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Étiquette : RTR

RPKI – More Routinator …

Following previous article on RPKI – Use Routinator with Cisco IOS-XR, you will find here some tips to run routinator in a production environnement.

routinator configuration

Routinator can be started with a configuration file as below :

routinator@srv-rpki01:~$ cat .routinator.conf
# Routinator Configuration
# The configuration file is a TOML file. It consists of a sequence of
# key-value pairs, each on its own line. Strings are to be enclosed in
# double quotes. Lists of values can be given by enclosing a
# comma-separated sequence of these values in square brackets.
# See for detailed information on the
# format.
# This file contains all configuration settings with explanations and their
# default values.

# Repository directory
# This is where Routinator stores the local copy of the RPKI repository.
# Any relative path is interpreted with respect to the directory this config
# lives in.
# This setting is mandatory.
repository-dir = "/home/routinator/.rpki-cache/repository/"

# Trust Anchor Locator (TAL) directory
# All the files with the extension ".tal" in this directory are treated as
# trust anchor locators for RPKI validation.
# A relative path is interpreted with respect to the directory this config
# lives in.
# This setting is mandatory.
tal-dir = "/home/routinator/.rpki-cache/tals/"

# Local exceptions files
# This settings contains a array of paths to files that contain local
# exceptions. The files are JSON files according to RFC 8416 (aka SLURM).
exceptions = [

# Strict mode
# If strict mode, Routinator will stick to the requirements in the respective
# RFCs very strictly. See
# for information on what is allowed when strict mode is off.
#strict = false

# Rsync command
# This is the command to run as rsync. This is only command, no options.
rsync-command = "rsync"

# Rsync arguments
# This is a list of arguments to give to rsync.
#rsync-args = []

# Number of parallel rsync commands
# This is the maximum number of rsync commands that are run in parallel.
# We are not sure, if the current default is any good. Some feedback whether
# it is causing trouble or whether a higher value would even be fine is very
# much appreciated.
#rsync-count = 4

# Number of validation threads
# The number of threads that are used for validating the repository. The
# default value is the number of CPUs.
validation-threads = 2

# Refresh interval
# How often the repository should be updated and validated in RTR mode.
# Specifically, this is the number of seconds the process will wait after
# having finished validation before starting the next update.
# The default is the value indirectly recommended by RFC 8210.
refresh = 3600

# RTR retry interval
# This is the time an RTR client is told to wait before retrying a failed
# query in seconds.
retry = 600

# RTR expire interval
# This is the time an RTR client is told to keep using data if it can't
# refresh it.
# default = 7200 (2h) set to 6h
expire = 21600

# History size
# The number of deltas to keep. If a client requests an older delta, it is
# served the entire set again.
# There was no particular reason for choosing the default ...
history-size = 10

# Listen addresses for RTR TCP transport.
# This is an array of strings, each string a socket address of the form
# "address:port" with IPv6 address in square brackets.
rtr-listen = [""]

# Listen addresses for Prometheus HTTP monitoring endpoint.
# This is an array of strings, each string a socket address of the form
# "address:port" with IPv6 address in square brackets.
# Port 9556 is allocated for the routinator exporter.
http-listen = [""]

# Log level
# The maximum log level ("off", "error", "warn", "info", or "debug") for
# which to log messages.
log-level = "info"

# Log target
# Where to log to. One of "stderr" for stderr, "syslog" for syslog, or "file"
# for a file. If "file" is given, the "log-file" field needs to be given, too.
# Can also be "default", in which case "syslog" is used in daemon mode and
# "stderr" otherwise
log = "file"

# Syslog facility
# The syslog facility to log to if syslog logging is used.
#syslog-facility = "daemon"

# Log file
# The path to the file to log to if file logging is used. If the path is
# relative, it is relative to the directory this config file lives in.
log-file = "/home/routinator/logs/routinator.log"

# Daemon PID file
# When in daemon mode, Routinator can store its process ID in a file given
# through this entry. It will keep that file locked while running. By default,
# no pid file is used.
pid-file = "/home/routinator/"

# Daemon working directory
# If this entry is given, the daemon process will change its working directory
# to this directory. Otherwise it remains in the current directory.
#working-dir = "/home/routinator/"

# Daemon Chroot
# If this entry is given, the daemon process will change its root directory to
# this directory. Startup will fail if any of the other directories given is
# not within this directory.
#chroot = ...

