The QoS Policy Information Model (QPIM) establishes a standard
framework and constructs for specifying and representing policies
that administer, manage, and control access to network QoS resources.
Such policies will be referred to as "QoS policies" in this document.
The framework consists of a set of classes and relationships that are
organized in an object-oriented information model. It is agnostic of
any specific Policy Decision Point (PDP) or Policy Enforcement Point
(PEP) (see [TERMS] for definitions) implementation, and independent
of any particular QoS implementation mechanism.
QPIM is designed to represent QoS policy information for large-scale
policy domains (the term "policy domain" is defined in [TERMS]). A
primary goal of this information model is to assist human
administrators in their definition of policies to control QoS
resources (as opposed to individual network element configuration).
The process of creating QPIM data instances is fed by business rules,
network topology and QoS methodology (e.g., Differentiated Services).
This document is based on the IETF Policy Core Information Model and
its extensions as specified by [PCIM] and [PCIMe]. QPIM builds upon
these two documents to define an information model for QoS
enforcement for differentiated and integrated services ([DIFFSERV]
and [INTSERV], respectively) using policy. It is important to note
that this document defines an information model, which by definition
is independent of any particular data storage mechanism and access
protocol. This enables various data models (e.g., directory
schemata, relational database schemata, and SNMP MIBs) to be designed
and implemented according to a single uniform model.
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 BCP 14, RFC 2119
[KEYWORDS].
This section describes the process of using QPIM for the definition
QoS policy for a policy domain. Figure 1 illustrates information
flow and not the actual procedure, which has several loops and
feedback not depicted.
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---------- ---------- -----------
| Business | | Topology | | QoS |
| Policy | | | |Methodology|
---------- ---------- -----------
| | |
| | |
------------------------------------
|
V
---------------
| QPIM/PCIM(e) |
| modeling |
---------------
|
| --------------
|<----------| Device info, |
| | capabilities |
| --------------
V
(---------------)
( device )---)
( configuration ) )---)
(---------------) ) )
(--------------) )
(-------------)
Figure 1: The QoS definition information flow
The process of QoS policy definition is dependent on three types of
information: the topology of the network devices under management,
the particular type of QoS methodology used (e.g., DiffServ) and the
business rules and requirements for specifying service(s) [TERMS]
delivered by the network. Both topology and business rules are
outside the scope of QPIM. However, important facets of both must be
known and understood for correctly specifying the QoS policy.
Typically, the process of QoS policy definition relies on a
methodology based on one or more QoS methodologies. For example, the
DiffServ methodology may be employed in the QoS policy definition
process.
The topology of the network consists of an inventory of the network
elements that make up the network and the set of paths that traffic
may take through the network. For example, a network administrator
may decide to use the DiffServ architectural model [DIFFSERV] and
classify network devices using the roles "boundary" and "core" (see
[TERMS] for a definition of role, and [PCIM] for an explanation of
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how they are used in the policy framework). While this is not a
complete topological view of the network, many times it may suffice
for the purpose of QoS policy definition.
Business rules are informal sets of requirements for specifying the
behavior of various types of traffic that may traverse the network.
For example, the administrator may be instructed to implement policy
such that VoIP traffic manifests behavior that is similar to legacy
voice traffic over telephone networks. Note that this business rule
(indirectly) prescribes specific behavior for this traffic type
(VoIP), for example in terms of minimal delay, jitter and loss.
Other traffic types, such as WEB buying transactions, system backup
traffic, video streaming, etc., will express their traffic
conditioning requirements in different terms. Again, this
information is required not by QPIM itself, but by the overall policy
management system that uses QPIM. QPIM is used to help map the
business rules into a form that defines the requirements for
conditioning different types of traffic in the network.
The topology, QoS methodology, and business rules are necessary
prerequisites for defining traffic conditioning. QPIM enables a set
of tools for specifying traffic conditioning policy in a standard
manner. Using a standard QoS policy information model such as QPIM
is needed also because different devices can have markedly different
capabilities. Even the same model of equipment can have different
functionality if the network operating system and software running in
those devices is different. Therefore, a means is required to
specify functionality in a standard way that is independent of the
capabilities of different vendors' devices. This is the role of
QPIM.
In a typical scenario, the administrator would first determine the
role(s) that each interface of each network element plays in the
overall network topology. These roles define the functions supplied
by a given network element independent of vendor and device type.
The [PCIM] and [PCIMe] documents define the concept of a role. Roles
can be used to identify what parts of the network need which type of
traffic conditioning. For example, network interface cards that are
categorized as "core" interfaces can be assigned the role name
"core-interface". This enables the administrator to design policies
to configure all interfaces having the role "core-interface"
independent of the actual physical devices themselves. QPIM uses
roles to help the administrator map a given set of devices or
interfaces to a given set of policy constructs.
