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Re: Question on draft-shiomoto-ccamp-gmpls-addressing-00.txt



Dimitri,

Thanks for the comments. Hopefully this text will get beaten into
shape with the attention you folks are paying to it.

On Tue, Mar 08, 2005 at 02:56:05PM +0100, dimitri papadimitriou wrote:
> ashok - this section is indeed to be clarified
> 
> 1. for non-PSC it should distinguish the logical from the physical 
> control channel separation with respect to the data plane channels, i do 
> not see for instance why DCC channels could not be used to exchange 
> control plane traffic and still keep a logical separation

Sure; of course we are not saying that. DCC channels although
travelling on the same fiber are logically separated from the data
channel on the same fiber. I don't think there is any statement to the
contrary.

> 
> 2. for PSC - why is there something different in terms of "practice" 
> than what is currently used in MPLS networks ?

We aren't recommending any. The separated L3 control plane idea I had
mentioned was my attempt to understand the kind of application that
Ben was getting at when he asked "why must control protocols (such as
LDP) NOT form adjacencies over the control plane interfaces". See below.

> 
> or
> 
> 3. do you assume that the interconnection of a PSC with non-PSC network 
> (both driven by GMPLS) could indeed introduce change from the current 
> practices operators used to use for their packet networks ? that in case 
> could be further applied to PSC-only networks ?

I'd say the first part of this is slightly true. Let me try and
reformulate; please tell me if this is better:

"Consider a GMPLS/TE network with optical switches in the core and PSC
devices at the edge, with a separated control plane (either OOB or via
DCC). The edge PSC devices have IP reachability with each other via
both the separated control plane network and via any optical GMPLS/TE
LSPs that may be configured between them (the "data traffic
network"). For the reasons mentioned below, traffic on the separated
control network MUST be limited to GMPLS/TE signalling traffic solely
for the purpose of established optical LSPs within the core of optical
switches. All bearer traffic carried through this network MUST be
carried over GMPLS/TE LSPs and MUST NOT be carried over the separated
control network. Further, any protocols that run purely between the
PSC devices that are not used for GMPLS/TE signalling within the
optical switch core (e.g. protocols for carrying bearer traffic like
LDP and BGP) MUST communicate over GMPLS/TE LSPs and MUST NOT form
adjacencies or exchange messages over the separated control network."

So there is in fact a change from the current practice of a PSC
network *only* at the edge of a cloud of optical switches running
GMPLS. If this was a regular cloud of routers then we could say "if
you have IP reachability over link X, use it". But in the case of an
optical switch network we may well have IP reachability through the
separated control network but we don't want to use it.

Regarding the second part of that question: we are not suggesting any
techniques to be applied in PSC-only networks. The separated PSC
control plane I alluded to earlier may be a useful idea, but it merits
separate treatment and is beyond the scope of this section IMHO.

