rfc5811
Internet Engineering Task Force (IETF) J. Hadi Salim
Request for Comments: 5811 Mojatatu Networks
Category: Standards Track K. Ogawa
ISSN: 2070-1721 NTT Corporation
March 2010
SCTP-Based Transport Mapping Layer (TML) for the
Forwarding and Control Element Separation (ForCES) Protocol
Abstract
This document defines the SCTP-based TML (Transport Mapping Layer)
for the ForCES (Forwarding and Control Element Separation) protocol.
It explains the rationale for choosing the SCTP (Stream Control
Transmission Protocol) and also describes how this TML addresses all
the requirements required by and the ForCES protocol.
Status of This Memo
This is an Internet Standards Track document.
This document is a product of the Internet Engineering Task Force
(IETF). It represents the consensus of the IETF community. It has
received public review and has been approved for publication by the
Internet Engineering Steering Group (IESG). Further information on
Internet Standards is available in Section 2 of RFC 5741.
Information about the current status of this document, any errata,
and how to provide feedback on it may be obtained at
http://www.rfc-editor.org/info/rfc5811.
Copyright Notice
Copyright (c) 2010 IETF Trust and the persons identified as the
document authors. All rights reserved.
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the Trust Legal Provisions and are provided without warranty as
described in the Simplified BSD License.
Hadi Salim & Ogawa Standards Track [Page 1]
RFC 5811 ForCES SCTP TML March 2010
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Table of Contents
1. Introduction ....................................................3
2. Definitions .....................................................3
3. Protocol Framework Overview .....................................4
3.1. The PL .....................................................5
3.2. The TML ....................................................5
3.2.1. TML and PL Interfaces ...............................5
3.2.2. TML Parameterization ................................6
4. SCTP TML Overview ...............................................7
4.1. Rationale for Using SCTP for TML ...........................7
4.2. Meeting TML Requirements ...................................8
4.2.1. SCTP TML Channels ...................................9
4.2.2. Satisfying TML Requirements ........................14
5. SCTP TML Channel Work ..........................................16
6. IANA Considerations ............................................16
7. Security Considerations ........................................17
7.1. IPsec Usage ...............................................17
7.1.1. SAD and SPD Setup ..................................18
8. Acknowledgements ...............................................18
9. References .....................................................19
9.1. Normative References ......................................19
9.2. Informative References ....................................20
Appendix A. Suggested SCTP TML Channel Work Implementation .......21
A.1. SCTP TML Channel Initialization ...........................21
A.2. Channel Work Scheduling ...................................21
A.2.1. FE Channel Work Scheduling ............................21
A.2.2. CE Channel Work Scheduling ............................22
A.3. SCTP TML Channel Termination ..............................23
A.4. SCTP TML NE-Level Channel Scheduling ......................23
Appendix B. Suggested Service Interface ..........................24
B.1. TML Bootstrapping .........................................24
B.2. TML Shutdown ..............................................26
B.3. TML Sending and Receiving .................................27
Hadi Salim & Ogawa Standards Track [Page 2]
RFC 5811 ForCES SCTP TML March 2010
1. Introduction
The ForCES (Forwarding and Control Element Separation) working group
in the IETF defines the architecture and protocol for separation of
control elements (CEs) and forwarding elements (FEs) in network
elements (NEs) such as routers. [RFC3654] and [RFC3746],
respectively, define architectural and protocol requirements for the
communication between CEs and FEs. The ForCES protocol layer
specification [RFC5810] describes the protocol semantics and
workings. The ForCES protocol layer operates on top of an inter-
connect hiding layer known as the TML. The relationship is
illustrated in Figure 1.
This document defines the SCTP-based TML for the ForCES protocol
layer. It also addresses all the requirements for the TML including
security, reliability, and etc., as defined in [RFC5810].
2. Definitions
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 [RFC2119].
The following definitions are taken from [RFC3654] and [RFC3746]:
LFB: Logical Functional Block. A template that
represents a fine-grained, logically separate
aspect of FE processing.
ForCES Protocol: The protocol used at the Fp reference point in the
ForCES Framework in [RFC3746].
ForCES PL: ForCES Protocol Layer. A layer in the ForCES
architecture that embodies the ForCES protocol and
the state transfer mechanisms as defined in
[RFC5810].
ForCES TML: ForCES Protocol Transport Mapping Layer. A layer
in the ForCES protocol architecture that
specifically addresses the protocol message
transportation issues, such as how the protocol
messages are mapped to different transport media
(like SCTP, IP, TCP, UDP, ATM, Ethernet, etc.), and
how to achieve and implement reliability, security,
etc.
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3. Protocol Framework Overview
The reader is referred to the Framework document [RFC3746], and in
particular Sections 3 and 4, for an architectural overview and
explanation of where and how the ForCES protocol fits in.
There is some content overlap between the ForCES protocol
specification [RFC5810] and this section (Section 3) in order to
provide basic context to the reader of this document.
The ForCES protocol layering constitutes two pieces, the PL and TML.
This is depicted in Figure 1.
+----------------------------------------------+
| CE PL |
+----------------------------------------------+
| CE TML |
+----------------------------------------------+
^
|
ForCES PL |messages
|
v
+-----------------------------------------------+
| FE TML |
+-----------------------------------------------+
| FE PL |
+-----------------------------------------------+
Figure 1: Message Exchange between CE and FE
to Establish an NE Association
The PL is in charge of the ForCES protocol. Its semantics and
message layout are defined in [RFC5810]. The TML is necessary to
connect two ForCES endpoints as shown in Figure 1.
