IGP for Network High AvailabilityFutureweiBoston, MAUSAHuaimo.chen@futurewei.com Verizon USAmehmet.toy@verizon.comChina TelecomBeiqijia Town, Changping DistrictBeijing102209Chinawangaj3@chinatelecom.cnFujitsuUSAliulei.kddi@gmail.comIBM CorporationUSAxufeng.liu.ietf@gmail.comThis document describes protocol extensions to OSPF and IS-IS
for improving the reliability or availability of a network
controlled by a controller cluster.The key words "MUST", "MUST NOT", "REQUIRED", "SHALL", "SHALL NOT",
"SHOULD", "SHOULD NOT", "RECOMMENDED", "MAY", and "OPTIONAL" in this
document are to be interpreted as described in RFC 2119.More and more networks are controlled by
central controllers or controller clusters.
A controller cluster is a single controller externally.
It normally consists of two or more controllers internally
working together to control a network, i.e., every network element
(NE) in the network.
The reliability or availability of a network is heavily
dependent on its controller cluster.
The issues or failures in the controller cluster may impact
the reliability or availability of the network greatly.For a controller cluster comprising two or more controllers
(i.e., primary controller, secondary controller, and so on),
the failures in the cluster may split the cluster into a few of
separated controller groups. These groups do not know each other
and may be out of synchronization.
Two or more groups may be elected to control the network at the
same time, which may cause some issues.This document proposes some procedures and extensions to OSPF and IS-IS
for the separated controllers or controller groups to know each other
thus elect one new primary controller or controller group correctly
when the cluster is split because of failures in the cluster.The following terminologies are used in this document.
Interior Gateway ProtocolOpen Shortest Path FirstIntermediate System to Intermediate SystemLink State Advertisement in OSPFLink State Protocol PDU in IS-ISProtocol Data UnitLink Sate, which is LSA in OSPF or LSP in IS-ISNetwork ElementCustomer EdgeProvider EdgeThis section briefs the mechanism of controller cluster
reliability or availability using IGP, and illustrates
some details through a simple example.When a cluster of controllers is split into a few of separated
groups because of failures in the cluster,
the live controllers are still actually connected to the
network (i.e., network elements).
Through some of these connections, each group can get
the information about the other groups.
A new primary controller or controller group is correctly elected
to control the network based on the information.Each controller may comprise an IGP as an information proxy,
called IGP information proxy or IGP for short.
The IGP has an IGP adjacency relation with each of
a given number of NEs (such as one NE) in the network.
When one adjacency is broken, a new adjacency is created and
maintained if possible. The given number of adjacency relations
is retained.In normal operations, the cluster has all its controllers connected.
They are the primary controller controlling the network, the secondary
controller, and so on. They have current position 1, 2, and so on respectively.
The primary controller advertises the information about the controllers
via its IGP adjacencies. The extensions to IGP below is used.When the cluster is split into a few separated groups,
each group elects an intent primary controller,
secondary controller and so on from the group,
which have intent position 1, 2, and so on respectively.
The intent primary controller advertises the information about
the controllers in the group.The information advertised by the (intent) primary controller
includes its current (intent) position, its old position,
its priority to become a primary controller, the number of controllers,
and the IDs of the controllers which are ordered according to their
(intent) positions. In addition, a flag C indicating that
whether it is Controlling the network (i.e., it is the primary
controller or intent primary controller) is included.
shows a controller cluster comprising two controllers:
the primary controller and the secondary controller.
Each controller includes an IGP as an information proxy.
The IGP in a controller has one IGP adjacency relation
with one NE in the network.
In ,
the IGP in controller A has IGP adjacency with NE1,
the IGP in B has IGP adjacency with NE4.In normal operations, the IGP of the primary controller
originates link state (LS) containing
the information about the controllers connected to it.
The LS originated by Controller A (Primary)
in
having the following contents:C = 1, A's current Position = 1, A's OldPosition = 1,
A's Priority, NoControllers = 2, A's ID, B's IDWhen failures happen in the cluster, the live controllers act as follows:For the Secondary Controller (e.g., B) alive,
if the primary controller is dead,
it promotes itself as the new primary controller;
if the primary controller is alive but separated from the secondary controller,
the secondary controller will not promote itself to be a new primary controller.For the Primary Controller (e.g., A),
if it is alive, it continues to be the primary controller.With the extensions to IGP, the secondary controller can determine
the status of the primary controller through using IGP
and obtaining the information about the primary controller.
The conditions that the primary controller is alive but separated from
the secondary controller (i.e., condition a: the connection between the primary
controller and the secondary controller in the cluster failed,
but condition b: the two controllers are alive) can be determined
by the secondary controller as follows:For condition a, when the heartbeat from the primary stops,
the secondary knows that the connection between the primary and
secondary controller failed.For condition b, it checks its link state database (LSDB) in
the IGP to see whether the IGP for the primary controller
is connected to some network elements and advertises
the LS.
If so, the primary controller is alive; otherwise, it is dead.This section describes extensions to OSPF and IS-IS.A new TLV, called OSPF Controllers TLV, is defined.
