Difference between revisions of "Spanning tree"

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== STP Port States ==
 
== STP Port States ==
{| [[image:Stp port states.png|thumb|none|200px|STP Port States]]
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{|
|*Blocking state (max-age 20 sek.)
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|[[image:Stp port states.png|thumb|none|300px|STP Port States]]
Lytter til BPDU’er
+
|
Data pakker sendes og modtages ikke
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*Blocking state (max-age 20 sek.)
Porten lærer ikke MAC adr.  
+
**Listening for BPDU’s
 +
**Data packets are not transmitted or received.
 +
**The port will not learn MAC addresses.  
 
*Listening state (forward delay = 15 sek.)
 
*Listening state (forward delay = 15 sek.)
Lytter til BPDU’er
+
**Listening for BPDU’s
Alle porte bliver i denne state indtil Root Swich�er valgt.
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**Data packets are not transmitted or received.
Data pakker afvises, lærer ikke MAC adresser.  
+
**The port will not learn MAC addresses.  
Non-designated porte blokeres
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**All ports remain in this state until the Root Switch is elected.
 +
**Non-designated ports are blocked.
 
*Learning state (forward delay = 15 sek.)
 
*Learning state (forward delay = 15 sek.)
Lytter til BPDU’er
+
**Listening for BPDU’s
Data pakker modtages for at lære MAC-adresser
+
**Data packets are not received to learn MAC addresses.
Data pakker sendes ikke
+
**Data packets are not transmitted.
*Forwarding state
+
*Forwarding state (Normal Operation)
Lytter til BPDU’er
+
**Listening for BPDU’s
Lærer MAC-adresser
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**Data packets are received and transmitted.
Sender og modtager datapakker
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**Learning MAC addresses.
 
*Disabled state
 
*Disabled state
porte der er administrativt lukkede (Ikke STP)  
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**Ports administratively closed, not disabled by STP. (Shutdown)
 
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Revision as of 08:10, 29 April 2009

The Spanning Tree protocol are used on Ethernet Switches to avoid broadcast storms.

Problems with Switches without Spanning Tree

Broadcast Storms

A broadcast starts when a Ethernet switch receives a broadcast from a Host and there exist a loop. See example below:

Broadcast storm example

Duplicate Ethernet Frames

Another problem with Ethernet loops is duplicate Ethernet frames. In the picture below, switch X can see PC-B mac-address on two ports and send the frame out of each port.

Duplicate Ethernet frame example

Instability in Switch MAC-Address table

Another problem with with Ethernet loops is instability in the Switches MAC-Address table See the picture below and consider:

  • The MAC-Address off PC-B is timed out on both Switches.
  • PC-A send a unicast packet to PC-B's MAC-Address.
  • PC-B's MAC-address is unknown to Switch X which send the Frame out of all ports. (Except the originating port 3)
  • Switch Y receives the Frame to PC-B on port 1 and on port 2.
  • PC-B's MAC-address is unknown to Switch X which send the Frame out of all ports. (Except originating port)
  • Switch X know receives Frames on port 1 and port 2 with source MAC-address o fPC-A
  • Switch X now thinks that PC-A is on Port 1, Port 2 and Port 3.
Broadcast storm example

The Spanning Tree protocol principle

If the Switches has enabled the Spanning Tree Protocol - STP - the Switches discover the loop and close one of the links for traffic. The closed link will be enabled if one of the other links breaks down.

Broadcast storm example

BPDU: Bridge Protocol Data unit

Connected Switches sends BPDU packets to each other, to make a hierarchy among them. The purpose is to build a loop free network.

  • BPDU packets are send as 802.1d multicast packets.
  • Switches not participating in the STP sends the BPDU packets out all ports. (Broadcast)
  • Switches participating in STP receives the packets on the multicast addresses 01-80-C2-00-00-00 and 01-80-C2-00-00-10
  • BPDU packets are send every 2 seconbds.

Selection of Root Bridge

BPDU packets are propagated through the switches, each switch identifying itself with its BID or Bridge Identifier. The switch with the lowest Bridge Identifier will become the Root Switch. Default the Priority Field of the Bridge Identifier is 32768 which will lead to the switch with the lowest MAC address being the Root Switch.

BID or Bridge Identifier

The BID is a Integer consisting of eight Bytes. The first two bytes are priority and the remaining six bytes are the MAC address of the switch.

2 Bytes Priority 6 Bytes MAC Address

The priority field is default 32768.

Manually selecting the Root Switch

To manually select the Root switch you can alter the priority


BPDU Packet

Bridge Protocol Data Unit
Bytes Field name Notes
2 Protocol ID Always 0
1 Version Always 0
1 Message Type Configuration or TCN BPPU
1 Flags
8 Root Bridge ID 2 Bytes priority and 6 Bytes MAC address
4 Path Cost Cost of all links from the transmitting switch to the root bridge

See table below

8 Bridge ID 2 Bytes priority and 6 Bytes MAC address
2 Port ID Transmitting switch port ID
2 Message age in 256's of a second
2 Max age in 256's of a second
2 Hello Time in 256's of a second
2 Forward delay in 256's of a second

BPDU Path Cost

STP Path cost
Link Bandwidth Old STP Cost New STP Cost
4 Mbps 250 250
10 Mbps 100 100
16 Mbps 63 62
45 Mbps 22 39
100 Mbps 10 19
622 Mbps 2 6
1 Gbps 1 4
10 Gbps 0 2

STP Port States

STP Port States
  • Blocking state (max-age 20 sek.)
    • Listening for BPDU’s
    • Data packets are not transmitted or received.
    • The port will not learn MAC addresses.
  • Listening state (forward delay = 15 sek.)
    • Listening for BPDU’s
    • Data packets are not transmitted or received.
    • The port will not learn MAC addresses.
    • All ports remain in this state until the Root Switch is elected.
    • Non-designated ports are blocked.
  • Learning state (forward delay = 15 sek.)
    • Listening for BPDU’s
    • Data packets are not received to learn MAC addresses.
    • Data packets are not transmitted.
  • Forwarding state (Normal Operation)
    • Listening for BPDU’s
    • Data packets are received and transmitted.
    • Learning MAC addresses.
  • Disabled state
    • Ports administratively closed, not disabled by STP. (Shutdown)

Enhancements to the Spanning Tree Protocol

MST: Multiple Spanning Tree protocol

hostname Switch-1
spanning-tree mode mst
spanning-tree extend system-id
!
spanning-tree mst configuration
 name TEKKOM
 revision 1
 instance 1 vlan 10-50
 instance 2 vlan 51-99
!
spanning-tree mst 1 priority 24576
spanning-tree mst 2 priority 32768

!
vlan internal allocation policy ascending
hostname Switch-2
spanning-tree mode mst
spanning-tree extend system-id
!
spanning-tree mst configuration
 name TEKKOM
 revision 1
 instance 1 vlan 10-50
 instance 2 vlan 51-99
!
spanning-tree mst 1 priority 32768
spanning-tree mst 2 priority 24576

!
vlan internal allocation policy ascending