BGP

About the Juniper to MikroTik series

In the world of network engineering, learning a new syntax for a NOS can be daunting if you need a specific config quickly. Juniper is a popular option for service providers/data centers and is widely deployed across the world.

This is a continuation of the Rosetta stone for network operating systems series. We’ll be working through several protocols over series of posts to help you quickly move between different environments.

While many commands have almost the exact same information, others are as close as possible. Since there isn’t always an exact match, sometimes you may have to run two or three commands to get the information needed.

Using EVE-NG for testing

We conducted all of this testing utilizing EVE-NG and the topology seen below.

Juniper Command	MikroTik Command
show bgp summary	routing bgp peer print brief
show bgp neighbor	routing bgp peer print status
show route advertising-protocol bgp 172.31.254.2	routing bgp advertisements print peer=peer_name
show route receive-protocol bgp 172.31.254.2	ip route print where received-from=peer_name
show route protocol bgp	ip route print where bgp=yes
clear bgp neighbor 172.31.254.2 soft-inbound	routing bgp peer refresh peer_name
clear bgp neighbor 172.31.254.2 soft	routing bgp peer resend peer_name
set routing-options autonomous-system 1	/routing bgp instance set default as=2
set protocols bgp group EBGP type external set protocols bgp group EBGP peer-as 2 set protocols bgp group EBGP neighbor 172.31.254.2	/routing bgp peer add name=PEER-1 remote-address=172.31.254.1 remote-as=1
set policy-options policy-statement REDIS-CONNECTED term 1 from protocol direct set policy-options policy-statement REDIS-CONNECTED term 1 then accept set protocols bgp group EBGP export REDIS-CONNECTED	/routing bgp network add network=100.89.88.0/24 add network=100.89.87.0/24 add network=100.89.86.0/24
set routing-options static route 0.0.0.0/0 discard set protocols bgp group EBGP export SEND-DEFAULT set policy-options policy-statement SEND-DEFAULT term 1 from protocol static set policy-options policy-statement SEND-DEFAULT term 1 from route-filter 0.0.0.0/0 exact set policy-options policy-statement SEND-DEFAULT term 1 then accept	/routing bgp peer add default-originate-always name=PEER-1 remote-address=172.31.254.1 remote-as=1

Examples of the commands above

This is a quick way to get a list of the peers/ASN and their status

[admin@MIKROTIK-BGP] > routing bgp peer print brief

root@JUNOS-BGP> show bgp summary

This next command will show you more information about a peer. In this case we did not specify the peer as there is only one. On a peering router with multiple peers it is recommended to look only at specific peer information to not be overwhelmed with irrelevant information.

[admin@MIKROTIK-BGP] > routing bgp peer print status

root@JUNOS-BGP> show bgp neighbor

The next command allows you to see the prefixes that are sent to your peer as well as the next-hop associated with it.

[admin@MIKROTIK-BGP] > routing bgp advertisements print peer=PEER-1

root@JUNOS-BGP> show route advertising-protocol bgp 172.31.254.2

This next one will show you what routes were received from the peer and the next-hop you will advertise.

[admin@MIKROTIK-BGP] > ip route print where received-from=PEER-1

root@JUNOS-BGP> show route receive-protocol bgp 172.31.254.2

Here we will see the BGP prefixes that are in the routing table – both active and not. On junOS you will see the count for hidden routes in the output but you will not see the hidden entries. This will require the use of “show route protocol bgp hidden” to see the hidden entries. On mikrotik you will see this type of route in the route table as inactive.

[admin@MIKROTIK-BGP] > ip route print where bgp=yes

root@JUNOS-BGP> show route protocol bgp

Configure BGP instance, peering, and originate a default route.

Here is a very basic BGP peering configuration to establish a peer, advertise a few routes, and originate a default route.

Let’s look at some of the differences in the configuration.

It’s worth noting that everything in CAPS was manually defined .

On junOS there is no concept of the “network” command that you might see in MikroTik or Cisco.

To accomplish the same functionality in this example I used a policy-statement named REDIS-CONNECTED that matched any connected route for redistribution.

This is then applied as an export statement into the EBGP peer group. Likewise, there is not a construct for “default-originate”. In order to accomplish the same functionality, we created a static route to discard and exported this to the EBGP peer.