Both the PL and TML are standardized by the IETF. While only one PL
is defined, different TMLs are expected to be standardized. The TML
at each of the nodes (CE and FE) is expected to be of the same
definition in order to inter-operate.
When transmitting from a ForCES endpoint, the PL delivers its
messages to the TML. The TML then delivers the PL message to the
destination TML(s).
On reception of a message, the TML delivers the message to its
destination PL (as described in the ForCES header).
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3.1. The PL
The PL is common to all implementations of ForCES and is standardized
by the IETF [RFC5810]. The PL is responsible for associating an FE
or CE to an NE. It is also responsible for tearing down such
associations.
An FE may use the PL to asynchronously send packets to the CE. The
FE may redirect various control protocol packets (e.g., OSPF, etc.)
to the CE via the PL (from outside the NE). Additionally, the FE
delivers various events that the CE has subscribed to via the PL
[RFC5812].
The CE and FE may interact synchronously via the PL. The CE issues
status requests to the FE and receives responses via the PL. The CE
also configures the components of the associated FE's LFBs using the
PL [RFC5812].
3.2. The TML
The TML is responsible for the transport of the PL messages.
[RFC5810], Section 5 defines the requirements that need to be met by
a TML specification. The SCTP TML specified in this document meets
all the requirements specified in [RFC5810], Section 5.
Section 4.2.2 of this document describes how the TML requirements are
met.
3.2.1. TML and PL Interfaces
There are two interfaces to the PL and TML. The specification of
these interfaces is out of scope for this document, but the
interfaces are introduced to show how they fit into the architecture
and summarize the function provided at the interfaces. The first
interface is between the PL and TML and the other is the CE Manager
(CEM)/FE Manager (FEM) [RFC3746] interface to both the PL and TML.
Both interfaces are shown in Figure 2.
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+----------------------------+
| +----------------------+ |
| | | |
+---------+ | | PL | |
| | | +----------------------+ |
|FEM/CEM |<---->| ^ |
| | | | |
+---------+ | |TML API |
| | |
| V |
| +----------------------+ |
| | | |
| | TML | |
| | | |
| +----------------------+ |
+----------------------------+
Figure 2: The TML-PL Interface
The CEM/FEM [RFC3746] interface is responsible for bootstrapping and
parameterization of the TML. In its most basic form, the CEM/FEM
interface takes the form of a simple static config file that is read
on startup in the pre-association phase.
Appendix B discusses the service interfaces in more detail.
3.2.2. TML Parameterization
It is expected that it should be possible to use a configuration
reference point, such as the FEM or the CEM, to configure the TML.
Some of the configured parameters may include:
o PL ID
o Connection Type and associated data. For example, if a TML uses
IP/SCTP, then parameters such as SCTP ports and IP addresses need
to be configured.
o Number of transport connections
o Connection Capability, such as bandwidth, etc.
o Allowed/Supported Connection Quality of Service (QoS) Policy (or
Congestion Control Policy)
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4. SCTP TML Overview
SCTP [RFC4960] is an end-to-end transport protocol that is equivalent
to TCP, UDP, or DCCP in many aspects. With a few exceptions, SCTP
can do most of what UDP, TCP, or DCCP can achieve. SCTP as can also
do most of what a combination of the other transport protocols can
achieve (e.g., TCP and DCCP or TCP and UDP).
Like TCP, it provides ordered, reliable, connection-oriented, flow-
controlled, congestion-controlled data exchange. Unlike TCP, it does
not provide byte streaming and instead provides message boundaries.
Like UDP, it can provide unreliable, unordered data exchange. Unlike
UDP, it does not provide multicast support
Like DCCP, it can provide unreliable, ordered, congestion controlled,
connection-oriented data exchange.
SCTP also provides other services that none of the three transport
protocols mentioned above provide that we found attractive. These
include:
o Multi-homing
o Runtime IP address binding
o A range of reliability shades with congestion control
o Built-in heartbeats
o Multi-streaming
o Message boundaries with reliability
o Improved SYN DOS protection
o Simpler transport events
o Simplified replicasting
4.1. Rationale for Using SCTP for TML
SCTP has all the features required to provide a robust TML. As a
transport that is all-encompassing, it negates the need for having
multiple transport protocols in order to satisfy the TML requirements
([RFC5810], Section 5). As a result, it allows for simpler coding
and therefore reduces a lot of the interoperability concerns.
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SCTP is also very mature and widely used, making it a good choice for
ubiquitous deployment.
4.2. Meeting TML Requirements
PL
+----------------------+
| |
+-----------+----------+
| TML API
TML |
+-----------+----------+
| | |
| +------+------+ |
| | TML core | |
| +-+----+----+-+ |
| | | | |
| SCTP socket API |
| | | | |
| | | | |
| +-+----+----+-+ |
| | SCTP | |
| +------+------+ |
| | |
| | |
| +------+------+ |
| | IP | |
| +-------------+ |
+----------------------+
Figure 3: The TML-SCTP Interface
Figure 3 details the interfacing between the PL and SCTP TML and the
internals of the SCTP TML. The core of the TML interacts on its
northbound interface to the PL (utilizing the TML API). On the
southbound interface, the TML core interfaces to the SCTP layer
utilizing the standard socket interface [TSVWG-SCTPSOCKET]. There
are three SCTP socket connections opened between any two PL endpoints
(whether FE or CE).