Please note the file /home/routinator/.exceptions.slurm will be used to create ROA/ROV exceptions.

Example below shows how to drop ROA received from TAL for ASN 65551, then create after local ROA exceptions for the prefix TEST-NET2, with a maxPrefixLength /24 and from ASN 65551.

routinator@srv-rpki01:~$ cat .exceptions.slurm
  "slurmVersion": 1,
  "validationOutputFilters": {
   "prefixFilters": [
        "asn": 65551,
        "comment": "All VRPs matching our ASN 65551 as we do assertions below"
   "bgpsecFilters": [
  "locallyAddedAssertions": {
   "prefixAssertions": [
      	"asn": 65551,
      	"prefix": "",
      	"maxPrefixLength": 24,
      	"comment": "IPv4 TEST-NET2"
   "bgpsecAssertions": [

Doing so will permit to create an ROA exception, distributed to your routers running RPKI. It will allow to permit this prefix to be considered as valid on your BGP infrastructure / routers running ROV, despite TAL valid, invalid and/or unknown RPKI state.

Note : this is not propagated to TAL. And it should used only in emergency for certain circumstances. I create a temporary hack deployed by Ansible for invalid ROAs which are not well declared by the originator (yes it happen). It could occur for some prefixes when moving property of some blocks or moving from RIR to another. In this case, unwanted behaviour for your customer can occur and you need to create temporary exceptions to keep the route in your BGP RIB.

If you need more details on how SLURM are defined and used, please take a look on :

systemd and routinator

To start automatically routinator with systemd, you just have to create the following unit file :

root@srv-rpki01:~# cat /etc/systemd/system/routinator.service
Description=Routinator RPKI daemon



ExecStart=/home/routinator/.cargo/bin/routinator server --pid-file /home/routinator/ --user routinator


Then enable and start it :

root@srv-rpki01:~# systemctl start routinator.service && tail -f /home/routinator/logs/*

root@srv-rpki01:~# systemctl status routinator.service
● routinator.service - Routinator RPKI daemon
   Loaded: loaded (/etc/systemd/system/routinator.service; enabled; vendor preset: enabled)
   Active: active (running) since Mon 2020-01-13 12:31:40 UTC; 2 weeks 3 days ago
 Main PID: 13469 (routinator)
    Tasks: 9 (limit: 2361)
   CGroup: /system.slice/routinator.service
           └─13469 /home/routinator/.cargo/bin/routinator server --pid-file /home/routinator/ --user routinator

Jan 13 12:31:40 srv-rpki01 systemd[1]: Started Routinator RPKI daemon.

root@srv-rpki01:~# systemctl daemon-reload

root@srv-rpki01:~# systemctl enable routinator.service

Next : How to monitor Routinator !


RPKI – Use Routinator with Cisco IOS-XR

While digging about how to drop invalid ROA, I tested Routinator setup. Installing Routinator RPKI-RTR Cache validator is pretty easy using their documentation.

curl -sSf | sh
source ~/.cargo/env
cargo install routinator
routinator init
# Follow instructions provided
routinator server --rtr

When this is done, you can then start configuration on the router. I almost work daily on Cisco IOS-XR platform (on ASR9K hardware). And in fact, there are some tricks to do for this to work, as IOS-XR support only RTR protocol over Secure Transport (SSH for example).

Configure RPKI server and secure transport

On the RPKI server, you should create a new user for SSH secure transport for RTR protocol

adduser rpki

Then you should setup a sub-system on sshd_config

# cat /etc/ssh/sshd_config
PermitRootLogin no
# needed for user RPKI
PasswordAuthentication yes
# Define an `rpki-rtr` subsystem which is actually `netcat` used to proxy STDIN/STDOUT to a running `routinator rtrd -a -l`
Subsystem       rpki-rtr        /bin/nc 3323
# Certain routers may use old KEX algos and Ciphers which are no longer enabled by default.
# These examples are required in IOS-XR 5.3 but no longer enabled by default in OpenSSH 7.3
Ciphers +3des-cbc
KexAlgorithms +diffie-hellman-group1-sha1

When you’ve done this, we can move on the IOS-XR side to setup RPKI server.

