Internet Draft Resource Management in Diffserv Framework Sept. 2003
Internet Engineering Task Force L. Westberg
INTERNET-DRAFT M. Jacobsson
Expires March 2004 S. Oosthoek
D. Partain
V. Rexhepi
R. Szabo
P. Wallentin
Ericsson
G. Karagiannis
University of Twente
Sept. 2003
Resource Management in Diffserv (RMD) Framework
draft-westberg-rmd-framework-04.txt
Status of this memo
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Distribution of this memo is unlimited.
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Copyright Notice
Copyright (C) The Internet Society (2002). All Rights Reserved.
Abstract
This draft presents the work on the framework for the Resource
Management in Diffserv (RMD) designed for edge-to-edge resource
reservation in a Differentiated Services (Diffserv) domain. The RMD
extends the Diffserv architecture with new resource reservation
concepts and features. Moreover, this framework enhances the Load
Control protocol described in [WeTu00].
The RMD framework defines two architectural concepts:
- the Per Hop Reservation (PHR)
- the Per Domain Reservation (PDR)
The PHR protocol is used within a Diffserv domain on a per-hop basis
to augment the Diffserv Per Hop Behavior (PHB) with resource
reservation. It is implemented in all nodes in a Diffserv domain. On
the other hand, the PDR protocol manages the resource reservation per
Diffserv domain, relying on the PHR resource reservation status in
all nodes. The PDR is only implemented at the boundary of the domain
(at the edge nodes).
The RMD framework presented in this draft describes the new
reservation concepts and features. Furthermore it describes the:
- relationship between the PHR and PHB
- interaction between the PDR and PHR
- interoperability between the PDR and external resource
reservation schemes
This framework is an open framework in the sense that it provides the
basis for interoperability with other resource reservation schemes
and can be applied in different types of networks as long as they are
Diffserv domains. It aims at extreme simplicity and low cost of
implementation along with good scaling properties.
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Table of Content
1 Introduction ................................................. 5
1.1 Definitions/Terminology .................................... 7
2 Overview of the RMD Framework Protocols ...................... 9
2.1 RMD framework scenarios .................................... 11
2.2 PDR protocol functions ..................................... 13
2.3 PHR protocol functions ..................................... 14
3 The PDR protocols ............................................ 14
3.1 Introduction ............................................... 14
3.2 Per Domain Reservation (PDR) protocol features ............. 15
3.2.1 Ingress node addressing .................................. 16
3.2.2 Error control ............................................ 16
3.2.3 Management of Reservation States ......................... 17
3.2.4 Resource Unavailability .................................. 18
3.2.5 Severe congestion handling ............................... 18
3.2.6 Modification of a reservation state ...................... 19
3.2.7 Bi-directional reservations .............................. 20
4 The PHR protocols ............................................ 21
4.1 Introduction ............................................... 21
4.2 Per Hop Reservation (PHR) protocol features ................ 22
4.2.1 One reservation state per Diffserv class PHB ............. 23
4.2.2 Sender-initiated ......................................... 23
4.2.3 Adapts to Load Sharing ................................... 24
4.2.4 Severe Congestion Detection and Notification ............. 26
4.2.4.1 Severe congestion Detection ............................ 26
4.2.4.2 Severe Congestion Notification ......................... 27
5 Examples of RMD Operation .................................... 28
5.1 Examples of signalling Message Types ....................... 28
5.1.1 PHR signalling message types ............................. 29
5.1.1.1 PHR_Resource_Request ................................... 29
5.1.1.2 PHR_Refresh_Update ..................................... 29
5.1.1.3 PHR_Resource_Release ................................... 29
5.1.2 PDR signalling message types ............................. 30
5.1.2.1 PDR_Reservation_Request ................................ 30
5.1.2.2 PDR_Refresh_Request .................................... 30
5.1.2.3 PDR_Release_Request .................................... 31
5.1.2.4 PDR_Reservation_Report ................................. 31
5.1.2.5 PDR_Refresh_Report ..................................... 31
5.1.2.6 PDR_Congestion_Report .................................. 31
5.1.2.7 PDR_Request_info ....................................... 32
5.2 Example of Normal operation ................................ 32
5.2.1 Normal Operation using the reservation-based PHR ......... 32
5.2.1.1 Example 1: No Reservation State in Ingress/Egress ...... 32
5.2.1.2 Example 2 .............................................. 38
5.2.2 Normal operation using the measurement-based PHR ......... 42
5.3 Example of Fault Handling Operation ........................ 44
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5.3.1 Loss of PHR signalling messages .......................... 44
5.3.2 Severe Congestion Handling operation ..................... 45
5.3.2.1 PHR message marking .................................... 45
5.3.2.2 Proportional marking ................................... 50
5.4 Example of Adaptation to equal cost path load sharing op-
eration ................................................... 51
5.5 Example of modification of reservation state ............... 55
6 Interoperability with external resource reservation schemes
........................................................... 57
7 Applicability scope of the RMD framework ..................... 58
8 Tunneling .................................................... 59
9 Security Considerations ...................................... 59
10 Conclusions ................................................. 59
11 References .................................................. 60
12 Acknowledgements ............................................ 62
13 Authors' Addresses .......................................... 62
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1. Introduction
Today's Internet applications range from simple ones such as e-mail,
web browsing and file transfers to highly demanding real-time
applications like audio and video streaming, IP telephony and
multimedia conferencing. This diversity has influenced the user's and
provider's expectations of the Internet infrastructure for satisfying
the diverse service needs of the applications. In a highly
competitive environment such as the Internet Service Providers'
(ISPs) world, satisfying customer needs, whether they are other ISPs
or end users, is key to survival. Therefore, the ISPs' zeal to
provide value-added services to their customers is natural.
One significant class of such value-added services requires real-time
message transport. It can be expected that these real-time services
will be popular as they replicate or are natural extensions of
existing communication services like telephony.
Moreover, it is expected that next generation ISP backbone networks
will have to support a huge real-time traffic (mixed with best effort
traffic) volume that is generated by a huge number of users.
Therefore, exact and reliable resource management (such as admission
control) is essential for achieving high utilization in networks with
real-time transport requirements. Solving this problem is difficult
primarily due to scalability issues.
The Differentiated Services (Diffserv) architecture ([RFC2475],
[RFC2638], [BeBi99]) was introduced as a result of efforts to avoid
the scalability and complexity problems of Intserv [RFC1633].
Scalability is achieved by offering services on an aggregate basis
rather than per-flow and by forcing as much of the per-flow state as
possible to the edges of the network. The service differentiation is
achieved using the Differentiated Services (DS) field in the IP
header and the Per-Hop Behavior (PHB) as main building blocks.
Packets are handled at each node according to the PHB indicated by
the DS field in the message header.
The Diffserv domain will provide to its customer, which is a host or
another domain, the required service by complying fully with the
Service Level Agreement (SLA) agreed upon. The SLA can either be
negotiated statically or dynamically. The transit service to be
provided with accompanying parameters like transmit capacity, burst
size and peak rate is specified in the technical part of the SLA, the
Service Level Specification (SLS).
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However, the Diffserv architecture currently does not standardize any
solution for dynamic resource reservation. This memo, the RMD
framework, defines a dynamic resource reservation scheme that can be
used for the dynamic SLS provisioning in an edge-to-edge Diffserv
domain. As such, once solutions for resource reservation are
introduced, Diffserv needs to be extended with new features.
Moreover, this framework enhances the Load Control protocol described
in [WeTu00]. The basic functionality in the interior nodes as
proposed by that memo is similar to the proposal in this memo.
The RMD framework distinguishes between two types of protocols, the
Per Domain Reservation (PDR) and Per Hop Reservation (PHR) protocols:
- A Per Domain Reservation protocol is used to perform resource
reservation in the complete Diffserv domain. A PDR protocol
is used by the edge nodes (ingress and egress), but not by
the interior nodes.
- A Per Hop Reservation protocol is used to perform a per-hop
reservation, extending the Diffserv PHB. A PHR protocol
is used in all nodes in the Diffserv domain (both edge and
interior nodes) on a hop by hop basis.
Furthermore, the RMD framework defines:
- the relationship between the PHR and PHB
- the interaction between the PDR and PHR
- interoperability between the PDR and external resource
reservation schemes
The design of the PHR and PDR protocols extends the Diffserv
framework with new features necessary for the deployment of the RMD
in Diffserv domains. The new features required in this reservation
scheme are presented in this framework draft. As this reservation
scheme is meant as a solution for a single domain, it is very
important that it is able to interoperate with other resource
reservation schemes used in other domains, and, as such, be part of
end-to-end resource reservation mechanisms. This framework is an open
framework in the sense that it provides the basis for
interoperability with other resource reservation schemes and is to be
applied in different types of networks as long as they are Diffserv
domains. Furthermore, it is possible for the RMD framework to co-
exist with statically allocated PHBs and SLSs.
The framework scheme presented in this document aims at extreme
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simplicity and low cost of implementation along with good scaling
properties.
1.1. Definitions/Terminology
DS behavior aggregate (identical to [RFC2475]):
A collection of packets with the same DS codepoint crossing
a link in a particular direction.
DS-compliant (identical to [RFC2475]):
Enabled to support differentiated services functions and
behaviors as defined in [RFC2474], this document, and other
differentiated services documents; usually used in reference
to a node or device.
Per Hop Behavior (PHB) (identical to [RFC2475]):
The externally observable forwarding behavior applied at
a DS-compliant node to a DS behavior aggregate.
Per Hop Reservation (PHR):
The per-hop resource reservation in a Diffserv domain,
extending the Diffserv PHB, e.g., the bandwidth allocated to
an AF PHB (see RFC2597]), with resource reservation. It is
implemented at both the interior nodes and the edge nodes.
Per Hop Reservation (PHR) protocol:
A type of protocol that is used to perform a per hop
reservation. A PHR protocol is used in all nodes in the
Diffserv domain (both edge and interior nodes) on a hop by
hop basis.
Per Domain Behavior (PDB)(similar to [NiKa01]):
Describes the behavior experienced by a particular set of
packets as they cross a DS domain. A PDB is characterized
by specific metrics that quantify the treatment that a set
of packets with a particular DSCP (or set of DSCPs) will
receive as it crosses a DS domain.
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Per Domain Reservation (PDR):
The resource reservation in the complete Diffserv domain.
Per Domain Reservation (PDR) protocol:
A type of protocol used to perform a per domain reservation.
A PDR protocol is used by edge nodes (ingress and egress),
but not by the interior nodes.
Edge nodes:
Nodes that are located at the boundary of a Diffserv domain.
Interior node:
All the nodes that are part of a Diffserv domain and are
not edge nodes.
Ingress node:
An edge node that handles the traffic as it enters the
Diffserv domain.
Egress node:
An edge node that handles the traffic as it leaves the
Diffserv domain.
End Host:
QoS-aware end terminal, either fixed or mobile, i.e. running
QoS-aware applications
RMD domain:
A Diffserv domain that uses the RMD framework.
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].
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2. Overview of the RMD Framework Protocols
The RMD framework is based on Diffserv principles for QoS
provisioning and extends these principles with new ones necessary to
provide resource provisioning and control in Diffserv domains.
The RMD operates in a Diffserv domain and therefore support for
different levels of Quality of Service (QoS) MUST be provided using
Diffserv, as defined in [RFC2475].
The RMD framework will use the Diffserv classes Expedited Forwarding
(EF) [RFC2598] and Assured Forwarding (AF) [RFC2597] as QoS classes.
This implies that any network supporting the RMD framework MUST be
able to classify, mark, police and schedule the traffic accordingly.
It is assumed that different externally defined QoS classes can be
translated into these Diffserv classes (Per Hop Behaviors).