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4.2.1. SCTP TML Channels
+--------------------+
| |
| TML core |
| |
+-+-------+--------+-+
| | |
| Med prio, |
| Semi-reliable |
| channel |
| | Low prio,
| | Unreliable
| | channel
| | |
^ ^ ^
| | |
Y Y Y
High prio,| | |
reliable | | |
channel | | |
Y Y Y
+-+--------+--------+-+
| |
| SCTP |
| |
+---------------------+
Figure 4: The TML-SCTP Channels
Figure 4 details further the interfacing between the TML core and
SCTP layers. There are three channels used to group and prioritize
the work for different types of ForCES traffic. Each channel
constitutes an SCTP socket interface that has different properties.
It should be noted that all SCTP channels are congestion aware (and
for that reason that detail is left out of the description of the
three channels). SCTP ports 6704, 6705, and 6706 are used for the
higher-, medium-, and lower-priority channels, respectively. SCTP
Payload Protocol ID (PPID) values of 21, 22, and 23 are used for the
higher-, medium-, and lower-priority channels, respectively.
4.2.1.1. Justifying Choice of Three Sockets
SCTP allows up to 64 K streams to be sent over a single socket
interface. The authors initially envisioned using a single socket
for all three channels (mapping a channel to an SCTP stream). This
simplifies programming of the TML as well as conserves use of SCTP
ports.
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Further analysis revealed head-of-line blocking issues with this
initial approach. Lower-priority packets not needing reliable
delivery could block higher-priority packets (needing reliable
delivery) under congestion situations for an indeterminate period of
time (depending on how many outstanding lower-priority packets are
pending). For this reason, we elected to go with mapping each of the
three channels to a different SCTP socket (instead of a different
stream within a single socket).
4.2.1.2. Higher-Priority, Reliable Channel
The higher-priority (HP) channel uses a standard SCTP reliable socket
on port 6704. SCTP PPID 21 is used for all messages on the HP
channel. The HP channel is used for CE-solicited messages and their
responses:
1. ForCES configuration messages flowing from CE to FE and responses
from the FE to CE.
2. ForCES query messages flowing from CE to FE and responses from
the FE to the CE.
PL priorities 4-7 MUST be used for all PL messages using this
channel. The following PL messages MUST use the HP channel for
transport:
o AssociationSetup (default priority: 7)
o AssociationSetupResponse (default priority: 7)
o AssociationTeardown (default priority: 7)
o Config (default priority: 4)
o ConfigResponse (default priority: 4)
o Query (default priority: 4)
o QueryResponse (default priority: 4)
If PL priorities outside of the specified range priority (4-7), PPID,
or PL message types other than the above are received on the HP
channel, then the PL message MUST be dropped.
Although an implementation may choose different values from the
defined range (4-7), it is RECOMMENDED that default priorities be
used. A response to a ForCES message MUST contain the same priority
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as the request. For example, a config sent by the CE with priority 5
MUST have a config-response from the FE with priority 5.
4.2.1.3. Medium-Priority, Semi-Reliable Channel
The medium-priority (MP) channel uses SCTP-PR on port 6705. SCTP
PPID 22 MUST be used for all messages on the MP channel. Time limits
on how long a message is valid are set on each outgoing message.
This channel is used for events from the FE to the CE that are
obsoleted over time. Events that are accumulative in nature and are
recoverable by the CE (by issuing a query to the FE) can tolerate
lost events and therefore should use this channel. For example, a
generated event that carries the value of a counter that is
monotonically incrementing is fit to use this channel.
PL priority 3 MUST be used for PL messages on this channel. The
following PL messages MUST use the MP channel for transport:
o Event Notification (default priority: 3)
If PL priorities outside of the specified priority, PPID, or PL
message type other than the above are received on the MP channel,
then the PL message MUST be dropped.
4.2.1.4. Lower-Priority, Unreliable Channel
The lower-priority (LP) channel uses SCTP port 6706. SCTP PPID 23 is
used for all messages on the LP channel. The LP channel also MUST
use SCTP-PR with lower timeout values than the MP channel. The
reason an unreliable channel is used for redirect messages is to
allow the control protocol at both the CE and its peer-endpoint to
take charge of how the end-to-end semantics of the said control
protocol's operations. For example:
1. Some control protocols are reliable in nature, therefore making
this channel reliable introduces an extra layer of reliability
that could be harmful. So any end-to-end retransmits will happen
remotely.
2. Some control protocols may desire having obsolescence of messages
over retransmissions; making this channel reliable contradicts
that desire.
Given ForCES PL heartbeats are traffic sensitive, sending them over
the LP channel also makes sense. If the other end is not processing
other channels, it will eventually get heartbeats; and if it is busy
processing other channels, heartbeats will be obsoleted locally over
time (and it does not matter if they did not make it).
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PL priorities 1-2 MUST be used for PL messages on this channel. PL
messages that MUST use the MP channel for transport are:
o PacketRedirect (default priority: 2)
o Heartbeat (default priority: 1)
If PL priorities outside of the specified priority range, PPID, or PL
message types other than the above are received on the LP channel,
then the PL message MUST be dropped.
