop validation color-extcomm disable
nexthop validation color-extcomm sr-policy
bgp bestpath igp-metric sr-policy
Before a BGP router installs a route in the routing table, it checks its own reachability to the Next-Hop (NH) IP address
of the route. In an SR-TE domain, a NH address may not be redistributed within the AS, or to a neighbor AS. So, BGP cannot
reach the NH, and does not install the corresponding route into the routing table. The following workarounds are available,
but they are tedious and might impact scalability:
Enable a non-default, static route to null0 covering the routes
Inject the routes into BGP using BGP-Labeled Unicast configuration
Redistribute routes between IGP domains
This feature introduces a more optimal design and solution - When you enable an SR policy on the SR-TE headend router, configure
the nexthop validation color-extcomm sr-policy command in BGP configuration mode. It instructs BGP that, instead of NH reachability
validation of BGP routes, the validation is done for SR policy-installed color NH addresses. When the NH address of such a
route is reachable, the route is added to the routing table.
Also, this configuration on the ingress/headend PE router reduces the route scale for NH reachability, and service (VPN) routes
automatically get NH reachability.
RR configuration – For intermediate router configuration, enable the RR with the nexthop validation color-extcomm disable
command. When enabled, and L3VPN prefixes are associated with a color ID, BGP skips NH validation on the RR.
When the RR has no reachability to the color-extcomm NH, either enable this command, or use a legacy static route.
The following sequence occurs when the headend router receives L3VPN prefixes based on a color ID such as purple, green, etc.
The router checks/learns the local SR policy, or requests the ODN SR policy for color ID and NH
BGP does validation of the SR policy routes’ NH addresses and applies the corresponding NH AD/metric. For a NH with a specific
BGP-based color attribute, SR-PCE provides the AD/metric
With BGP NH reachability, traffic is transported smoothly
On the RR, BGP does not validate NH reachability
BGP Best Path Selection Based On SR Policy Effective Metric
BGP uses an algorithm to select the best path for installing the route in the RIB or for making a choice of which BGP path
to propagate. At a certain point in the process, if there is IGP reachability to a BGP NH address, the algorithm chooses the
path with the lowest IGP metric as the best path. The SR Policy path metric is not considered even if it has a better metric.
This feature addresses the issue.
To ensure that BGP prefers the SR policy path metric over the IGP metric, enable bgp bestpath igp-metric sr-policy in BGP
configuration mode.
Use this command to view BGP Soft Next-Hop Validation details.
Headend # show bgp process detail | i Nexthop
Use SR-Policy admin/metric of color-extcomm Nexthop during path comparison: enabled ExtComm Color Nexthop validation: SR-Policy then RIB
Use this command to view BGP Best Path Selection Based on SR Policy Metric.
Headend # show bgp vrf VRF1002 ipv4 unicast 207.77.2.0
BGP routing table entry for 207.77.2.0/24, Route Distinguisher: 18522:1002 Versions:
Process bRIB/RIB SendTblVer
Speaker 5232243 5232243 Paths: (1 available, best #1)
Advertised to CE peers (in unique update groups): 10.11.2.11 101.15.2.2
Path #1: Received by speaker 0
Advertised to CE peers (in unique update groups): 10.11.2.11 101.15.2.2
16611 770
10.1.1.33 C:1129 (bsid:27163) (admin 20) (metric 25) from 10.1.1.100 (10.1.1.33)
Received Label 24007
Origin IGP, localpref 100, valid, internal, best, group-best, import-candidate, imported Received Path ID 1, Local Path ID 1, version 5232243
Extended community: Color:1129 RT:17933:1002 RT:18522:1002
Originator: 10.1.1.33, Cluster list: 10.1.1.100
SR policy color 1129, up, registered, bsid 27163, if-handle 0x200053dc
Source AFI: VPNv4 Unicast, Source VRF: default, Source Route Distinguisher: 18522:3002
Details
10.1.1.33 C:1129 - BGP path is selected based on the SR policy with color ID C:1129
If no SR policy is up, or if the SR policy metric is not configured, only the RIB metric is displayed
admin 20 and metric 25 are SR policy references
SR-TE Policy Path Types
A dynamic path is based on an optimization objective and a set of constraints. The head-end computes a solution, resulting in a SID-list
or a set of SID-lists. When the topology changes, a new path is computed. If the head-end does not have enough information
about the topology, the head-end might delegate the computation to a Segment Routing Path Computation Element (SR-PCE). For
information on configuring SR-PCE, see Configure Segment Routing Path Computation Element chapter.
An explicit path is a specified SID-list or set of SID-lists.
An SR-TE policy initiates a single (selected) path in RIB/FIB. This is the preferred valid candidate path. A path is selected
when the path is valid and its preference is the best among all candidate paths for that policy.
Note
The protocol of the source is not relevant in the path selection logic.
A candidate path has the following characteristics:
It has a preference – If two policies have the same {color, endpoint} but different preferences, the policy with the highest
preference is selected.
It is associated with a single binding SID (BSID) – A BSID conflict occurs when there are different SR policies with the same
BSID. In this case, the policy that is installed first gets the BSID and is selected.
It is valid if it is usable.
Dynamic Paths
Behaviors and Limitations
For a dynamic path that traverses a specific interface between nodes (segment), the algorithm may encode this segment using
an Adj-SID. The SR-TE process prefers the protected Adj-SID of the link, if one is available. In addition, the SR-TE process prefers a manual protected Adj-SID over a dynamic protected Adj-SID.
Optimization Objectives
Optimization objectives allow the head-end router to compute a SID-list that expresses the shortest dynamic path according
to the selected metric type:
IGP metric — Refer to the "Implementing IS-IS" and "Implementing OSPF" chapters in the Routing Configuration Guide for Series Routers.
Constraints allow the head-end router to compute a dynamic path according to the selected metric type:
Affinity — You can apply a color or name to links or interfaces by assigning affinity bit-maps to them. You can then specify
an affinity (or relationship) between an SR policy path and link colors. SR-TE computes a path that includes or excludes links
that have specific colors,or combinations of colors. See the Named Interface Link Admin Groups and SR-TE Affinity Maps section for information on named interface link admin groups and SR-TE Affinity Maps.
Disjoint — SR-TE computes a path that is disjoint from another path in the same disjoint-group. Disjoint paths do not share
network resources. Path disjointness may be required for paths between the same pair of nodes, between different pairs of
nodes, or a combination (only same head-end or only same end-point).
Flexible Algorithm — Flexible Algorithm allows for user-defined algorithms where the IGP computes paths based on a user-defined
combination of metric type and constraint.
Named Interface Link Admin Groups and SR-TE Affinity Maps
Named Interface Link Admin Groups and SR-TE Affinity Maps provide a simplified and more flexible means of configuring link
attributes and path affinities to compute paths for SR-TE policies.
In the traditional TE scheme, links are configured with attribute-flags that are flooded with TE link-state parameters using
Interior Gateway Protocols (IGPs), such as Open Shortest Path First (OSPF).
Named Interface Link Admin Groups and SR-TE Affinity Maps let you assign, or map, up to 256 color names for affinity and attribute-flag attributes instead of 32-bit
hexadecimal numbers. After mappings are defined, the attributes can be referred to by
the corresponding color name in the CLI. Furthermore, you can define constraints using
include-any, include-all, and exclude-any arguments, where each
statement can contain up to 10 colors.
Note
You can configure affinity constraints using attribute flags or the Flexible Name Based Policy Constraints scheme; however,
when configurations for both schemes exist, only the configuration pertaining to the new scheme is applied.
Configure Named Interface Link Admin Groups and SR-TE Affinity Maps
Use the affinity nameNAME command in SR-TE interface submode to assign affinity to interfaces. Configure this on routers with interfaces that have
an associated admin group attribute.
Router# configure
Router(config)# segment-routing
Router(config-sr)# traffic-eng
Router(config-sr-te)# interface TenGigE0/0/1/2
Router(config-sr-if)# affinity
Router(config-sr-if-affinity)# name RED
Use the affinity-map nameNAMEbit-positionbit-position command in SR-TE sub-mode to define affinity maps. The bit-position range is from 0 to 255.
Configure affinity maps on the following routers:
Routers with interfaces that have an associated admin group attribute.
Routers that act as SR-TE head-ends for SR policies that include affinity constraints.
The following example shows how to assign affinity to interfaces and to define affinity maps. This configuration is applicable
to any router (SR-TE head-end or transit node) with colored interfaces.
segment-routing
traffic-eng
interface TenGigE0/0/1/1
affinity
name CROSS
name RED
!
!
interface TenGigE0/0/1/2
affinity
name RED
!
!
interface TenGigE0/0/2/0
affinity
name BLUE
!
!
affinity-map
name RED bit-position 23
name BLUE bit-position 24
name CROSS bit-position 25
!
end
Configure SR Policy with Dynamic Path
To configure a SR-TE policy with a dynamic path, optimization objectives, and affinity constraints, complete the following
configurations:
Define the constraints. See the Constraints section.
Create the policy.
Behaviors and Limitations
For a dynamic path that traverses a specific interface between nodes (segment), the algorithm may encode this segment using
an Adj-SID. The SR-TE process prefers the protected Adj-SID of the link, if one is available. In addition, the SR-TE process prefers a manual protected Adj-SID over a dynamic protected Adj-SID.