In order to maximize the scalability in the Diffserv domain the
complexity imposed by the resource reservation scheme has to be moved
as much as possible away from the interior nodes. Therefore, the RMD
framework separates the problem of a complex reservation within a
domain from a simple reservation within a node. This is accomplished
by specifying two types of resource reservation protocols.
The first resource reservation protocol type is denoted as Per Hop
Reservation (PHR) that enables reservation of resources per PHB in
each node within a Diffserv domain. This protocol type is optimized
to reduce the requirements placed on the functionality of the
interior nodes. For example, the nodes that implement this protocol
type do not have per flow responsibilities. This protocol can be
either reservation-based or measurement-based. In the reservation-
based PHR, each node keeps only one reservation state per PHB. In the
measurement-based PHR no reservation states are installed and the
resource availability is checked by measuring real average traffic
(user) data load.
The second protocol type is denoted as Per Domain Reservation (PDR)
and is responsible for the resource reservation within the complete
Diffserv domain. The PDR is used by edge nodes (ingress and egress)
but not by the interior nodes. This protocol introduces strict and
complex requirements on the functionality implemented on the edge
nodes. An example of such functionality is the mapping of the traffic
parameters signalled by an external QoS request to parameters that
are useful to the RMD scheme. In the RMD framework, different PDR
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and PHR protocols can be used within a Diffserv domain
simultaneously.
The PHR protocol is a new protocol while the PDR protocol can be
either a new protocol or (one or more) existing protocols. Examples
of such existing protocols can be the Resource Reservation Protocol
(RSVP) [RFC2205], RSVP aggregation [RFC3175], Simple Network
Management Protocol (SNMP) [RFC1905], Common Open Policy Service
(COPS) [RFC2748].
There may be different levels of granularity between external QoS
requests and PDR reservations, e.g., one to one, many-to-one.
Similarly there may be different levels of granularity between PDR
protocol actions and PHR protocol actions, e.g., one to one, one-to-
many and many-to-one.
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2.1. RMD framework scenarios
Two different scenarios are identified wherein this framework is
applied. The first scenario illustrated in Figure 1 includes ingress
nodes, egress nodes and interior nodes.
The second scenario, illustrated in Figure 2, includes in addition to
the nodes depicted in Figure 1, also an "oracle" (or "agent") that is
involved in the per domain reservation, but which does not provide
any resources by itself. Note that combinations of the two scenarios
may be possible.
|--------| |--------| |--------| |--------| |--------|
| | | | | | | | | |
|Ingress | |Interior| |Interior| |Interior| | Egress |
| node |<->| node |<->| node |<->| node |<->| node |
| | | | | | | | | |
|--------| |--------| |--------| |--------| |--------|
Figure 1: First scenario for the RMD framework
|--------|
| |
-------------------->|"Oracle"|<---------------------
| | | |
| |--------| |
v v
|--------| |--------| |--------| |--------| |--------|
| | | | | | | | | |
|Ingress | |Interior| |Interior| |Interior| | Egress |
| node |<->| node |<->| node |<->| node |<->| node |
| | | | | | | | | |
|--------| |--------| |--------| |--------| |--------|
Figure 2: Second scenario for the RMD framework
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Figures 3 and Figure 4 depict the peers in the communication of the
PDR and PHR protocols in the two different scenarios. In Section 5
below, some examples illustrating the usage of actual PDR and PHR
protocols in different scenarios are given.
External
QoS <---|
Request |
\|/
|---------| |---------|
| PDR |<---------------------------------------->| PDR |
|---------| |---------|
| |
|---------| |--------| |--------| |--------| |---------|
| PHR |<->| PHR |<->| PHR |<->| PHR |<->| PHR |
|---------| |--------| |--------| |--------| |---------|
ingress interior interior interior egress
Figure 3: PDR and PHR protocol peers in the first scenario
In the first scenario, the PDR protocol is used between the ingress
and egress nodes. The ingress node receives an external QoS request
and initiates the per domain reservation. The PHR protocol is used
between all nodes on an hop-by-hop basis along the path from the
ingress to the egress. The PDR protocol may use the PHR protocol or
any underlying protocol for the transport of PDR messages.
External
QoS <--------|
Request |
\|/
|---------| |----------| |---------|
| PDR |<------------->| PDR |<------------->| PDR |
|---------| |----------| |---------|
| |
|---------| |--------| |--------| |---------|
| PHR |<->| PHR |<-------------->| PHR |<->| PHR |
|---------| |--------| |--------| |---------|
ingress interior oracle interior egress
Figure 4: PDR and PHR protocol peers in the second scenario
In the second scenario, the "oracle" receives the external QoS
request and uses a PDR protocol towards the ingress and egress nodes
to perform the per domain reservation. Note that the "oracle" does
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not use the PHR protocol.
In the RMD framework all of the PHR signalling messages are to be
generated and discarded at the edge nodes (ingress and egress nodes)
and not at the end hosts. Moreover, all of the PDR messages are to be
generated and discarded either at the edge nodes or at the oracle.
2.2. PDR protocol functions
A PDR protocol implements all or a subset of the following functions:
* Mapping of external QoS request to a Diffserv Code Point
(DSCP).
* Admission control and/or resource reservation within
a domain.
* Maintenance of flow identifier and reservation state
per flow (or aggregated flows), e.g. by using soft state
refresh.
* Modification of an already installed reservation state.
* Notification of the ingress node IP address to the egress
node.
* Notification that lost signalling messages (PHR and PDR)
occurred in the communication path from the ingress to the
egress nodes.
* Notification of resource availability in all the nodes
located in the communication path from the ingress to the
egress nodes.
* Severe congestion handling. Due to a route change or a
link failure, a severe congestion situation may occur.
The egress node is notified by PHR when such a severe
congestion situation occurs. Using PDR, the egress node
notifies the ingress node about this severe congestion
situation. The ingress node resolves this situation by using
a predefined policy, e.g., refusing new incoming flows and
terminating a portion of the affected flows.
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2.3. PHR protocol functions
A PHR protocol implements all or a subset of the following
functions:
* Admission control and/or resource reservation within a node.
* Management of one reservation state per PHB by using
a combination of the reservation soft state and explicit
release principles.
* Measurement of the user traffic load.
* Stores a pre-configured threshold value on maximal allowable
traffic load (or resource units) per PHB.
* Adaptation to load sharing. Load sharing allows interior
nodes to take advantage of multiple routes to the same
destination by sending via some or all of these available
routes. The PHR protocol has to adapt to load sharing once
it is used.
* Severe congestion notification. This situation occurs as
a result of route changes or a link failure. The PHR
has to notify the edges about the occurrence of this
situation.
* Transport of transparent PDR messages. The PHR protocol may
encapsulate and transport PDR messages from an ingress node
to an egress node.
3. The PDR protocols
3.1. Introduction
A PDR protocol component interacts with external resource requests
(via, for example, RSVP [RFC2205]) and with the PHR protocol
component for handling resources within the edge-to-edge domain.
A PDR protocol manages the reservation of the resources per Diffserv
domain and is implemented at the edges of this domain. This protocol
handles the dynamic reservation requests, that is their admission or
rejection, and possibly based on the results of the edge-to-edge
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domain per hop reservation (PHR). These dynamic reservation requests,
shown as "ext. QoS request" in Figures 1 to 4, are generated
externally to the Diffserv domain and various protocols might
potentially be used to make these requests (RSVP, RSVP aggregation,
etc.).
A PDR protocol component should always be able to interpret the
resource request and map it into an appropriate DSCP to be used in
the edge-to-edge domain. Depending on these external protocols or
resource reservation schemes, different PDR protocols can be defined
in order to comply with the above requirement. The PDR protocol thus
is a link between the external resource reservation scheme and the
edge-to-edge PHR.
A PDR protocol should be able to identify and specify any external
request for establishment and maintenance of resources using a
(possibly aggregated) flow definition, i.e., flow specification
identifier (ID).
The flow specification ID is only used by the edge nodes to provide
the per-domain reservation (PDR) functionality. Depending on the PDR
type used, different flow IDs can be specified. For example, a flow
specification ID can be a combination of source IP address,
destination IP address and the DSCP field. The flow specification ID
is used to identify a (possibly aggregated) state that will only be
maintained in the edge nodes.
3.2. Per Domain Reservation (PDR) protocol features
Depending either on the external resource reservation scheme with
which the Diffserv domain has to interwork or on the characteristics
of the network, the RMD framework MAY specify that several PDRs could
use one PHR.
For example, a core network that is applying RSVP aggregation for
resource management will use a different PDR than the PDR that has to
be used in a wireless access network that is interconnected to the
same core network which is using RSVP/Intserv for resource
management.
However, both Diffserv domains may use the same reservation-based
PHR. For each of these PDRs, there MAY be certain specific functions
defined. However, the RMD framework defines a common set of features
that need to be realized by any PDR that uses a specific PHR, such as
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the RODA PHR [RODA]. These features are described in the sections
below. Besides this common set of features, there is also an optional
feature described in Section 3.2.6.
3.2.1. Ingress node addressing
There are many situations, such as acknowledgement of a request, when
the egress node has to notify the ingress node about the resource
reservation status of the communication path between ingress and
egress nodes using the PDR protocol, i.e., the request is admitted or
is rejected.
This means that the egress node MUST be able to send a PDR signalling
message to the ingress node. Depending on the PDR used and
consequently also on the flow id specification (see Section 3.1), the
IP address of the ingress node can be derived in two ways:
* The egress node can determine the IP address of the ingress
node from the available information contained in the
header of a received PHR signalling message. This could,
for example, be the source IP address of the PHR signalling
message received.
* The ingress node has to encapsulate its IP address in the
PDR signalling message that is encapsulated in a PHR
signalling message. The egress node decapsulating the PHR
is able to extract the PDR signalling message and the IP
address of the ingress node.
3.2.2. Error control
The PHR signalling messages may be dropped in the communication path
from the ingress to the egress nodes.
If a reservation-based PHR is used, these messages might have been
received by some of the intermediate interior nodes located in this
communication path before being dropped. Some other interior nodes
located on the same communication path might not receive these PHR
signalling messages. This will mean that the interior nodes that
received this PHR signalling message will reserve resources that will
not be used.
Should this occur, the PDR protocol MUST be able to handle the
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recovery of the dropped reservation-based and measurement-based PHR
signalling messages. One possible solution to this is described in
Section 5.3.1.
3.2.3. Management of Reservation States
The per-domain reservation functionality MUST support the initiation
and maintenance of PDR states. This can be accomplished by using
either a new defined PDR protocol or (one or more) already existing
protocols. Examples of such existing protocols are the Resource
Reservation Protocol (RSVP) [RFC2205], RSVP aggregation [RFC3175],
Simple Network Management Protocol (SNMP) [RFC1905], Common Open
Policy Service (COPS) [RFC2748]. These states will be identified
using the flow specification ID (see Section 3.1) and the related
requested resource unit per Diffserv class PHB.
The egress node MUST be able to identify the flow using the flow
specification ID after receiving a PHR signalling message. Depending
on the PDR protocol type being used, the flow specification ID can be
derived in two ways:
* Derived from PHR message: the flow specification ID can be
derived from the available information contained in the
header of the PHR signalling message received. This could,
for example, be the combination of the source and destination
IP addresses and the DSCP in the PHR signalling message.
* Derived from PDR message: the flow specification ID is
included in the PDR signalling message that is encapsulated
by the ingress node into the PHR signalling message. The
egress node decapsulating the PHR is able to extract the PDR
signalling message and the flow specification ID information.
Moreover, the PDR signalling message that is sent by the
egress node towards the ingress node MUST also contain the
flow specification ID information.
The PDR resource reservation states can be either hard or soft
states. If these states are hard they will have to be initiated,
updated or released explicitly. If these states are soft states then
they have to be updated regularly. The PDR soft state can be released
by using the refresh timeout or by explicit release of the reserved
resources.