4.2.1.5. Scheduling of the Three Channels
In processing the sending and receiving of the PL messages, the TML
core uses strict priority work-conserving scheduling, as shown in
Figure 5.
This means that the HP messages are always processed first until
there are no more left. The LP channel is processed only if channels
that are a higher priority than itself have no messages left to
process. This means that under a congestion situation, a higher-
priority channel with sufficient messages that occupy the available
bandwidth would starve lower-priority channel(s).
The design intent of the SCTP TML is to tie processing
prioritization, as described in Section 4.2.1.1, and transport
congestion control to provide implicit node congestion control. This
is further detailed in Appendix A.2.
It should be emphasized that the work scheduling prioritization
scheme prescribed in this document is receiver-based processing.
Fully arrived packets on any of the channels are a source of work
whose output may result in transmitted packets. However, we have no
control on the order in which the SCTP/OS/network chooses to send
transmitted packets across and make them available to the receiver.
This is a limitation that we try to ameliorate by our choice of
channel properties, ForCES message grouping, and the tying of CE and
FE work scheduling. While that helps us ameliorate some of these
issues, it does not fully resolve all.
From a ForCES perspective, we can tolerate some reordering. For
example, if an FE transmits a config response (HP) followed by 10000
OSPF redirect packets (LP) and the CE gets 5 OSPF redirects (LP)
first before the config response (HP), that is tolerable. What
matters is the CE gets to processing the HP message soon (instead of
sitting in long periods of time processing OSPF packets that would
have happened if we use a single socket with three streams). This is
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RFC 5811 ForCES SCTP TML March 2010
particularly important in order to deal with node overload well, as
discussed in Section 4.2.2.6.
SCTP channel +----------+
Work available | DONE +---<--<--+
| +---+------+ |
Y ^
| +-->--+ +-->---+ |
+-->-->-+ | | | | |
| | | | | | ^
| ^ ^ v ^ v |
^ / \ | | | | |
| / \ | ^ | ^ ^
| / Is \ | / \ | / \ |
| / there \ | /Is \ | /Is \ |
^ / HP work \ ^ /there\ ^ /there\ ^
| \ ? / | /MP work\ | /LP work\ |
| \ / | \ ? / | \ ? / |
| \ / | \ / | \ / ^
| \ / ^ \ / ^ \ / |
| \ / | \ / | \ / |
^ Y-->-->-->+ Y-->-->-->+ Y->->->-+
| | NO | NO | NO
| | | |
| Y Y Y
| | YES | YES | YES
^ | | |
| Y Y Y
| +----+------+ +---|-------+ +----|------+
| |- process | |- process | |- process |
| | HP work | | MP work | | LP work |
| +------+----+ +-----+-----+ +-----+-----+
| | | |
^ Y Y Y
| | | |
| Y Y Y
+--<--<---+--<--<----<----+-----<---<-----+
Figure 5: SCTP TML Strict Priority Scheduling
4.2.1.6. SCTP TML Parameterization
The following is a list of parameters needed for booting the TML. It
is expected these parameters will be extracted via the FEM/CEM
interface for each PL ID.
1. The IP address(es) or a resolvable DNS/hostname(s) of the CE/FE.
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2. Whether or not to use IPsec. If IPsec is used, how to
parameterize the different required ciphers, keys, etc., as
described in Section 7.1
3. The HP SCTP port, as discussed in Section 4.2.1.2. The default
HP port value is 6704 (Section 6).
4. The MP SCTP port, as discussed in Section 4.2.1.3. The default
MP port value is 6705 (Section 6).
5. The LP SCTP port, as discussed in Section 4.2.1.4. The default
LP port value is 6706 (Section 6).
4.2.2. Satisfying TML Requirements
[RFC5810], Section 5 lists requirements that a TML needs to meet.
This section describes how the SCTP TML satisfies those requirements.
4.2.2.1. Satisfying Reliability Requirement
As mentioned earlier, a shade of reliability ranges is possible in
SCTP. Therefore, this requirement is met.
4.2.2.2. Satisfying Congestion Control Requirement
Congestion control is built into SCTP. Therefore, this requirement
is met.
4.2.2.3. Satisfying Timeliness and Prioritization Requirement
By using three sockets in conjunction with the partial-reliability
feature [RFC3758], both timeliness and prioritization requirements
are addressed.
4.2.2.4. Satisfying Addressing Requirement
There are no extra headers required for SCTP to fulfill this
requirement. SCTP can be told to replicast packets to multiple
destinations. The TML implementation will need to translate PL
addresses to a variety of unicast IP addresses in order to emulate
multicast and broadcast PL addresses.
4.2.2.5. Satisfying High-Availability Requirement
Transport link resiliency is one of SCTP's strongest points. Failure
detection and recovery is built in, as mentioned earlier.
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o The SCTP multi-homing feature is used to provide path diversity.
Should one of the peer IP addresses become unreachable, the others
are used without needing lower-layer convergence (routing, for
example) or even the TML becoming aware.
o SCTP heartbeats and data transmission thresholds are used on a
per-peer IP address to detect reachability faults. The faults
could be a result of an unreachable address or peer, which may be
caused by a variety of reasons, like interface, network, or
endpoint failures. The cause of the fault is noted.
o With the ADDIP feature, one can migrate IP addresses to other
nodes at runtime. This is not unlike the Virtual Router
Redundancy Protocol (VRRP) [RFC5798] use. This feature is used in
addition to multi-homing in a planned migration of activity from
one FE/CE to another. In such a case, part of the provisioning
recipe at the CE for replacing an FE involves migrating activity
of one FE to another.