Examples
The following example shows a configuration of an SR policy at an SR-TE head-end router. The policy has a dynamic path with
optimization objectives and affinity constraints computed by the head-end router.
segment-routing
traffic-eng
policy foo
color 100 end-point ipv4 10.1.1.2
candidate-paths
preference 100
dynamicmetrictype te
!
!
constraintsaffinityexclude-anyname RED
!
!
!
!
!
!
The following example shows a configuration of an SR policy at an SR-TE head-end router. The policy has a dynamic path with
optimization objectives and affinity constraints computed by the SR-PCE.
segment-routing
traffic-eng
policy baa
color 101 end-point ipv4 10.1.1.2
candidate-paths
preference 100
dynamicpcep
!
metrictype te
!
!
constraintsaffinityexclude-anyname BLUE
!
!
!
!
!
!
Explicit Paths
SR-TE Policy with Explicit Path
An explicit segment list is defined as a sequence of one or more segments. A segment can be configured as an IP address or
an MPLS label representing a node or a link.
An explicit segment list can be configured with the following:
IP-defined segments
MPLS label-defined segments
A combination of IP-defined segments and MPLS label-defined segments
Usage Guidelines and Limitations
An IP-defined segment can be associated with an IPv4 address (for example, a link or a Loopback address).
When a segment of the segment list is defined as an MPLS label, subsequent segments can only be configured as MPLS labels.
When configuring an explicit path using IP addresses of links along the path, the SR-TE process prefers the protected Adj-SID
of the link, if one is available. In addition, when manual Adj-SIDs are configured, the SR-TE process prefers a manual protected Adj-SID over a dynamic protected
Adj-SID.
Configure Local SR-TE Policy Using Explicit Paths
To configure an SR-TE policy with an explicit path, complete the following configurations:
Create the segment list.
Create the SR-TE policy.
Create a segment list with IPv4 addresses:
Router# configure
Router(config)# segment-routing
Router(config-sr)# traffic-eng
Router(config-sr-te)# segment-list name SIDLIST1
Router(config-sr-te-sl)# index 10 address ipv4 10.1.1.2
Router(config-sr-te-sl)# index 20 address ipv4 10.1.1.3
Router(config-sr-te-sl)# index 30 address ipv4 10.1.1.4
Router(config-sr-te-sl)# exit
Create a segment list with MPLS labels:
Router(config-sr-te)# segment-list name SIDLIST2
Router(config-sr-te-sl)# index 10 mpls label 16002
Router(config-sr-te-sl)# index 20 mpls label 16003
Router(config-sr-te-sl)# index 30 mpls label 16004
Router(config-sr-te-sl)# exit
Create a segment list with IPv4 addresses and MPLS labels:
Router(config-sr-te)# segment-list name SIDLIST3
Router(config-sr-te-sl)# index 10 address ipv4 10.1.1.2
Router(config-sr-te-sl)# index 20 mpls label 16003
Router(config-sr-te-sl)# index 30 mpls label 16004
Router(config-sr-te-sl)# exit
Router# show running-configuration
segment-routing
traffic-eng
segment-list SIDLIST1
index 10 address ipv4 10.1.1.2
index 20 address ipv4 10.1.1.3
index 30 address ipv4 10.1.1.4
!
segment-list SIDLIST2
index 10 mpls label 16002
index 20 mpls label 16003
index 30 mpls label 16004
!
segment-list SIDLIST3
index 10 address ipv4 10.1.1.2
index 20 mpls label 16003
index 30 mpls label 16004
!
segment-list SIDLIST4
index 10 mpls label 16009
index 20 mpls label 16003
index 30 mpls label 16004
!
policy POLICY1
color 10 end-point ipv4 10.1.1.4
candidate-paths
preference 100
explicit segment-list SIDLIST1
!
!
!
!
policy POLICY2
color 20 end-point ipv4 10.1.1.4
candidate-paths
preference 100
explicit segment-list SIDLIST1
!
!
preference 200
explicit segment-list SIDLIST2
!
!
!
policy POLICY3
color 30 end-point ipv4 10.1.1.4
candidate-paths
preference 100
explicit segment-list SIDLIST3
!
!
!
!
!
!
Verification
Verify the SR-TE policy configuration using:
Router# show segment-routing traffic-eng policy name srte_c_20_ep_10.1.1.4
SR-TE policy database
---------------------
Color: 20, End-point: 10.1.1.4
Name: srte_c_20_ep_10.1.1.4
Status:
Admin: up Operational: up for 00:00:15 (since Jul 14 00:53:10.615)
Candidate-paths:
Preference: 200 (configuration) (active)
Name: POLICY2
Requested BSID: dynamic
Protection Type: protected-preferred
Maximum SID Depth: 8
Explicit: segment-list SIDLIST2 (active)
Weight: 1, Metric Type: TE
16002
16003
16004
Preference: 100 (configuration) (inactive)
Name: POLICY2
Requested BSID: dynamic
Protection Type: protected-preferred
Maximum SID Depth: 8
Explicit: segment-list SIDLIST1 (inactive)
Weight: 1, Metric Type: TE
[Adjacency-SID, 10.1.1.2 - <None>]
[Adjacency-SID, 10.1.1.3 - <None>]
[Adjacency-SID, 10.1.1.4 - <None>]
Attributes:
Binding SID: 51301
Forward Class: Not Configured
Steering labeled-services disabled: no
Steering BGP disabled: no
IPv6 caps enable: yes
Invalidation drop enabled: no
Configuring Explicit Path with Affinity Constraint Validation
To fully configure SR-TE flexible name-based policy constraints, you must complete these high-level tasks in order:
Assign Color Names to Numeric Values
Associate Affinity-Names with SR-TE Links
Associate Affinity Constraints for SR-TE Policies
/* Enter the global configuration mode and assign color names to numeric values
Router# configure
Router(config)# segment-routing
Router(config-sr)# traffic-eng
Router(config-sr-te)# affinity-map
Router(config-sr-te-affinity-map)# blue bit-position 0
Router(config-sr-te-affinity-map)# green bit-position 1
Router(config-sr-te-affinity-map)# red bit-position 2
Router(config-sr-te-affinity-map)# exit
/* Associate affinity-names with SR-TE links
Router(config-sr-te)# interface Gi0/0/0/0
Router(config-sr-te-if)# affinity
Router(config-sr-te-if-affinity)# blue
Router(config-sr-te-if-affinity)# exit
Router(config-sr-te-if)# exit
Router(config-sr-te)# interface Gi0/0/0/1
Router(config-sr-te-if)# affinity
Router(config-sr-te-if-affinity)# blue
Router(config-sr-te-if-affinity)# green
Router(config-sr-te-if-affinity)# exit
Router(config-sr-te-if)# exit
Router(config-sr-te)#
/* Associate affinity constraints for SR-TE policies
Router(config-sr-te)# segment-list name SIDLIST1
Router(config-sr-te-sl)# index 10 address ipv4 10.1.1.2
Router(config-sr-te-sl)# index 20 address ipv4 2.2.2.23
Router(config-sr-te-sl)# index 30 address ipv4 10.1.1.4
Router(config-sr-te-sl)# exit
Router(config-sr-te)# segment-list name SIDLIST2
Router(config-sr-te-sl)# index 10 address ipv4 10.1.1.2
Router(config-sr-te-sl)# index 30 address ipv4 10.1.1.4
Router(config-sr-te-sl)# exit
Router(config-sr-te)# segment-list name SIDLIST3
Router(config-sr-te-sl)# index 10 address ipv4 10.1.1.5
Router(config-sr-te-sl)# index 30 address ipv4 10.1.1.4
Router(config-sr-te-sl)# exit
Router# show running-configuration
segment-routing
traffic-eng
interface GigabitEthernet0/0/0/0
affinity
blue
!
!
interface GigabitEthernet0/0/0/1
affinity
blue
green
!
!
segment-list name SIDLIST1
index 10 address ipv4 10.1.1.2
index 20 address ipv4 2.2.2.23
index 30 address ipv4 10.1.1.4
!
segment-list name SIDLIST2
index 10 address ipv4 10.1.1.2
index 30 address ipv4 10.1.1.4
!
segment-list name SIDLIST3
index 10 address ipv4 10.1.1.5
index 30 address ipv4 10.1.1.4
!
policy POLICY1
binding-sid mpls 1000
color 20 end-point ipv4 10.1.1.4
candidate-paths
preference 100
explicit segment-list SIDLIST3
!
!
preference 200
explicit segment-list SIDLIST1
!
explicit segment-list SIDLIST2
!
constraints
affinity
exclude-any
red
!
!
!
!
!
!
affinity-map
blue bit-position 0
green bit-position 1
red bit-position 2
!
!
!
Protocols
Path Computation Element Protocol
The path computation element protocol (PCEP) describes a set of procedures by which a path computation client (PCC) can report
and delegate control of head-end label switched paths (LSPs) sourced from the PCC to a PCE peer. The PCE can request the PCC
to update and modify parameters of LSPs it controls. The stateful model also enables a PCC to allow the PCE to initiate computations
allowing the PCE to perform network-wide orchestration.