MikroTik BGP Configuration

/routing bgp instance
set default as=2
/routing bgp network
add network=100.89.88.0/24
add network=100.89.87.0/24
add network=100.89.86.0/24
/routing bgp peer
add default-originate=always name=PEER-1 remote-address=172.31.254.1 remote-as=1

Juniper BGP Configuration

set interfaces lo0 unit 0 family inet address 100.99.98.1/24
set interfaces lo0 unit 0 family inet address 100.99.97.1/24
set interfaces lo0 unit 0 family inet address 100.99.96.1/24
set routing-options static route 0.0.0.0/0 discard
set routing-options autonomous-system 1
set protocols bgp group EBGP type external
set protocols bgp group EBGP export REDIS-CONNECTED
set protocols bgp group EBGP export SEND-DEFAULT
set protocols bgp group EBGP peer-as 2
set protocols bgp group EBGP neighbor 172.31.254.2
set policy-options policy-statement REDIS-CONNECTED term 1 from protocol direct
set policy-options policy-statement REDIS-CONNECTED term 1 then accept
set policy-options policy-statement SEND-DEFAULT term 1 from protocol static
set policy-options policy-statement SEND-DEFAULT term 1 from route-filter 0.0.0.0/0 exact
set policy-options policy-statement SEND-DEFAULT term 1 then accept

More to come

There are so many commands to consider for BGP, we probably could have added close to 100, but we decided to list the commands we use most often to start with and will be adding to the list of BGP commands as well as other like OSPF, MPLS, and VLANs in future posts.

If you missed it, take a look at MikroTik’s video on RouterOS v7 routing performance and changes.

Overview

One of the long awaited benefits of RouterOS version 7 is a new routing protocol stack that enables new capabilities and fixes limitations in RouterOSv6 caused by the use of a very old Linux kernel.

The new routing stack in v7 has created quite a buzz in the MikroTik community as lab tests have shown that it’s significantly more efficient in processing large numbers of BGP routes.

The ability to use MikroTik’s new generation of CCR routers with ARM64 to quickly process BGP routes is a blog post all to itself and we’ll tackle that in the future – however, the information below provides a quick look into the performance comparison between ROS v6 and v7.

The new routing stack also paves the way to add a number of features that have been needed for a long time like RPKI and large community support.

Using a lab based on EVE-NG, we’ll take a look at configuration changes and iBGP using the IPv6 AFI with OSPFv3 as the IGP for loopback/next hop reachability. Prior to 7.1beta2, this has been nonfunctional for years due to routing recursion limitations.

v7 Routing Protocol Status

For the most up to date information about features and capabilities in v7, MikroTik created a page that tracks feature status across the different beta releases

https://help.mikrotik.com/docs/display/ROS/v7+Routing+Protocol+Status

Lab design

ROS Version: 7.1beta2 (7.1beta3 was released just before I published this – at some point i’ll update with testing on beta3)
Network Modeling: EVE-NG Pro

OSPFv3

One of the biggest changes in OSPF for both version 2 (IPv4) and version 3 (IPv6) is the consolidation of menus into a single location for OSPF configuration.

In ROSv7, all configuration occurs under /routing/ospf/ and instances can be created for v2 or v3.

Change from ROSv6: OSPF Menu options have changed in ROSv7, this is partly due to combining OPSFv2 and OSPFv3 into a single configuration framework.

OSPF command options in ROSv6 for OSPFv2 and OSPFv3

OSPF command options in ROSv7 for both versions of OSPF

Change from ROSv6: There is a new flag in the IPv6 routing table for ECMP and no flag for RIP

When looking at the new output for the routing table, a few things stand out. ECMP has a new flag using the “+” symbol to denote two or more equal paths.

ECMP in IPv6 is a feature limitation that RouterOSv6 had and this will make it easier to deploy IPv6 networks with MikroTik.

RIP or Routing Internet Protocol is missing from the routing flags. It’s unclear at this point whether RIPv2 or RIP-NG will make it into RouterOSv7 since it’s not used very often anymore in prod networks.

Correcting issues with recursive routing in IPv6.

Being able to use recursive routing for advertising loopbacks and using iBGP with IPv6 has been a limitation of ROSv6 for a long time due to the older linux kernel in use.

Now that ROSv7 has added the initial support for OSPF and BGP, we are able to test IPv6 routing recursion.

Here is a test from PE-1 to PE-2 (2001:db8:101::12) using iBGP

It works!

Change from ROSv6: Using filters in OSPF

One of the first major challenges I had to solve when working with ROSv7 was figuring out why every route available became advertised into OSPF.

At first it looked like a bug, but when I dug deeper, I came across this snippet in the new MikroTik help docs

ROSv7 Basic Routing Examples – RouterOS – MikroTik Documentation

As it turns out, the default behavior is to advertise all routes in the absence of an outbound filter.