4.2.2.6. Satisfying Node Overload Prevention Requirement
The architecture of this TML defines three separate channels, one per
socket, to be used within any FE-CE setup. The work scheduling
design for processing the TML channels (Section 4.2.1.5) is a strict
priority. A fundamental desire of the strict prioritization is to
ensure that more important processing work always gets node resources
over less important work.
When a ForCES node CPU is overwhelmed because the incoming packet
rate is higher than it can keep up with, the channel queues grow and
transport congestion subsequently follows. By virtue of using SCTP,
the congestion is propagated back to the source of the incoming
packets and eventually alleviated.
The HP channel work gets prioritized at the expense of the MP, which
gets prioritized over LP channels. The preferential scheduling only
kicks in when there is node overload regardless of whether there is
transport congestion. As a result of the preferential work
treatment, the ForCES node achieves a robust steady processing
capacity. Refer to Appendix A.2 for details on scheduling.
For an example of how the overload prevention works, consider a
scenario where an overwhelming amount of redirected packets (from
outside the NE) coming into the NE may overload the FE while it has
outstanding config work from the CE. In such a case, the FE, while
it is busy processing config requests from the CE, essentially
ignores processing the redirect packets on the LP channel. If enough
redirect packets accumulate, they are dropped either because the LP
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channel threshold is exceeded or because they are obsoleted. If on
the other hand, the FE has successfully processed the higher-priority
channels and their related work, then it can proceed and process the
LP channel. So as demonstrated in this case, the TML ties transport
congestion and node overload implicitly together.
4.2.2.7. Satisfying Encapsulation Requirement
The SCTP TML sets SCTP PPIDs to identify channels used as described
in Section 4.2.1.1.
5. SCTP TML Channel Work
There are two levels of TML channel work within an NE when a ForCES
node (CE or FE) is connected to multiple other ForCES nodes:
1. NE-level I/O work where a ForCES node (CE or FE) needs to choose
which of the peer nodes to process.
2. Node-level I/O work where a ForCES node, handles the three SCTP
TML channels separately for each single ForCES endpoint.
NE-level scheduling definition is left up to the implementation and
is considered out of scope for this document. Appendix A.4 briefly
discusses some constraints about which an implementer needs to worry.
This document provides suggestions on SCTP channel work
implementation in Appendix A.
The FE SHOULD do channel connections to the CE in the order of
incrementing priorities, i.e., LP socket first, followed by MP, and
ending with HP socket connection. The CE, however, MUST NOT assume
that there is ordering of socket connections from any FE.
6. IANA Considerations
Following the policies outlined in "Guidelines for Writing an IANA
Considerations Section in RFCs" [RFC5226], the following namespaces
are defined in ForCES SCTP TML.
o SCTP port 6704 for the HP channel, 6705 for the MP channel, and
6706 for the LP channel.
o SCTP Payload Protocol ID (PPID) 21 for the HP channel (ForCES-HP),
22 for the MP channel (ForCES-MP), and 23 for the LP channel
(ForCES-LP).
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7. Security Considerations
The SCTP TML provides the following security services to the PL:
o A mechanism to authenticate ForCES CEs and FEs at the transport
level in order to prevent the participation of unauthorized CEs
and unauthorized FEs in the control and data path processing of a
ForCES NE.
o A mechanism to ensure message authentication of PL data and
headers transferred from the CE to FE (and vice versa) in order to
prevent the injection of incorrect data into PL messages.
o A mechanism to ensure the confidentiality of PL data and headers
transferred from the CE to FE (and vice versa), in order to
prevent disclosure of PL information transported via the TML.
Security choices provided by the TML are made by the operator and
take effect during the pre-association phase of the ForCES protocol.
An operator may choose to use all, some or none of the security
services provided by the TML in a CE-FE connection.
When operating under a secured environment, or for other operational
concerns (in some cases performance issues) the operator may turn off
all the security functions between CE and FE.
IP Security Protocol (IPsec) [RFC4301] is used to provide needed
security mechanisms.
IPsec is an IP-level security scheme transparent to the higher-layer
applications and therefore can provide security for any transport
layer protocol. This gives IPsec the advantage that it can be used
to secure everything between the CE and FE without expecting the TML
implementation to be aware of the details.
The IPsec architecture is designed to provide message integrity and
message confidentiality outlined in the TML security requirements
[RFC5810]. Mutual authentication and key exchange protocol are
provided by Internet Key Exchange (IKE) [RFC2409].
7.1. IPsec Usage
A ForCES FE or CE MUST support the following:
o Internet Key Exchange (IKE)[RFC2409] with certificates for
endpoint authentication.
o Transport Mode Encapsulating Security Payload (ESP) [RFC4303].
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o HMAC-SHA1-96 [RFC2404] for message integrity protection
o AES-CBC with 128-bit keys [RFC3602] for message confidentiality.
o Replay protection [RFC4301].
A compliant implementation SHOULD provide operational means for
configuring the CE and FE to negotiate other cipher suites and even
use manual keying.