Configure the Head-End Router as PCEP PCC
Configure the head-end router as PCEP Path Computation Client (PCC) to establish a connection to the PCE. The PCC and PCE
addresses must be routable so that TCP connection (to exchange PCEP messages) can be established between PCC and PCE.
Configure the PCC to Establish a Connection to the PCE
Use the segment-routing traffic-eng pcc command to configure the PCC source address, the SR-PCE address, and SR-PCE options.
A PCE can be given an optional precedence. If a PCC is connected to multiple PCEs, the PCC selects a PCE with the lowest precedence
value. If there is a tie, a PCE with the highest IP address is chosen for computing path. The precedence value range is from 0 to 255.
TCP Message Digest 5 (MD5) authentication has been used for authenticating PCEP (TCP) sessions by using a clear text or encrypted
password. This feature introduces support for TCP Authentication Option (TCP-AO), which replaces the TCP MD5 option.
TCP-AO uses Message Authentication Codes (MACs), which provides the following:
Protection against replays for long-lived TCP connections
More details on the security association with TCP connections than TCP MD5
A larger set of MACs with minimal system and operational changes
TCP-AO is compatible with Master Key Tuple (MKT) configuration. TCP-AO also protects connections when using the same MKT across
repeated instances of a connection. TCP-AO protects the connections by using traffic key that are derived from the MKT, and
then coordinates changes between the endpoints.
Note
TCP-AO and TCP MD5 are never permitted to be used simultaneously. TCP-AO supports IPv6, and is fully compatible with the proposed
requirements for the replacement of TCP MD5.
TCP Message Digest 5 (MD5) Authentication
Use the password {clear | encrypted} LINE command to enable TCP MD5 authentication for all PCEP peers. Any TCP segment coming from the PCC that does not contain a
MAC matching the configured password will be rejected. Specify if the password is encrypted or clear text
Use the tcp-aokey-chain [include-tcp-options] command to enable TCP Authentication Option (TCP-AO) authentication for all PCEP peers. Any TCP segment coming from the
PCC that does not contain a MAC matching the configured key chain will be rejected. Use the include-tcp-options keyword to include other TCP options in the header for MAC calculation.
Use the timers keepalive command to specify how often keepalive messages are sent from PCC to its peers. The range is from 0 to 255 seconds; the default
value is 30.
Router(config-sr-te-pcc)# timers keepaliveseconds
Use the timers deadtimer command to specify how long the remote peers wait before bringing down the PCEP session if no PCEP messages are received
from this PCC. The range is from 1 to 255 seconds; the default value is 120.
Router(config-sr-te-pcc)# timers deadtimerseconds
Use the timers delegation-timeout command to specify how long a delegated SR policy can remain up without an active connection to a PCE. The range is from
0 to 3600 seconds; the default value is 60.
Use the timers initiated orphans command to specify the amount of time that a PCE-initiated SR policy will remain delegated to a PCE peer that is no longer
reachable by the PCC. The range is from 10 to 180 seconds; the default value is 180.
Use the timers initiated state command to specify the amount of time that a PCE-initiated SR policy will remain programmed while not being delegated to
any PCE. The range is from 15 to 14440 seconds (24 hours); the default value is 600.
To better understand how the PCE-initiated SR policy timers operate, consider the following example:
PCE A instantiates SR policy P at head-end N.
Head-end N delegates SR policy P to PCE A and programs it in forwarding.
If head-end N detects that PCE A is no longer reachable, then head-end N starts the PCE-initiated orphan and state timers for SR policy P.
If PCE A reconnects before the orphan timer expires, then SR policy P is automatically delegated back to its original PCE (PCE A).
After the orphan timer expires, SR policy P will be eligible for delegation to any other surviving PCE(s).
If SR policy P is not delegated to another PCE before the state timer expires, then head-end N will remove SR policy P from its forwarding.
Enable SR-TE SYSLOG Alarms
Use the logging policy status command to enable SR-TE related SYSLOG alarms.
Router(config-sr-te)# logging policy status
Enable PCEP Reports to SR-PCE
Use the report-all command to enable the PCC to report all SR policies in its database to the PCE.
Router(config-sr-te-pcc)# report-all
Customize MSD Value at PCC
Use the maximum-sid-depthvalue command to customize the Maximum SID Depth (MSD) signaled by PCC during PCEP session establishment.
The default MSD value is equal to the maximum MSD supported by the platform (12).
Router(config-sr-te)# maximum-sid-depthvalue
Note
The platform's SR-TE label imposition capabilities are as follows:
Up to 12 transport labels when no service labels are imposed
Up to 9 transport labels when service labels are imposed
For cases with path computation at PCE, a PCC can signal its MSD to the PCE in the following ways:
During PCEP session establishment – The signaled MSD is treated as a node-wide property.
MSD is configured under segment-routing traffic-eng maximum-sid-depthvalue command
During PCEP LSP path request – The signaled MSD is treated as an LSP property.
On-demand (ODN) SR Policy: MSD is configured using the segment-routing traffic-eng on-demand colorcolormaximum-sid-depthvalue command
Local SR Policy: MSD is configured using the segment-routing traffic-eng policyWORDcandidate-paths preferencepreferencedynamic metric sid-limitvalue command.
Note
If the configured MSD values are different, the per-LSP MSD takes precedence over the per-node MSD.
After path computation, the resulting label stack size is verified against the MSD requirement.
If the label stack size is larger than the MSD and path computation is performed by PCE, then the PCE returns a "no path"
response to the PCC.
If the label stack size is larger than the MSD and path computation is performed by PCC, then the PCC will not install the
path.
Note
A sub-optimal path (if one exists) that satisfies the MSD constraint could be computed in the following cases:
For a dynamic path with TE metric, when the PCE is configured with the pce segment-routing te-latency command or the PCC is configured with the segment-routing traffic-eng te-latency command.
For a dynamic path with LATENCY metric
For a dynamic path with affinity constraints
For example, if the PCC MSD is 4 and the optimal path (with an accumulated metric of 100) requires 5 labels, but a sub-optimal
path exists (with accumulated metric of 110) requiring 4 labels, then the sub-optimal path is installed.
Customize the SR-TE Path Calculation
Use the te-latency command to enable ECMP-aware path computation for TE metric.
Router(config-sr-te)# te-latency
Note
ECMP-aware path computation is enabled by default for IGP and LATENCY metrics.
Configure PCEP Redundancy Type
Use the redundancy pcc-centric command to enable PCC-centric high-availability model. The PCC-centric model changes the default PCC delegation behavior
to the following:
After LSP creation, LSP is automatically delegated to the PCE that computed it.
If this PCE is disconnected, then the LSP is redelegated to another PCE.
If the original PCE is reconnected, then the delegation fallback timer is started. When the timer expires, the LSP is redelegated
back to the original PCE, even if it has worse preference than the current PCE.
Router(config-sr-te-pcc)# redundancy pcc-centric
Configuring Head-End Router as PCEP PCC and Customizing SR-TE Related Options: Example
The following example shows how to configure an SR-TE head-end router with the following functionality:
Enable the SR-TE head-end router as a PCEP client (PCC) with 3 PCEP servers (PCE) with different precedence values. The PCE
with IP address 10.1.1.57 is selected as BEST.
Enable SR-TE related syslogs.
Set the Maximum SID Depth (MSD) signaled during PCEP session establishment to 5.
Enable PCEP reporting for all policies in the node.
RP/0/RSP0/CPU0:Router# show segment-routing traffic-eng pcc ipv4 peer
PCC's peer database:
--------------------
Peer address: 10.1.1.57, Precedence: 150, (best PCE)
State up
Capabilities: Stateful, Update, Segment-Routing, Instantiation
Peer address: 10.1.1.58, Precedence: 200
State up
Capabilities: Stateful, Update, Segment-Routing, Instantiation
Peer address: 10.1.1.59, Precedence: 250
State up
Capabilities: Stateful, Update, Segment-Routing, Instantiation
Configure SR-TE PCE Groups
Table 4. Feature History Table
Feature Name
Release
Description
SR-TE PCE Groups
Release 7.3.2
This feature allows an SR policy to be delegated to a set of PCE servers configured under a PCE group. Multiple PCE groups
can be configured to allow SR policies on the same head-end to be delegated to different sets of PCEs.
With this functionality, an operator can designate sets of PCEs for various purposes, such as PCE-per-service-type or PCE-per-wholesale-customers.
This feature allows an SR policy to be delegated or reported to a set of PCE servers configured under a PCE group. Multiple
PCE groups can be configured to allow different SR policies on the same head-end to be delegated or reported to different
sets of PCEs.
With this functionality, an operator can designate sets of PCEs for various purposes, such as PCE-per-service-type or PCE-per-wholesale-customer.
In the figure below, Router A has a PCEP session with 5 PCEs. The PCEs are configured over 3 PCE groups. PCE1 is in the “default”
group. PCE2 and PCE3 are in the RED group. PCE4 and PCE5 are in the BLUE group.
In case of PCE failure, each candidate path is re-delegated to the next-best PCE within the same PCE group. For example, if
the best PCE in the RED group (PCE2) fails, then all candidate paths in the RED group fallback to the secondary PCE in the
RED group (PCE3). If all the PCEs in the RED group fail, then all candidate paths in the RED group become undelegated; they
are not delegated to the PCEs in the BLUE group. If there are no more available PCEs in the given PCE group, then the outcome
is the same as when there are no available PCEs.
