Hierarchical PCE DeterminationFutureweiBoston, MAUSAHuaimo.chen@futurewei.comVerizonUSAmehmet.toy@verizon.comIBM CorporationUSAxufeng.liu.ietf@gmail.comFujitsuUSAliulei.kddi@gmail.comChina MobileNo.32 Xuanwumenxi Ave., Xicheng DistrictBeijing100032P.R. Chinali_zhenqiang@hotmail.com
Routing
PCE Working Group
This document presents extensions to
the Path Computation Element Communication Protocol (PCEP)
for determining parent child relations and
exchanging the information between a parent and a child PCE
in a hierarchical PCE system.
A hierarchical PCE architecture is described in RFC 6805, in which a parent PCE has a number of child PCEs. A child PCE may also be a parent PCE, which has multiple child PCEs.
For a parent PCE, it needs to obtain the information about each of its child PCEs. The information about a child PCE comprises the address or ID of the PCE and the domain for which the PCE is responsible. It may also include the position of the PCE, which indicates whether the PCE is a leaf (i.e., only a child) or branch (i.e., a child and also a parent).
In addition, the information may indicate
whether the child PCE and its responsible domain
is in a same organization as the parent PCE.
For a child PCE, it needs to obtain the information about its parent PCE, which includes the address or ID of the parent PCE. The information may also indicate whether
the parent PCE is in a same organization as the child PCE.
After a user configures a parent PCE and a child PCE
over a session, this parent child PCE relation needs to be
determined in the protocol level.
This is similar to OSPF and BGP.
After an adjacency between two OSPF routers is configured
by a user, the OSPF protocol (refer to RFC 2328, Section 7)
will determine whether the adjacency is allowed
based on the parameters configured,
and forms the OSPF adjacency after the determination.
After a peer relation between two BGP routers is configured
by a user, the BGP protocol (refer to RFC 4271, Section 8)
will determine whether the peer is allowed
based on the parameters configured,
and forms the BGP peer relation after the determination.For a parent child PCE relation determination,
the PCE protocol needs to check or confirm
whether the parent child PCE relation is allowed based on
the parameters configured.
If so, the child PCE has to send its parent PCE the information
about it and vice versa.
This document presents extensions to the Path Computation Element Communication Protocol (PCEP) for
determining parent child relations and
exchanging the information between a parent and a child PCE in a hierarchical PCE system.
The following terminology is used in this document.
A domain higher up in a domain hierarchy such that it
contains other domains (child domains) and potentially other links
and nodes.A domain lower in a domain hierarchy such that it has a
parent domain.A PCE responsible for selecting a path across a parent
domain and any number of child domains by coordinating with child
PCEs and examining a topology map that shows domain inter-
connectivity.A PCE responsible for computing the path across one or
more specific (child) domains. A child PCE maintains a relationship
with at least one parent PCE.Traffic Engineering Database.This document uses terminology defined in .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 .This section describes the extensions to PCEP
for determining the relation between a parent PCE and a child PCE and
exchanging the information between a parent and a child PCE
in a hierarchical PCE system.
A child PCE is simply called a child and
a parent PCE is called a parent in the following sections.
During a PCEP session establishment between two PCEP speakers,
each of them advertises its capabilities for Hierarchical PCE (H-PCE for short)
through the Open Message with the Open Object containing
a new TLV to indicate its capabilities for H-PCE.
This new TLV is called H-PCE capability TLV. It has the following format.
The type of the TLV is TBD1. It has a length of 4 octets plus the size of optional Sub-TLVs.
The value of the TLV comprises a capability flags field of 32 bits,
which are numbered from the most significant as bit zero.
Some of them are defined as follows. The others are not defined and MUST be set to zero.
P (Parent - 1 bit): Bit 0 is used as P flag.
It is set to 1 indicating a parent.C (Child - 1 bit): Bit 1 is used as C flag.
It is set to 1 indicating a child.S (Same Org - 1 bit): Bit 2 is used as S flag.
It is set to 1 indicating a PCE in a same organization
as its remote peer.B (Both - 1 bit): Bit 3 is used as B flag.