7.1.1. SAD and SPD Setup
To minimize the operational configuration, it is RECOMMENDED that
only the IANA-issued SCTP protocol number (132) be used as a selector
in the Security Policy Database (SPD) for ForCES. In such a case,
only a single SPD and SAD entry is needed.
Setup MAY alternatively extend the above policy so that it uses the
three SCTP TML port numbers as SPD selectors. But as noted above,
this choice will require an increased number of SPD entries.
In scenarios where multiple IP addresses are used within a single
association, and there is desire to configure different policies on a
per-IP address, then following [RFC3554] is RECOMMENDED.
8. Acknowledgements
The authors would like to thank Joel Halpern, Michael Tuxen, Randy
Stewart, Evangelos Haleplidis, Chuanhuang Li, Lars Eggert, Avshalom
Houri, Adrian Farrel, Juergen Quittek, Magnus Westerlund, and Pasi
Eronen for engaging us in discussions that have made this document
better.
Ross Callon was an excellent manager who persevered in providing us
guidance and Joel Halpern was an excellent document shepherd without
whom this document would have taken longer to publish.
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9. References
9.1. Normative References
[RFC2119] Bradner, S., "Key words for use in RFCs to Indicate
Requirement Levels", BCP 14, RFC 2119, March 1997.
[RFC2404] Madson, C. and R. Glenn, "The Use of HMAC-SHA-1-96 within
ESP and AH", RFC 2404, November 1998.
[RFC2409] Harkins, D. and D. Carrel, "The Internet Key Exchange
(IKE)", RFC 2409, November 1998.
[RFC3554] Bellovin, S., Ioannidis, J., Keromytis, A., and R.
Stewart, "On the Use of Stream Control Transmission
Protocol (SCTP) with IPsec", RFC 3554, July 2003.
[RFC3602] Frankel, S., Glenn, R., and S. Kelly, "The AES-CBC Cipher
Algorithm and Its Use with IPsec", RFC 3602,
September 2003.
[RFC3758] Stewart, R., Ramalho, M., Xie, Q., Tuexen, M., and P.
Conrad, "Stream Control Transmission Protocol (SCTP)
Partial Reliability Extension", RFC 3758, May 2004.
[RFC4301] Kent, S. and K. Seo, "Security Architecture for the
Internet Protocol", RFC 4301, December 2005.
[RFC4303] Kent, S., "IP Encapsulating Security Payload (ESP)",
RFC 4303, December 2005.
[RFC4960] Stewart, R., "Stream Control Transmission Protocol",
RFC 4960, September 2007.
[RFC5226] Narten, T. and H. Alvestrand, "Guidelines for Writing an
IANA Considerations Section in RFCs", BCP 26, RFC 5226,
May 2008.
[RFC5810] Doria, A., Ed., Hadi Salim, J., Ed., HAAS, R., Ed.,
Khosravi, H., Ed., Wang, W., Ed., Dong, L., Gopal, R., and
J. Halpern, "Forwarding and Control Element Separation
(ForCES) Protocol Specification", RFC 5810, March 2010.
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9.2. Informative References
[RFC3654] Khosravi, H. and T. Anderson, "Requirements for Separation
of IP Control and Forwarding", RFC 3654, November 2003.
[RFC3746] Yang, L., Dantu, R., Anderson, T., and R. Gopal,
"Forwarding and Control Element Separation (ForCES)
Framework", RFC 3746, April 2004.
[RFC5812] Halpern, J. and J. Hadi Salim, "Forwarding and Control
Element Separation (ForCES) Forwarding Element Model",
RFC 5812, March 2010.
[RFC5798] Nadas, S., Ed., "Virtual Router Redundancy Protocol (VRRP)
Version 3 for IPv4 and IPv6", RFC 5798, March 2010.
[TSVWG-SCTPSOCKET]
Stewart, R., Poon, K., Tuexen, M., Yasevich, V., and P.
Lei, "Sockets API Extensions for Stream Control
Transmission Protocol (SCTP)", Work in Progress,
March 2010.
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Appendix A. Suggested SCTP TML Channel Work Implementation
As mentioned in Section 5, there are two levels of TML channel work
within an NE when a ForCES node (CE or FE) is connected to multiple
other ForCES nodes:
1. NE-level I/O work where a ForCES node (CE or FE) needs to choose
which of the peer nodes to process.
2. Node-level I/O work where a ForCES node, handles the three SCTP
TML channels separately for each single ForCES endpoint.
NE-level scheduling definition is left up to the implementation and
is considered out of scope for this document. Appendix A.4 briefly
discusses some constraints about which an implementer needs to worry.
This document, and in particular Appendix A.1, Appendix A.2, and
Appendix A.3 discuss details of node-level I/O work.
A.1. SCTP TML Channel Initialization
As discussed in Section 5, it is recommended that the FE SHOULD do
socket connections to the CE in the order of incrementing priorities,
i.e., LP socket first, followed by MP, and ending with HP socket
connection. The CE, however, MUST NOT assume that there is ordering
of socket connections from any FE. Appendix B.1 has more details on
the expected initialization of SCTP channel work.
A.2. Channel Work Scheduling
This section provides high-level details of the scheduling view of
the SCTP TML core (Section 4.2.1). A practical scheduler
implementation takes care of many little details (such as timers,
work quanta, etc.) not described in this document. It is left to the
implementer to take care of those details.