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3.2.4. Resource Unavailability
When there are insufficient resources available in the communication
path between the ingress node and egress node, the ingress node that
generated the PHR signalling messages will have to be notified by
means of a PDR reporting message. Any interior node that does not
admit a reservation request will mark the PHR signalling message that
will be sent towards the egress node. The egress node will in return
generate and send to the ingress node a marked PDR signalling message
to indicate that the communication path is not able to admit the
reservation request. Upon receiving this message the PDR
functionality in the ingress node will inform the external resource
reservation scheme that its associated request for RMD resources is
rejected.
When the reservation based PHR group is used, the marked PHR
signalling message will also include the number of previous interior
nodes that successfully reserved the resources for this PHR
reservation signalling message (see [RODA]). This information will be
sent to the ingress node as part of the PDR report message. The
ingress node will initiate a partial explicit release procedure. This
procedure will release the resources that were unnecessarily reserved
by the interior nodes located on the same communication path as the
interior node that rejected and marked the PHR reservation message
(see Section 5.2.1).
Note that when the adaptation to load sharing procedure is applied,
(see Section 4.2.3), the partial explicit release procedure should
not be used. In this case the resources that were unnecessarily
reserved by the interior nodes located on the same communication path
as the interior node that rejected and marked the PHR reservation
message will be released by using the reservation soft state
principle.
3.2.5. Severe congestion handling
Severe congestion can be considered as an undesirable state which may
occur as a result of a route change or a link failure. Typically,
routing algorithms are able to adapt and change their routing
decisions to reflect changes in the topology and traffic volume. In
such situations the re-routed traffic will have to follow a new path.
Nodes located on this new path may become overloaded, since they
suddenly might need to support more traffic than their capacity.
Moreover, when a link fails, the traffic passing through it might be
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dropped, degrading its performance.
Severe congestion occurrence in the communication path has to be
notified to the ingress node that generated the PHR signalling
messages. Any interior node that detects the severe congestion will
mark (severe congestion bit) the PHR signalling message that will be
sent towards the egress node. The egress node will in return generate
and send to the ingress node a marked PDR signalling message to
indicate the severe congestion occurrence in the communication path.
Upon receiving this message the ingress node resolves this situation
by using a predefined policy, e.g., refusing new incoming flows and
by using the PHR protocol, a portion of the affected by severe
congestion flows either is terminated or is preempted (e.g., shifted
to an alternative PHB).
When the reservation-based PHR is used, the (severe congestion)
marked PHR reservation message will also include the number of
previous interior nodes that successfully processed this PHR
reservation message (see [RODA]). This information will be sent to
the ingress node as part of the PDR report message. The ingress node
will initiate a partial explicit release procedure. This procedure
will release the resources that were unnecessarily reserved by the
interior nodes located on the same communication path as the severe
congested interior node.
Note that when the adaptation to load sharing procedure is applied
(see Section 4.2.3), the partial explicit release procedure should
not be used. In this case the resources that were unnecessarily
reserved by the interior nodes located on the same communication path
as the severe congested interior node will be released by using the
reservation soft state principle.
3.2.6. Modification of a reservation state
The number of resources that were reserved for a certain flow can be
modified by using this feature (see also Section 5.5). When the
ingress node receives an external QoS request that is requesting a
modification on the number of reserved resources then the following
process can be realized. When the modification request requires an
increase on the number of reserved resources, then the ingress node
will have to subtract the old and already reserved number of
resources from the number of resources included in the new
modification request. The result of this subtraction should be
introduced within a PHR request message as the requested resources
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value. When the modification request requires a decrease on the
number of reserved resources, then the ingress node will have to
subtract the number of resources included in the new modification
request from the old and already reserved number of resources. The
result of this subtraction should be introduced in a PHR release
message. Furthermore, if the PDR protocol maintains PDR reservation
states then the number of resources that were reserved for a certain
flow should also be replaced with the number of resources included in
the modification request.
3.2.7. Bi-directional reservations
Bi-directional reservations are an optional feature and do not belong
to the common set of features described in Sections 3.2.1 to 3.2.6.
This feature is only relevant when using the RMD framework in
specific kinds of networks.
One method for bi-directional reservations is based on combining two
uni-directional reservations. This is because messages travelling
from the reserving entity are likely to follow a different path than
messages travelling towards it. The bi-directional reservation
imposes a few requirements on the edge nodes, as described below:
* The edge nodes must be able to distinguish between a
uni-directional and a bi-directional resource reservation
PDR signalling message. This SHOULD be accomplished by
using a flag in the header of the PDR signalling messages.
Furthermore, these bi-directional packets MUST include
the requested resource parameters for initiating a
uni-directional reservation in the opposite direction
(from the egress to the ingress). Note that the requested
resource parameters used for bi-directional reservations are
asymmetric, i.e., the value of the requested resources used
in the direction from the ingress node towards the egress
node could be different than the requested resources used in
the direction from the egress node towards the ingress node.
* When an egress node receives a bi-directional reservation
message, the egress node will have to construct a
uni-directional PDR signalling message and a PHR signalling
message that will be sent in the opposite direction. The
source IP address of this PHR signalling message that is
sent towards the ingress node will be the same as the
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destination IP address of the PHR signalling message it
received, while the destination IP address of this PHR
signalling message will be the same as the source IP address
of the PHR signalling message it received.
The ingress node that performs a bi-directional reservation, assuming
that the above requirements are satisfied, will notify the egress
node by means of the PDR signalling messages. On receiving this PDR
signalling message, the egress node will initiate a uni-directional
reverse PDR signalling message, which will take care of the
reservation in the opposite direction.
4. The PHR protocols
4.1. Introduction
The Per Hop Reservation (PHR) protocols extend the PHB in Diffserv by
adding resource reservation, thus enabling reservation of resources
per Diffserv class PHB per hop in each node within a Diffserv domain.
The RMD Framework currently specifies two different PHR groups:
- The Reservation-Based PHR group
In this PHR group, each node in the communication path
from an ingress node to an egress node keeps only one
reservation state per PHB.
The reservation is done in terms of resource units, which
may be based on a single parameter, such as bandwidth,
or on more sophisticated parameters. These resources are
requested dynamically per PHB (i.e., per DSCP) and reserved
on demand on all nodes in the communication path from an
ingress node to an egress node.
Furthermore, this PHR group has to maintain a threshold for
each PHB that specifies the maximum number of reservable
resource units. This threshold could, for example, be
statically configured.
A reservation-based PHR protocol is described in detail in
[RODA]. The RMD framework uses a combination of reservation
soft state and explicit release principles.
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- The Measurement-based Admission Control (MBAC) PHR group
This PHR group is used to check the availability of
resources before flows are admitted and without installing
any reservation state. That is, measurements are done
on the real average traffic (user) data load. The main
advantage of this PHR group is that the PHR functionality
that is executed at the edge and interior nodes will not
have to maintain any reservation states. However, the
measurement based PHR uses two states that do not have
to be maintained by the PHR protocol. One state per PHB
that stores the measured user traffic load associated to
the PHB and another state per PHB that stores the maximum
allowable traffic load per PHB.
Although this is all that is currently defined, new types of PHRs
within a PHR group may be defined in the future, as might new PHR
groups.
To the extent possible, traffic patterns SHOULD be configured in the
nodes rather than signalled. The goal is to simplify the traffic
parameter mapping at the interior nodes and keep complexity at the
edges. This also simplifies the processing of on-demand requests.
For example, some of the token bucket parameters such as token bucket
peak rate and bucket size can be configured.
The negotiated parameter within the edge-to-edge Diffserv domain in
the RMD framework is the number of the requested resource units. For
example, the RODA PHR [RODA] specifies that this parameter is a
simple "bandwidth" parameter and can have a maximum value of 2^16 =
65536 resource units. However, this unit may not necessarily be a
simple bandwidth value. It might be defined in terms of any resource
unit (e.g., effective bandwidth) to support statistical multiplexing
at the message level.
A mapping MUST be performed between the type of the resource units
requested by an external reservation protocol and the resource units
understood by the RMD scheme.
4.2. Per Hop Reservation (PHR) protocol features
The required features for the two PHR groups (the reservation-based
and measurement-based (MBAC)) are different for the two groups.
These features are described in the sections below.
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4.2.1. One reservation state per Diffserv class PHB
The reservation-based PHR installs and maintains one reservation
state per PHB, i.e., per DSCP, in all the nodes located in the
communication path from the ingress node up to the egress node. This
state represents the number of currently reserved resource units that
are signalled by the PHR protocol for the admitted incoming flows.
Thus, the ingress node generates for each incoming flow a PHR
signalling message, which signals only the resource units requested
by this particular flow. These resource units if reserved are going
to be added to the currently reserved resources per PHB and therefore
they will become a part of the per PHB reservation state.
The per PHB reservation states can be created and maintained by
combination of the reservation soft state and explicit release
principles.
When the reservation soft state principle is used, a finite lifetime
is set for the length of the reservation. These reservations are then
maintained by sending periodic PHR refresh messages. The length of
the refresh period MUST be the same throughout the Diffserv domain
and SHOULD be configurable. If this reservation state does not
receive a PHR refresh message within a refresh period, reserved
resources associated to this PHR message will be automatically
released.
The reserved resources for a particular flow can also be explicitly
released from a PHB reservation state by means of PHR release
message. The usage of explicit release enables the instantaneous
release of the resources regardless of the length of the refresh
period. This allows a longer refresh period, which will also reduce
the number of periodic refresh messages.
Furthermore, each node has to maintain a threshold for each PHB that
specifies the maximum number of reservable resource units that could
for example, be statically configured.
This feature is specific only to the reservation-based PHR group.
4.2.2. Sender-initiated
In general, a resource reservation scheme can be sender-initiated or
receiver-initiated. In a receiver-initiated scheme, such as the
Resource reSerVation Protocol [RFC2205], the reservation of the
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resources is initiated by the receiver. This means that backward
routing information has to be stored in the nodes that are located in
the forwarding path between the sender and receiver. This backward
routing information will be used by the reservation messages sent by
the receiver to the sender. All signalling messages belonging to the
same flow will then follow the same backward and forward path.
In order to avoid storing backward routing information in the RMD
framework, a sender-initiated scheme is used.
The ingress node will initiate and manage the resource reservation
process, meaning that it will generate the PHR signalling messages.
Each of these messages may carry either the total amount of the
requested resources or a part of the requested resources.
Assuming that typical IP routing protocols are used, i.e., packets
are routed based on IP destination address, all the PHR signalling
messages that are generated by the edge nodes SHOULD use the IP
addresses of the end hosts involved in the resource reservation
session as the source and destination IP addresses. However,
depending on the PDR used, exceptions should be allowed. For example,
the PHR signalling messages may have the IP addresses of the edge
nodes as the source and destination IP addresses. This will imply
that the traffic (user) data associated with these PHR signalling
messages must be encapsulated with the IP addresses of the edge nodes
as the source and destination IP addresses.
Both PHR groups MUST be sender-initiated.
4.2.3. Adapts to Load Sharing
Load sharing, also known as load balancing, allows interior nodes to
take advantage of multiple routes to the same destination by sending
messages via some or all of these available routes. However, load
sharing will imply that the traffic (user) data will not follow
exactly the same paths as the PHR signalling messages that are used
to reserve the transport resources used by the traffic (user) data.
Load sharing can be characterized as equal or unequal cost (see
[Doy98]), where cost is specified as a generic term referring to any
metric that is associated with the path. Equal cost load sharing
(see, for example, [RFC2676]) distributes traffic equally among the
multiple paths. Unequal cost load sharing, on the other hand, does
not distribute the traffic equally.
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An example of this type may be the optimized multi-path (OMP) that is
able to distribute loading information, proposing a means for
adjusting forwarding and providing an algorithm for making the
adjustments gradually enough to ensure stability yet providing
reasonably fast adjustment when needed. Note that "reasonably fast"
means adaptation in a couple of hours, i.e., daily load fluctuations.