Configure PCE Groups
Use the segment-routing traffic-eng pcc pce address {ipv4ipv4_addr | ipv6ipv6_addr} pce-groupWORD command to configure the PCE groups.
The following example shows how to configure the PCE groups
Assign PCE Group to a Candidate Path or ODN Template
Use the segment-routing traffic-eng policypolicypce-groupWORD command to assign the PCE group to all candidate paths of an SR policy.
Use the segment-routing traffic-eng policypolicycandidate-paths preferenceprefpce-groupWORD command to assign the PCE group to a specific candidate path of an SR policy.
Use the segment-routing traffic-eng on-demand colorcolorpce-groupWORD command to assign the PCE group to on-demand candidate paths triggered by an ODN template.
Note
Only one PCE group can be attached to a given SR policy candidate path.
The following example shows how to configure a policy with all candidate paths delegated/reported to PCEs in the default group:
The following example shows how to configure a policy with a specific candidate path (explicit path) reported to PCEs in the
blue group:
Router(config-sr-te)# policy C
Router(config-sr-te-policy)# color 100 end-point ipv4 192.168.0.4
Router(config-sr-te-policy)# candidate-paths
Router(config-sr-te-policy-path)# preference 100
Router(config-sr-te-policy-path-pref)# pce-group blue
Router(config-sr-te-policy-path-pref)# explicit segment-list SLA
Router(config-sr-te-pp-info)# exit
Router(config-sr-te-policy-path-pref)# exit
Router(config-sr-te-policy-path)# exit
Router(config-sr-te-policy)# exit
The following example shows how to configure an ODN template with on-demand candidate paths delegated/reported to PCEs in
the blue group:
Router(config-sr-te)# on-demand color 10
Router(config-sr-te-color)# pce-group blue
Router(config-sr-te-color)# dynamic
Router(config-sr-te-color-dyn)#pcep
Router(config-sr-te-color-dyn-pce)#
Running Config
segment-routing
traffic-eng
on-demand color 10
dynamic
pcep
!
!
pce-group blue
!
policy A
color 100 end-point ipv4 192.168.0.2
candidate-paths
preference 100
dynamic
pcep
!
!
!
!
!
policy B
color 100 end-point ipv4 192.168.0.3
pce-group red
candidate-paths
preference 100
dynamic
pcep
!
!
!
!
!
policy C
color 100 end-point ipv4 192.168.0.4
candidate-paths
preference 100
explicit segment-list SLA
!
pce-group blue
!
!
!
!
!
end
Verification
Router# show segment-routing traffic-eng pcc ipv4 peer
PCC's peer database:
--------------------
Peer address: 10.1.1.1
Precedence: 10 (best PCE)
State up
Capabilities: Stateful, Update, Segment-Routing, Instantiation
Peer address: 2.2.2.2
Group: red, Precedence 20
State up
Capabilities: Stateful, Update, Segment-Routing, Instantiation
Peer address: 3.3.3.3
Group: red, Precedence 30
State up
Capabilities: Stateful, Update, Segment-Routing, Instantiation
Peer address: 4.4.4.4
Group: blue, Precedence 40
State up
Capabilities: Stateful, Update, Segment-Routing, Instantiation
Peer address: 5.5.5.5
Group: blue, Precedence 50
State up
Capabilities: Stateful, Update, Segment-Routing, Instantiation
Router# show segment-routing traffic-eng policy name srte_c_100_ep_192.168.0.3
SR-TE policy database
---------------------
Color: 100, End-point: 192.168.0.3
Name: srte_c_100_ep_192.168.0.3
Status:
Admin: up Operational: up for 00:13:26 (since Sep 17 22:52:48.365)
Candidate-paths:
Preference: 100 (configuration)
Name: B
Requested BSID: dynamic
PCC info:
Symbolic name: cfg_B_discr_100
PLSP-ID: 2
Protection Type: protected-preferred
Maximum SID Depth: 10
PCE Group: red
Dynamic (pce 192.168.1.4) (valid)
Metric Type: TE, Path Accumulated Metric: 10
Attributes:
Forward Class: 0
Steering labeled-services disabled: no
Steering BGP disabled: no
IPv6 caps enable: no
Invalidation drop enabled: no
BGP SR-TE
BGP may be used to distribute SR Policy candidate paths to an SR-TE head-end. Dedicated BGP SAFI and NLRI have been defined
to advertise a candidate path of an SR Policy. The advertisement of Segment Routing policies in BGP is documented in the IETF
drafthttps://datatracker.ietf.org/doc/draft-ietf-idr-segment-routing-te-policy/
SR policies with IPv4 and IPv6 end-points can be advertised over BGPv4 or BGPv6 sessions between the SR-TE controller and
the SR-TE headend.
The Cisco IOS-XR implementation supports the following combinations:
IPv4 SR policy advertised over BGPv4 session
IPv6 SR policy advertised over BGPv4 session
IPv6 SR policy advertised over BGPv6 session
Configure BGP SR Policy Address Family at SR-TE Head-End
Perform this task to configure BGP SR policy address family at SR-TE head-end:
Procedure
Command or Action
Purpose
Step 1
configure
Step 2
router bgpas-number
Example:
RP/0/RP0/CPU0:router(config)# router bgp 65000
Specifies the BGP AS number and enters the BGP configuration mode, allowing you to configure the BGP routing process.
Specifies either the IPv4 or IPv6 address family and enters address family configuration submode.
Step 9
route-policyroute-policy-name { in | out}
Example:
RP/0/RP0/CPU0:router(config-bgp-nbr-af)# route-policy pass out
Applies the specified policy to IPv4 or IPv6 unicast routes.
Example: BGP SR-TE with BGPv4 Neighbor to BGP SR-TE Controller
The following configuration shows the an SR-TE head-end with a BGPv4 session towards a BGP SR-TE controller. This BGP session
is used to signal both IPv4 and IPv6 SR policies.
router bgp 65000
bgp router-id 10.1.1.1
!
address-family ipv4 sr-policy
!
address-family ipv6 sr-policy
!
neighbor 10.1.3.1
remote-as 10
description *** eBGP session to BGP SRTE controller ***
address-family ipv4 sr-policy
route-policy pass in
route-policy pass out
!
address-family ipv6 sr-policy
route-policy pass in
route-policy pass out
!
!
!
Example: BGP SR-TE with BGPv6 Neighbor to BGP SR-TE Controller
The following configuration shows an SR-TE head-end with a BGPv6 session towards a
BGP SR-TE controller. This BGP session is used to signal both IPv4 and IPv6 SR policies.
router bgp 65000
bgp router-id 10.1.1.1
address-family ipv4 sr-policy
!
address-family ipv6 sr-policy
!
neighbor 3001::10:1:3:1
remote-as 10
description *** eBGP session to BGP SRTE controller ***
address-family ipv4 sr-policy
route-policy pass in
route-policy pass out
!
address-family ipv6 sr-policy
route-policy pass in
route-policy pass out
!
!
!
Traffic Steering
Automated Steering
Automated steering (AS) allows service traffic to be automatically steered onto the required transport SLA path programmed
by an SR policy.
With AS, BGP automatically steers traffic onto an SR Policy based on the next-hop and color of a BGP service route. The color
of a BGP service route is specified by a color extended community attribute. This color is used as a transport SLA indicator,
such as min-delay or min-cost.
When the next-hop and color of a BGP service route matches the end-point and color of an SR Policy, BGP automatically installs
the route resolving onto the BSID of the matching SR Policy. Recall that an SR Policy on a head-end is uniquely identified
by an end-point and color.
When a BGP route has multiple extended-color communities, each with a valid SR Policy, the BGP process installs the route
on the SR Policy giving preference to the color with the highest numerical value.
The granularity of AS behaviors can be applied at multiple levels, for example:
At a service level—When traffic destined to all prefixes in a given service is associated to the same transport path type.
All prefixes share the same color.
At a destination/prefix level—When traffic destined to a prefix in a given service is associated to a specific transport path
type. Each prefix could be assigned a different color.
At a flow level—When flows destined to the same prefix are associated with different transport path types
AS behaviors apply regardless of the instantiation method of the SR policy, including:
Color-only steering is a traffic steering mechanism where a policy is created with given color, regardless of the endpoint.
You can create an SR-TE policy for a specific color that uses a NULL end-point (0.0.0.0 for IPv4 NULL, and ::0 for IPv6 NULL
end-point). This means that you can have a single policy that can steer traffic that is based on that color and a NULL endpoint
for routes with a particular color extended community, but different destinations (next-hop).
Note
Every SR-TE policy with a NULL end-point must have an explicit path-option. The policy cannot have a dynamic path-option (where
the path is computed by the head-end or PCE) since there is no destination for the policy.
You can also specify a color-only (CO) flag in the color extended community for overlay routes. The CO flag allows the selection
of an SR-policy with a matching color, regardless of endpoint Sub-address Family Identifier (SAFI) (IPv4 or IPv6). See Setting CO Flag.
Router# show running-configuration
segment-routing
traffic-eng
policy P1
color 1 end-point ipv4 0.0.0.0
!
policy P2
color 2 end-point ipv6 ::
!
