Network Working Group S. Shah
Request for Comments: 3619 M. Yip
Category: Informational Extreme Networks
October 2003
Extreme Networks'
Ethernet Automatic Protection Switching (EAPS)
Version 1
Status of this Memo
This memo provides information for the Internet community. It does
not specify an Internet standard of any kind. Distribution of this
memo is unlimited.
Copyright Notice
Copyright (C) The Internet Society (2003). All Rights Reserved.
Abstract
This document describes the Ethernet Automatic Protection Switching
(EAPS) (tm) technology invented by Extreme Networks to increase the
availability and robustness of Ethernet rings. An Ethernet ring
built using EAPS can have resilience comparable to that provided by
SONET rings, at a lower cost and with fewer constraints (e.g., ring
size).
Many Metropolitan Area Networks (MANs) and some Local Area Networks
(LANs) have a ring topology, as the fibre runs. The Ethernet
Automatic Protection Switching (EAPS) technology described here works
well in ring topologies for MANs or LANs.
Most MAN operators want to minimise the recovery time in the event
that a fibre cut occurs. The Ethernet Automatic Protection Switching
(EAPS) technology described here converges in less than one second,
often in less than 50 milliseconds. EAPS technology does not limit
the number of nodes in the ring, and the convergence time is
independent of the number of nodes in the ring.
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RFC 3619 Extreme Networks' EAPS October 2003
An EAPS Domain exists on a single Ethernet ring. Any Ethernet
Virtual Local Area Network (VLAN) that is to be protected is
configured on all ports in the ring for the given EAPS Domain. Each
EAPS Domain has a single designated "master node". All other nodes
on that ring are referred to as "transit nodes".
Of course, each node on the ring will have 2 ports connected to the
ring. One port of the master node is designated as the "primary
port" to the ring, while the other port is designated as the
"secondary port".
In normal operation, the master node blocks the secondary port for
all non-control Ethernet frames belonging to the given EAPS Domain,
thereby avoiding a loop in the ring. Existing Ethernet switching and
learning mechanisms operate per existing standards on this ring.
This is possible because the master node makes the ring appear as
though there is no loop from the perspective of the Ethernet standard
algorithms used for switching and learning. If the master node
detects a ring fault, it unblocks its secondary port and allows
Ethernet data frames to pass through that port. There is a special
"Control VLAN" that can always pass through all ports in the EAPS
Domain, including the secondary port of the master node.
EAPS uses both a polling mechanism and an alert mechanism, described
below, to verify the connectivity of the ring and quickly detect any
faults.
When a transit node detects a link-down on any of its ports in the
EAPS Domain, that transit node immediately sends a "link down"
control frame on the Control VLAN to the master node.
When the master node receives this "link down" control frame, the
master node moves from the "normal" state to the ring-fault state and
unblocks its secondary port. The master node also flushes its
bridging table, and the master node also sends a control frame to all
other ring nodes, instructing them to flush their bridging tables as
well. Immediately after flushing its bridging table, each node
begins learning the new topology.
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RFC 3619 Extreme Networks' EAPS October 2003
The master node sends a health-check frame on the Control VLAN at a
user-configurable interval. If the ring is complete, the health-
check frame will be received on its secondary port, where the master
node will reset its fail-period timer and continue normal operation.
If the master node does not receive the health-check frame before the
fail-period timer expires, the master node moves from the normal
state to the "ring-fault" state and unblocks its secondary port. The
master node also flushes its bridging table and sends a control frame
to all other nodes, instructing them to also flush their bridging
tables. Immediately after flushing its bridge table, each node
starts learning the new topology. This ring polling mechanism
provides a backup in the event that the Link Down Alert frame should
get lost for some unforeseen reason.
The master node continues sending periodic health-check frames out
its primary port even when operating in the ring-fault state. Once
the ring is restored, the next health-check frame will be received on
the master node's secondary port. This will cause the master node to
transition back to the normal state, logically block non-control
frames on the secondary port, flush its own bridge table, and send a
control frame to the transit nodes, instructing them to flush their
bridging tables and re-learn the topology.
During the time between the transit node detecting that its link is
restored and the master node detecting that the ring is restored, the
secondary port of the master node is still open -- creating the
possibility of a temporary loop in the topology. To prevent this,
the transit node will place all the protected VLANs transiting the
newly restored port into a temporary blocked state, remember which
port has been temporarily blocked, and transition into the "pre-
forwarding" state. When the transit node in the "pre-forwarding"
state receives a control frame instructing it to flush its bridging
table, it will flush the bridging table, unblock the previously
blocked protected VLANs on the newly restored port, and transition to
the "normal" state.