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The policy constructs define the functionality required to perform
the desired traffic conditioning for particular traffic type(s). The
functions themselves depend on the particular type of networking
technologies chosen. For example, the DiffServ methodology
encourages us to aggregate similar types of traffic by assigning to
each traffic class a particular per-hop forwarding behavior on each
node. RSVP enables bandwidth to be reserved. These two
methodologies can be used separately or in conjunction, as defined by
the appropriate business policy. QPIM provides specific classes to
enable DiffServ and RSVP conditioning to be modeled.
The QPIM class definitions are used to create instances of various
policy constructs such as QoS actions and conditions that may be
hierarchically organized in rules and groups (PolicyGroup and
PolicyRule as defined in [PCIM] and [PCIMe]). Examples of policy
actions are rate limiting, jitter control and bandwidth allocation.
Policy conditions are constructs that can select traffic according to
a complex Boolean expression.
A hierarchical organization was chosen for two reasons. First, it
best reflects the way humans tend to think about complex policy.
Second, it enables policy to be easily mapped onto administrative
organizations, as the hierarchical organization of policy mirrors
most administrative organizations. It is important to note that the
policy definition process described here is done independent of any
specific device capabilities and configuration options. The policy
definition is completely independent from the details of the
implementation and the configuration interface of individual network
elements, as well as of the mechanisms that a network element can use
to condition traffic.
This section explains the QPIM design goals and how these goals are
addressed in this document. This section also describes the
ramifications of the design goals and the design decisions made in
developing QPIM.
The primary design goal of QPIM is to model policies controlling QoS
behavior in a way that as closely as possible reflects the way humans
tend to think about policy. Therefore, QPIM is designed to address
the needs of policy definition and management, and not device/network
configuration.
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There are several ramifications of this design goal. First, QPIM
uses rules to define policies, based on [PCIM] and [PCIMe]. Second,
QPIM uses hierarchical organizations of policies and policy
information extensively. Third, QPIM does not force the policy
writer to specify all implementation details; rather, it assumes that
configuration agents (PDPs) interpret the policies and match them to
suit the needs of device-specific configurations.
Policy is best described using rule-based modeling as explained and
described in [PCIM] and [PCIMe]. A QoS policy rule is structured as
a condition clause and an action clause. The semantics are simple:
if the condition clause evaluates to TRUE, then a set of QoS actions
(specified in the action clause) can be executed. For example, the
rule:
"WEB traffic should receive at least 50% of the available
bandwidth resources or more, when more is available"
can be formalized as:
"<If protocol == HTTP> then <minimum BW = 50%>"
where the first angle bracketed clause is a traffic condition and the
second angle bracketed clause is a QoS action.
This approach differs from data path modeling that describes the
mechanisms that operates on the packet flows to achieve the desired
effect.
Note that the approach taken in QPIM specifically did NOT subclass
the PolicyRule class. Rather, it uses the SimplePolicyCondition,
CompoundPolicyCondition, SimplePolicyAction, and CompoundPolicyAction
classes defined in [PCIMe], as well as defining subclasses of the
following classes: Policy, PolicyAction, SimplePolicyAction,
PolicyImplicitVariable, and PolicyValue. Subclassing the PolicyRule
class would have made it more difficult to combine actions and
conditions defined within different functional domains [PCIMe] within
the same rules.
The organization of the information represented by QPIM is designed
to be hierarchical. To do this, QPIM utilizes the PolicySetComponent
aggregation [PCIMe] to provide an arbitrarily nested organization of
policy information. A policy group functions as a container of
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policy rules and/or policy groups. A policy rule can also contain
policy rules and/or groups, enabling a rule/sub-rule relationship to
be realized.
The hierarchical design decision is based on the realization that it
is natural for humans to organize policy rules in groups. Breaking
down a complex policy into a set of simple rules is a process that
follows the way people tend to think and analyze systems. The
complexity of the abstract, business-oriented policy is simplified
and made into a hierarchy of simple rules and grouping of simple
rules.
The hierarchical information organization helps to simplify the
definition and readability of data instances based on QPIM.
Hierarchies can also serve to carry additional semantics for QoS
actions in a given context. An example, detailed in section 2.3,
demonstrates how hierarchical bandwidth allocation policies can be
specified in an intuitive form, without the need to specify complex
scheduler structures.
QPIM facilitates goal-oriented QoS policy definition. This means
that the process of defining QoS policy is focused on the desired
effect of policies, as opposed to the means of implementing the
policy on network elements.
QPIM is intended to define a minimal specification of desired network
behavior. It is the role of device-specific configuration agents to
interpret policy expressed in a standard way and fill in the
necessary configuration details that are required for their
particular application. The benefit of using QPIM is that it
provides a common lingua franca that each of the device- and/or
vendor-specific configuration agents can use. This helps ensure a
common interpretation of the general policy as well as aid the
administrator in specifying a common policy to be implemented across
different devices. This is analogous to the fundamental object-
oriented paradigm of separating specification from implementation.