!
!
end
Setting CO Flag
The BGP-based steering mechanism matches BGP color and next-hop with that of an SR-TE policy. If the policy does not exist,
BGP requests SR-PCE to create an SR-TE policy with the associated color, end-point, and explicit paths. For color-only steering
(NULL end-point), you can configure a color-only (CO) flag as part of the color extended community in BGP.
The behavior of the steering mechanism is based on the following values of the CO flags:
co-flag 00
The BGP next-hop and color <N, C> is matched with an SR-TE policy of same <N, C>.
If a policy does not exist, then IGP path for the next-hop N is chosen.
co-flag 01
The BGP next-hop and color <N, C> is matched with an SR-TE policy of same <N, C>.
If a policy does not exist, then an SR-TE policy with NULL end-point with the same address-family as N and color C is chosen.
If a policy with NULL end-point with same address-family as N does not exist, then an SR-TE policy with any NULL end-point
and color C is chosen.
If no match is found, then IGP path for the next-hop N is chosen.
Configuration Example
Router(config)# extcommunity-set opaque overlay-color
Router(config-ext)# 1 co-flag 01
Router(config-ext)# end-set
Router(config)#
Router(config)# route-policy color
Router(config-rpl)# if destination in (5.5.5.1/32) then
Router(config-rpl-if)# set extcommunity color overlay-color
Router(config-rpl-if)# endif
Router(config-rpl)# pass
Router(config-rpl)# end-policy
Router(config)#
Address-Family Agnostic Automated Steering
Address-family agnostic steering uses an SR-TE policy to steer both labeled and unlabeled IPv4 and IPv6 traffic. This feature
requires support of IPv6 encapsulation (IPv6 caps) over IPV4 endpoint policy.
IPv6 caps for IPv4 NULL end-point is enabled automatically when the policy is created in Segment Routing Path Computation
Element (SR-PCE). The binding SID (BSID) state notification for each policy contains an "ipv6_caps" flag that notifies SR-PCE
clients (PCC) of the status of IPv6 caps (enabled or disabled).
An SR-TE policy with a given color and IPv4 NULL end-point could have more than one candidate path. If any of the candidate
paths has IPv6 caps enabled, then all of the remaining candidate paths need IPv6 caps enabled. If IPv6 caps is not enabled
on all candidate paths of same color and end-point, traffic drops can occur.
You can disable IPv6 caps for a particular color and IPv4 NULL end-point using the ipv6 disable command on the local policy. This command disables IPv6 caps on all candidate paths that share the same color and IPv4 NULL
end-point.
The steering of traffic through a Segment Routing (SR) policy is based on the candidate paths of that policy. For a given
policy, a candidate path specifies the path to be used to steer traffic to the policy’s destination. The policy determines
which candidate path to use based on the candidate path’s preference and state. The candidate path that is valid and has the
highest preference is used to steer all traffic using the given policy. This type of policy is called a Per-Destination Policy
(PDP).
Per-Flow Automated Traffic Steering using SR-TE Policies introduces a way to steer traffic on an SR policy based on the attributes
of the incoming packets, called a Per-Flow Policy (PFP).
A PFP provides up to 8 "ways" or options to the endpoint. With a PFP, packets are classified by a classification policy and
marked using internal tags called forward classes (FCs). The FC setting of the packet selects the “way”. For example, this
“way” can be a traffic-engineered SR path, using a low-delay path to the endpoint. The FC is represented as a numeral with
a value of 0 to 7.
A PFP defines an array of FC-to-PDP mappings. A PFP can then be used to steer traffic into a given PDP based on the FC assigned
to a packet.
As with PDPs, PFPs are identified by a {headend, color, endpoint} tuple. The color associated with a given FC corresponds
to a valid PDP policy of that color and same endpoint as the parent PFP. So PFP policies contain mappings of different FCs
to valid PDP policies of different colors. Every PFP has an FC designated as its default FC. The default FC is associated
to packets with a FC undefined under the PFP or for packets with a FC with no valid PDP policy.
The following example shows a per-flow policy from Node1 to Node4:
FC=0 -> shortest path to Node4
IGP shortest path = 16004
FC=1 -> Min-delay path to Node4
SID list = {16002,16004}
The same on-demand instantiation behaviors of PDPs apply to PFPs. For example, an edge node automatically (on demand) instantiates
Per-Flow SR Policy paths to an endpoint by service route signaling. Automated Steering steers the service route in the matching
SR Policy.
Like PDPs, PFPs have a binding SID (BSID). Existing SR-TE automated steering (AS) mechanisms for labeled traffic (via BSID)
and unlabeled traffic (via BGP) onto a PFP is similar to that of a PDP. For example, a packet having the BSID of a PFP as
the top label is steered onto that PFP. The classification policy on the ingress interface marks the packet with an FC based
on the configured class-map. The packet is then steered to the PDP that corresponds to that FC.
Usage Guidelines and Limitations
The following guidelines and limitations apply to the platform when acting as a head-end of a PFP policy:
BGP IPv4 unicast over PFP (steered via ODN/AS) is supported
BGP IPv6 unicast (with IPv4 next-hop [6PE]) over PFP (steered via ODN/AS) is supported
BGP IPv6 unicast (with IPv6 next-hop) over PFP (steered via ODN/AS) is supported
BGP VPNv4 over PFP is not supported
BGP VPNv6 (6VPE) over PFP is not supported
BGP EVPN over PFP is not supported
Pseudowire and VPLS over PFP are not supported
BGP multipath is not supported
BGP PIC is not supported
Labeled traffic (Binding SID) steered over PFP is not supported
When not explicitly configured, FC 0 is the default FC.
A PFP is considered valid as long as its default FC has a valid PDP.
An ingress QoS policy applied to an input interface is used to classify flows and set corresponding forward-class (FC) values.
The following counters are supported:
PFP’s BSID counter (packet, bytes)
Per-FC counters (packet, byte)
Collected from the PDP’s segment-list-per-path egress counters
If an SR policy is used for more than one purpose (as a regular policy as well as a PDP under one or more PFPs), then the
collected counters will represent the aggregate of all contributions. To preserve independent counters, it is recommended
that an SR policy be used only for one purpose.
Inbound packet classification, based on the following fields, is supported:
A color associated with a PFP SR policy cannot be used by a non-PFP SR policy. For example, if a per-flow ODN template for
color 100 is configured, then the system will reject the configuration of any non-PFP SR policy using the same color. You
must assign different color value ranges for PFP and non-PFP SR policies.
Configuring ODN Template for PFP Policies: Example
The following example depicts an ODN template for PFP policies that includes three FCs.
The example also includes the corresponding ODN templates for PDPs as follows:
FC0 (default FC) mapped to color 10 = Min IGP path
FC1 mapped to color 20 = Flex Algo 128 path
FC2 mapped to color 30 = Flex Algo 129 path
segment-routing
traffic-eng
on-demand color 10
dynamic
metric
type igp
!
!
!
on-demand color 20
dynamic
sid-algorithm 128
!
!
on-demand color 30
dynamic
sid-algorithm 129
!
!
on-demand color 1000per-flowforward-class 0 color 10forward-class 1 color 20forward-class 2 color 30
Manually Configuring a PFP and PDPs: Example
The following example depicts a manually defined PFP that includes three FCs and corresponding manually defined PDPs.
The example also includes the corresponding PDPs as follows:
FC0 (default FC) mapped to color 10 = Min IGP path
FC1 mapped to color 20 = Min TE path
FC2 mapped to color 30 = Min delay path
segment-routing
traffic-eng
policy MyPerFlow
color 1000 end-point ipv4 10.1.1.4
candidate-paths
preference 100
per-flowforward-class 0 color 10forward-class 1 color 20forward-class 2 color 30
!
policy MyLowIGP
color 10 end-point ipv4 10.1.1.4
candidate-paths
preference 100
dynamic
metric type igp
!
policy MyLowTE
color 20 end-point ipv4 10.1.1.4
candidate-paths
preference 100
dynamic
metric type te
!
policy MyLowDelay
color 30 end-point ipv4 10.1.1.4
candidate-paths
preference 100
dynamic
metric type delay
Configuring Ingress Classification: Example
An MQC QoS policy is used to classify and mark traffic to a corresponding fowarding class.
The following shows an example of such ingress classification policy:
class-map match-any MinDelay
match dscp 46
end-class-map
!
class-map match-any PremiumHosts
match access-group ipv4 PrioHosts
end-class-map
!
!
policy-map MyPerFlowClassificationPolicy
class MinDelayset forward-class 2
!
class PremiumHostsset forward-class 1
!
class class-default
!
end-policy-map
!
interface GigabitEthernet0/0/0/0
description PE_Ingress_Interface
service-policy input MyPerFlowClassificationPolicy
!
Determining Per-Flow Policy State
A PFP is brought down for the following reasons:
The PDP associated with the default FC is in a down state.
All FCs are associated with PDPs in a down state.
The FC assigned as the default FC is missing in the forward class mapping.