Configure IOS-XR RPKI server

To configure IOS-XR, you’ll need first to setup RPKI server using SSH username and password (which will be not shown after commit in the configuration).

router bgp 64567
 rpki server
  username rpki
  password rpkipassword
  transport ssh port 22
  refresh-time 3600
  response-time 600

When this is done, you will need to setup SSH client, as yes, IOS-XR ssh client is still using Cisco SSH v1.99 protocol version ! You can also setup vrf source and interface source if needed. Take care, some releases, like eXR (IOS-XR x64 version) in 6.1.x will not support ssh client v2 option …

ssh client v2
ssh client vrf myVRF
ssh client source-interface Loopback10

Then after, connection should be established


RP/0/RP0/CPU0:router#sh bgp rpki summary

RPKI cache-servers configured: 1
RPKI database
  Total IPv4 net/path: 97550/105601
  Total IPv6 net/path: 15818/17522

RP/0/RP0/CPU0:router#sh bgp rpki server

RPKI Cache-Server
  Transport: SSH port 22
  Connect state: ESTAB
  Conn attempts: 1
  Total byte RX: 4080600
  Total byte TX: 7652
SSH information
  Username: rpki
  Password: *****
  SSH PID: 674259340
RPKI-RTR protocol information
  Serial number: 727
  Cache nonce: 0x79CA
  Protocol state: DATA_END
  Refresh  time: 3600 seconds
  Response time: 600 seconds
  Purge time: 60 seconds
  Protocol exchange
    ROAs announced: 131296 IPv4   23152 IPv6
    ROAs withdrawn:  25695 IPv4    5630 IPv6
    Error Reports :      0 sent       0 rcvd

Then now, you can enable ROV on IOS-XR, based on the RPKI table

RP/0/RP0/CPU0:router#sh bgp rpki table

  Network               Maxlen          Origin-AS         Server            24              13335               24              13335           29              9583                24              4788               24              65037              24              24514   

Enable Route Origin Validation on IOS-XR

As stated in the Cisco documentation : BGP Prefix Origin Validation Based on RPKI, and thanks to a Cisco SE, I’ve discover that “Starting from Release 6.5.1, origin-as validation is disabled by default, you must enable it per address family”.

router bgp 64567
 address-family ipv4 unicast
  bgp origin-as validation enable
  bgp bestpath origin-as use validity
  bgp bestpath origin-as allow invalid
 address-family ipv6 unicast
  bgp origin-as validation enable
  bgp bestpath origin-as use validity
  bgp bestpath origin-as allow invalid

In fact, if you enable “bgp bestpath origin-as use validity“, you should take care on how the BGP Best Path Selection is modified. See Patel NANOG presentation about Cisco’s Origin Validation Implementation. Reading this, BGP will prefer Valid pathes over Not-known path (over Invalid ones if you allow it). It means eBGP paths received on iBGP sessions will probably will be removed sooner from Best Path Selection algorithm, even if Local-Pref or Med is preferred on iBGP received paths due to a higher priority on the tie break for RPKI ROV.

bgp bestpath origin-as use validity behavior

During BGP best path selection, the default behavior, if neither of the above options is configured, is that the system will prefer prefixes in the following order:
Those with a validation state of valid.
Those with a validation state of not found.
Those with a validation state of invalid (which, by default, will not be installed in the routing table).
These preferences override metric, local preference, and other choices made during the bestpath computation.

You should use the useful command to understand and check impact.

RP/0/RP0/CPU0:router# sh bgp bestpath-compare

On my side, I prefer to drop invalid using route policies on the eBGP sessions, so I can keep control. So I do not use bestpath validation :

router bgp 64567 bgp origin-as validation time 30
router bgp 64567 address-family ipv4 unicast bgp origin-as validation enable
router bgp 64567 address-family ipv4 unicast bgp bestpath origin-as allow invalid
router bgp 64567 address-family ipv6 unicast bgp origin-as validation enable
router bgp 64567 address-family ipv6 unicast bgp bestpath origin-as allow invalid

To drop invalid on each eBGP sessions, I simply use the following standard route-policy :

  if validation-state is invalid then

This RPL is called at start when dropping some Bogons Prefixes (aka Martians) or ASN.

route-policy RP_EBGP_PEER_IN

Then you’ve done 😉 Next article : how to setup Routinator with configuration file and SLURM exceptions file.