OMP discovers multiple paths, not necessarily equal cost paths, to
any destinations in the network, but based on the load reported from
a particular path, it determines which fraction of the traffic to
direct to the given path. Incoming packets are subject to a (source,
destination address) hash computation, and effective load sharing is
accomplished by means of adjusting the hash thresholds. When
combining with multi-protocol label switching (MPLS) forwarding, OMP
becomes an effective route optimization engine that can serve the
requirements claimed on traffic engineering (TE) in [RFC2702].
Load sharing can be accomplished in different ways:
* Per-destination load sharing: distributes the traffic
based on the destination address. All messages for one
destination on the network travel on the same path.
* Per-message load sharing (or round robin): given equal cost
paths, the first message destined for a particular
destination on the network is sent via one path, the next
message to the same destination is sent via another path,
and so on.
* Using a predefined hash function: the combination of
the source and destination IP addresses and the source and
destination ports is used in a hash function to determine
for each message which load sharing path should be used. In
this situation, even if the various paths may have equivalent
metrics, the traffic associated with one TCP connection is
always routed on a single path.
The Resource Management in Diffserv framework, by means of PHR and
PDR functionality, has the necessary support to adapt to load sharing
when it is used. This feature is mandatory for both PHR groups. An
example of this operation is described in Section 5.4.
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4.2.4. Severe Congestion Detection and Notification
Severe congestion may occur as a result of route changes or a link
failure. Severe congestion SHOULD always be signalled to the edges
by the interior nodes regardless of the type of PHR used. The
interior nodes report the severe congestion occurrence to the edges
by means of PHR signalling messages. The edges MUST solve this
severe congestion state as described in Section 3.2.5.
Severe congestion occurrence in the interior nodes has to be first
detected and then the edges are notified. Due to the fact that the
interior node does not maintain any flow related information, it is
not possible to identify the ID of the passing flow and the IP
address of the ingress node. Therefore, the interior node is not able
to notify the ingress node that a severe congestion situation
occurred.
4.2.4.1. Severe congestion Detection
The PHR functionality in the interior nodes detects the severe
congestion and the PDR protocol informs the edge nodes about this severe
congestion situation.
A number of possible methods of detecting severe congestion are listed
below:
* Link failure: the interior node activates the severe
congestion state whenever a link failure occurs.
* Volume measurements: by using measurements on the data
traffic volume. If the volume of the data traffic increases
suddenly, it is deduced that a possible route change and
at the same time, a severe congestion situation occurred.
* Counting: using a counter that counts the number of
dropped data packets. The severe congestion state is
activated when this number is higher than a pre-defined
threshold. This method is similar to the previous one but
is much simpler. However, it can only be applied when the
traffic characteristics are known.
* Increased number of refreshes: if the number of resource
units, per PHB, requested by PHR refresh messages is
much higher than the number of resources refreshed in
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the previous refresh period, then the node deduces that
a severe congestion occurred. This is a very efficient,
but it can only be used when the PHR refresh period is small.
The first three detection methods can be applied on both types of PHR,
i.e., reservation-based and measurement-based. The last method can only
be applied on the reservation-based RMD scheme.
4.2.4.2. Severe Congestion Notification
Once detected the severe congestion should be signalled to the edges. As
previously mentioned, the egress node will first be notified, after
which the egress will notify the ingress node via the PDR protocol.
Below is a list of several notification methods that can be used:
* Greedy marking: all user data packets which pass through
a severe congested interior node and are associated with a
certain PHB will be remarked into a domain specific Diffserv
code point (DSCP)
* Proportional marking: this method is similar to the previous
method, with the difference that the number of the remarked
packets is proportional to the detected overload
* PHR message marking: only PHR signalling messages that
pass through a severely congested interior node will be
marked. The marking is done by setting a special flag in
the protocol message, i.e., "S" (see [RODA]). This is an
efficient procedure, but it can only be used when the PHR
refresh period is small.
The last method can only be applied on the reservation-based PHR, while
the other two can be applied on both PHR types. A comparison between
different severe congestion solutions is given in [CsTa02]. Furthermore,
[CsTa02] demonstrates that there are severe congestion solutions that
can efficiently solve the severe congestion situation.
The simple operation in case of a severe congestion is described in
Section 5.3.2.
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5. Examples of RMD Operation
The RMD framework extends the Diffserv architecture by adding dynamic
resource reservations. It is applied edge-to-edge in a dynamically
provisioned Diffserv domain. The admission or rejection of the
incoming SLS request relies on the result of the PHR signalling
protocol. The PDR protocol is the one that links the SLA/SLS request
and the PHR protocol. Later in this document, the SLA/SLS request
will be referred to simply as a QoS request.
The functional operation of the RMD framework is described as
interoperation between the PHR and PDR functions, abstracted from the
details in the following scenarios:
* normal operation
* fault handling:
- loss of PHR signalling messages
- severe congestion handling
There are two typical example scenarios used for describing the
normal operation and fault handling of the RMD framework:
Example 1: PDR protocol will initiate and maintain the PDR
states in the ingress/egress nodes. In this scenario
it is assumed that the external QoS request does
not create any resource reservation states in the
ingress/egress nodes.
Example 2: PDR protocol will use (partially or fully) the
resource reservation states initiated and maintained
by an external protocol as PDR states.
The signalling message types are also explained briefly.
5.1. Examples of signalling Message Types
The RMD Framework classifies the signalling messages into PHR and PDR
signalling messages for supporting PHR and PDR functionality,
respectively.
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5.1.1. PHR signalling message types
There are three types of PHR signalling messages.
5.1.1.1. PHR_Resource_Request
The "PHR_Resource_Request" signalling message is common to both PHR
groups, but its role is different in the two PHR groups:
1. The reservation-based "PHR_Resource_Request" signalling
message is generated by the ingress node in order to
initiate or update the aggregated soft state reservation
in the communication path to the egress node.
2. The measurement-based "PHR_Resource_Request" PHR
signalling message is generated by the ingress node to
check the monitoring status of each node located in the
communication path between the ingress node and egress node.
5.1.1.2. PHR_Refresh_Update
The "PHR_Refresh_Update" signalling message is specific to
reservation-based PHR group.
The "PHR_Refresh_Update" signalling message is generated by the
ingress node in order to initiate, update or refresh the soft state
reservation per DSCP in the communication path to egress node.
If possible, all the nodes should process the "PHR_Refresh_Update"
messages with a higher priority than the "PHR_Resource_Request"
messages.
5.1.1.3. PHR_Resource_Release
The "PHR_Resource_Release" signalling message is used only when the
RMD framework supports PHR explicit release procedures.
The "PHR_Resource_Release" signalling message is generated by the
ingress edge in order to release a part of, or all the reserved
resources per DSCP. Furthermore, this message should specify the
amount of resources that have to be explicitly released.
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Note that in case that the bi-directional reservation is required,
the egress router in addition to the normal processing, it will also
respond to a bi-directional "PHR_Resource_Release" message with a
unidirectional reservation "PHR_Resource_Release" message that is
sent towards the ingress node. This uni-directional reservation
message should be processed with a higher priority then other
"PHR_Resource_Release" messages.
5.1.2. PDR signalling message types
The PDR signalling messages are processed only by the RMD edge nodes
and not by the interior nodes. The PDR protocol can either be an
entirely new protocol (see Example 1, Section 5.2.1.1) or it may use
one of the existing protocols such as RSVP, RSVP aggregation, SNMP,
COPS, etc. (see Example 2, Section 5.2.1.2) as part of its
functionality. In order to describe the functionality of the PDR
there are several messages denoted in this document, which are not
formally specified protocol messages, but represent an
exemplification of possible protocol messages used for exchanging the
PDR information (such as flow id, address of the ingress) between
edge nodes. These PDR signalling messages may also be encapsulated
into PHR messages in case it is necessary.
These PDR signalling exemplification messages are listed below. If
possible all the nodes should process the "PDR_Refresh_Report"
messages with a higher priority than the "PDR_Reservation_Report"
messages.
5.1.2.1. PDR_Reservation_Request
The "PDR_Reservation_Request" signalling message is generated by the
ingress node in order to initiate or update the PDR state in the
egress node.
5.1.2.2. PDR_Refresh_Request
The "PDR_Refresh_Request" message is sent by the ingress node to the
egress node to refresh the PDR states located in the egress node.
Any of the "PDR_Reservation_Request" or "PDR_Refresh_Request"
messages may either be or not be encapsulated into a PHR message.
When any of these PDR messages is encapsulated into one PHR message,
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then this PDR message SHOULD contain the information that is required
by the egress node to associate the PHR signalling message that
encapsulated this PDR message to for example the PDR flow ID and/or
the IP address of the ingress node. sh 4 "PDR_Modification_Request"
The "PDR_Modification_Request" message is sent by the ingress node to
the egress node to modify the PDR states located in the egress node.
5.1.2.3. PDR_Release_Request
The "PDR_Release_Request" messages are only used when the PDR state
does not use a reservation soft state principle. These messages are
sent by the ingress node to the egress node to release the flows
explicitly.
5.1.2.4. PDR_Reservation_Report
The "PDR_Reservation_Report" messages are sent by the egress node to
the ingress node to report that a
"PHR_Resource_Request"/"PDR_Reservation_Request" has been received
and that the request has been admitted or rejected. The same report
message can be used to report that a
"PHR_Resource_Request"/"PDR_Modification_Request" received and that
the modification request has been admitted or rejected.
5.1.2.5. PDR_Refresh_Report
The "PDR_Refresh_Report" messages are sent by the egress node to the
ingress node to report that a "PHR_Refresh_Update"/
"PDR_Refresh_Request" message has been received and has been
processed.
5.1.2.6. PDR_Congestion_Report
The "PDR_Congestion_Report" messages are used for severe congestion
notification and are sent by the egress node to the ingress node.
These PDR report messages are only used when either the "greedy
marking" or "proportional marking" severe congestion notification
procedures, described in Section 4.2.4, are used.
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5.1.2.7. PDR_Request_info
A "PDR_Request_info" message is encapsulated into a PHR signalling
message that is sent by the ingress node towards the egress node.
This PDR message is containing the information that is required by
the egress node to associate the PHR signalling message that
encapsulated this PDR message to for example the PDR flow ID and/or
the IP address of the ingress node.
5.2. Example of Normal operation
Normal operation refers to the situation when no problems are
occurring in the network, such as route or link failure, severe
congestion, loss of PHR signalling messages, etc. Normal operation
is different for the two PHR groups (the reservation-based PHR and
the measurement-based PHR). Both are explained in the following
sections.
5.2.1. Normal Operation using the reservation-based PHR
Depending on the functionality of the external resource reservation
protocol that interoperates with the RMD domain two scenario types
can be identified:
* Example 1, where the external resource reservation
protocol does not create any reservation states in
ingress/egress nodes.
* Example 2, where the external resource reservation
protocol creates reservation states in ingress/egress
nodes.
5.2.1.1. Example 1: No Reservation State in Ingress/Egress
In this scenario the external resource reservation protocol that
interoperates with the RMD framework does not create any reservation
states in ingress/egress nodes.
When a QoS request arrives at the ingress node, the PDR protocol must
classify it into an appropriate Diffserv class PHB. It should
calculate the associated resource unit for this QoS request, i.e.,
bandwidth parameter. The PDR state will be associated with a flow
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specification ID. If the QoS request is satisfied locally, then the
ingress node will generate the "PHR_Resource_Request" signalling
message and the "PDR_Reservation_Request", which will be encapsulated
in the "PHR_Resource_Request" signalling message. The PDR signalling
message MAY contain information such as the IP address of the ingress
node and the per-flow specification ID. The PDR_Request_Info message
MUST be decapsulated and processed by the egress node only.