Using QPIM, traffic conditioning can be specified in a general manner
that can help different implementations satisfy a common goal.
For example, a valid policy may include only a single rule that
specifies that bandwidth should be reserved for a given set of
traffic flows. The rule does not need to include any of the various
other details that may be needed for implementing a scheduler that
supports this bandwidth allocation (e.g., the queue length required).
It is assumed that a PDP or the PEPs would fill in these details
using (for example) their default queue length settings. The policy
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writer need only specify the main goal of the policy, making sure
that the preferred application receives enough bandwidth to operate
adequately.
An important design goal of QPIM is to provide a means for defining
policies that span numerous devices. This goal differentiates QPIM
from device-level information models, which are designed for modeling
policy that controls a single device, its mechanisms and
capabilities.
This design goal has several ramifications. First, roles [PCIM] are
used to define policies across multiple devices. Second, the use of
abstract policies frees the policy definition process from having to
deal with individual device peculiarities, and leaves interpretation
and configuration to be modeled by PDPs or other configuration
agents. Third, QPIM allows extensive reuse of all policy building
blocks in multiple rules used within different devices.
QPIM models QoS policy in a way designed to be independent of any
particular device or vendor. This enables networks made up of
different devices that have different capabilities to be managed and
controlled using a single standard set of policies. Using such a
single set of policies is important because otherwise, the policy
will itself reflect the differences between different device
implementations.
The use of roles enables a policy definition to be targeted to the
network function of a network element, rather than to the element's
type and capabilities. The use of roles for mapping policy to
network elements provides an efficient and simple method for compact
and abstract policy definition. A given abstract policy may be
mapped to a group of network elements without the need to specify
configuration for each of those elements based on the capabilities of
any one individual element.
The policy definition is designed to allow aggregating multiple
devices within the same role, if desired. For example, if two core
network interfaces operate at different rates, one does not have to
define two separate policy rules to express the very same abstract
policy (e.g., allocating 30% of the interface bandwidth to a given
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preferred set of flows). The use of hierarchical context and
relative QoS actions in QPIM addresses this and other related
problems.
Reusable objects, as defined by [PCIM] and [PCIMe], are the means for
sharing policy building blocks, thus allowing central management of
global concepts. QPIM provides the ability to reuse all policy
building blocks: variables and values, conditions and actions,
traffic profiles, and policy groups and policy rules. This provides
the required flexibility to manage large sets of policy rules over
large policy domains.
For example, the following rule makes use of centrally defined
objects being reused (referenced):
If <DestinationAddress == FinanceSubNet> then <DSCP =
MissionCritical>
In this rule, the condition refers to an object named FinanceSubNet,
which is a value (or possibly a set of values) defined and maintained
in a reusable objects container. The QoS action makes use of a value
named MissionCritical, which is also a reusable object. The
advantage of specifying a policy in this way is its inherent
flexibility. Given the above policy, whenever business needs require
a change in the subnet definition for the organization, all that's
required is to change the reusable value FinanceSubNet centrally.
All referencing rules are immediately affected, without the need to
modify them individually. Without this capability, the repository
that is used to store the rules would have to be searched for all
rules that refer to the finance subnet, and then each matching rule's
condition would have to be individually updated. This is not only
much less efficient, but also is more prone to error.
For a complete description of reusable objects, refer to [PCIM] and
[PCIMe].
Policy defined by QPIM should be enforceable. This means that a PDP
can use QPIM's policy definition in order to make the necessary
decisions and enforce the required policy rules. For example, RSVP
admission decisions should be made based on the policy definitions
specified by QPIM. A PDP should be able to map QPIM policy
definitions into PEP configurations, using either standard or
proprietary protocols.
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QPIM is designed to be agnostic of any particular, vendor-dependent
technology. However, QPIM's constructs SHOULD always be interpreted
so that policy-compliant behavior can be enforced on the network
under management. Therefore, there are three fundamental
requirements that QPIM must satisfy:
1. Policy specified by QPIM must be able to be mapped to actual
network elements.
2. Policy specified by QPIM must be able to control QoS network
functions without making reference to a specific type of device or
vendor.
3. Policy specified by QPIM must be able to be translated into
network element configuration.
QPIM satisfies requirements #1 and #2 above by using the concept of
roles (specifically, the PolicyRoles property, defined in PCIM). By
matching roles assigned to policy groups and to network elements, a
PDP (or other enforcement agent) can determine what policy should be
applied to a given device or devices.
The use of roles in mapping policy to network elements supports model
scalability. QPIM policy can be mapped to large-scale policy domains
by assigning a single role to a group of network elements. This can
be done even when the policy domain contains heterogeneous devices.
So, a small set of policies can be deployed to large networks without
having to re-specify the policy for each device separately. This
QPIM property is important for QoS policy management applications
that strive to ease the task of policy definition for large policy
domains.
