Network Working Group A. Doria
Request for Comments: 3294 Lulea University of Technology
Category: Informational K. Sundell
Nortel Networks
June 2002
General Switch Management Protocol (GSMP) Applicability
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 (2002). All Rights Reserved.
Abstract
This memo provides an overview of the GSMP (General Switch Management
Protocol) and includes information relating to its deployment in a IP
network in an MPLS environment. It does not discuss deployment in an
ATM (Asynchronous Transfer Mode) network or in a raw ethernet
configuration.
The General Switch Management Protocol (GSMP) has been available to
the IETF community for several years now as informational RFCs. Both
GSMPv1.1 (released in March 1996 as RFC 1987 [2]) and GSMPv2.0
(released in August 1998 as RFC 2297 [3]) are available. Several
vendors have implemented GSMPv1.1.
In V1.1 and V2 GSMP was intended only for use with ATM switches.
During the course of the last two years, the GSMP working group has
decided to expand the purview of GSMP to the point where it can be
used to control a number of different kinds of switch and can thus
live up to what its name indicates; a general switch management
protocol. To do this, commands and arguments needed to be
generalised and sections needed to be added, discussing the manner in
which the generalised protocol could be applied to specific kinds of
switches and port types. In short, the protocol has gone through
major changes in the last 24 months.
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GSMP provides an interface that can be used to separate the data
forwarder from the routing and other control plane protocols such as
LDP. As such it allows service providers to move away from
monolithic systems that bundle the control plane and the data plane
into a single tightly coupled system - usually in a single chassis.
Separating the control components from the forwarding components and
using GSMP for switch management, enables service providers to create
multi-service systems composed of various vendors equipment. It also
allows for a more dynamic means of adding services to their networks.
The IETF GSMP working group was established in the routing area
because GSMP was being seen as an optional part of the MPLS solution.
In a MPLS system, it is possible to run the routing protocols and
label distribution protocols on one system while passing data across
a generic switch, e.g., an ATM switch. GSMP provides the switch
resource management mechanism needed in such a scenario.
GSMP has also been selected by the Multiservice Switching Forum (MSF)
as its protocol of choice for the Switch Control Interface identified
in their architecture. The MSF is an industry forum which, among its
activities establishes their member's requirements and then works
with the appropriate standards bodies to foster their goals. In the
case of GSMP, the MSF presented the IETF GSMP Working Group with a
set of requirements for GSMP. The working group has made a
determined effort to comply with those requirements in its
specifications.
The current version of GSMP is documented in 3 documents:
- GSMP: General Switch Management protocol V3 [5]
- GSMP-ENCAPS: General Switch Management Protocol (GSMP) Packet
Encapsulations for Asynchronous Transfer Mode (ATM), Ethernet and
Transmission Control Protocol (TCP) [4]
- GSMP-MIB: Definitions of Managed Objects for the General Switch
Management Protocol [1]
The General Switch Management Protocol V3 (GSMPv3) [5], is a general
purpose protocol to control a label switch. GSMP allows a
controller to establish and release connections across the switch;
add and delete leaves on a multicast connection; reserve
resources; manage switch ports; request configuration information;
and request statistics. It also allows the switch to inform the
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controller of asynchronous events such as a link going down. The
GSMPv3 protocol is asymmetric, the controller being the master and
the switch being the slave.
A physical switch can be partitioned into many virtual switches.
GSMPv3 does not provide support for defining switch partitions.
GSMPv3 treats a virtual switch as if it were a physical switch.
GSMPv3 may be transported in three ways:
- GSMPv3 operation across an IP network is specified.
- GSMPv3 operation across an ATM virtual channel is specified.
- GSMPv3 operation across an Ethernet link is specified.
Other encapsulations are possible, but have not been defined.
Encapsulations are defined in [4].
A label switch is a frame or cell switch that supports connection
oriented switching using the exact match forwarding algorithm
based on labels attached to incoming cells or frames.
A label switch may support multiple label types. However, each
switch port can support only one label type. The label type
supported by a given port is indicated in a port configuration
message. Connections may be established between ports supporting
different label types using the adaptation methods. GSMPv3
supports TLV labels similar to those defined in MPLS. Examples of
labels which are defined include ATM, Frame Relay, DS1, DS3, E1,
E3, MPLS Generic Labels and MPLS FECs.
A connection across a switch is formed by connecting an incoming
labelled channel to one or more outgoing labelled channels.
Connections are generally referenced by the input port on which
they arrive and the label values of their incoming labelled
channel. In some messages, connections are referenced by the
output port.
GSMPv3 supports point-to-point and point-to-multipoint connections.
A multipoint-to-point connection is specified by establishing
multiple point-to-point connections, each of which specifies the
same output label. A multipoint-to-multipoint connection is
specified by establishing multiple point-to-multipoint connections
each of which specifies a different input label with the same
output labels.
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In general a connection is established with a certain quality of
service (QoS). GSMPv3 includes a default QoS Configuration and
additionally allows the negotiation of alternative, optional QoS
configurations. The default QoS Configuration includes three QoS
Models: a default service model, a simple priority model and a QoS
profile model. GSMPv3 also supports the reservation of resources
when the labels are not yet known. This ability can be used in
support of MPLS.