The intermediate interior nodes receiving the "PHR_Resource_Request"
must identify the Diffserv class PHB (the DSCP type of the PHR
signalling message) and, if possible, reserve the requested
resources. The node reserves the requested resources by adding the
requested amount to the total amount of reserved resources for that
Diffserv class PHB.
The behavior of the egress node on admission or rejection of the
"PHR_Resource_Request" is the same as in the interior nodes. After
processing the "PHR_Resource_Request" message, the egress node
decapsulates the "PDR_Reservation_Request" and creates/identifies the
flow specification ID and the state associated with it. In order to
report the successful reservation to the ingress node, the egress
node will send the "PDR_Reservation_Report" message back to the
ingress node. After receiving the "PDR_Reservation_Report" the
ingress node will inform the external source of the successful
reservation, which will in turn send traffic (user) data.
If the reserved resources need to be refreshed (updated), the ingress
node will generate a "PDR_Refresh_Request" message in order to
refresh the PDR soft state in the egress node. A
"PHR_Refresh_Update" is used to refresh the PHR aggregated soft state
in both interior and egress nodes. The "PDR_Refresh_Request" will be
encapsulated into the "PHR_Refresh_Update". The PHR refresh periods
should be equal in all edge and interior nodes.
Interior nodes that receive the "PHR_Refresh_Update" will
refresh/update the aggregated reservation state related to the
Diffserv class PHB (DSCP).
After processing the "PHR_Refresh_Update" message, the egress node
MUST identify the flow specification ID carried by either the header
of the PHR signalling message or the encapsulated PDR signalling
message (see Section 5.1.2). In this way the PDR state associated
with this flow specification ID can be refreshed instantaneously. The
egress node will send the "PDR_Refresh_Report" signalling message
back to ingress node to acknowledge the admission and processing of
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the "PHR_Refresh_Update" signalling message.
In addition to the reservation soft state principle, the PHR
resources in any node can also be released explicitly by means of
explicit release signalling messages. In this case, the ingress node
will create a "PHR_Release_Request" message, and it will include the
amount of the PHR requested resources specified the PDR reservation
state. This message will also encapsulate a "PDR_Request_Info"
message. Note that in case the PDR reservation state does not use a
reservation soft state principle the "PDR_Request_Info" message will
represent a "PDR_Release_Request".
Any node that receives a "PHR_Resource_Release" signalling message
must identify the DSCP and release the requested bandwidth associated
with it. This can be achieved by subtracting the amount of PHR
requested resources, included in the "PHR_Release_Request" message,
from the total reserved amount of resources stored in the DSCP state.
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The flow diagram showing the normal operation in case of successful
reservation for Example 1 is shown in Figure 5.
Ingress Interior Interior Egress
QoS |PHR_Resource_Request| | |
request | (PDR_ResReq*) | | |
-------> |------------------->|PHR_Resource_Request| |
| | (PDR_ResReq*) | |
| |------------------->|PHR_Resource_Request|
| | | (PDR_ResReq*) |
| | |------------------->|
| | | |
| PDR_Reservation_Report| |
|<-------------------|--------------------|--------------------|
| | | |
| | Traffic(user) Data | |
-------->|------------------->|------------------->|------------------->|--->
| | | |
| PHR_Refresh_Update | | |
| (PDR_RefReq*) | | |
| ------------------>| PHR_Refresh_Update | |
| | (PDR_RefReq*) | |
| |------------------->| PHR_Refresh_Update |
| | | (PDR_RefReq*) |
| | |------------------->|
| | PDR_Refresh_Report | |
|<-------------------|--------------------|--------------------|
|PHR_Resource_Release| | |
| (PDR_ReqInfo*) | | |
| ------------------>|PHR_Resource_Release| |
| | (PDR_ReqInfo*) | |
| |------------------->|PHR_Resource_Release|
| | | (PDR_ReqInfo*) |
| | |------------------->|
| | | |
(PDR_ResReq*) - represents the PDR_Reservation_Request message
encapsulated in the PHR_Resource_Request
message. This message is processed only by the
ingress and egress nodes.
(PDR_RefReq*) - represents the PDR_Refresh_Request message
encapsulated in the PHR_Refresh_Update message. This
message is processed only by the ingress and
egress nodes.
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(PDR_ReqInfo*) - represents the PDR_Request_Info
message encapsulated into a PHR message
message. This message is processed only by the
ingress and egress nodes. Note that in case the
PDR reservation state does not use a reservation
soft state principle, this message will represent
a PDR_Release_Request.
Figure 5: Normal Operation for successful reservation- Example 1
If there are no resources available locally, the ingress node will
immediately reject the external QoS request and will not generate any
signalling messages related to this request.
If the resources are lacking on the interior or egress of the
network, these nodes MUST mark and forward the "PHR_Resource_Request"
signalling message they receive in order to indicate the lack of the
resources and that no reservation was made to the ingress node.
When a reservation-based PHR group is used, in addition to being
marked, a "PHR_Resource_Request" message will also include the number
of previous interior nodes that successfully processed this PHR
message (see [RODA]). This number can, for example, be identified by
the TTL (Time-To-Live) value included in the IP header of the
received packet. Note that each time that an IP packet passes a
node, its TTL value is decreased by one. Thus if the ingress node is
able to initiate the TTL value included in the IP header of any PHR
signalling message sent towards the egress node then any interior
node will be able to find out how many nodes before it, processed
this PHR message.
The interior node will copy the TTL value included in the IP header
of the received "PHR_Resource_Request" message into the
"PDR_Reservation_Request" message encapsulated within the
"PHR_Resource_Request" message. For simplicity, we denote this
variable as PDR_TTL. Moreover, the "T" field value of the
"PHR_Refresh_Update" message is set to "1". This PHR message will be
sent towards the egress node. Interior nodes receiving a marked
"PHR_Resource_Request" message will not process it. Egress nodes
receiving the marked "PHR_Resource_Request" MUST "M" mark the
"PDR_Reservation_Report" message that is sent towards the ingress
node. Moreover, if the "T" field value is "1" then the PDR_TTL value
that was included by the interior node into the
"PHR_Resource_Request" message will be copied into the
"PDR_Reservation_Report" message.
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After receiving the marked "PDR_Reservation_Report", the ingress node
will reject the external QoS request. Simultaneously, the ingress
node will start a partial explicit release procedure, for releasing
the unnecessarily reserved resources in some interior nodes for the
rejected flow.
In this case, the ingress node will generate a "PHR_Release_Request"
message, and it will include the amount of the PHR requested
resources specified the PDR reservation state. It will also insert
the received PDR_TTL value in the TTL - IP header field of the
"PHR_Resource_Release" message. Moreover, this message will
encapsulate a "PDR_Request_Info" message.
Any node that receives a "PHR_Resource_Release" signalling message
must identify the DSCP and release the requested bandwidth associated
with it. This can be achieved by subtracting the amount of PHR
requested resources, included in the "PHR_Release_Request" message,
from the total reserved amount of resources stored in the DSCP state.
Moreover, its TTL value is decremented by one. When this value
becomes zero, the "PHR_Resource_Release" message reached the interior
node that marked the "PHR_Resource_Request" message and it will be
destroyed. This means that this message will not release any
resources in this node.
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Figure 6 depicts the normal operation for an unsuccessful reservation
for Example 1.
Ingress Interior Interior Egress
QoS |PHR_Resource_Request| | |
Request | (PDR_ResReq*) | | |
-------->|------------------->|PHR_Resource_Request |
| | (PDR_ResReq*)| |
| |----------------->|PHR_Resource_Request(marked)
| | |(PDR_ResReq*) |
| | M------------------>|
| PDR_Reservation_Report (marked) |
|<-------------------|------------------|-------------------|
|PHR_Resource_Release| | |
| (PDR_ReqInfo*) | | |
| ------------------>| | |
QoS | | | |
Request | | | |
Rejected | | | |
<--------| | | |
(PDR_ResReq*) - represents the PDR_Reservation_Request message
encapsulated in the PHR_Resource_Request
message. This message is processed only by the
ingress and egress nodes.
(PDR_ReqInfo*) - represents the PDR_Request_Info message
encapsulated into a PHR message message. This
message is processed only by the ingress and egress
nodes. Note that in case the PDR reservation state
does not use a reservation soft state principle,
this message will represent a PDR_Release_Request.
Figure 6: Normal Operation for unsuccessful reservation - Example 1
5.2.1.2. Example 2
In this scenario the external resource reservation protocol that
interoperates with the RMD domain creates reservation states in
ingress/egress nodes that are used (partially or completely) by the
RMD framework as PDR resource reservation states.
In this scenario as already mentioned an external protocol (such as
RSVP, RSVP aggregation) initiates and maintains the states (per flow
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or per aggregates) in the ingress and egress nodes. In the RMD
framework these states (fully or partially) are to be used by the PDR
handling the resource reservation in the Diffserv domain as PDR
states, which will consist of for example a flow id and a DSCP.
Furthermore, in this scenario the "PHR_Resource_Request",
"PHR_Refresh_Update" and "PHR_Release_Request" messages are
encapsulating "PDR_Request_Info" messages that are used to associate
the PHR signalling message that encapsulated this PDR message to for
example the PDR flow ID and/or the IP address of the ingress node.
Apart from this the rest of the functionality in generating and
processing the PDR and PHR signalling messages by the edge and
interior nodes is the same as in previous case (see Example 1).
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Figure 7 shows the flow diagram for normal operation in case of
successful reservation for Example 2.
Ingress Interior Interior Egress
| | | |
External | External | | |Ext.
Protocol | Protocol (used for initiation of the PDR states) |Prot.
<------> |<--------------|-------------------|------------------>|<-->
(QoS | | | |
request)| | | |
|PHR_Resource_ | | |
| Request | | |
|(PDR_ReqInfo*) | | |
|-------------->|PHR_Resource_Request |
| | (PDR_ReqInfo*) | |
| |------------------>|PHR_Resource_Request
| | | (PDR_ReqInfo*) |
| | |------------------>|
| PDR_Reservation_Report |
|<--------------|-------------------|-------------------|
| | Traffic(user) Data| |
-------->|-------------->|------------------>|------------------>|--->
External | External | | |Ext.
Protocol | Protocol (used for maintenance of the PDR states)|Prot.
<------> |<--------------|-------------------|------------------>|<--->
|PHR_Refresh_- | | |
|Update | | |
|(PDR_ReqInfo*) | | |
| ------------->| PHR_Refresh_Update| |
| | (PDR_ReqInfo*) | |
| |------------------>| PHR_Refresh_Update|
| | | (PDR_ReqInfo*) |
| | |------------------>|
| | PDR_Refresh_Report| |
|<--------------|-------------------|-------------------|
|PHR_Resource_ | | |
|Release | | |
|(PDR_ReqInfo*) | | |
|-------------->|PHR_Resource_ | |
| |Release | |
| |(PDR_ReqInfo*) | |
| |------------------>|PHR_Resource_ |
| | |Release |
| | |(PDR_ReqInfo*) |
| | |------------------>|
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(PDR_ReqInfo*) - represents the PDR_Request_Info
message encapsulated into a PHR message
message. This message is processed only by
the ingress and egress nodes.
Figure 7: Normal Operation for successful reservation - Example 2
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When there are no resources available in ingress/egress nodes or
interior nodes, the operation is similar to the one in Example 1,
with the difference that the PDR resource reservation states are
handled by the external protocol.
Figure 8 depicts the normal operation for an unsuccessful reservation
for Example 2, where X represents the external protocol states
related to the unsuccessful reservation, that need to be released in
this particular case based on the soft state principle by the
external protocol.
Ingress Interior Interior Egress
External | | | |Ext.
Protocol | External Protocol (used for PDR state initiation) |Prot.
