Manual:CRS3xx VLANs with Bonds
This page will show how to configure multiple switches to use bonding interfaces and port based VLANs, it will also show a working example with a DHCP-Server, interVLAN routing, management IP and invalid VLAN filtering configuration.
In this setup SwitchA and SwitchC will tag all traffic from ports ether1-ether8 to VLAN ID 10, ether9-ether16 to VLAN ID 20, ether17-ether24 to VLAN ID 30. Management will only be possible if user is connecting with tagged traffic with VLAN ID 99 from ether1 on SwitchA or SwitchB, connecting to all devices will also be possible from the router using tagged traffic with VLAN ID 99. SFP+ ports in this setup are going to be used as VLAN trunk ports while being in a bond to create a LAG interface.
All switches in this setup require that all used ports are switched together (except for ports that are going to be part of a bonding interface). Use these commands on SwitchA and SwitchC:
/interface bridge add name=bridge vlan-filtering=no /interface bridge port add bridge=bridge interface=ether1 pvid=10 add bridge=bridge interface=ether2 pvid=10 add bridge=bridge interface=ether3 pvid=10 add bridge=bridge interface=ether4 pvid=10 add bridge=bridge interface=ether5 pvid=10 add bridge=bridge interface=ether6 pvid=10 add bridge=bridge interface=ether7 pvid=10 add bridge=bridge interface=ether8 pvid=10 add bridge=bridge interface=ether9 pvid=20 add bridge=bridge interface=ether10 pvid=20 add bridge=bridge interface=ether11 pvid=20 add bridge=bridge interface=ether12 pvid=20 add bridge=bridge interface=ether13 pvid=20 add bridge=bridge interface=ether14 pvid=20 add bridge=bridge interface=ether15 pvid=20 add bridge=bridge interface=ether16 pvid=20 add bridge=bridge interface=ether17 pvid=30 add bridge=bridge interface=ether18 pvid=30 add bridge=bridge interface=ether19 pvid=30 add bridge=bridge interface=ether20 pvid=30 add bridge=bridge interface=ether21 pvid=30 add bridge=bridge interface=ether22 pvid=30 add bridge=bridge interface=ether23 pvid=30 add bridge=bridge interface=ether24 pvid=30
Bonding interfaces are used when a larger amount of bandwidth is required, this is done by creating a link aggregation group, which also provides hardware automatic failover and load balancing for CRS3xx series switches. By adding two 10Gbps interfaces to a bonding, you can increase the theoretical bandwidth limit to 20Gbps. Make sure that all bonded interfaces are linked to the same speed rates.
To create a 20Gbps bonding interface from sfp-sfpplus1 and sfp-sfpplus2 between SwitchA to SwitchB and between SwitchC to SwitchB, use these commands on SwitchA and SwitchC:
/interface bonding add mode=802.3ad name=bond_1-2 slaves=sfp-sfpplus1,sfp-sfpplus2
To create a 40Gbps bonding interface between SwitchB and the Router and 20Gbps bonding interfaces between SwitchA and SwitchC, use these commands on SwitchB:
/interface bonding add mode=802.3ad name=bond_1-2 slaves=sfp-sfpplus1,sfp-sfpplus2 add mode=802.3ad name=bond_3-4 slaves=sfp-sfpplus3,sfp-sfpplus4 add mode=802.3ad name=bond_5-6-7-8 slaves=sfp-sfpplus5,sfp-sfpplus6,sfp-sfpplus7,sfp-sfpplus8
When all the bonding interfaces are create, they must be added as a bridge port. Use these commands on SwitchA and SwitchB:
/interface bridge port add bridge=bridge interface=bond_1-2
Add all bonding interfaces to a single bridge on SwitchB by using these commands on SwitchB:
/interface bridge port add bridge=bridge interface=bond_1-2 add bridge=bridge interface=bond_3-4 add bridge=bridge interface=bond_5-6-7-8
In our case the Router needs a software based bonding interface, use these commands on Router:
/interface bonding add mode=802.3ad name=bond_1-2-3-4 slaves=sfp-sfpplus1,sfp-sfpplus2,sfp-sfpplus3,sfp-sfpplus4
It is very useful to create a management interface and assign an IP address to it in order to preserve access to the switch. This is also very useful when updating your switches since such traffic to the switch will be blocked when enabling invalid VLAN filtering.
