Cisco Systems 3130 User Manual
19-7
Cisco Catalyst Blade Switch 3130 for Dell Software Configuration Guide
OL-13270-01
Chapter 19 Configuring Optional Spanning-Tree Features
Understanding Optional Spanning-Tree Features
Each switch in the stack decides if the sending switch is a better choice than itself to be the stack root
of this spanning-tree instance by comparing the root, cost, and bridge ID. If the sending switch is the
best choice as the stack root, each switch in the stack returns an acknowledgement; otherwise, it sends
a fast-transition request. The sending switch then has not received acknowledgements from all stack
switches.
of this spanning-tree instance by comparing the root, cost, and bridge ID. If the sending switch is the
best choice as the stack root, each switch in the stack returns an acknowledgement; otherwise, it sends
a fast-transition request. The sending switch then has not received acknowledgements from all stack
switches.
When acknowledgements are received from all stack switches, the Fast Uplink Transition Protocol on
the sending switch immediately transitions its alternate stack-root port to the forwarding state. If
acknowledgements from all stack switches are not obtained by the sending switch, the normal
spanning-tree transitions (blocking, listening, learning, and forwarding) take place, and the
spanning-tree topology converges at its normal rate (2 * forward-delay time + max-age time).
the sending switch immediately transitions its alternate stack-root port to the forwarding state. If
acknowledgements from all stack switches are not obtained by the sending switch, the normal
spanning-tree transitions (blocking, listening, learning, and forwarding) take place, and the
spanning-tree topology converges at its normal rate (2 * forward-delay time + max-age time).
The Fast Uplink Transition Protocol is implemented on a per-VLAN basis and affects only one
spanning-tree instance at a time.
spanning-tree instance at a time.
Events that Cause Fast Convergence
Depending on the network event or failure, the CSUF fast convergence might or might not occur.
Fast convergence (less than 1 second under normal network conditions) occurs under these
circumstances:
circumstances:
•
The stack-root port link fails.
If two switches in the stack have alternate paths to the root, only one of the switches performs the
fast transition.
fast transition.
•
The failed link, which connects the stack root to the spanning-tree root, recovers.
•
A network reconfiguration causes a new stack-root switch to be selected.
•
A network reconfiguration causes a new port on the current stack-root switch to be chosen as the
stack-root port.
stack-root port.
Note
The fast transition might not occur if multiple events occur simultaneously. For example, if a stack
member is powered off, and at the same time, the link connecting the stack root to the spanning-tree root
comes back up, the normal spanning-tree convergence occurs.
member is powered off, and at the same time, the link connecting the stack root to the spanning-tree root
comes back up, the normal spanning-tree convergence occurs.
Normal spanning-tree convergence (30 to 40 seconds) occurs under these conditions:
•
The stack-root switch is powered off, or the software failed.
•
The stack-root switch, which was powered off or failed, is powered on.
•
A new switch, which might become the stack root, is added to the stack.
Understanding BackboneFast
BackboneFast detects indirect failures in the core of the backbone. BackboneFast is a complementary
technology to the UplinkFast feature, which responds to failures on links directly connected to access
switches. BackboneFast optimizes the maximum-age timer, which controls the amount of time the
switch stores protocol information received on an interface. When a switch receives an inferior BPDU
from the designated port of another switch, the BPDU is a signal that the other switch might have lost
its path to the root, and BackboneFast tries to find an alternate path to the root.
technology to the UplinkFast feature, which responds to failures on links directly connected to access
switches. BackboneFast optimizes the maximum-age timer, which controls the amount of time the
switch stores protocol information received on an interface. When a switch receives an inferior BPDU
from the designated port of another switch, the BPDU is a signal that the other switch might have lost
its path to the root, and BackboneFast tries to find an alternate path to the root.