Requirement #2 is also satisfied by making QPIM domain-oriented (see
[TERMS] for a definition of "domain"). In other words, the target of
the policy is a domain, as opposed to a specific device or interface.
Requirement #3 is satisfied by modeling QoS conditions and actions
that are commonly configured on various devices. However, QPIM is
extensible to allow modeling of actions that are not included in
QPIM.
It is important to note that different PEPs will have different
capabilities and functions, which necessitate different individual
configurations even if the different PEPs are controlled by the same
policy.
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The two predominant standards-based QoS methodologies developed so
far are Differentiated Services (DiffServ) and Integrated Services
(IntServ). The DiffServ provides a way to enforce policies that
apply to a large number of devices in a scalable manner. QPIM
provides actions and conditions that control the classification,
policing and shaping done within the differentiated service domain
boundaries, as well as actions that control the per-hop behavior
within the core of the DiffServ network. QPIM does not mandate the
use of DiffServ as a policy methodology.
Integrated services, together with its signaling protocol (RSVP),
provides a way for end nodes (and edge nodes) to request QoS from the
network. QPIM provides actions that control the reservation of such
requests within the network.
As both methodologies continue to evolve, QPIM does not attempt to
provide full coverage of all possible scenarios. Instead, QPIM aims
to provide policy control modeling for all major scenarios. QPIM is
designed to be extensible to allow for incorporation of control over
newly developed QoS mechanisms.
Another design goal of QPIM is to facilitate interoperability among
policy systems such as PDPs and policy management applications. QPIM
accomplishes this interoperability goal by standardizing the
representation of policy. Producers and consumers of QoS policy need
only rely on QPIM-based schemata (and resulting data models) to
ensure mutual understanding and agreement on the semantics of QoS
policy.
For example, suppose that a QoS policy management application, built
by vendor A writes its policies based on the LDAP schema that maps
from QPIM to a directory implementation using LDAP. Now assume that
a separately built PDP from vendor B also relies on this same LDAP
schema derived from QPIM. Even though these are two vendors with two
different PDPs, each may read the schema of the other and
"understand" it. This is because both the management application and
the PDP were architected to comply with the QPIM specification. The
same is true with two policy management applications. For example,
vendor B's policy application may run a validation tool that computes
whether there are conflicts within rules specified by the other
vendor's policy management application.
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Interoperability of QPIM producers/consumers is by definition at a
high level, and does not guarantee that the same policy will result
in the same PEP configuration. First, different PEPs will have
different capabilities and functions, which necessitate different
individual configurations even if the different PEPs are controlled
by the same policy. Second, different PDPs will also have different
capabilities and functions, and may choose to translate the high-
level QPIM policy differently depending on the functionality of the
PDP, as well as on the capabilities of the PEPs that are being
controlled by the PDP. However, the different configurations should
still result in the same network behavior as that specified by the
policy rules.
This section provides a discussion of QoS policy abstraction and the
way QPIM addresses this issue.
As described above, the main goal of the QPIM is to create an
information model that can be used to help bridge part of the
conceptual gap between a human policy maker and a network element
that is configured to enforce the policy. Clearly this wide gap
implies several translation levels, from the abstract to the
concrete. At the abstract end are the business QoS policy rules.
Once the business rules are known, a network administrator must
interpret them as network QoS policy and represent this QoS policy by
using QPIM constructs. QPIM facilitates a formal representation of
QoS rules, thus providing the first concretization level: formally
representing humanly expressed QoS policy.
When a human business executive defines network policy, it is usually
done using informal business terms and language. For example, a
human may utter a policy statement that reads:
"human resources applications should have better QoS than simple
web applications"
This might be translated to a slightly more sophisticated form, such
as:
"traffic generated by our human resources applications should have
a higher probability of communicating with its destinations than
traffic generated by people browsing the WEB using non-mission-
critical applications"
While this statement clearly defines QoS policy at the business
level, it isn't specific enough to be enforceable by network
elements. Translation to "network terms and language" is required.
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On the other end of the scale, a network element functioning as a
PEP, such as a router, can be configured with specific commands that
determine the operational parameters of its inner working QoS
mechanisms. For example, the (imaginary) command "output-queue-depth
= 100" may be an instruction to a network interface card of a router
to allow up to 100 packets to be stored before subsequent packets are
discarded (not forwarded). On a different device within the same
network, the same instruction may take another form, because a
different vendor built that device or it has a different set of
functions, and hence implementation, even though it is from the same
vendor. In addition, a particular PEP may not have the ability to
create queues that are longer than, say, 50 packets, which may result
in a different instruction implementing the same QoS policy.
The first example illustrates 'abstract policy', while the second
illustrates 'concrete configuration'. Furthermore, the first example
illustrates end-to-end policy, which covers the conditioning of
application traffic throughout the network. The second example
illustrates configuration for a particular PEP or a set thereof.