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RFC 3619 Extreme Networks' EAPS October 2003
An EAPS-enabled switch can be part of more than one ring. Hence, an
EAPS-enabled switch can belong to more than one EAPS Domain at the
same time. Each EAPS Domain on a switch requires a separate instance
of the EAPS protocol on that same switch, one instance per EAPS-
protected ring.
One can also have more than one EAPS domain running on the same ring
at the same time. Each EAPS Domain has its own unique master node
and its own set of protected VLANs. This facilitates spatial reuse
of the ring's bandwidth.
EAPS Frame Format
0 1 2 3 4 4
12345678 90123456 78901234 56789012 34567890 12345678
+--------+--------+--------+--------+--------+--------+
| Destination MAC Address (6 bytes) |
+--------+--------+--------+--------+--------+--------+
| Source MAC Address (6 bytes) |
+--------+--------+--------+--------+--------+--------+
| EtherType |PRI | VLAN ID | Frame Length |
+--------+--------+--------+--------+--------+--------+
| DSAP/SSAP | CONTROL| OUI = 0x00E02B |
+--------+--------+--------+--------+--------+--------+
| 0x00bb | 0x99 | 0x0b | EAPS_LENGTH |
+--------+--------+--------+--------+--------+--------+
|EAPS_VER|EAPSTYPE| CTRL_VLAN_ID | 0x0000 |
+--------+--------+--------+--------+--------+--------+
| 0x0000 | SYSTEM_MAC_ADDR (6 bytes) |
+--------+--------+--------+--------+--------+--------+
| | HELLO_TIMER | FAIL_TIMER |
+--------+--------+--------+--------+--------+--------+
| STATE | 0x00 | HELLO_SEQ | 0x0000 |
+--------+--------+--------+--------+--------+--------+
| RESERVED (0x000000000000) |
+--------+--------+--------+--------+--------+--------+
| RESERVED (0x000000000000) |
+--------+--------+--------+--------+--------+--------+
| RESERVED (0x000000000000) |
+--------+--------+--------+--------+--------+--------+
| RESERVED (0x000000000000) |
+--------+--------+--------+--------+--------+--------+
| RESERVED (0x000000000000) |
+--------+--------+--------+--------+--------+--------+
| RESERVED (0x000000000000) |
+--------+--------+--------+--------+--------+--------+
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RFC 3619 Extreme Networks' EAPS October 2003
Where:
Destination MAC Address is always 0x00e02b000004.
PRI contains 3 bits of priority, with 1 other bit reserved.
EtherType is always 0x8100.
DSAP/SSAP is always 0xAAAA.
CONTROL is always 0x03.
EAPS_LENGTH is 0x40.
EAPS_VERS is 0x0001.
CTRL_VLAN_ID is the VLAN ID for the Control VLAN in use.
SYSTEM_MAC_ADDR is the System MAC Address of the sending node.
HELLO_TIMER is the value set by the Master Node.
FAIL_TIMER is the value set by the Master Node.
HELLO_SEQ is the sequence number of the Hello Frame.
EAPS Type (EAPSTYPE) values:
HEALTH = 5
RING-UP-FLUSH-FDB = 6
RING-DOWN-FLUSH-FDB = 7
LINK-DOWN = 8
All other values are reserved.
STATE values:
IDLE = 0
COMPLETE = 1
FAILED = 2
LINKS-UP = 3
LINK-DOWN = 4
PRE-FORWARDING = 5
All other values are reserved.
Anyone with physical access to the physical layer connections could
forge any sort of Ethernet frame they wished, including but not
limited to Bridge frames or EAPS frames. Such forgeries could be
used to disrupt an Ethernet network in various ways, including
methods that are specific to EAPS or other unrelated methods, such as
forged Ethernet bridge frames.
As such, it is recommended that users not deploy Ethernet without
some form of encryption in environments where such active attacks are
considered a significant operational risk. IEEE standards already
exist for link-layer encryption. Those IEEE standards could be used
to protect an Ethernet's links. Alternately, upper-layer security
mechanisms could be used if it is more appropriate to the local
threat model.
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RFC 3619 Extreme Networks' EAPS October 2003
The IETF has been notified of intellectual property rights claimed in
regard to some or all of the specification contained in this
document. For more information, consult the online list of claimed
rights.
This document was edited together and put into RFC format by R.J.
Atkinson from internal documents created by the authors below. The
Editor is solely responsible for any errors made during redaction.
S. Shah
Extreme Networks
3585 Monroe Street
Santa Clara, CA, 95051
Phone: +1 (408)579-2800
EMail: sshah@extremenetworks.com
M. Yip
Extreme Networks
3585 Monroe Street
Santa Clara, CA, 95051
Phone: +1 (408)579-2800
EMail: my@extremenetworks.com
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RFC 3619 Extreme Networks' EAPS October 2003
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Acknowledgement
Funding for the RFC Editor function is currently provided by the
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