When OSPF acts as a proxy of a controller in a cluster,
it may advertise the information about the controllers such as
the number of controllers connected to it (including itself)
in its router information LSA, which contains a Controllers TLV
of the following format.
TBD1 is to be assigned by IANA.It indicates the length of the value portion in octets.One flag bit, C-bit, is defined. When set,
it indicates that the position is the position of the current active primary
controller. In this case, C = 1 and Position = 1, which indicate
that the controller is the current active primary controller controlling
the network.It indicates the current/intent position
of the controller in the controller cluster or group.
1: primary (first) controller, 2: secondary controller, 3: third controller,
and so on (i.e., Controller Position of value n: n-th controller
in the cluster or group).It indicates the old position of
the controller in the controller cluster before it is split.It indicates the priority of the
controller to be elected as a primary controller.Reserved field, must set to zero for
transmission and ignored for reception.It indicates the number of controllers
connected to the controller advertising the TLV.It represents the identifier (ID)
of controller i at position i (i = 1, ..., n) in the cluster or group.When the information about the controllers is changed,
OSPF
of a primary controller originates an OSPF Router Information Opaque LSA,
which includes a OSPF Controllers TLV.Similar to OSPF, a new TLV, called IS-IS Controllers TLV,
is defined.
When IS-IS acts as a proxy of a controller in a cluster,
it may advertise the information about the cluster such as
the number of controllers connected to it (including itself)
in its LSP, which contains an IS-IS Controllers TLV of the
following format.
TBD2 is to be assigned by IANA.It indicates the length of the value
portion in octets.The meaning of each of the other fields
is the same as the one of the corresponding field in
the OSPF Controllers TLV defined above.When the information about the controllers is changed, the IS-IS
of a primary controller originates an LSP,
which includes an IS-IS Controllers TLV.This section describes the recovery procedure for
a controller cluster of n (n > 2) controllers, which are
the primary controller A, the secondary controller B, ...,
the n-th controller N.When failures happen in the cluster, it may be split
into a few separated groups of controllers.
In one policy, the group with the maximum number of controllers
is responsible for controlling the network as the primary group of
the cluster, in which the new primary controller, secondary controller,
and so on are elected.For each separated group of controllers,
the intent primary controller, secondary controller, and so on are elected.
The intent primary controller of the group advertises the information
about the group through its IGP.
The information includes its intent position, its old position,
its priority to become a primary controller,
the number of controllers in the group, and
identifiers of the controllers in the group.
The identifiers of the controllers are ordered according to their positions.
The identifier of the intent primary controller, which has position 1,
is the first one;
The identifier of the intent secondary controller, which has position 2,
is the second one; and so on.
Thus every separated group has the information about the other groups and
can determine which group has the maximum number of controllers. In the case of tie (i.e., two or more groups have the same maximum number
of controllers), the group with the highest priority controller wins
in one policy.
In another policy, the group with the highest old position controller
(e.g., the old primary controller) wins.Some details of the recovery procedures
in the current and intent primary controller
in a controller cluster or group are as follows.In normal operations, it advertises Controllers TLV containing:C = 1, Position = 1, Old Position = 1,
Primary Controller's priority, NoControllers = n, Primary Controller's ID,
secondary controller's ID, ..., and n-th Controller's ID.When failures cause the cluster split, it advertises Controllers TLV
containing:C = 0, Position = 1,
Old Position = 1, Intent Primary Controller's priority,
NoControllers = m (m is the number of controllers in the group
that the primary controller is connected after the failures),
Intent Primary Controller's ID, IDs of the other controllers connected.Then after a given time, it checks if the group is elected as the primary
group. If so, it advertises Controllers TLV containing:C = 1, Position = 1, Old Position = 1, its Priority, NoControllers = m,
the IDs of the controllers in the group.One example is that failures split the cluster into two separated groups:
group 1 comprising A and C, group 2 consisting of B and N.
Each group elects its intent primary controller, secondary controller,
and so on.
Suppose that controller A and C are elected as the intent primary and
secondary controller respectively in group 1;
controller B and N are elected as the intent primary and secondary
controller respectively in group 2.Each of the intent primary controllers A and B advertises
the information about the controllers in its group.
The information advertised by A includes:C = 0, Position = 1, OldPosition = 1,
A's Priority, NoControllers = 2, A's ID, C's ID.The information advertised by B includes:C = 0, Position = 1, OldPosition = 2,
B's Priority, NoControllers = 2, B's ID, N's ID.Group 1 and 2 have the same number of controllers, which is 2.
But OldPosition in group 1 is higher than that in group 2.
Group 1 is elected as the primary group, and
the intent primary controller A in the primary group is determined
as the current primary controller.
After the determination, the information about the controllers
in group 1 (i.e., the primary group) is changed.
The updated information advertised by A includes:C = 1, Position = 1, OldPosition = 1,
A's Priority, NoControllers = 2, A's ID, C's ID.TBDTBDTBD
Intermediate System to Intermediate System
Intra-Domain Routing Exchange Protocol for use in Conjunction
with the Protocol for Providing the Connectionless-mode Network
Service (ISO 8473)
International Organization for Standardization