While an end-to-end policy statement can only be enforced by
configuration of PEPs in various parts of the network, the
information model of policy and that of the mechanisms that a PEP
uses to implement that policy are vastly different.
The translation process from abstract business policy to concrete PEP
configuration is roughly expressed as follows:
1. Informal business QoS policy is expressed by a human policy maker
(e.g., "All executives' WEB requests should be prioritized ahead
of other employees' WEB requests")
2. A network administrator analyzes the policy domain's topology and
determines the roles of particular device interfaces. A role may
be assigned to a large group of elements, which will result in
mapping a particular policy to a large group of device interfaces.
3. The network administrator models the informal policy using QPIM
constructs, thus creating a formal representation of the abstract
policy. For example, "If a packet's protocol is HTTP and its
destination is in the 'EXECUTIVES' user group, then assign IPP 7
to the packet header".
4. The network administrator assigns roles to the policy groups
created in the previous step matching the network elements' roles
assigned in step #2 above.
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5. A PDP translates the abstract policy constructs created in step #3
into device-specific configuration commands for all devices
effected by the new policy (i.e., devices that have interfaces
that are assigned a role matching the new policy constructs'
roles). In this process, the PDP consults the particular devices'
capabilities to determine the appropriate configuration commands
implementing the policy.
6. For each PEP in the network, the PDP (or an agent of the PDP)
issues the appropriate device-specific instructions necessary to
enforce the policy.
QPIM, PCIM and PCIMe are used in step #3 above.
Policy is described by a set of policy rules that may be grouped into
subsets [PCIMe]. Policy rules and policy groups can be nested within
other policy rules, providing a hierarchical policy definition.
Nested rules are also called sub-rules, and we use both terms in this
document interchangeably. The aggregation PolicySetComponent
(defined in [PCIMe] is used to represent the nesting of a policy rule
or group in another policy rule.
The hierarchical policy rule definition enhances policy readability
and reusability. Within the QoS policy information model, hierarchy
is used to model context or scope for the sub-rule actions. Within
QPIM, bandwidth allocation policy actions and drop threshold actions
use this hierarchal context. First we provide a detailed example of
the use of hierarchy in bandwidth allocation policies. The
differences between flat and hierarchical policy representation are
discussed. The use of hierarchy in drop threshold policies is
described in a following subsection. Last but not least, the
restrictions on the use of rule hierarchies within QPIM are
described.
Consider the following example where the informal policy reads:
On any interface on which these rules apply, guarantee at least
30% of the interface bandwidth to UDP flows, and at least 40% of
the interface bandwidth to TCP flows.
The QoS Policy information model follows the Policy Core information
model by using roles as a way to specify the set of interfaces on
which this policy applies. The policy does not assume that all
interfaces are run at the same speed, or have any other property in
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common apart from being able to forward packets. Bandwidth is
allocated between UDP and TCP flows using percentages of the
available interface bandwidth. Assume that we have an available
interface bandwidth of 1 Mbits/sec. Then this rule will guarantee
300Kbits/sec to UDP flows. However, if the interface bandwidth was
instead only 64kbits/sec, then this rule would correspondingly
guarantee 19.2kb/sec.
This policy is modeled within QPIM using two policy rules of the
form:
If (IP protocol is UDP) THEN (guarantee 30% of available BW) (1)
If (IP protocol is TCP) THEN (guarantee 40% of available BW) (2)
Assume that these two rules are grouped within a PolicySet [PCIMe]
carrying the appropriate role combination. A possible implementation
of these rules within a PEP would be to use a Weighted-Round-Robin
scheduler with 3 queues. The first queue would be used for UDP
traffic, the second queue for TCP traffic and the third queue for the
rest of the traffic. The weights of the Weighted-Round-Robin
scheduler would be 30% for the first queue, 40% for the second queue
and 30% for the last queue.
The actions specifying the bandwidth guarantee implicitly assume that
the bandwidth resource being guaranteed is the bandwidth available at
the interface level. A PolicyRoleCollection is a class defined in
[PCIMe] whose purpose is to identify the set of resources (in this
example, interfaces) that are assigned to a particular role. Thus,
the type of managed elements aggregated within the
PolicyRoleCollection defines the bandwidth resource being controlled.
In our example, interfaces are aggregated within the
PolicyRoleCollection. Therefore, the rules specify bandwidth
allocation to all interfaces that match a given role. Other behavior
could be similarly defined by changing what was aggregated within the
PolicyRoleCollection.
Normally, a full specification of the rules would require indicating
the direction of the traffic for which bandwidth allocation is being
made. Using the direction variable defined in [PCIMe], the rules can
be specified in the following form:
If (direction is out)
If (IP protocol is UDP) THEN (guarantee 30% of available BW)
If (IP protocol is TCP) THEN (guarantee 40% of available BW)
where indentation is used to indicate rule nesting. To save space,
we omit the direction condition from further discussion.
