CCNP Equal Cost Multi Path (ECMP)
From Datateknik
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Ensure that the ARP is resolved between the router and the node being pinged. | Ensure that the ARP is resolved between the router and the node being pinged. | ||
### END ### | ### END ### | ||
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=NEXT= | =NEXT= | ||
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hej. | hej. | ||
Revision as of 13:30, 2 December 2016
Intro
Contents |
Routing
Verification of Configuration
Leaf-1#show ip route
Gateway of last resort is not set
10.0.0.0/8 is variably subnetted, 10 subnets, 2 masks
C 10.1.1.0/24 is directly connected, gig0/1
L 10.1.1.1/32 is directly connected, gig0/1
C 10.2.2.0/24 is directly connected, gig0/2
L 10.2.2.1/32 is directly connected, gig0/2
C 10.3.3.0/24 is directly connected, gig0/3
L 10.3.3.1/32 is directly connected, gig0/3
Note above that we have one subnet for each spine switch
O 10.2.0.0/16 [110/2] via 10.1.1.3, 1d19h, gig0/1 ← Assuming we add summary
[110/2] via 10.2.2.3, 1d19h, gig0/2
[110/2] via 10.3.3.3, 1d19h, gig0/3
O 10.3.0.0/16 [110/2] via 10.1.1.3, 1d19h, gig0/1 ← Assuming we add summary
[110/2] via 10.2.2.3, 1d19h, gig0/2
[110/2] via 10.3.3.3, 1d19h, gig0/3
O 10.4.0.0/16 [110/2] via 10.1.1.3, 1d19h, gig0/1 ← Assuming we add summary
[110/2] via 10.2.2.3, 1d19h, gig0/2
[110/2] via 10.3.3.3, 1d19h, gig0/3
Note above that we have three equal cost paths to servers on other leafs, the same amount of parallel paths as we have spines.
C 10.1.10.0/30 is directly connected, gig0/10 L 10.1.10.1/32 is directly connected, gig0/10 C 10.1.11.0/30 is directly connected, gig0/11 L 10.1.11.1/32 is directly connected, gig0/11 C 10.1.12.0/30 is directly connected, gig0/12 L 10.1.12.1/32 is directly connected, gig0/12
Note above that every server is in its own LAN, with 10.$leaf.$down_port.1 as default-gateway. ($y ??)
Now we check the hash-buckets for load balancing over spines/between leafs.
Leaf-4#show ip cef 10.5.0.0 internal
10.5.0.0/16, epoch 3, RIB[I], refcount 6, per-destination sharing
sources: RIB
feature space:
Broker: linked, distributed at 4th priority
ifnums:
FastEthernet0/1(469): 10.1.1.5
FastEthernet0/2(470): 10.2.2.5
FastEthernet0/2(470): 10.3.3.5
path 0625780C, path list 053A00B0, share 1/1, type attached nexthop, for IPv4
nexthop 10.1.1.5 gig0/1, adjacency IP adj out of gig0/1, addr 10.1.1.5 058EF420
path 0625787C, path list 053A00B0, share 1/1, type attached nexthop, for IPv4
nexthop 10.2.2.5 gig0/2, adjacency IP adj out of gig0/2, addr 10.2.2.5 058EF280
path 0625787C, path list 053A00B0, share 1/1, type attached nexthop, for IPv4
nexthop 10.3.3.5 gig0/2, adjacency IP adj out of gig0/2, addr 10.2.2.5 05EFAKE0
output chain:
loadinfo 0588EE68, per-session, 2 choices, flags 0003, 6 locks
flags: Per-session, for-rx-IPv4
16 hash buckets
< 0 > IP adj out of FastEthernet0/1, addr 10.1.1.3 058EF420
< 1 > IP adj out of FastEthernet0/2, addr 10.2.2.3 058EF280
< 2 > IP adj out of FastEthernet0/3, addr 10.1.1.3 058FAKE0
< 3 > IP adj out of FastEthernet0/1, addr 10.2.2.3 058EF420
< 4 > IP adj out of FastEthernet0/2, addr 10.1.1.3 058EF280
< 5 > IP adj out of FastEthernet0/3, addr 10.2.2.3 058FAKE0
< 6 > IP adj out of FastEthernet0/1, addr 10.1.1.3 058EF420
< 7 > IP adj out of FastEthernet0/2, addr 10.2.2.3 058EF280
< 8 > IP adj out of FastEthernet0/3, addr 10.1.1.3 058FAKE0
< 9 > IP adj out of FastEthernet0/1, addr 10.2.2.3 058EF420
<10 > IP adj out of FastEthernet0/2, addr 10.1.1.3 058EF280
<11 > IP adj out of FastEthernet0/3, addr 10.2.2.3 058FAKE0
<12 > IP adj out of FastEthernet0/1, addr 10.1.1.3 058EF420
<13 > IP adj out of FastEthernet0/2, addr 10.2.2.3 058EF280
<14 > IP adj out of FastEthernet0/3, addr 10.1.1.3 058FAKE0
<15 > -- not used /Robert
Subblocks:
None
Leaf-4#
Sometimes you need to tweak the load balancing scheme with the command
ip cef load-sharing algorithm include-ports source destination
Done!
Congratulations.
</pre>
CEF with EtherChannel
Regular Interface (No Subinterfaces)
Step 1 View the Address Resolution Protocol (ARP). RP/0/RSP0/CPU0:router# show arp Step 2 Verify that the lag table is programmed properly in the hardware. RP/0/RSP0/CPU0:router# show interface bundle-ether bundle-id Step 3 View the running configuration information. RP/0/RSP0/CPU0:router# show running-config Step 4 View information about packets forwarded by CEF. RP/0/RSP0/CPU0:router# show cef Step 5 RP/0/RSP0/CPU0:router# show cef hardware ingress location node-id Step 6 RP/0/RSP0/CPU0:router# show cef hardware egress location node-id '''Subinterface''' Step 1 Troubleshoot Layer 3 IPv4 traffic. Step 2 Ensure that VLAN traffic coming in matches that on the incoming interface. Ping Failed over Bundle Step 1 View the ARP. RP/0/RSP0/CPU0:router# show arp Step 2 View the ARP information on the particular LC or RSP. RP/0/RSP0/CPU0:router# show arp location node-id Step 3 RP/0/RSP0/CPU0:router# show cef hardware detail location node-id ingress Step 4 RP/0/RSP0/CPU0:router# show interface Step 5 Use the hash calculator to determine which bundle member (interface) to test. Step 6 Remove the interface from the bundle. Step 7 Assign an IP address to the interface. Step 8 Ping the interface. Step 9 Ensure that the ARP is resolved between the router and the node being pinged. ### END ###
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hej.