Scenario 1—FC 0 (default FC) is not configured in the FC mappings below:
policy foo
color 1 end-point ipv4 10.1.1.1
per-flow
forward-class 1 color 10
forward-class 2 color 20
Scenario 2—FC 1 is configured as the default FC, however it is not present in the FC mappings:
policy foo
color 1 end-point ipv4 10.1.1.1
per-flow
forward-class 0 color 10
forward-class 2 color 20
forward-class default 1
Using Binding Segments
The binding segment is a local segment identifying an SR-TE policy. Each SR-TE policy is associated with a binding segment
ID (BSID). The BSID is a local label that is automatically allocated for each SR-TE policy when the SR-TE policy is instantiated.
BSID can be used to steer traffic into the SR-TE policy and across domain borders, creating seamless end-to-end inter-domain
SR-TE policies. Each domain controls its local SR-TE policies; local SR-TE policies can be validated and rerouted if needed,
independent from the remote domain’s head-end. Using binding segments isolates the head-end from topology changes in the remote
domain.
Packets received with a BSID as top label are steered into the SR-TE policy associated with the BSID. When the BSID label
is popped, the SR-TE policy’s SID list is pushed.
BSID can be used in the following cases:
Multi-Domain (inter-domain, inter-autonomous system)—BSIDs can be used to steer traffic across domain borders, creating seamless
end-to-end inter-domain SR-TE policies.
Large-Scale within a single domain—The head-end can use hierarchical SR-TE policies by nesting the end-to-end (edge-to-edge)
SR-TE policy within another layer of SR-TE policies (aggregation-to-aggregation). The SR-TE policies are nested within another
layer of policies using the BSIDs, resulting in seamless end-to-end SR-TE policies.
Label stack compression—If the label-stack size required for an SR-TE policy exceeds the platform capability, the SR-TE policy
can be seamlessly stitched to, or nested within, other SR-TE policies using a binding segment.
Explicit Binding SID
Use the binding-sid mplslabel command in SR-TE policy configuration mode to specify the explicit BSID. Explicit BSIDs are allocated from the segment routing
local block (SRLB) or the dynamic range of labels. A best-effort is made to request and obtain the BSID for the SR-TE policy.
If requested BSID is not available (if it does not fall within the available SRLB or is already used by another application
or SR-TE policy), the policy stays down.
Use the binding-sid explicit {fallback-dynamic | enforce-srlb} command to specify how the BSID allocation behaves if the BSID value is not available.
Fallback to dynamic allocation – If the BSID is not available, the BSID is allocated dynamically and the policy comes up:
This example shows how to configure an SR policy to use an explicit BSID of 1000. If the BSID is not available, the BSID is
allocated dynamically and the policy comes up.
Stitching SR-TE Polices Using Binding SID: Example
In this example, three SR-TE policies are stitched together to form a seamless end-to-end path from node 1 to node 10. The
path is a chain of SR-TE policies stitched together using the binding-SIDs of intermediate policies, providing a seamless
end-to-end path.
Table 5. Router IP Address
Router
Prefix Address
Prefix SID/Adj-SID
3
Loopback0 - 10.1.1.3
Prefix SID - 16003
4
Loopback0 - 10.1.1.4
Link node 4 to node 6 - 10.4.6.4
Prefix SID - 16004
Adjacency SID - dynamic
5
Loopback0 - 10.1.1.5
Prefix SID - 16005
6
Loopback0 - 10.1.1.6
Link node 4 to node 6 - 10.4.6.6
Prefix SID - 16006
Adjacency SID - dynamic
9
Loopback0 - 10.1.1.9
Prefix SID - 16009
10
Loopback0 - 10.1.1.10
Prefix SID - 16010
Procedure
Step 1
On node 5, do the following:
Define an SR-TE policy with an explicit path configured using the loopback interface IP addresses of node 9 and node 10.
Define an explicit binding-SID (mpls label 15888) allocated from SRLB for the SR-TE policy.
Define an SR-TE policy with an explicit path configured using the following:
Loopback interface IP address of node 4
Interface IP address of link between node 4 and node 6
Loopback interface IP address of node 5
Binding-SID of the SR-TE policy defined in Step 1 (mpls label 15888)
Note
This last segment allows the stitching of these policies.
Define an explicit binding-SID (mpls label 15900) allocated from SRLB for the SR-TE policy.
Example:
Node 3
segment-routing
traffic-eng
segment-list PATH-4_4-6_5_BSID
index 10 address ipv4 10.1.1.4
index 20 address ipv4 10.4.6.6
index 30 address ipv4 10.1.1.5
index 40 mpls label 15888
!
policy baa
binding-sid mpls 15900
color 777 end-point ipv4 10.1.1.5
candidate-paths
preference 100
explicit segment-list PATH-4_4-6_5_BSID
!
!
!
!
!
!
RP/0/RSP0/CPU0:Node-3# show segment-routing traffic-eng policy color 777
SR-TE policy database
---------------------
Color: 777, End-point: 10.1.1.5
Name: srte_c_777_ep_10.1.1.5
Status:
Admin: up Operational: up for 00:00:32 (since Aug 19 07:40:32.662)
Candidate-paths:
Preference: 100 (configuration) (active)
Name: baa
Requested BSID: 15900
PCC info:
Symbolic name: cfg_baa_discr_100
PLSP-ID: 70
Explicit: segment-list PATH-4_4-6_5_BSID (valid)
Weight: 1, Metric Type: TE
16004 [Prefix-SID, 10.1.1.4]
80005 [Adjacency-SID, 10.4.6.4 - 10.4.6.6]
16005 [Prefix-SID, 10.1.1.5]
15888
Attributes:
Binding SID: 15900 (SRLB)
Forward Class: 0
Steering BGP disabled: no
IPv6 caps enable: yes
Step 3
On node 1, define an SR-TE policy with an explicit path configured using the loopback interface IP address of node 3 and the
binding-SID of the SR-TE policy defined in step 2 (mpls label 15900). This last segment allows the stitching of these policies.
Example:
Node 1
segment-routing
traffic-eng
segment-list PATH-3_BSID
index 10 address ipv4 10.1.1.3
index 20 mpls label 15900
!
policy bar
color 777 end-point ipv4 10.1.1.3
candidate-paths
preference 100
explicit segment-list PATH-3_BSID
!
!
!
!
!
!
RP/0/RSP0/CPU0:Node-1# show segment-routing traffic-eng policy color 777
SR-TE policy database
---------------------
Color: 777, End-point: 10.1.1.3
Name: srte_c_777_ep_10.1.1.3
Status:
Admin: up Operational: up for 00:00:12 (since Aug 19 07:40:52.662)
Candidate-paths:
Preference: 100 (configuration) (active)
Name: bar
Requested BSID: dynamic
PCC info:
Symbolic name: cfg_bar_discr_100
PLSP-ID: 70
Explicit: segment-list PATH-3_BSID (valid)
Weight: 1, Metric Type: TE
16003 [Prefix-SID, 10.1.1.3]
15900
Attributes:
Binding SID: 80021
Forward Class: 0
Steering BGP disabled: no
IPv6 caps enable: yes
L2VPN Preferred Path
EVPN VPWS Preferred Path over SR-TE Policy feature allows you to set the preferred path between the two end-points for EVPN
VPWS pseudowire (PW) using SR-TE policy.
L2VPN VPLS or VPWS Preferred Path over SR-TE Policy feature allows you to set the preferred path between the two end-points
for L2VPN Virtual Private LAN Service (VPLS) or Virtual Private Wire Service (VPWS) using SR-TE policy.
Static Route over Segment Routing Policy
This feature allows you to specify a Segment Routing (SR) policy as an interface type when configuring static routes for MPLS
data planes.
For information on configuring static routes, see the "Implementing Static Routes" chapter in the Routing Configuration Guide for Cisco NCS 540 Series Routers.
Configuration Example
The following example depicts a configuration of a static route for an IPv4 destination over an SR policy.
Router# show run segment-routing traffic-eng
segment-routing
traffic-eng
segment-list sample-SL
index 10 mpls adjacency 10.1.1.102
index 20 mpls adjacency 10.1.1.103
!
policy sample-policy
color 777 end-point ipv4 10.1.1.103
candidate-paths
preference 100
explicit segment-list sample-SL
Router# show run segment-routing traffic-eng
router static
address-family ipv4 unicast
10.1.1.4/32 sr-policy srte_c_200_ep_10.1.1.4
!
!
Verification
Router# show segment-routing traffic-eng policy candidate-path name sample-policy
SR-TE policy database
---------------------
Color: 777, End-point: 10.1.1.103
Name: srte_c_777_ep_10.1.1.103
Status:
Admin: up Operational: up for 00:06:35 (since Jan 17 14:34:35.120)
Candidate-paths:
Preference: 100 (configuration) (active)
Name: sample-policy
Requested BSID: dynamic
PCC info:
Symbolic name: cfg_sample-policy_discr_100
PLSP-ID: 5
Constraints:
Protection Type: protected-preferred
Maximum SID Depth: 9
Explicit: segment-list sample-SL (valid)
Weight: 1, Metric Type: TE
SID[0]: 100102 [Prefix-SID, 10.1.1.102]
SID[1]: 100103 [Prefix-SID, 10.1.1.103]
Attributes:
Binding SID: 24006
Forward Class: Not Configured
Steering labeled-services disabled: no
Steering BGP disabled: no
IPv6 caps enable: yes
Invalidation drop enabled: no
Max Install Standby Candidate Paths: 0
Router# show static sr-policy sample-policy
SR-Policy-Name State Binding-label Interface ifhandle VRF Paths
sample-policy Up 24006 srte_c_777_ep_10.1.1.103 0x2000803c default 10.1.100.100/32
Reference count=1, Internal flags=0x0
Last Policy notification was Up at Jan 17 13:39:46.478
Router# show route 10.1.100.100/32
Routing entry for 10.1.100.100/32
Known via "static", distance 1, metric 0
Installed Jan 17 14:35:40.969 for 00:06:38
Routing Descriptor Blocks
directly connected, via srte_c_777_ep_10.1.1.103
Route metric is 0
No advertising protos.