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Rule nesting provides the ability to further refine the scope of
bandwidth allocation within a given traffic class forwarded via these
interfaces. The example below adds two nested rules to refine
bandwidth allocation for UDP and TCP applications.
If (IP protocol is UDP) THEN (guarantee 30% of available BW) (1)
If (protocol is TFTP) THEN (guarantee 10% of available BW) (1a)
If (protocol is NFS) THEN (guarantee 40% of available BW) (1b)
If (IP protocol is TCP) THEN (guarantee 40% of available BW) (2)
If (protocol is HTTP) THEN guarantee 20% of available BW) (2a)
If (protocol is FTP) THEN (guarantee 30% of available BW) (2b)
Subrules 1a and 1b specify bandwidth allocation for UDP applications.
The total bandwidth resource being partitioned among UDP applications
is the bandwidth available for the UDP traffic class (i.e., 30%), not
the total bandwidth available at the interface level. Furthermore,
TFTP and NFS are guaranteed to get at least 10% and 40% of the total
available bandwidth for UDP, while other UDP applications aren't
guaranteed to receive anything. Thus, TFTP and NFS are guaranteed to
get at least 3% and 12% of the total bandwidth. Similar logic
applies to the TCP applications.
The point of this section will be to show that a hierarchical policy
representation enables a finer level of granularity for bandwidth
allocation to be specified than is otherwise available using a non-
hierarchical policy representation. To see this, let's compare this
set of rules with a non-hierarchical (flat) rule representation. In
the non-hierarchical representation, the guaranteed bandwidth for
TFTP flows is calculated by taking 10% of the bandwidth guaranteed to
UDP flows, resulting in 3% of the total interface bandwidth
guarantee.
If (UDP AND TFTP) THEN (guarantee 3% of available BW) (1a)
If (UDP AND NFS) THEN (guarantee 12% of available BW) (1b)
If (other UDP APPs) THEN (guarantee 15% of available BW) (1c)
If (TCP AND HTTP) THEN guarantee 8% of available BW) (2a)
If (TCP AND FTP) THEN (guarantee 12% of available BW) (2b)
If (other TCP APPs) THEN (guarantee 20% of available BW) (2c)
Are these two representations identical? No, bandwidth allocation is
not the same. For example, within the hierarchical representation,
UDP applications are guaranteed 30% of the bandwidth. Suppose a
single UDP flow of an application different from NFS or TFTP is
running. This application would be guaranteed 30% of the interface
bandwidth in the hierarchical representation but only 15% of the
interface bandwidth in the flat representation.
Snir, et al. Standards Track [Page 19]
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A two stage scheduler is best modeled by a hierarchical
representation whereas a flat representation may be realized by a
non-hierarchical scheduler.
A schematic hierarchical Weighted-Round-Robin scheduler
implementation that supports the hierarchical rule representation is
described below.
--UDP AND TFTP queue--10%
--UDP AND NFS queue--40%-Scheduler-30%--+
--Other UDP queue--50% A1 |
|
--TCP AND HTTP queue--20% |
--TCP AND FTP queue--30%-Scheduler-40%--Scheduler--Interface
--Other TCP queue--50% A2 | B
|
------------Non UDP/TCP traffic-----30%--+
Scheduler A1 extracts packets from the 3 UDP queues according to the
weight specified by the UDP sub-rule policy. Scheduler A2 extracts
packets from the 3 TCP queues specified by the TCP sub-rule policy.
The second stage scheduler B schedules between UDP, TCP and all other
traffic according to the policy specified in the top most rule level.
Another difference between the flat and hierarchical rule
representation is the actual division of bandwidth above the minimal
bandwidth guarantee. Suppose two high rate streams are being
forwarded via this interface: an HTTP stream and an NFS stream.
Suppose that the rate of each flow is far beyond the capacity of the
interface. In the flat scheduler implementation, the ratio between
the weights is 8:12 (i.e., HTTP:NFS), and therefore HTTP stream would
consume 40% of the bandwidth while NFS would consume 60% of the
bandwidth. In the hierarchical scheduler implementation the only
scheduler that has two queues filled is scheduler B, therefore the
ratio between the HTTP (TCP) stream and the NFS (UDP) stream would be
30:40, and therefore the HTTP stream would consume approximately 42%
of the interface bandwidth while NFS would consume 58% of the
interface bandwidth. In both cases both HTTP and NFS streams got
more than the minimal guaranteed bandwidth, but the actual rates
forwarded via the interface differ.
The conclusion is that hierarchical policy representation provides
additional structure and context beyond the flat policy
representation. Furthermore, policies specifying bandwidth
allocation using rule hierarchies should be enforced using
hierarchical schedulers where the rule hierarchy level is mapped to
the hierarchical scheduler level.
Snir, et al. Standards Track [Page 20]
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Two major resources govern the per hop behavior in each node. The
bandwidth allocation resource governs the forwarding behavior of each
traffic class. A scheduler priority and weights are controlled by
the bandwidth allocation policies, as well as the (minimal) number of
queues needed for traffic separation. A second resource, which is
not controlled by bandwidth allocation policies, is the queuing
length and drop behavior. For this purpose, queue length and
threshold policies are used.