GSMP contains an adjacency protocol. The adjacency protocol is used
to synchronise states across the link, to negotiate which version
of the GSMP protocol to use, to discover the identity of the
entity at the other end of a link, and to detect when it changes.
In GSMPv3 switch partitioning is static and occurs prior to running
the protocol. The partitions of a physical switch are isolated from
each other by the implementation and the controller assumes that the
resources allocated to a partition are at all times available to that
partition and only that partition. A partition appears to its
controller as a physical label switch. The resources allocated to a
partition appear to the controller as if they were the actual
physical resources of a physical switch. For example if the
bandwidth of a port is divided among several partitions, each
partition would appear to the controller to have its own independent
port with its fixed set of resources.
GSMPv3 controls a partitioned switch through the use of a partition
identifier that is carried in every GSMPv3 message. Each partition
has a one-to-one control relationship with its own logical controller
entity (which in the remainder of the document is referred to simply
as a controller) and GSMPv3 independently maintains adjacency between
each controller-partition pair.
Multiple switches may be controlled by a single controller using
multiple instantiations of the protocol over separate control
connections.
Alternatively, multiple controllers can control a single switch.
Each controller would establish a control connection to the switch
using the adjacency protocol. The adjacency mechanism maintains a
state table indicating the control connections that are being
maintained by the same partition. The switch provides information to
the controller group about the number and identity of the attached
controllers. It does nothing, however, to co-ordinate the activities
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of the controllers, and will execute all commands as they are
received. It is the controller group's responsibility to co-ordinate
its use of the switch. This mechanism is most commonly used for
controller redundancy and load sharing. Definition of the mechanism
by which controllers use to co-ordinate their control is not within
GSMPv3's scope.
All GSMPv3 switches support the default QoS Configuration. A GSMPv3
switch may additionally support one or more alternative QoS
Configurations. GSMP includes a negotiation mechanism that allows a
controller to select from the QoS configurations that a switch
supports.
The default QoS Configuration includes three models:
The Service Model is based on service definitions found external
to GSMP such as in CR-LDP, Integrated Services or ATM Service
Categories. Each connection is assigned a specific service
that defines the handling of the connection by the switch.
Additionally, traffic parameters and traffic controls may be
assigned to the connection depending on the assigned service.
In the Simple Abstract Model a connection is assigned a priority
when it is established. It may be assumed that for connections
that share the same output port, a cell or frame on a
connection with a higher priority is much more likely to exit
the switch before a cell or frame on a connection with a lower
priority if they are both in the switch at the same time.
The QoS Profile Model provides a simple mechanism that allows QoS
semantics defined externally to GSMP to be assigned to
connections. Each profile is an opaque indicator that has been
predefined in the controller and in the switch.
The following table gives a summary of the messages defined in this
version of the specification. It also makes a recommendation of the
minimal set of messages that should be supported in an MPLS
environment. These messages will be labelled as "Required", though
the service provided by the other messages are essential for the
operation of carrier quality controller/switch operations. GSMPv1.1
or GSMPv2 commands that are no longer support are marked as
"Obsolete" and should no longer be used.
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The security of GSMP's TCP/IP control channel has been addressed in
[4]. For all uses of GSMP over an IP network, it is REQUIRED that
GSMP be run over TCP/IP using the security considerations discussed
in [4].
References
[1] Sjostrand, H., Buerkle, J. and B. Srinivasan, "Definitions of
Managed Objects for the General Switch Management Protocol
(GSMP)", RFC 3295, June 2002.
[2] Newman, P., Edwards, W., Hinden, R., Hoffman, E., Ching Liaw, F.,
Lyon, T. and Minshall, G., "Ipsilon's General Switch Management
Protocol Specification Version 1.1", RFC 1987, August 1996.
[3] Newman, P., Edwards, W., Hinden, R., Hoffman, E., Ching Liaw, F.,
Lyon, T. and G. Minshall, "Ipsilon's General Switch Management
Protocol Specification Version 2.0", RFC 2297, March 1998.
[4] Worster, T., Doria, A. and J. Buerkle, "General Switch Management
Protocol (GSMP) Packet Encapsulations for Asynchronous Transfer
Mode (ATM), Ethernet and Transmission Control Protocol (TCP)",
RFC 3293, June 2002.
[5] Doria, A., Sundell, K., Hellstrand, F. and T. Worster, "General
Switch Management Protocol (GSMP) V3", RFC 3292, June 2002.
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Authors' Addresses
Avri Doria
Div. of Computer Communications
Lulea University of Technology
S-971 87 Lulea
Sweden
Phone: +1 401 663 5024
EMail: avri@acm.org
Kenneth Sundell
Nortel Networks AB
S:t Eriksgatan 115 A
P.O. Box 6701
SE-113 85 Stockholm Sweden
EMail: sundell@nortelnetworks.com
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RFC 3294 GSMP Applicability June 2002
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