Router# show route 10.1.100.100/32 detail
Routing entry for 10.1.100.100/32
Known via "static", distance 1, metric 0
Installed Jan 17 14:35:40.969 for 00:06:44
Routing Descriptor Blocks
directly connected, via srte_c_777_ep_10.1.1.103
Route metric is 0
Label: None
Tunnel ID: None
Binding Label: 0x5dc6 (24006)
Extended communities count: 0
NHID: 0x0 (Ref: 0)
Route version is 0x1 (1)
No local label
IP Precedence: Not Set
QoS Group ID: Not Set
Flow-tag: Not Set
Fwd-class: Not Set
Route Priority: RIB_PRIORITY_STATIC (9) SVD Type RIB_SVD_TYPE_LOCAL
Download Priority 3, Download Version 3169
No advertising protos.
Router# show cef 10.1.100.100/32
10.1.100.100/32, version 3169, internal 0x1000001 0x30 (ptr 0x8b1b95d8) [1], 0x0 (0x0), 0x0 (0x0)
Updated Jan 17 14:35:40.971
Prefix Len 32, traffic index 0, precedence n/a, priority 3
gateway array (0x8a92f228) reference count 1, flags 0x2010, source rib (7), 0 backups
[1 type 3 flags 0x48441 (0x8a9d1b68) ext 0x0 (0x0)]
LW-LDI[type=0, refc=0, ptr=0x0, sh-ldi=0x0]
gateway array update type-time 1 Jan 17 14:35:40.971
LDI Update time Jan 17 14:35:40.972
via local-label 24006, 3 dependencies, recursive [flags 0x0]
path-idx 0 NHID 0x0 [0x8ac59f30 0x0]
recursion-via-label
next hop via 24006/1/21
Load distribution: 0 (refcount 1)
Hash OK Interface Address
0 Y recursive 24006/1
Autoroute Include
Table 6. Feature History Table
Feature Name
Release
Description
Autoroute Include
Release 7.3.2
This feature allows you to steer specific IGP (IS-IS, OSPF) prefixes, or all prefixes, over non-shortest paths and to divert
the traffic for those prefixes on to an SR-TE policy.
You can configure SR-TE policies with Autoroute Include to steer specific IGP (IS-IS, OSPF) prefixes, or all prefixes, over
non-shortest paths and to divert the traffic for those prefixes on to the SR-TE policy.
The autoroute include all option applies Autoroute Announce functionality for all destinations or prefixes.
The autoroute include ipv4address option applies Autoroute Destination functionality for the specified destinations or prefixes. This option is supported for
IS-IS only; it is not supported for OSPF.
The Autoroute SR-TE policy adds the prefixes into the IGP, which determines if the prefixes on the endpoint or downstream
of the endpoint are eligible to use the SR-TE policy. If a prefix is eligible, then the IGP checks if the prefix is listed
in the Autoroute Include configuration. If the prefix is included, then the IGP downloads the prefix route with the SR-TE
policy as the outgoing path.
Usage Guidelines and Limitations
Autoroute Include supports three metric types:
Default (no metric): The path over the SR-TE policy inherits the shortest path metric.
Absolute (constant) metric: The shortest path metric to the policy endpoint is replaced with the configured absolute metric.
The metric to any prefix that is Autoroute Included is modified to the absolute metric. Use the autoroute metric constantconstant-metric command, where constant-metric is from 1 to 2147483647.
Relative metric: The shortest path metric to the policy endpoint is modified with the relative value configured (plus or minus).
Use the autoroute metric relativerelative-metric command, where relative-metric is from -10 to +10.
Note
To prevent load-balancing over IGP paths, you can specify a metric that is lower than the value that IGP takes into account
for autorouted destinations (for example, autoroute metric relative -1).
LDP over SR-TE not supported.
LDP to SR-TE interworking is not supported.
Static route over SR-TE is not supported.
Configuration Examples
The following example shows how to configure autoroute include for all prefixes:
Router# configure
Router(config)# segment-routing
Router(config-sr)# traffic-eng
Router(config-sr-te)#policy P1
Router(config-sr-te-policy)# color 20 end-point ipv4 10.1.1.2
Router(config-sr-te-policy)# autoroute include all
Router(config-sr-te-policy)# candidate-paths
Router(config-sr-te-policy-path)# preference 100
Router(config-sr-te-pp-index)# explicit segment-list Plist-1
The following example shows how to configure autoroute include for the specified IPv4 prefixes:
Note
This option is supported for IS-IS only; it is not supported for OSPF.
Policy-Based Tunnel Selection (PBTS) is a mechanism that lets you direct traffic into specific SR-TE policies based on different
classification criteria. PBTS benefits Internet service providers (ISPs) that carry voice and data traffic through their networks,
who want to route this traffic to provide optimized voice service.
PBTS works by selecting SR-TE policies based on the classification criteria of the incoming packets, which are based on the
IP precedence, experimental (EXP), differentiated services code point (DSCP), or type of service (ToS) field in the packet.
Default-class configured for paths is always zero (0). If there is no TE for a given forward-class, then the default-class
(0) will be tried. If there is no default-class, then the packet is dropped. PBTS supports up to seven (exp 1 - 7) EXP values
associated with a single SR-TE policy.
For more information about PBTS, refer to the "Policy-Based Tunnel Selection" section in the
MPLS Configuration Guide for Cisco NCS 540 Series RoutersMPLS Configuration Guide.
Configure Policy-Based Tunnel Selection for SR-TE Policies
The following section lists the steps to configure PBTS for an SR-TE policy.
Note
Steps 1 through 4 are detailed in the "Implementing MPLS Traffic Engineering" chapter of the
MPLS Configuration Guide for Cisco NCS 540 Series RoutersMPLS Configuration Guide.
Define a class-map based on a classification criteria.
Define a policy-map by creating rules for the classified traffic.
Associate a forward-class to each type of ingress traffic.
Enable PBTS on the ingress interface, by applying this service-policy.
Create one or more egress SR-TE policies (to carry packets based on priority) to the destination and associate the egress
SR-TE policy to a forward-class.
Configuration Example
Router(config)# segment-routing traffic-eng
Router(config-sr-te)# policy POLICY-PBTS
Router(config-sr-te-policy)# color 1001 end-point ipv4 10.1.1.20
Router(config-sr-te-policy)# autoroute
Router(config-sr-te-policy-autoroute)# include all
Router(config-sr-te-policy-autoroute)# forward-class 1
Router(config-sr-te-policy-autoroute)# exit
Router(config-sr-te-policy)# candidate-paths
Router(config-sr-te-policy-path)# preference 1
Router(config-sr-te-policy-path-pref)# explicit segment-list SIDLIST1
Router(config-sr-te-policy-path-pref)# exit
Router(config-sr-te-pp-info)# exit
Router(config-sr-te-policy-path-pref)# exit
Router(config-sr-te-policy-path)# preference 2
Router(config-sr-te-policy-path-pref)# dynamic
Router(config-sr-te-pp-info)# metric
Router(config-sr-te-path-metric)# type te
Router(config-sr-te-path-metric)# commit
Running Configuration
segment-routing
traffic-eng
policy POLICY-PBTS
color 1001 end-point ipv4 10.1.1.20
autoroute
include all
forward-class 1
!
candidate-paths
preference 1
explicit segment-list SIDLIST1
!
!
preference 2
dynamic
metric
type te
Miscellaneous
SR Policy Liveness Monitoring
SR Policy liveness monitoring allows you to verify end-to-end traffic forwarding over an SR Policy candidate path by periodically
sending performance monitoring (PM) packets. The head-end router sends PM packets to the SR policy's endpoint router, which
sends them back to the head-end without any control-plane dependency on the endpoint router.
The LDP over Segment Routing Policy feature enables an LDP-targeted adjacency over a Segment Routing (SR) policy between two
routers. This feature extends the existing MPLS LDP address family neighbor configuration to specify an SR policy as the targeted
end-point.
LDP over SR policy is supported for locally configured SR policies with IPv4 end-points.
For more information about MPLS LDP, see the "Implementing MPLS Label Distribution Protocol" chapter in the MPLS Configuration Guide.
For more information about Autoroute, see the Autoroute Announce for SR-TE
section.
Note
Before you configure an LDP targeted adjacency over SR policy name, you need to create the SR policy under Segment Routing
configuration. The SR policy interface names are created internally based on the color and endpoint of the policy. LDP is
non-operational if SR policy name is unknown.