Rule hierarchy is used to describe the context on which thresholds
act. The policy rule's condition describes the traffic class and the
rule's actions describe the bandwidth allocation, the forwarding
priority and the queue length. If the traffic class contains
different drop precedence sub-classes that require different
thresholds within the same queue, the sub-rules actions describe
these thresholds.
Below is an example of the use of rule nesting for threshold control
purposes. Let's look at the following rules:
If (protocol is FTP) THEN (guarantee 10% of available BW)
(queue length equals 40 packets)
(drop technique is random)
if (src-ip is from net 2.x.x.x) THEN min threshold = 30%
max threshold = 70%
if (src-ip is from net 3.x.x.x) THEN min threshold = 40%
max threshold = 90%
if (all other) THEN min threshold = 20%
max threshold = 60%
The rule describes the bandwidth allocation, the queue length and the
drop technique assigned to FTP flows. The sub-rules describe the
drop threshold priorities within those FTP flows. FTP packets
received from all networks apart from networks 2.x.x.x and 3.x.x.x
are randomly dropped when the queue threshold for FTP flows
accumulates to 20% of the queue length. Once the queue fills to 60%,
all these packets are dropped before queuing. The two other sub
rules provide other thresholds for FTP packets coming from the
specified two subnets. The Assured Forwarding per hop behavior (AF)
is another good example of the use of hierarchy to describe the
different drop preferences within a traffic class. This example is
provided in a later section.
Snir, et al. Standards Track [Page 21]
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Rule nesting is used within QPIM for two important purposes:
1) Enhance clarity, readability and reusability.
2) Provide hierarchical context for actions.
The second point captures the ability to specify context for
bandwidth allocation, as well as providing context for drop threshold
policies.
When is a hierarchy level supposed to specify the bandwidth
allocation context, when is the hierarchy used for specifying the
drop threshold context, and when is it used merely for clarity and
reusability? The answer depends entirely on the actions. Bandwidth
control actions within a sub-rule specify how the bandwidth allocated
to the traffic class determined by the rule's condition clause should
be further divided among the sub-rules. Drop threshold actions
control the traffic class's queue drop behavior for each of the sub-
rules. The bandwidth control actions have an implicit pointer
saying: the bandwidth allocation is relative to the bandwidth
resources defined by the higher level rule. Drop threshold actions
have an implicit pointer saying: the thresholds are taken from the
queue resources defined by the higher level rule. Other actions do
not have such an implicit pointer, and for these actions hierarchy is
used only for reusability and readability purposes.
Each rule that includes a bandwidth allocation action implies that a
queue should be allocated to the traffic class defined by the rule's
condition clause. Therefore, once a bandwidth allocation action
exists within the actions of a sub-rule, a threshold action within
this sub-rule cannot refer to thresholds of the parent rule's queue.
Instead, it must refer to the queue of the sub-rule itself.
Therefore, in order to have a clear and unambiguous definition,
refinement of thresholds and refinements of bandwidth allocations
within sub-rules should be avoided. If both refinements are needed
for the same rule, threshold refinements and bandwidth refinements
rules should each be aggregated to a separate group, and these groups
should be aggregated under the policy rule, using the
PolicySetComponent aggregation.
Snir, et al. Standards Track [Page 22]
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QPIM is intended for several audiences. The following lists some of
the intended audiences and their respective uses:
1. Developers of QoS policy management applications can use this
model as an extensible framework for defining policies to control
PEPs and PDPs in an interoperable manner.
2. Developers of Policy Decision Point (PDP) systems built to control
resource allocation signaled by RSVP requests.
3. Developers of Policy Decision Points (PDP) systems built to create
QoS configuration for PEPs.
4. Builders of large organization data and knowledge bases who decide
to combine QoS policy information with other networking policy
information, assuming all modeling is based on [PCIM] and [PCIMe].
5. Authors of various standards may use constructs introduced in this
document to enhance their work. Authors of data models wishing to
map a storage specific technology to QPIM must use this document
as well.
This section describes the QoS actions that are modeled by QPIM. QoS
actions are policy enforced network behaviors that are specified for
traffic selected by QoS conditions. QoS actions are modeled using
the classes PolicyAction (defined in [PCIM]), SimplePolicyAction
(defined in [PCIMe]) and several QoS actions defined in this document
that are derived from both of these classes, which are described
below.
Note that there is no discussion of PolicyRule, PolicyGroup, or
different types of PolicyCondition classes in this document. This is
because these classes are fully specified in [PCIM] and [PCIMe].
QoS policy based systems allow the network administrator to specify a
set of rules that control both the selection of the flows that need
to be provided with a preferred forwarding treatment, as well as
specifying the specific set of preferred forwarding behaviors. QPIM
provides an information model for specifying such a set of rules.