The next challenge was figuring out the new filtering syntax.

/routing filter rule
add chain=OSPF-permit-only-configured
/routing filter select-rule
add chain=OSPF-permit-only-configured_select do-where=\
OSPF-permit-only-configured

In order to use a rule in ROSv7, the “/routing filter select-rule” command must be used and reference the filter rule or no action will be taken.

In the example above, only interfaces that have been configured for OSPF will be advertised.

OSPF Config

Here is a summary of the OSPF configuration from the PE-1 router

/routing ospf instance
add name=IPv6 out-filter=OSPF-permit-only-configured_select router-id=\
100.127.0.11 version=3
/routing ospf area
add area-id=0.0.0.0 instance=IPv6 name=area-0
/routing filter rule
add chain=OSPF-permit-only-configured
/routing filter select-rule
add chain=OSPF-permit-only-configured_select do-where=\
OSPF-permit-only-configured
/routing ospf interface
add area=area-0 network=ether1 network-type=point-to-point
add area=area-0 network=ether2 network-type=point-to-point
add area=area-0 network=lo-ospf network-type=broadcast

As with OSPF, BGP saw a change in menu structure.

In ROSv7, BGP configuration has been revamped and is much closer to the style of configuration that Cisco/Juniper use with config elements that can be nested and reused.

Considering all the work that’s being done to improve full table convergence time on ROSv7, this change is a step in the right direction to allow MikroTik to compete with larger network vendors in the area of peering and transit.

Change from ROSv6: BGP Menu options have changed in ROSv7 to accommodate new features like Templates and RPKI

BGP command options in ROSv6

BGP command options in ROSv7

New Feature: BGP Roles

This is a new capability in BGP as of July 2020 and MikroTik was one of the first to have it implemented.

draft-ietf-idr-bgp-open-policy-13 – Route Leak Prevention using Roles in Update and Open messages

The main goal is to classify peerings into different roles that prevent inadvertent route leaks by adopting some basic filtering policies as a component of the role assignment.

Acceptable pairings are:

Here is an example of role types in ROSv7

This is an overview of how the roles deal with route advertisements and filtering.

New Feature: BGP Templates

BGP Templates allow specific settings for a peer connection to be reused in the connection configuration.

This saves quite a bit of time when deploying a large number of iBGP peerings, transit peerings, IX peerings, etc

Options available to set in templates

Here is a BGP template as configured in the lab for this post. The template is referenced by the connection config (aka peer config)

/routing bgp template
add address-families=ipv6 as=8675309 instance=bgp name=ASN-8675309

/routing bgp connection
add local.address=2001:db8:127::11 .role=ibgp-rr-client remote.address=\
2001:db8:127::1 .as=8675309 template=ASN-8675309

New Feature: iBGP ECMP for IPv6

ECMP has been working in ROSv6 for a ling time, but due to kernel limitations, it hasn’t been available in IPv6 due to the problems in routing recursion and making iBGP operational.

Now that routing recursion is fixed for IPv6, ECMP is possible.

ECMP capable IPV6 routes in BGP noted by the new “+” symbol in the routing table for ECMP.

Here is an example of a traceroute to the same prefix that’s using two different paths with ECMP.

BGP Configuration

Here is an overview of the BGP configuration for PE-1

/routing instance
add id=100.127.0.11 name=bgp
/routing bgp template
add address-families=ipv6 as=8675309 instance=bgp name=ASN-8675309
/routing bgp connection
add local.address=2001:db8:127::11 .role=ibgp-rr-client remote.address=\
2001:db8:127::1 .as=8675309 template=ASN-8675309

Lab configurations

All Lab configs for ROSv7 are listed below (tested in 7.1beta2)