Create a VLAN interface on SwitchA, SwitchB, SwitchC:
/interface vlan add interface=bridge name=MGMT vlan-id=99
The Router needs the VLAN interface to be created on the bonding interface, use these commands to create a VLAN interface on Router':
/interface vlan add interface=bond_1-2-3-4 name=MGMT vlan-id=99
For this guide we are going to use these addresses for each device:
Add an IP address for each device on the VLAN interface (change X to appropriate number):
/ip address add address=192.168.99.X/24 interface=MGMT
Don't forget to add the default gateway and specify a DNS server:
/ip route add gateway=192.168.99.1 /ip dns set servers=192.168.99.1
Add the IP address on the Router:
/ip address add address=192.168.99.1/24 interface=MGMT
Invalid VLAN filtering
Enable ingress traffic filtering for more security, use these commands on SwitchA, SwitchB and SwitchC:
/interface bridge port set [f] ingress-filtering=yes
Since most ports on SwitchA and SwitchC are going to be access ports, you can set all ports to accept only certain types of packets, in this case we will want SwitchA and SwitchC to only accept untagged packets, use these commands on SwitchA and SwitchC:
/interface bridge port set [f] frame-types=admit-only-untagged-and-priority-tagged
There is an exception for frame types on SwitchA and SwitchB, in this setup access to management port is required from ether1, bonding interfaces require that only tagged traffic can be forwarded. Use these commands on SwitchA and SwitchC:
/interface bridge port set [find where interface=ether1] frame-types=admit-all set [find where interface=bond_1-2] frame-types=admit-only-vlan-tagged
On SwitchB only tagged packets should be forwarded, use these commands on SwitchB:
/interface bridge port set [f] frame-types=admit-only-vlan-tagged
To create InterVLAN routing, VLAN interface for each customer VLAN ID must be created on the router and must have an IP address assigned to it. The VLAN interface must be created on the bonding interface created previously.
Use these commands on the Router:
/interface vlan add interface=bond1 name=Vlan10 vlan-id=10 add interface=bond1 name=Vlan20 vlan-id=20 add interface=bond1 name=Vlan30 vlan-id=30 add interface=bond1 name=Vlan40 vlan-id=40 /ip address add address=192.168.10.1/24 interface=Vlan10 add address=192.168.20.1/24 interface=Vlan20 add address=192.168.30.1/24 interface=Vlan30 add address=192.168.40.1/24 interface=Vlan40
To get the DHCP-Server working for each VLAN ID, the server must be set up on the previously created VLAN interfaces (one server for each VLAN ID). Preferably each VLAN ID should have its own subnet and its own IP pool. DNS Server could be specified as the router's IP address for particular VLAN ID or a global DNS Server could be used, but this address must be reachable.
To set up the DHCP-Server, use these commands on the Router:
/ip pool add name=Vlan10_pool ranges=192.168.10.100-192.168.10.200 add name=Vlan20_pool ranges=192.168.20.100-192.168.20.200 add name=Vlan30_pool ranges=192.168.30.100-192.168.30.200 add name=Vlan40_pool ranges=192.168.40.100-192.168.40.200 /ip dhcp-server add address-pool=Vlan10_pool disabled=no interface=Vlan10 name=Vlan10_DHCP add address-pool=Vlan20_pool disabled=no interface=Vlan20 name=Vlan20_DHCP add address-pool=Vlan30_pool disabled=no interface=Vlan30 name=Vlan30_DHCP add address-pool=Vlan40_pool disabled=no interface=Vlan40 name=Vlan40_DHCP /ip dhcp-server network add address=192.168.10.0/24 dns-server=192.168.10.1 gateway=192.168.10.1 add address=192.168.20.0/24 dns-server=192.168.20.1 gateway=192.168.20.1 add address=192.168.30.0/24 dns-server=192.168.30.1 gateway=192.168.30.1 add address=192.168.40.0/24 dns-server=192.168.40.1 gateway=192.168.40.1
In case the router's DNS Server is being used, don't forget to allow remote requests and make sure DNS Servers are configured on the router. Use these commands on the Router:
/ip dns set allow-remote-requests=yes servers=220.127.116.11
Don't forget to create NAT, assuming that sfp-sfpplus1 is used as WAN port, use these commands on the Router:
/ip firewall nat add action=masquerade chain=srcnat out-interface=sfp-sfpplus1
One can increase the total throughput in such a setup by enabling jumbo frames. This reduces the packet overhead by increasing the Maximum Transmission Unit (MTU). If a device in your network does not support jumbo frames, then it will not benefit from a larger MTU. Usually the whole network does not support jumbo frames, but you can still benefit when sending data between devices that support jumbo frames, including all switches in the path.
In this case, if clients behind SwitchA and client behind SwitchC supports jumbo frames, then enabling jumbo frames will be beneficial. Before enabling jumbo frames, determine the MAX-L2MTU by using this command:
[admin@MikroTik] > /interface> print Flags: D - dynamic, X - disabled, R - running, S - slave # NAME TYPE ACTUAL-MTU L2MTU MAX-L2MTU 0 R ether1 ether 1500 1580 4064
When MAX-L2MTU is determined, choose the MTU size depending on the traffic on your network, use this command on SwitchA, SwitchB and SwitchC:
/interface ethernet set [ find ] l2mtu=4064 mtu=4040