-Ashok


> 
> thanks,
> - dimitri.
> 
> Ashok Narayanan wrote:
> 
> >Ben,
> >
> >Thanks for the comment. We'll try to clarify this in the next
> >version.
> >
> >-Ashok
> >
> >On Tue, Mar 08, 2005 at 01:14:08PM -0000,
> >benjamin.niven-jenkins@bt.com wrote:
> >
> >>Ashok,
> >>
> >>Thanks for the explanation.  If I understand correctly what you are
> >>saying is that the best current practice is to use an OOB control
> >>plane for the non-PSC  layer networks and an in-band control plane
> >>for the PSC layer networks.  So one must avoid using the control
> >>plane network (of a non-PSC layer network) for the transfer of data
> >>(or control) plane packets from the PSC layer network's control &
> >>data planes.  Fine, I agree that is the BCP, but I don't believe
> >>the current draft articulates that intent very well and section 7.4
> >>probably needs expanding (IMO one or two paragraphs is probably not
> >>enough to discuss/address/detail OOB Vs in-band properly and
> >>unambiguously), for example it is not IMO clear from the current
> >>text that you are talking about 2 separate control plane networks -
> >>one OOB (for non-PSC layer networks/nodes) and one inband (for PSC
> >>layer networks/nodes).
> >>
> >>Thanks Ben
> >>
> >>
> >>>-----Original Message----- From: Ashok Narayanan
> >>>[mailto:ashokn@cisco.com] Sent: 08 March 2005 12:59 To:
> >>>Niven-jenkins,B,Ben,XDE73 R Cc: ccamp@ops.ietf.org Subject: Re:
> >>>Question on draft-shiomoto-ccamp-gmpls-addressing-00.txt
> >>>
> >>>
> >>>
> >>>>I am trying to understand section 7.4 (Separation of
> >>>
> >>>Control and Data Plane Traffic) of 
> >>>draft-shiomoto-ccamp-gmpls-addressing-00.txt better.
> >>>
> >>>>The draft states: "PSC-capable nodes implementing an OOB
> >>>>control plane (perhaps to communicate with an optical switch)
> >>>>MUST NOT use the OOB control plane for data traffic.  For
> >>>>example, in the case of MPLS service running on top of a GMPLS
> >>>>LSP, if the peer PSC device is reachable via both the control
> >>>>plane and the data plane, control protocols such as LDP MUST
> >>>>NOT form adjacencies over the control plane interfaces.  This
> >>>>may be provided by a combination of implementation features and
> >>>>deployment guidelines."
> >>>>
> >>>>So, if the control plane is OOB why must control protocols
> >>>>(such as LDP) NOT form adjacencies over the control plane
> >>>>interfaces?  This implies that LDP (for e.g.) MUST form its
> >>>>adjacencies over the data plane interfaces and therefore LDP is
> >>>>not running OOB (and therefore the control plane is not
> >>>>entirely OOB).
> >>>>
> >>>
> >>>That's an interesting question. The draft focuses on GMPLS/TE 
> >>>deployments and the use of an out-of-band control channel as a
> >>>matter of necessity (i.e. because optical switches are not
> >>>capable of handling in-band control traffic). Consider the
> >>>general deployment of a core of optical switches surrounded by
> >>>GMPLS/TE routers at the edge. From the perspective of this
> >>>network (optical switches, edge routers, and the links in
> >>>between), that statement translates to:
> >>>
> >>>_ The GMPLS/TE control plane between the edge routers and the
> >>>optical switches in the core is entirely out-of-band
> >>>
> >>>- All other protocols between the edge routers MUST be entirely
> >>>in-band.
> >>>
> >>>The control plane network may well be a series of point-to-point
> >>>GRE tunnels overlaid on some other low-bandwidth network
> >>>(actually this is what the draft recommends). Ordinarily one
> >>>would establish a GRE tunnel between each pair of neighbors so
> >>>they can talk to each other. But this means that signalling
> >>>messages going from edge router to edge router actually have to
> >>>be routed through the control planes of intermediate switches.
> >>>The two alternatives to avoid this (to create a full mesh of GRE
> >>>tunnels - at least between all the edge routers - or to not use
> >>>GRE at all if the control plane is switched Ethernet, and 
> >>>therefore to essentially permit a full mesh of OSPF peers) are
> >>>not really palatable (and in the case of SDCC, not usable). The
> >>>optical switches in the core should not be in the business of
> >>>routing packets. Sometimes they have to (e.g. Notify messages),
> >>>but they are not designed for this purpose and should not be
> >>>deployed as such.
> >>>
> >>>And practically speaking the control network is expected to be a 
> >>>low-bandwidth network that can "just get the job done". A single 
> >>>10/100 Ethernet (or, worse, 192kbps SDCCs) can probably handle
> >>>the control traffic for a GMPLS/TE network, but will probably
> >>>fail if we want to use it to peer LDP or BGP for 10,000
> >>>prefixes/labels between the edge routers.
> >>>
> >>>The best current practice is therefore to use the low-bandwidth 
> >>>control network between routers and switches for GMPLS/TE
> >>>signaling (RSVP-TE, OSPF, LMP) and use the high-bandwidth optical
> >>>TE LSPs signalled between edge routers to do other L3 protocols
> >>>between them.
> >>>
> >>>The issue of a separated control plane between PSC edge routers
> >>>for different L3 protocols for administrative reasons is an
> >>>interesting one. Nothing precludes you from creating multiple
> >>>parallel LSPs between edge routers and using one of them to carry
> >>>control traffic between the two edge routers on behalf of all the
> >>>others; that would still satisfy this requirement. Alternatively,
> >>>one could engineer a more beefy control plane network so that it
> >>>can in fact carry all the control plane traffic (BGP, LDP etc.)
> >>>but that is not the BCP today based on available implementations.
> >>>
> >>>
> >>>-Ashok
> >>>
> >>>On Tue, Mar 08, 2005 at 10:33:54AM -0000, 
> >>>benjamin.niven-jenkins@bt.com wrote:
> >>>
> >>>>Colleagues,
> >>>>
> >>>>I am trying to understand section 7.4 (Separation of
> >>>
> >>>Control and Data Plane Traffic) of 
> >>>draft-shiomoto-ccamp-gmpls-addressing-00.txt better.
> >>>
> >>>>The draft states: "PSC-capable nodes implementing an OOB
> >>>>control plane
> >>>
> >>>(perhaps to communicate with an optical switch) MUST NOT use the
> >>>OOB control plane for data traffic.  For example, in the case of
> >>>MPLS service running on top of a GMPLS LSP, if the peer PSC
> >>>device is reachable via both the control plane and the data
> >>>plane, control protocols such as LDP MUST NOT form adjacencies
> >>>over the control plane interfaces.  This may be provided by a
> >>>combination of implementation features and deployment
> >>>guidelines."
> >>>
> >>>>So, if the control plane is OOB why must control protocols
> >>>
> >>>(such as LDP) NOT form adjacencies over the control plane 
> >>>interfaces?  This implies that LDP (for e.g.) MUST form its 
> >>>adjacencies over the data plane interfaces and therefore LDP is
> >>>not running OOB (and therefore the control plane is not entirely
> >>>OOB).
> >>>
> >>>>Thanks Ben
> >>>>
> >>>>
> >>>>-- Ben Niven-Jenkins Networking Specialist, BT Exact
> >>>>
> >>>>e-mail: benjamin.niven-jenkins@bt.com tel: +44(0) 1473 648225 
> >>>>mob: +44(0) 7918 077205
> >>>>
> >>>>pp34/161 B81 Callisto House, Adastral Park, Martlesham,
> >>>
> >>>Ipswich IP5 3RE, UK
> >>>
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> >>>
> >>>
> >>>--- Asok the Intern ---------------------------------------- 
> >>>Ashok Narayanan IOS Network Protocols, Cisco Systems 1414 Mass
> >>>Ave, Boxborough MA 01719 Ph: 978-936-1608.  Fax: 978-936-2218
> >>>(Attn: Ashok Narayanan)
> >>>
> >
> >

-- 



--- Asok the Intern ----------------------------------------
Ashok Narayanan
IOS Network Protocols, Cisco Systems
1414 Mass Ave, Boxborough MA 01719
Ph: 978-936-1608.  Fax: 978-936-2218 (Attn: Ashok Narayanan)