<------> |<-------------------|--------------------|------------------->|<--->
(QoS |PHR_Resource_Request| | |
request)| (PDR_ResReq*) | | |
-------->|------------------->| PHR_Resource_Request |
| | (PDR_ResReq*)| |
| |------------------->| PHR_Resource_Request(M)
| | | (PDR_ResReq*) |
| | M------------------->|
| PDR_Reservation_Report (marked) |
|<-------------------|--------------------|--------------------|
|PHR_Resource_Release| | |
| (PDR_ReqInfo*) | | |
| ------------------>| | |
External | | | |Ext.
Protocol | | External Protocol | |Prot.
<------> X<-------------------|--------------------|------------------->X<--->
(QoS | | | |
request)| | | |
(PDR_ReqInfo*) - represents the PDR_Request_Info message
encapsulated into a PHR message. This message is
processed only by the ingress and egress nodes.
Figure 8: Normal Operation for unsuccessful reservation - Example 2
5.2.2. Normal operation using the measurement-based PHR
This RMD functionality is quite similar to that which uses the
reservation-Based PHR. As with the reservation_based PHR, in this
case both of the example scenarios are considered and the same
differences between the two in the manner of handling the PDR states,
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applies here as well. The classification of the QoS request is done
as described in Sections 5.2.1.1 and 5.2.1.2 respectively.
The difference with the reservation-based is that the measurement-
based PHR relies on a measurement algorithm on admission or rejection
of the resource requests. As such, it does not have to maintain any
resource reservation state per PHB in the edge or interior nodes.
However, the measurement based PHR uses two states that are not
maintained by the PHR protocol. One state per PHB that stores the
measured user traffic load associated to that PHB and another state
per PHB that stores the maximum allowable traffic load per PHB.
However, the edges maintain a PDR resource reservation state (see
Section 3.2.3).
The initiation and maintenance of the PDR resource reservation states
is accomplished in an identical way as described in Section 5.2.1.1
and Section 5.2.1.2 respectively. If the QoS request can be
satisfied locally, the ingress node will start the process of
generating the "PHR_Resource_Request" message. In addition, depending
on how the external resource reservation protocol initiates and
maintains the PDR resource reservation states at the edges, the
ingress node will also create either the "PHR_Resource_Request"
message or the "PDR_Request_Info" message (see Section 5.2.1.1). On
receiving the "PHR_Resource_Request" signalling message, the interior
node has to check the monitoring status by, for example, measuring
the real average traffic (user) data load per PHB. By "monitoring
status", we specify how much of the resources allocated to a
particular PHB have been consumed.
If the sum of the value of the PHR requested resources and the value
specified by the monitoring status is less than or equal to the
maximum node capacity associated with the given PHB, then the request
is accepted.
Otherwise, the node does not have the requested amount of resources.
Therefore, "PHR_Resource_Request" is marked as not admitted.
The behavior of the egress node on admission or rejection of the
"PHR_Resource_Request" is the same as in the interior nodes. The
reporting process used to inform the ingress node about the
monitoring status is similar to the process explained in Section
5.2.1.1.
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5.3. Example of Fault Handling Operation
Fault Handling Operation refers to the situations when there are
problems in the network, such as loss of the PHR signalling messages,
route change, link failure, etc. Two typical situations will be
described: the loss of the PHR signalling messages and severe
congestion. The fault handling operation described here is in
general independent from the type of the example scenarios, thus it
can be applied in both cases.
5.3.1. Loss of PHR signalling messages
The PHR signalling messages and subsequently the PDR signalling
messages might be dropped, for example due to route or link failure.
The loss of the PHR signalling messages is especially problematic for
the reservation-based PHR since the dropped signalling messages might
have reserved resources in some interior nodes in the communication
path that will now not be used. This does not present a problem for
the measurement-based PHR since there are no reservation states.
The ingress nodes are responsible for handling the loss of the PHR
signalling messages. When sending a "PDR_Reservation_Request", a
"PDR_Refresh_Request" or a "PDR_Request_Info" message as encapsulated
in a PHR message, the ingress node will start a timer. The ingress
node will then wait for a predefined amount of time to receive an
acknowledgement, either as a "PDR_Reservation_Report" or
"PDR_Refresh_Report" message. If the ingress node does not receive
this acknowledgement within the predefined amount of time, it will
conclude that an error has occurred. Moreover, it will also know that
this error occurred during the resource reservation process for the
flow session that is associated with the "PDR_Reservation_Request",
"PDR_Refresh_Request" or "PDR_Request_Info" message it sent
previously.
When a "PHR_Resource_Request" message is dropped, then the ingress
node will not send any new PDR and PHR signalling messages associated
with the same flow session during the first subsequent refresh
period. In this way all the possible unused reserved resources will
implicitly be released within one refresh period.
When a "PHR_Refresh_Update" message is dropped, the ingress node,
depending on which PDR type was used, will send a PDR and
"PHR_Refresh_Update" message during either the first or second
subsequent refresh period. In the first case, one or more interior
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nodes may reserve double the amount of the required resources, while
only half of the amount of these reserved resources will be used. In
the second case, the ingress node will not send any new PDR and
"PHR_Refresh_Update" messages associated with the same flow session
during the first subsequent refresh period. In this way all possible
unused reserved resources will implicitly be released. However, the
application may experience a possible QoS degradation during one
refresh period.
In case a "PHR_Release_Request" message gets dropped the ingress node
will rely on the reservation soft state principle for the release of
the unnecessary reserved PHR resources.
5.3.2. Severe Congestion Handling operation
As explained in Section 4.2.4 above, severe congestion can be
detected by any interior node by using different methods. Moreover,
the severe congestion situation can be notified by any interior node
to egress nodes by using three approaches, i.e., "Greedy Marking",
"Proportional Marking" and "PHR message marking". The "PHR message
marking" can only be applied on the reservation-based PHP, while the
other two methods can be applied on both PHR types.
In this section the "PHR message marking" and "Proportional Marking"
severe congestion notification methods are used.
5.3.2.1. PHR message marking
Using this severe congestion notification method, only PHR signalling
message that pass through a severely congested interior node will be
marked. If the severe congestion occurs in the interior or the
egress node, then these nodes will set the "severe congestion" flag
[RODA] in the PHR signalling message and will forward it to the
egress node. The egress node will inform the ingress node by sending
a PDR report message with the "severe congestion" flag set. After
receiving this message, the ingress node will discard all new
incoming requests for the severely congested path for a predefined
time.
A flow diagram showing the severe congestion handling is depicted in
Figures 9 and 10, where in (a) the severe congestion notification is
performed by the "PHR_Resource_Request" and in (b) this notification
is performed by the "PHR_Refresh_Update".
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If the severe congestion notification is performed by the
"PHR_Resource_Request" message (see Figure 9 (a)), after detecting
the severe congestion, the "S" flag is set. The egress node will
detect the marked "PHR Resource_Request" message and by "S" marking a
"PDR_Reservation_Report" will inform the ingress node that a severe
congestion situation occurred. The ingress node will then not admit
any new QoS requests for that communication path.
If using the reservation-based PHR group, the "PHR_Resource_Request",
besides being "S" marked, will include the number of previous
interior nodes that successfully processed this PHR message (see
[RODA]). This number is calculated and used by the PHR functionality
in a similar way as in the "normal operation for unsuccessful
reservations", i.e., using the TTL field. The interior node will
copy the TTL value included in the IP header of the received
"PHR_Resource_Request" message into the "PDR_Reservation_Request"
message encapsulated within the "PHR_Resource_Request" message. For
simplicity, we denote this variable as PDR_TTL. Moreover, the "T"
field value of the "PHR_Refresh_Update" message is set to "1". This
PHR message will be sent towards the egress node.
Interior nodes receiving a marked "PHR_Resource_Request" message will
not process it.
Egress nodes receiving the "S" marked "PHR_Resource_Request" MUST
mark (with the "S" bit) the "PDR_Reservation_Report" message that is
sent towards the ingress node. Moreover, if the "T" filed included in
the "PHR_Resource_Request" is "1" the egress node will include the
received PDR_TTL value into the PDR_Reservation_Report.
After receiving the "S" marked "PDR_Reservation_Report", the ingress
node will not admit new QoS requests for that communication path.
Simultaneously, the ingress node will start a partial explicit
release procedure. It will generate a "PHR_Release_Request" message,
and it will include the amount of the PHR requested resources
specified in the PDR reservation state and insert the PDR_TTL
received in the "PDR_Reservation_Report" message in the TTL - IP
header field of the "PHR_Resource_Release" message. This message will
also encapsulate a "PDR_Request_Info" message.
Any node that receives a "PHR_Resource_Release" signalling message
must identify the DSCP and release the requested resources associated
with it. This can be achieved by subtracting the amount of PHR
requested resources, included in the "PHR_Release_Request" message,
from the total reserved amount of resources stored in the PHB
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reservation state. Moreover, its TTL value is decremented by one.
When this value becomes zero, the "PHR_Resource_Release" message
reached the interior node that marked the "PHR_Resource_Request"
message and it will be destroyed. This means that this message will
not release any resources in this node.
In case the severe congestion notification is performed by the
"PHR_Refresh_Update" message (see Figure 9 (b)), the procedure is the
same as when this is done by the "PHR_Resource_Request" message, but
in this scenario the partial release will not be used.
Note that this separation is only for illustrative purposes. Figure
9 illustrates the scenario that is denoted in Section 5.2.1.1 as
"Example 1" and Figure 10 illustrates the scenario that is denoted in
Section 5.2.1.2 as "Example 2". The "PHR message marking" procedure
is efficient, but it can only be used when the PHR refresh period is
small.
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(a)
Ingress Interior Interior Egress
QoS |PHR_Resource_Request| | |
Request | (PDR_ResReq*) | | |
-------->|------------------->| PHR_Resource_Request |
| | (PDR_ResReq*)| |
| |------------------->| PHR_Resource_Request("S")
| | | (PDR_ResReq*) |
| | S------------------->|
| PDR_Reservation_Report ("S" marked) |
|<-------------------|--------------------|--------------------|
|PHR_Resource_Release| | |
| (PDR_ReqInfo*) | | |
| ------------------>| | |
QoS | | | |
Request | | | |
Rejected | | | |
<--------| | | |
(b)
| | Traffic(user) Data | |
-------->|------------------->|------------------->|------------------->|--->
|PHR_Refresh_Update | | |
| (PDR_RefReq*) | PHR_Refresh_Update | |
|------------------->| (PDR_RefReq*) | |
| |------------------->| PHR_Refresh_Update ("S")
| | | (PDR_RefReq*) |
| | S------------------->|
| PDR_Refresh_Report ("S" marked) |
|<-------------------|--------------------|--------------------|
Traffic | | | |
data | | | |
blocked | | | |
---------X | | |
| | | |
(PDR_ResReq*) - represents the PDR_Reservation_Request message encap-
sulated in the PHR_Resource_Request message. This message
is processed only by the ingress and egress nodes.
(PDR_RefReq*) - represents the PDR_Refresh_Request message encap-
sulated in the PHR_Refresh_Update message. This message
is processed only by the ingress and egress nodes.
(PDR_ReqInfo*) - represents the PDR_Request_Info message encapsulated
into a PHR message message. This message is processed
only by the ingress and egress nodes. Note that in case
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the PDR reservation state does not use a reservation soft
state principle, this message will represent a
PDR_Release_Request.
Figure 9: Severe Congestion handling Operation applied to Example 1
(a)
Ingress Interior Interior Egress
External | | | |Ext.
Protocol | External Protocol (used for PDR state initiation) |Prot.