It is set to 1 indicating a PCE as both a child and a parent.The following Sub-TLVs are defined:
A Domain Sub-TLV containing an AS number and optional area, andPCE-ID Sub-TLV containing the ID of a PCE.When a child sends its parent a Open message,
it places the information about it in the message
through using some optional Sub-TLVs.
When a parent sends each of its child PCEs a Open message,
it puts the information about it in the message.
A domain is an AS or an area in an AS.
An AS is identified by an AS number.
An area in an AS is identified by the combination of the AS and the area.
The former is indicated by an AS number and the latter by an area number.
A domain is represented by a domain Sub-TLV containing an AS number and
a optional area number.
The format of the domain Sub-TLV is shown below:
An AS is represented by a domain Sub-TLV containing only the AS number of the AS.
In this case, the Length is four.
An area in an AS is represented by a domain Sub-TLV containing
the AS number of the AS and the area number of the area.
In this case, the Length is eight.
An Identifier (ID) of a PCE (PCE ID for short) is
a 32-bit number
that uniquely identifies the PCE among all PCEs.
This 32-bit number for PCE ID SHOULD NOT be zero.
The format of the PCE ID Sub-TLV is shown below:
Alternatively, an IP address attached to a PCE can also be used
as an identifier of the PCE.
The format of an IPv4 address Sub-TLV is shown below:
The IPv4 address Sub-TLV specifies an IPv4 address associated with the PCE,
which is used as the identifier of the PCE.
The format of an IPv6 address Sub-TLV is shown below:
The IPv6 Sub-TLV specifies an IPv6 address associated with the PCE,
which is used as the identifier of the PCE.
For two PCEs A and B configured as parent and child,
they determine parent child relation through Open messages
in the initialization phase.
The following is a sequence of events related.
A sends B a Open message with P=1 and A's ID
after B is configured as its child on it.
B sends A a Open message with C=1 and B's ID
after A is configured as its parent on it.
When A receives the Open message from B and
determines C=1 and the PCE ID of B in the message is the same as the PCE ID of the child locally configured,
B is A's child.
When B receives the Open message from A and
determines P=1 and the PCE ID of A in the message is the same as the PCE ID of the parent locally configured,
A is B's parent.
The Open message from child B to its parent A contains
B's domain, which is represented by
a domain Sub-TLV in the H-PCE capability TLV.
If child B is also a parent, the B flag in the TLV is set to 1.
The PCE ID in a Open message may be represented
in one of the following ways:
The source IP address of the message (i.e., PCE session).A PCE ID Sub-TLV in the H-PCE capability TLV.An IP address Sub-TLV in the H-PCE capability TLV.
When the IP address Sub-TLV is used, the address in the Sub-TLV MUST
be the same as the source IP address of the PCE session.
For a child that is a leaf, it is normally responsible for one domain,
which is contained in the message to its parent.
For a child that is a branch (i.e., also a parent of multiple child PCEs),
it may be directly responsible for one domain,
which is contained in the message to its parent.
In addition, it is responsible for the domains of its child PCEs.
In other words, it is responsible for computing paths crossing
the domains through working together with its child PCEs.
If these domains are all areas of an AS,
the AS is included in the message to its parent.
A parent stores the information about each of its child PCEs received.
When the session to one of them is down, it removes the information about
the child on that session.
A child stores the information about its parent received.
When the session to the parent is down, it removes the information about
the parent.
If there already exists a session between A and B and
the configurations on parent and child are issued on them,
the procedures above may be executed through bringing down
the existing session and establishing a new session between them.
Alternatively,
they may determine parent child relation through using
extended Notification messages in the same procedures
as using Open messages described above without bringing down
the existing session.
The following new Notification-type and Notification-value are
defined for H-PCE:
Notification-type=5 (TBD): Determination of H-PCE
Notification-value=1: The information about a parent PCE or a child PCE.
A Notification-type=5, Notification-value=1 indicates that the
PCE sends its peer the information about it and
a TLV containing the information is in the Notification object.
The format and contents of the TLV is the same as the H-PCE capability TLV described above.
The only difference may be the type of the TLV. The mechanism described in this document does not raise any new security issues for the PCEP protocols.This section specifies requests for IANA allocation.The authors would like to Jescia Chen, Adrian Farrel for their valuable comments on this draft.