PE-1

/interface bridge
add name=lo-bgp
add name=lo-ospf
/interface wireless security-profiles
set [ find default=yes ] supplicant-identity=MikroTik
/ip vrf
add list=all name=main
/routing instance
add id=100.127.0.11 name=bgp
/routing bgp template
add address-families=ipv6 as=8675309 instance=bgp name=ASN-8675309
/routing ospf instance
add name=IPv6 out-filter=OSPF-permit-only-configured_select router-id=\
    100.127.0.11 version=3
/routing ospf area
add area-id=0.0.0.0 instance=IPv6 name=area-0
/ip dhcp-client
add disabled=no interface=ether1
/ipv6 address
add address=2001:db8:126:1::2/126 advertise=no interface=ether1
add address=2001:db8:127::11/128 advertise=no interface=lo-ospf
add address=2001:db8:101::11/128 advertise=no interface=lo-bgp
add address=2001:db8:126:3::2/126 advertise=no interface=ether2
add address=2001:db8:a1a::1 interface=ether4
/routing bgp connection
add local.address=2001:db8:127::11 .role=ibgp-rr-client remote.address=\
    2001:db8:127::1 .as=8675309 template=ASN-8675309
/routing filter rule
add chain=OSPF-permit-only-configured
/routing filter select-rule
add chain=OSPF-permit-only-configured_select do-where=\
    OSPF-permit-only-configured
/routing ospf interface
add area=area-0 network=ether1 network-type=point-to-point
add area=area-0 network=ether2 network-type=point-to-point
add area=area-0 network=lo-ospf network-type=broadcast
/system identity
set name=PE-1

CORE-1

/interface bridge
add name=lo-bgp
add name=lo-ospf
/interface wireless security-profiles
set [ find default=yes ] supplicant-identity=MikroTik
/ip vrf
add list=all name=main
/routing instance
add id=100.127.0.1 name=bgp
/routing bgp template
add address-families=ipv6 as=8675309 instance=bgp name=ASN-8675309
/routing ospf instance
add name=IPv6 router-id=100.127.0.1 version=3
/routing ospf area
add area-id=0.0.0.0 instance=IPv6 name=area-0
/ip dhcp-client
add disabled=no interface=ether1
/ipv6 address
add address=2001:db8:126:1::1/126 advertise=no interface=ether1
add address=2001:db8:127::1/128 advertise=no interface=lo-ospf
add address=2001:db8:126:2::1/126 advertise=no interface=ether2
add address=2001:db8:126:3::1/126 advertise=no interface=ether3
add address=2001:db8:101::1/128 advertise=no interface=lo-bgp
add address=2001:db8:126:4::1/126 advertise=no interface=ether4
/routing bgp connection
add listen=yes local.address=2001:db8:127::1 .role=ibgp-rr remote.address=\
    2001:db8:127::11 template=ASN-8675309
add listen=yes local.address=2001:db8:127::1 .role=ibgp-rr remote.address=\
    2001:db8:127::12 template=ASN-8675309
/routing filter rule
add chain=OSPFv3-in match-prfx-value=dst<equal>2001:db8:101::/128
add chain=OSPFv3-in match-prfx-value=dst<equal>2001:db8:101::/128
/routing ospf interface
add area=area-0 network=ether1 network-type=point-to-point
add area=area-0 network=ether2 network-type=point-to-point
add area=area-0 network=ether3 network-type=point-to-point
add area=area-0 network=lo-ospf network-type=broadcast
add area=area-0 network=ether4 network-type=point-to-point
/system identity
set name=CORE-1

PE-2

/interface bridge
add name=lo-bgp
add name=lo-ospf
/interface wireless security-profiles
set [ find default=yes ] supplicant-identity=MikroTik
/ip vrf
add list=all name=main
/routing instance
add id=100.127.0.12 name=bgp
/routing bgp template
add address-families=ipv6 as=8675309 instance=bgp name=ASN-8675309
/routing ospf instance
add name=IPv6 out-filter=OSPF-permit-only-configured_select router-id=\
    100.127.0.12 version=3
/routing ospf area
add area-id=0.0.0.0 instance=IPv6 name=area-0
/ip dhcp-client
add disabled=no interface=ether1
/ipv6 address
add address=2001:db8:126:2::2/126 advertise=no interface=ether1
add address=2001:db8:127::12/128 advertise=no interface=lo-ospf
add address=2001:db8:101::12/128 advertise=no interface=lo-bgp
add address=2001:db8:a1b::1 interface=ether4
add address=2001:db8:126:4::2/126 advertise=no interface=ether2
/routing bgp connection
add local.address=2001:db8:127::12 .role=ibgp-rr-client remote.address=\
    2001:db8:127::1 .as=8675309 template=ASN-8675309
/routing filter rule
add chain=OSPF-permit-only-configured
/routing filter select-rule
add chain=OSPF-permit-only-configured_select do-where=\
    OSPF-permit-only-configured
/routing ospf interface
add area=area-0 network=ether1 network-type=point-to-point
add area=area-0 network=lo-ospf network-type=broadcast
add area=area-0 network=ether2 network-type=point-to-point
/system identity
set name=PE-2

Category: BGP

Juniper to MikroTik – BGP commands