<------> |<-------------------|--------------------|------------------->|<--->
QoS |PHR_Resource_Request| | |
Request | (PDR_ResReq*) | | |
-------->|------------------->| PHR_Resource_Request |
| | (PDR_ResReq*)| |
| |------------------->| PHR_Resource_Request("S")
| | | (PDR_ResReq*) |
| | S------------------->|
| PDR_Reservation_Report ("S" marked) |
|<-------------------|--------------------|--------------------|
|PHR_Resource_Release| | |
| (PDR_ReqInfo*) | | |
| ------------------>| | |
QoS req. | | | |
Rejected | | | |
<--------| | | |
(b) | | Traffic(user) Data | |
-------->|------------------->|------------------->|------------------->|--->
|PHR_Refresh_Update | | |
| (PDR_RefReq*) | PHR_Refresh_Update | |
|------------------->| (PDR_RefReq*) | |
| |------------------->| PHR_Refresh_Update ("S")
| | | (PDR_RefReq*) |
| | S------------------->|
| PDR_Refresh_Report ("S" marked) |
|<-------------------|--------------------|--------------------|
Traffic | | | |
data | | | |
---------X | | |
blocked | | | |
(PDR_ReqInfo*) - represents the PDR_Request_Info message encapsulated
into a PHR message message. This message is processed
only by the ingress and egress nodes.
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Figure 10: Severe Congestion handling Operation applied to Example 2
5.3.2.2. Proportional marking
Using this severe congestion notification method, after detecting the
severe congestion situation, the interior node will notify the egress
node by using remarking of user data packets that pass through the
node. Proportionally to the detected overload the interior node will
remark a number of user data packets which are passing through a
severe congested interior node and are associated with a certain PHB,
into a domain specific DSCP.
When the marked packets arrive at the egress node, the egress node
will generate a "PDR_Congestion_Report" message and send it to the
ingress node containing the over-allocation volume of the flow in
question, e.g., a blocking probability. For each flow ID, the egress
node will count the number of marked bytes (# marked bytes) and the
number of unmarked bytes (# unmarked bytes).
Based on this information the egress node will have to calculate the
blocking estimation of data. The egress node will actually calculate
the blocking probability (Pdrop), which will be used by an ingress
node to block this particular flow.
The blocking probability is calculated as the ratio between the
dropped bytes and the maximum number of bytes that can be supported
by the interior node:
Pdrop = (# marked bytes)/(# marked bytes + # unmarked bytes)
This blocking probability will be included in the
"PDR_Congestion_Report" message that will be sent to the ingress.
The ingress node, based on this blocking probability, might terminate
the flow, i.e., for a higher blocking probability there is a higher
chance that the flow is terminated.
If a flow needs to be terminated, then for this flow, the ingress
node will generate a "PHR_Release_Request" message.
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The operation of this severe congestion solution is given in Figure
11.
(sent)
user | (sent) user data | | |
data | | | |
-------->|------------------->| (sent) user data | user data |
| |------------------->S(# marked bytes) |
| | S------------------->|
| | S(# unmarked bytes) |
| | S------------------->|
| PDR_Congestion_Report ("S" marked + Pdrop) |
Terminate|<-------------------|--------------------|--------------------|
flow? |PHR_Resource_Release| | |
YES | (PDR_ReqInfo*) |PHR_Resource_Release| |
| ------------------>| (PDR_ReqInfo*) |PHR_Resource_Release|
QoS | |------------------->| (PDR_ReqInfo*) |
Request | | |------------------->|
Rejected | | | |
<--------| | | |
(PDR_ReqInfo*) - represents the PDR_Request_Info
message encapsulated into a PHR message
message. This message is processed only by
the ingress and egress nodes.
Figure 11: Severe Congestion handling Operation: with proportional marking
5.4. Example of Adaptation to equal cost path load sharing operation
Due to load sharing (see e.g., [RFC2676]), a node, influenced by the
applied routing protocol, may cycle between different routes in order
to balance the load. This will imply that the traffic (user) data
will not follow exactly the same paths as the PHR messages used to
reserve or refresh the transport resources used by this traffic
(user) data. As such, interior nodes MUST be able to observe when a
load sharing situation occurs.
In case a network domain is using a routing protocol which is
applying an equal cost path load sharing principle, any interior node
will be able to know the number, e.g., "N", of multiple equal cost
paths that the routing protocol will use to provide the load sharing
principle. Subsequently, for each arrived PHR message which is
affected by the load sharing principle, the interior node according
to [RODA] will be able to create "N" number of PHR messages of
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identical type as the original one. Each of these generated PHR
messages will contain in its "Requested Resources" field a value
equal to the requested resources value which was included in the
"Requested Resources" field of the original PHR message divided by
the number of equal cost paths, i.e., "N". Moreover, each of these
generated PHR messages SHOULD also contain in its "Shared %" field a
new value that is calculated by dividing the shared percentage value,
included in the "Shared %" field of the original PHR message, by the
number of equal cost paths, i.e., "N".
When the egress node receives a "PHR_Resource_Request" or
"PDR_Refresh_Update" message it must send a "PDR_Reservation_Report"
or "PDR_Refresh_Report", respectively, back to the ingress node. In
other words the egress node will have to copy the "M" and "S" fields
from the PHR signalling message into a PDR report message.
Furthermore, the PDR report messages have to include the PDR state
information, i.e., flow specification ID and the IP address of the
egress node. Moreover, the shared percentage value included in the
received PHR message, i.e., the "Shared %" field (see [RODA]) is
copied into the PDR report message. When the ingress node receives
any PDR report message it must check if the shared percentage value
included in the PDR report message is equal to 100. Note that any
ingress node sets the "Shared %" value of any PHR message sent into
the RMD domain, to 100.
If that is the case then the ingress node will deduce that no load
sharing took place state. If this values is not equal to 100, then
the ingress node deduces that a load sharing in the communication
path occurred. Moreover, the ingress node has to store the IP source
address of the message, i.e., IP address of the egress node, and the
shared percentage value included in the received PDR report messages.
In this example we call the shared percentage value that was carried
by the initial PHR request message as initial_shared_percentage.
Each time that a new PDR report message associated to the same PDR
state arrives, the ingress node must check the IP source address of
this message with the IP address of the egress node that sent the
previous PDR report message. If these two addresses are equal then
the ingress node deduces that the same egress node sent the two PDR
report messages. Otherwise, the ingress node will deduce that
different egress nodes sent the PDR messages. Depending on the policy
used and if the external QoS protocol does not adapt to load sharing
then the ingress node may deduce that the reservation was
unsuccessful. Otherwise, the ingress node must add the shared
percentage value of the previous received PDR report, i.e.,
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initial_shared_percentage, with the shared percentage value included
in the current received PDR report message. If the result of this
addition is equal to 100, it means that the ingress node received all
expected PDR report messages associated with this PDR state.
Otherwise, more PDR report messages associated to the same PDR state,
will have to arrive. The same procedure explained above is repeated
until all the PDR report messages associated to the same PDR state
are received.
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The operation of this adaptation to load sharing operation for
"PHR_Resource_Request" and "PHR_Refresh_Update" messages is given in
Figure 12(a) and Figure 12(b), respectively.
(a)
Ingress Interior Interior Interior Egress
|(Shared% = 100) | | |
QoS |PHR_Res_Req* | | | |
Request (PDR_ReqInfo*) |(Shared% = 50) | | |
-------->|------------>"L" PHR_Res_Req* | | |
| |(PDR_ReqInfo*) | (Shared% = 50)| |
| |-------------->| PHR_Res_Req* | |
| |(Shared% = 50) | (PDR_ReqInfo*)| |
| |(PHR_Res_Req*) |------------------------------>|
| |(PDR_ReqInfo*) | | |
| |------------------------------>| (Shared% = 50)|
| | | | PHR_Res_Req* |
| | | | PDR_ReqInfo*) |
| | | |-------------->|
| | PDR_Reservation_Report (Shared % = 50) |
|<-------------------------------------------------------------|
| | PDR_Reservation_Report (Shared % = 50) |
|<-------------------------------------------------------------|
QoS req. | | | | |
Admitted | | | | |
<--------| | | | |
(b) | | Traffic(user) Data | |
-------->|------------->|-------------->|--------------->|------------->|
|PHR_Ref_Upd* | | | |
|(PDR_ReqInfo*)|(Shared% = 50) | | |
|------------>"L" PHR_Ref_Upd* | | |
| |(PDR_ReqInfo*) | (Shared% = 50) | |
| |-------------->| PHR_Ref_Upd* | |
| |(Shared% = 50) | (PDR_ReqInfo* | |
| |(PHR_Ref_Upd*) |------------------------------>|
| |(PDR_ResReq*) | | |
| |------------------------------->|(Shared% = 50)|
| | | | PHR_Ref_Upd* |
| | | | PDR_ReqInfo*)|
| | | |------------->|
| | PDR_Refresh_Report (Shared % = 50) |
|<-------------------------------------------------------------|
| | PDR_Refresh_Report (Shared % = 50) |
|<-------------------------------------------------------------|
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"L" - the routing protocol detects two equal cost paths
PHR_Res_Req* - represents the PHR_Resource_Request message
PHR_Ref_Upd* - represents the PHR_Refresh_Update message
(PDR_ReqInfo*) - represents the PDR_Request_Info message encap-
sulated into a PHR message message. This message
is processed only by the ingress and egress nodes.
Figure 12: Adaptation to equal cost path load sharing operation
5.5. Example of modification of reservation state
This section presents an example that describes how the modification
of a reservation state procedure can be specified.
When the RMD functionality of the ingress node receives an external
QoS request that is requesting a modification on the number of
reserved resources then the following process can be realized. When
the modification request requires an increase on the number of
reserved resources (see Figure 13), then the RMD functionality of the
ingress node will have to subtract the old and already reserved
number of resources from the number of resources included in the new
modification request. The result of this subtraction should be
introduced within a PHR_Resource_Request message as the requested
resources value. If a node is not able to reserve the number of
requested resources, then the PHR_Resource_Request will be marked. In
this situation the PHR and PDR protocol functionality associated with
an unsuccessful reservation procedure will be applied for this case.
When the modification request requires a decrease on the number of
reserved resources (see Figure 14), then the ingress node will have
to subtract the number of resources included in the new modification
request from the old and already reserved number of resources. The
result of this subtraction should be introduced in a PHR release
message. Furthermore, if the PDR protocol part maintains PDR
reservation states (e.g., Example 1) then the number of resources
that were reserved for a certain flow should also be replaced with
the number of resources included in the modification request. In this
situation the above used PHR messages, i.e., PHR_Resource_Request and
PHR_Resource_Release will have to encapsulate the
PDR_Modification_Request message. If the PDR protocol does not
maintain PDR reservation states (e.g., Example 2) then the above used
PHR messages, i.e., PHR_Resource_Request and PHR_Resource_Release
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will have to encapsulate the PDR_Request_Info message.
Ingress Interior Interior Egress
QoS |PHR_Resource_Request| | |
modification (PDR_ModReq*)) | | |
--------->|------------------->| | |
| |PHR_Resource_Request| |
| | (PDR_Modreq*) | |
| |------------------->|PHR_Resource_Request|
| | | (PDR_ModReq*) |
| | |------------------->|
| |PDR_Reservation_Report |
|<-------------------|--------------------|--------------------|
| | | |
(PDR_ModReq*) - represents the PDR_Modification_Request
message encapsulated into a PHR message
message. This message is processed only by the
ingress and egress nodes.
Figure 13: Modification of reserved resources when new number of resources is
higher than number of already reserved resources
Ingress Interior Interior Egress
QoS |PHR_Resource_Release| | |
modification (PDR_ModReq*)) | | |
-------->|------------------->| | |
| |PHR_Resource_Release| |
| | (PDR_ModReq*) | |
| |------------------->|PHR_Resource_Release|
| | | (PDR_ModReq*) |
| | |------------------->|
| | | |
(PDR_ModReq*) - represents the PDR_Modification_Request
message encapsulated into a PHR message
message. This message is processed only by the
ingress and egress nodes.