The CE(s) and FE(s) are coupled together in the principles of the
scheduling scheme described here to tie together node overload with
transport congestion. The design intent is to provide the highest
possible robust work throughput for the NE under any network or
processing congestion.
A.2.1. FE Channel Work Scheduling
The FE scheduling, in priority order, needs to I/O process:
1. The HP channel I/O in the following priority order:
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1. Transmitting back to the CE any outstanding result of
executed work via the HP channel transmit path.
2. Taking new incoming work from the CE that creates ForCES work
to be executed by the FE.
2. ForCES events that result in transmission of unsolicited ForCES
packets to the CE via the MP channel.
3. Incoming Redirect work in the form of control packets that come
from the CE via LP channel. After redirect processing, these
packets get sent out on external (to the NE) interface.
4. Incoming Redirect work in the form of control packets that come
from other NEs via external (to the NE) interfaces. After some
processing, such packets are sent to the CE.
It is worth emphasizing, at this point again, that the SCTP TML
processes the channel work in strict priority. For example, as long
as there are messages to send to the CE on the HP channel, they will
be processed first until there are no more left before processing the
next priority work (which is to read new messages on the HP channel
incoming from the CE).
A.2.2. CE Channel Work Scheduling
The CE scheduling, in priority order, needs to deal with:
1. The HP channel I/O in the following priority order:
1. Process incoming responses to requests of work it made to the
FE(s).
2. Transmit any outstanding HP work it needs the FE(s) to
complete.
2. Incoming ForCES events from the FE(s) via the MP channel.
3. Outgoing Redirect work in the form of control packets that get
sent from the CE via LP channel destined to external (to the NE)
interface on FE(s).
4. Incoming Redirect work in the form of control packets that come
from other NEs via external interfaces (to the NE) on the FE(s).
It is worth repeating, for emphasis, that the SCTP TML processes the
channel work in strict priority. For example, if there are messages
incoming from an FE on the HP channel, they will be processed first
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until there are no more left before processing the next priority
work, which is to transmit any outstanding HP channel messages going
to the FE.
A.3. SCTP TML Channel Termination
Appendix B.2 describes a controlled disassociation of the FE from the
NE.
It is also possible for connectivity to be lost between the FE and CE
on one or more sockets. In cases where SCTP multi-homing features
are used for path availability, the disconnection of a socket will
only occur if all paths are unreachable; otherwise, SCTP will ensure
reachability. In the situation of a total connectivity loss of even
one SCTP socket, it is recommended that the FE and CE SHOULD assume a
state equivalent to ForCES Association Teardown being issued and
follow the sequence described in Appendix B.2.
A CE could also disconnect sockets to an FE to indicate an "emergency
teardown". The "emergency teardown" may be necessary in cases when a
CE needs to disconnect an FE but knows that an FE is busy processing
a lot of outstanding commands (some of which the FE hasn't gotten
around to processing, yet). By virtue of the CE closing the
connections, the FE will immediately be asynchronously notified and
will not have to process any outstanding commands from the CE.
A.4. SCTP TML NE-Level Channel Scheduling
In handling NE-level I/O work, an implementation needs to worry about
being both fair and robust across peer ForCES nodes.
Fairness is desired so that each peer node makes progress across the
NE. For the sake of illustration, consider two FEs connected to a
CE; whereas one FE has a few HP messages that need to be processed by
the CE, another may have infinite HP messages. The scheduling scheme
may decide to use a quota scheduling system to ensure that the second
FE does not hog the CE cycles.
Robustness is desired so that the NE does not succumb to a Denial-of-
Service (DoS) attack from hostile entities and always achieves a
maximum stable workload processing level. For the sake of
illustration, consider again two FEs connected to a CE. Consider FE1
as having a large number of HP and MP messages and FE2 having a large
number of MP and LP messages. The scheduling scheme needs to ensure
that while FE1 always gets its messages processed, at some point we
allow FE2 messages to be processed. A promotion and preemption-based
scheduling could be used by the CE to resolve this issue.
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Appendix B. Suggested Service Interface
This section outlines a high-level service interface between FEM/CEM
and TML, the PL and TML, and between local and remote TMLs. The
intent of this interface discussion is to provide general guidelines.
The implementer is expected to care of details and even follow a
different approach if needed.
The theory of operation for the PL-TML service is as follows:
1. The PL starts up and bootstraps the TML. The end result of a
successful TML bootstrap is that the CE TML and the FE TML
connect to each other at the transport level.
2. Transmission and reception of the PL messages commences after a
successful TML bootstrap. The PL uses send and receive PL-TML
interfaces to communicate to its peers. The TML is agnostic to
the nature of the messages being sent or received. The first
message exchanges that happen are to establish ForCES
association. Subsequent messages may be either unsolicited
events from the FE PL, control message redirects to/from the CE
to/from FE, or configuration from the CE to the FE, and their
responses flowing from the FE to the CE.
3. The PL does a shutdown of the TML after terminating ForCES
association.
B.1. TML Bootstrapping
Figure 6 illustrates a flow for the TML bootstrapped by the PL.
When the PL starts up (possibly after some internal initialization),
it boots up the TML. The TML first interacts with the FEM/CEM and
acquires the necessary TML parameterization (Section 4.2.1.6). Next,
the TML uses the information it retrieved from the FEM/CEM interface
to initialize itself.