The following functionality applies:
Configure the SR policy – LDP receives the associated end-point address from the interface manager (IM) and stores it in the
LDP interface database (IDB) for the configured SR policy.
Configure the SR policy name under LDP – LDP retrieves the stored end-point address from the IDB and uses it. Use the auto-generated
SR policy name assigned by the router when creating an LDP targeted adjacency over an SR policy. Auto-generated SR policy
names use the following naming convention: srte_c_color_val_ep_endpoint-address. For example, srte_c_1000_ep_10.1.1.2
Configuration Example
/* Enter the SR-TE configuration mode and create the SR policy. This example corresponds to a local SR policy with an explicit path. */
Router(config)# segment-routing
Router(config-sr)# traffic-eng
Router(config-sr-te)# segment-list sample-sid-list
Router(config-sr-te-sl)# index 10 address ipv4 10.1.1.7
Router(config-sr-te-sl)# index 20 address ipv4 10.1.1.2
Router(config-sr-te-sl)# exit
Router(config-sr-te)# policy sample_policy
Router(config-sr-te-policy)# color 1000 end-point ipv4 10.1.1.2
Router(config-sr-te-policy)# candidate-paths
Router(config-sr-te-policy-path)# preference 100
Router(config-sr-te-policy-path-pref)# explicit segment-list sample-sid-list
Router(config-sr-te-pp-info)# end
/* Configure LDP over an SR policy */
Router(config)# mpls ldp
Router(config-ldp)# address-family ipv4
Router(config-ldp-af)# neighbor sr-policy srte_c_1000_ep_10.1.1.2 targeted
Router(config-ldp-af)#
Note
Do one of the following to configure LDP discovery for targeted hellos:
Router# show mpls ldp interface brief
Interface VRF Name Config Enabled IGP-Auto-Cfg TE-Mesh-Grp cfg
--------------- ------------------- ------ ------- ------------ ---------------
Te0/3/0/0/3 default Y Y 0 N/A
Te0/3/0/0/6 default Y Y 0 N/A
Te0/3/0/0/7 default Y Y 0 N/A
Te0/3/0/0/8 default N N 0 N/A
Te0/3/0/0/9 default N N 0 N/A
srte_c_1000_ default YY 0 N/A
Router# show mpls ldp interface
Interface TenGigE0/3/0/0/3 (0xa000340)
VRF: 'default' (0x60000000)
Enabled via config: LDP interface
Interface TenGigE0/3/0/0/6 (0xa000400)
VRF: 'default' (0x60000000)
Enabled via config: LDP interface
Interface TenGigE0/3/0/0/7 (0xa000440)
VRF: 'default' (0x60000000)
Enabled via config: LDP interface
Interface TenGigE0/3/0/0/8 (0xa000480)
VRF: 'default' (0x60000000)
Disabled:
Interface TenGigE0/3/0/0/9 (0xa0004c0)
VRF: 'default' (0x60000000)
Disabled:
Interface srte_c_1000_ep_10.1.1.2 (0x520)VRF: 'default' (0x60000000)Enabled via config: LDP interface
Router# show segment-routing traffic-eng policy color 1000
SR-TE policy database
---------------------
Color: 1000, End-point: 10.1.1.2
Name: srte_c_1000_ep_10.1.1.2
Status:
Admin: up Operational: up for 00:02:00 (since Jul 2 22:39:06.663)
Candidate-paths:
Preference: 100 (configuration) (active)
Name: sample_policy
Requested BSID: dynamic
PCC info:
Symbolic name: cfg_sample_policy_discr_100
PLSP-ID: 17
Explicit: segment-list sample-sid-list (valid)
Weight: 1, Metric Type: TE
16007 [Prefix-SID, 10.1.1.7]
16002 [Prefix-SID, 10.1.1.2]
Attributes:
Binding SID: 80011
Forward Class: 0
Steering BGP disabled: no
IPv6 caps enable: yes
Router# show mpls ldp neighbor 10.1.1.2 detail
Peer LDP Identifier: 10.1.1.2:0
TCP connection: 10.1.1.2:646 - 10.1.1.6:57473
Graceful Restart: No
Session Holdtime: 180 sec
State: Oper; Msgs sent/rcvd: 421/423; Downstream-Unsolicited
Up time: 05:22:02
LDP Discovery Sources:
IPv4: (1)
Targeted Hello (10.1.1.6 -> 10.1.1.2, active/passive)
IPv6: (0)
Addresses bound to this peer:
IPv4: (9)
10.1.1.2 2.2.2.99 10.1.2.2 10.2.3.2
10.2.4.2 10.2.22.2 10.2.222.2 10.30.110.132
11.2.9.2
IPv6: (0)
Peer holdtime: 180 sec; KA interval: 60 sec; Peer state: Estab
NSR: Disabled
Clients: LDP over SR Policy
Capabilities:
Sent:
0x508 (MP: Point-to-Multipoint (P2MP))
0x509 (MP: Multipoint-to-Multipoint (MP2MP))
0x50a (MP: Make-Before-Break (MBB))
0x50b (Typed Wildcard FEC)
Received:
0x508 (MP: Point-to-Multipoint (P2MP))
0x509 (MP: Multipoint-to-Multipoint (MP2MP))
0x50a (MP: Make-Before-Break (MBB))
0x50b (Typed Wildcard FEC)
SR-TE MPLS Label Imposition Enhancement
The SR-TE MPLS Label Imposition Enhancement feature increases the maximum label imposition capabilities of the platform.
In previous releases, the platform supported:
Up to 5 MPLS transport labels when no MPLS service labels are imposed
Up to 3 MPLS transport labels when MPLS service labels are imposed
With the SR-TE MPLS Label Imposition Enhancement feature, the platform supports the following:
Up to 12 MPLS transport labels when no MPLS service labels are imposed
Up to 9 MPLS transport labels when MPLS service labels are imposed
This enhancement is enabled and disabled dynamically, as the label count changes. For example, if a path requires only 3 MPLS
transport labels, the MPLS Label Imposition Enhancement feature is not enabled.
You can disable labeled services for SR-TE policies. The label switching database (LSD) needs to know if labeled services
are disabled on top of an SR-TE policy to perform proper label stack splitting.
Disable Labeled Services per Local Policy
Use the labeled-services disable command to disable steering for labeled services for a configured policy. This configuration applies per policy.
segment-routing
traffic-eng
policy policy name
steering
labeled-services disable
Disable Labeled Services per ODN color
Use the labeled-services disable command to disable steering of labeled-services for on-demand color policies. This configuration applies for a specific ODN
color.
segment-routing
traffic-eng
on-demand color color
steering
labeled-services disable
Disable Labeled Services per Policy Type
Use the labeled-services disable command to disable steering of labeled services for all policies for the following policy types:
all — all policies
local — all locally configured policies
on-demand — all BGP on-demand color policies
bgp-srte — all controller-initiated BGP SR-TE policies
Use the show segment-routing traffic-eng policy command to display SR policy information. The following output shows that steering of labeled services for the on-demand
SR policy are disabled.
SR-TE path re-optimization occurs when the head-end determines that there is a more optimal path available than the one currently
used. For example, in case of a failure along the SR-TE LSP path, the head-end could detect and revert to a more optimal path
by triggering re-optimization.
Re-optimization can occur due to the following events:
The explicit path hops used by the primary SR-TE LSP explicit path are modified
The head-end determines the currently used path-option are invalid due to either a topology path disconnect, or a missing
SID in the SID database that is specified in the explicit-path
A more favorable path-option (lower index) becomes available
For event-based re-optimization, you can specify various delay timers for path re-optimization. For example, you can specify
how long to wait before switching to a reoptimized path
Additionally, you can configure a timer to specify how often to perform reoptimization of policies. You can also trigger an
immediate reoptimization for a specific policy or for all policies.
SR-TE Reoptimization
To trigger an immediate SR-TE reoptimization, use the segment-routing traffic-eng reoptimization command in Exec mode:
Use the all option to trigger an immediate reoptimization for all policies. Use the namepolicy option to trigger an immediate reoptimization for a specific policy.
Configuring SR-TE Reoptimization Timers
Use these commands in SR-TE configuration mode to configure SR-TE reoptimization timers:
timers candidate-path cleanup-delayseconds—Specifies the delay before cleaning up candidate paths, in seconds. The range is from 0 (immediate clean-up) to 86400; the
default value is 120
timers cleanup-delayseconds—Specifies the delay before cleaning up previous path, in seconds. The range is from 0 (immediate clean-up) to 300; the default
value is 10.
timers init-verify-restartseconds—Specifies the delay for topology convergence after the topology starts populating due to a restart, in seconds. The range
is from 10 to 10000; the default is 40.
timers init-verify-startupseconds—Specifies the delay for topology convergence after topology starts populating for due to startup, in seconds. The range is
from 10 to 10000; the default is 300
timers init-verify-switchoverseconds—Specifies the delay for topology convergence after topology starts populating due to a switchover, in seconds. The range
is from 10 to 10000; the default is 60.
timers install-delayseconds—Specifies the delay before switching to a reoptimized path, in seconds. The range is from 0 (immediate installation of new
path) to 300; the default is 10.
timers periodic-reoptimizationseconds—Specifies how often to perform periodic reoptimization of policies, in seconds. The range is from 0 to 86400; the default
is 600.