Figure 14: Modification of reserved resources when new number of resources is
lower than number of already reserved resources
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6. Interoperability with external resource reservation schemes
The RMD framework is initially designed for a single edge-to-edge
Diffserv domain. As part of the global Internet, this single edge-
to-edge Diffserv domain will have to interoperate with other domains
that may or may not be Diffserv-capable and which may use different
resource reservation schemes. The RMD framework, which is specified
as an open framework, MUST be able to interoperate with these
external resource reservation schemes. That is, the PDR
functionality will have to take care of interoperability between the
external resource reservation schemes and the PHR protocol. The
external resource reservation scheme could be applied either on an
end-to-end or an edge-to-edge basis.
In order to describe this interoperability, the two most typical
scenarios are chosen:
- Interoperability of the RMD framework with an RSVP/Intserv
domain
For a description of this interoperability, the Integrated
Services over Differentiated Services framework [RFC2998]
is used as a reference.
The framework for Integrated Services (Intserv)
operation over Differentiated Services (Diffserv) views
the two architectures as complementary towards deploying
end-to-end QoS. It is primarily intended to support the
quantitative (guaranteed) end-to-end services that have
not been commercially deployed yet by RSVP/Intserv due
to the lack of scalability. The specific realization
of the RSVP/Intserv - Diffserv interoperation depends
on Diffserv resource management and on Diffserv network
region RSVP awareness. Resource management in Diffserv
can either be static (managed by human agents) or dynamic
(via protocols). When the resource management in Diffserv
is performed using the RSVP protocol, then according to the
scenario described in Section 5.2.1.2, the RSVP protocol will
have to be used as an external resource reservation protocol
that will initiate and maintain the PDR resource reservation
states used at the edges of the RMD domain. Independently
of the Diffserv resource management, the service mapping
of Intserv-defined services to Diffserv-defined services
is essential for Intserv-over-Diffserv operation, unless
Diffserv is used only as transmission medium. Service
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mapping depends on appropriate selection of PHB, admission
control and policy control on the Intserv request based
on the available resources and policies in the Diffserv
domain. In this framework, it is the edge nodes that will
perform the service mapping on receiving of the RESV message.
- Dynamically Assigned Trunk Reservations
In this case, the SLAs/SLSs between different Diffserv
domains are negotiated in a dynamic way. In this
scenario, RSVP aggregation [RFC3175] is used to signal
QoS requests, that is, negotiate the SLAs/SLSs between
Diffserv domains. Furthermore, the DSCP marking is
performed in a domain outside the RMD domain, such as the
neighboring Diffserv domain located upstream. When the RSVP
aggregation protocol is used to dynamically assign the trunk
reservations, then according to the scenario described in
Section 5.2.1.2, the RSVP aggregation protocol will have to
be used as an external resource reservation protocol that
will initiate and maintain the PDR resource reservation
states used at the edges of the RMD domain.
7. Applicability scope of the RMD framework
The RMD framework is designed to be applicable to core networks and
any type of access networks, wired and wireless, as long as they are
using the Diffserv architecture edge-to-edge.
As a particular example, the RMD framework applicability to wireless
cellular access networks, that is, IP-based Radio Access Networks
(RANs), is considered.
The specific characteristics of the RAN (see [PaKa01]) constrain the
resource management strategies applied in the IP-based RAN with
strict requirements, which are explained in [PaKa01] in detail. These
requirements are not satisfactorily met by the current resource
management strategies (see [PaKa01]). The RMD framework design on the
other hand satisfies these specific resource management requirements,
which gives the RMD framework an advantage over the current resource
management strategies.
In order to fulfill the specific requirements related to resource
management strategies applied in the IP-based RAN given in [PaKa01],
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the PDR protocol in the RMD framework MUST be able to support the bi-
directional reservations. This means that the PDR protocol MUST
support the bi-directional feature described in Section 3.2.7. in
addition to the mandatory ones given in Section 3.2.1 to 3.2.6.
8. Tunneling
When PHR/PDR signalling messages are tunneled within the RMD Diffserv
domain, the tunneling messages MUST include the PHR/PDR option field.
9. Security Considerations
The general security and tunneling considerations stated in Section 6
of [RFC2475] apply also to this RMD framework.
In addition, unlike Differentiated Services PHBs, and PDBs, the RMD
framework allows the edge nodes to reserve bandwidth or other QoS
parameters dynamically. This flexibility makes it more vulnerable to
erroneous reservations and sabotage. In order to keep functioning
properly, the edge nodes MUST be certain that any flow reserving
resources in the core network is allowed to do this and only up to
that flow's agreed-upon limit. If the edge node detects erroneous or
malicious behavior, it MUST police that flow to the agreed-upon
limits or reject it entirely.
Because of the use of soft state, the RMD framework can recover
relatively easily from incorrect reservations. Thus, it is quite safe
to deploy the RMD framework in a well-controlled network with
trustworthy edge nodes.
In order to prevent abuse of the QoS capabilities of the core
network, the ingress nodes SHOULD filter any PHR or PDR related
header information coming from the outside before sending it through
the core network. Whether this information needs to be preserved and
later re-inserted or if it should be discarded from the packet or if
the entire packet should be discarded is an open issue.
10. Conclusions
The Resource Management in Diffserv (RMD) framework presented in this
memo is an open framework, which by means of the PHR and PDR
functionality provides a scalable and simple solution for resource
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reservation in a single edge-to-edge Diffserv domain. Furthermore,
the Resource Management in Diffserv framework provides the necessary
functionality for interoperability with other external resource
management strategies, which makes it a part of the effort to achieve
end-to-end QoS deployment.
Also of particular importance is to note that the RMD framework can
be applied on any IP network that has to support a huge real-time
traffic (mixed with best effort traffic) volume which is generated by
a huge number of users. Such networks can for example be next
generation ISP backbone networks, and various wired and wireless
access networks.
11. References
[CsTa02] Csaszar, A., Takacs, A., Szabo, R., Rexhepi, V.,
Karagiannis, G., "Severe Congestion Handling
with Resource Management in Diffserv On Demand",
submitted to Networking 2002, May 19-24 2002,
Pisa - ITALY.
[Doy98] Doyle, J, "CCIE Professional Development: Routing
TCP/IP", Volume 1, CISCO Press, 1998.
[NiKa01] Nichols, K., Carpenter, B., "Definition of
Differentiated Services Per Domain Behaviors and
Rules for their Specification", Internet Draft,
Work in progress.
[RODA] Westberg, L., Karagiannis, G., Partain, D., Oosthoek,
S., Jacobsson, M., Rexhepi, V., "Resource Management
in Diffserv On DemAnd (RODA) PHR", Internet Draft,
Work in progress.
[PaKa01] Partain, D., Karagiannis, G., Westberg, L., "Resource
Reservation Issues in Cellular Access Networks",
Internet Draft, Work in progress.
[RFC1633] Braden, R., Clark, D., Shenker, S., "Integrated
Services in the Internet Architecture: An Overview",
IETF RFC 1633, 1994.
[RFC1905] Case, J., McCloghrie, K., Rose, M. and S. Waldbusser,
"Protocol Operations for Version 2 of the Simple
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Network Management Protocol (SNMPv2)", RFC 1905, 1996.
[RFC2119] Bradner, S., "Key words for use in RFCs to Indicate
Requirement Levels", BCP 14, RFC2119, March 1997.
[RFC2205] Braden, R., Zhang, L., Berson, S., Herzog, A.,
Jamin, S., "Resource ReSerVation Protocol (RSVP)
-- Version 1 Functional Specification", IETF RFC
2205, 1997.
[RFC2474] Nichols, K., Blake, S., Baker, F. and D. Black,
"Definition of the Differentiated Services Field
(DS Field) in the IPv4 and IPv6 Headers", RFC 2474,
December 1998.
[RFC2475] Blake, S., Black, D., Carlson, M., Davies, E., Wang,
Zh., Weiss, W., "An Architecture for Differentiated
Services", IETF RFC 2475, 1998.
[RFC2543] Handley, M., Schulzrinne, H., Schooler, E., Rosenberg,
J., "SIP: Session Initiation Protocol", IETF RFC
2543, 1999.
[RFC2597] Heinanen, J., Baker, F., Weiss, W., Wroclawski, J.,
"Assured Forwarding PHB group", IETF RFC 2597, 1999.
[RFC2598] Jacobson, V., Nichols, K., Poduri, K., "An Expedited
Forwarding PHB", IETF RFC 2598, 1999.
[RFC2638] Nichols, K., Jacobson, V., Zhang, L., " A two-bit
Differentiated Services Architecture for the
Internet", IETF RFC 2638, 1999.
[RFC2676] Apostolopoulos, G., Willians, D., Kamat, S., Guerin,
R., Orda, A., Przygienda, T., "QoS Routing Mechanisms
and OSPF Extensions", IETF Experimental RFC 2676,
August 1999.
[RFC2702] Awduche, D., Malcolm, J., Agogbua, J., O'Dell, M.,
McManus, J., "Requirements for Traffic Engineering
Over MPLS", IETF Informational RFC 2702, Sept.
1999.
[RFC2748] Durham, D., Boyle, J., Cohen, R., Herzog, S., Raja,
R., Sastry, A., "The COPS (Common Open Policy Service)
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Protocol" IETF RFC 2748, January 2000.
[RFC2859] Fang, W., Seddigh, N., Nandy, B., "A Time Sliding
Window Three Colour Marker (TSWTCM)", IETF
Experimental RFC 2859, June 2000.
[RFC2998] Bernet, Y., Yavatkar, R., Ford, P., baker, F.,
Zhang, L., Speer, M., Braden, R., Davie, B.,
"Felstaine, E., "Framework for Integrated Services
operation over Diffserv Networks", IETF RFC 2998,
2000.
[RFC3175] Baker, F., Iturralde, C. Le Faucher, F., Davie, B.,
"Aggregation of RSVP for IPv4 and IPv6 Reservations",
IETF RFC 3175, 2001.
[WeTu00] Westberg. L., Turanyi Z. R., Partain, D., "Load
Control of Real-Time Traffic", Internet Draft,
Work in progress.
12. Acknowledgements
Special thanks to Geert Heijenk for reviewing this and providing
useful input.
13. Authors' Addresses
Lars Westberg
Ericsson Research
Torshamnsgatan 23
SE-164 80 Stockholm
Sweden
EMail: Lars.Westberg@era.ericsson.se
Martin Jacobsson
Ericsson EuroLab Netherlands B.V.
Institutenweg 25
P.O.Box 645
7500 AP Enschede
The Netherlands
EMail: Martin.Jacobsson@eln.ericsson.se
Georgios Karagiannis
University of Twente
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P.O. BOX 217
7500 AE Enschede
The Netherlands
EMail: karagian@cs.utwente.nl
Simon Oosthoek
Ericsson EuroLab Netherlands B.V.
Institutenweg 25
P.O.Box 645
7500 AP Enschede
The Netherlands
EMail: Simon.Oosthoek@eln.ericsson.se
David Partain
Ericsson Radio Systems AB
P.O. Box 1248
SE-581 12 Linkoping
Sweden
EMail: David.Partain@ericsson.com
Vlora Rexhepi
Ericsson EuroLab Netherlands B.V.
Institutenweg 25
P.O.Box 645
7500 AP Enschede
The Netherlands
EMail: Vlora.Rexhepi@eln.ericsson.se
Robert Szabo
Net Lab
Ericsson Hungary Ltd.
Laborc u. 1
H-1037 Budapest
Hungary
EMail: robert.szabo@eth.ericsson.se
Pontus Wallentin
Ericsson Radio Systems AB
P.O. Box 1248
SE-581 12 Linkoping
Sweden
EMail: Pontus.Wallentin@era.ericsson.se
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