The TML on the FE proceeds to connect the three channels to the CE.
The socket interface is used for each of the channels. The TML
continues to re-try the connections to the CE until all three
channels are connected. It is advisable that the number of
connection retry attempts and the time between each retry is also
configurable via the FEM. On failure to connect one or more
channels, and after the configured number of retry thresholds is
exceeded, the TML will return an appropriate failure indicator to the
PL. On success (as shown in Figure 6), a success indication is
presented to the PL.
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FE PL FE TML FEM CEM CE TML CE PL
| | | | | |
| | | | | Bootup |
| | | | |<-------------------|
| Bootup | | | | |
|----------->| | |get CEM info| |
| |get FEM info | |<-----------| |
| |------------>| ~ ~ |
| ~ ~ |----------->| |
| |<------------| | |
| | |-initialize TML |
| | |-create the 3 chans.|
| | | to listen to FEs |
| | | |
| |-initialize TML |Bootup success |
| |-create the 3 chans. locally |------------------->|
| |-connect 3 chans. remotely | |
| |------------------------------>| |
| ~ ~ - FE TML connected ~
| ~ ~ - FE TML info init ~
| | channels connected | |
| |<------------------------------| |
| Bootup | | |
| succeeded | | |
|<-----------| | |
| | | |
Figure 6: SCTP TML Bootstrapping
On the CE, things are slightly different. After initializing from
the CEM, the TML on the CE side proceeds to initialize the three
channels to listen to remote connections from the FEs. The success
or failure indication is passed on to the CE PL (in the same manner
as was done in the FE).
Post bootup, the CE TML waits for connections from the FEs. Upon a
successful connection by an FE, the CE TML level keeps track of the
transport-level details of the FE. Note, at this stage only
transport-level connection has been established; ForCES-level
association follows using send/receive PL-TML interfaces (refer to
Appendix B.3 and Figure 8).
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B.2. TML Shutdown
Figure 7 shows an example of an FE shutting down the TML. It is
assumed at this point that the ForCES Association Teardown has been
issued by the CE. It should also be noted that different
implementations may have different procedures for cleaning up state,
etc.
When the FE PL issues a shutdown to its TML for a specific PL ID, the
TML releases all the channel connections to the CE. This is achieved
by closing the sockets used to communicate to the CE. This results
in the stack sending a SCTP shutdown, which is received on the CE.
FE PL FE TML CE TML CE PL
| | | |
| Shutdown | | |
|----------->| | |
| |-disconnect 3 chans. | |
| |-SCTP level shutdown | |
| |------------------------>| |
| | | |
| | |TML detects shutdown|
| | |-FE TML info cleanup|
| | |-optionally tell PL |
| | |------------------->|
| | | |
| |- clean up any state of | |
| |-channels disconnected | |
| |<------------------------| |
| |-SCTP shutdown ACK | |
| | | |
| Shutdown | | |
| succeeded | | |
|<-----------| | |
| | | |
Figure 7: FE Shutting Down
On the CE side, a TML disconnection would result in possible cleanup
of the FE state. Optionally, depending on the implementation, there
may be need to inform the PL about the TML disconnection. The CE-
stack-level SCTP sends an acknowledgement to the FE TML in response
to the earlier SCTP shutdown.
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B.3. TML Sending and Receiving
The TML should be agnostic to the content of the PL messages, or
their operations. The PL should provide enough information to the
TML for it to assign an appropriate priority and loss behavior to the
message. Figure 8 shows an example of a message exchange originated
at the FE and sent to the CE (such as a ForCES association message),
which illustrates all the necessary service interfaces for sending
and receiving.
When the FE PL sends a message to the TML, the TML is expected to
pick one of HP/MP/LP channels and send out the ForCES message.
FE PL FE TML CE TML CE PL
| | | |
|PL send | | |
|----------->| | |
| | | |
| | | |
| |-pick channel | |
| |-TML Send | |
| |------------->| |
| | | |
| | |-TML Receive on chan. |
| | |- mux to PL/PL recv |
| | |--------------------->|
| | | ~
| | | ~ PL Process
| | | ~
| | | PL send |
| | |<---------------------|
| | |-pick chan to send on |
| | |-TML send |
| |<-------------| |
| |-TML Receive | |
| |-mux to PL | |
| PL Recv | | |
|<---------- | | |
| | | |
Figure 8: Send and Recv Flow
When the CE TML receives the ForCES message on the channel on which
it was sent, it demultiplexes the message to the CE PL.
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The CE PL, after some processing (in this example, dealing with the
FE's association), sends the TML the response. As in the case of FE
PL, the CE TML picks the channel to send on before sending.
The processing of the ForCES message upon arrival at the FE TML and
delivery to the FE PL is similar to the CE side equivalent as shown
above in Appendix B.3.
Authors' Addresses
Jamal Hadi Salim
Mojatatu Networks
Ottawa, Ontario
Canada
EMail: hadi@mojatatu.com
Kentaro Ogawa
NTT Corporation
3-9-11 Midori-cho
Musashino-shi, Tokyo 180-8585
Japan
EMail: ogawa.kentaro@lab.ntt.co.jp
Hadi Salim & Ogawa Standards Track [Page 28]
ERRATA