QoS policy rules enable controlling environments in which RSVP
signaling is used to request different forwarding treatment for
different traffic types from the network, as well as environments
where no signaling is used, but preferred treatment is desired for
Snir, et al. Standards Track [Page 26]
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some (but not all) traffic types. QoS policy rules also allow
controlling environments where strict QoS guarantees are provided to
individual flows, as well as environments where QoS is provided to
flow aggregates. QoS actions allow a PDP or a PEP to determine which
RSVP requests should be admitted before network resources are
allocated. QoS actions allow control of the RSVP signaling content
itself, as well as differentiation between priorities of RSVP
requests. QoS actions allow controlling the Differentiated Service
edge enforcement including policing, shaping and marking, as well as
the per-hop behaviors used in the network core. Finally, QoS actions
can be used to control mapping of RSVP requests at the edge of a
differentiated service cloud into per hop behaviors.
Four groups of actions are derived from action classes defined in
[PCIM] and [PCIMe]. The first QoS action group contains a single
action, QoSPolicyRSVPSimpleAction. This action is used for both RSVP
signal control and install actions. The second QoS action group
determines whether a flow or class of flows should be admitted. This
is done by specifying an appropriate traffic profile using the
QoSPolicyTrfcProf class and its subclasses. This set of actions also
includes QoS admission control actions, which use the
QoSPolicyAdmissionAction class and its subclasses. The third group
of actions control bandwidth allocation and congestion control
differentiations, which together specify the per-hop behavior
forwarding treatment. This group of actions includes the
QoSPolicyPHBAction class and its subclasses. The fourth QoS action
is an unconditional packet discard action, which uses the
QoSPolicyDiscardAction class. This action is used either by itself
or as a building block of the QoSPolicyPoliceAction.
Note that some QoS actions are not directly modeled. Instead, they
are modeled by using the class SimplePolicyAction with the
appropriate associations. For example, the three marking actions
(DSCP, IPP and CoS) are modeled by using the SimplePolicyAction
class, and associating that class with variables and values of the
appropriate type defined in [PCIMe].
There are three types of decisions a PDP (either remote or within a
PEP) can make when it evaluates an RSVP request:
1. Admit or reject the request
2. Add or modify the request admission parameters
3. Modify the RSVP signaling content
Snir, et al. Standards Track [Page 27]
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The COPS for RSVP [RFC2749] specification uses different Decision
object types to model each of these decisions. QPIM follows the COPS
for RSVP specification and models each decision using a different
action class.
The QoSPolicyRSVPAdmissionAction controls the Decision Command and
Decision Flags objects used within COPS for RSVP. The
QoSPolicyRSVPAdmissionAction class, with its associated
QoSPolicyIntServTrfcProf class, is used to determine whether to
accept or reject a given RSVP request by comparing the RSVP request's
TSPEC or RSPEC parameters against the traffic profile specified by
the QoSPolicyIntServTrfcProf. For a full description of the
comparison method, see section 4. Following the COPS for RSVP
specification, the admission decision has an option to both accept
the request and send a warning to the requester. The
QoSPolicyRSVPAdmissionAction can be used to limit the number of
admitted reservations as well.
The class QoSPolicyRSVPSimpleAction, which is derived from the
PolicySimpleAction class [PCIMe], can be used to control the two
other COPS RSVP decision types. The property qpRSVPActionType
designates the instance of the class to be either of type 'REPLACE',
'STATELESS', or both ('REPLACEANDSTATELESS'). For instances carrying
a qpRSVPActionType property value of 'REPLACE', the action is
interpreted as a COPS Replace Decision, controlling the contents of
the RSVP message. For instances carrying a qpRSVPActionType property
value of 'STATELESS', the action is interpreted as a COPS Stateless
Decision, controlling the admission parameters. If both of these
actions are required, this can be done by assigning the value
REPLACEANDSTATELESS to the qpRSVPActionType property.
This class is modeled to represent the COPS for RSVP Replace and
Stateless decisions. This similarity allows future use of these COPS
decisions to be directly controlled by a QoSPolicySimpleAction. The
only required extension might be the definition of a new RSVP
variable.
The QoSPolicyRSVPSimpleAction allows the specification of admission
parameters. It allows specification of the preemption priority
[RFC3181] of a given RSVP Reservation request. Using the preemption
priority value, the PEP can determine the importance of a Reservation
compared with already admitted reservations, and if necessary can
preempt lower priority reservations to make room for the higher
priority one. This class can also be used to control mapping of RSVP
requests to a differentiated services domain by setting the
Snir, et al. Standards Track [Page 28]
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QoSPolicyRSVPDCLASSVariable to the required value. This instructs
the PEP to mark traffic matching the Session and Sender
specifications carried in an RSVP request to a given DSCP value.
A Policy system should be able to control the information carried in
the RSVP messages. The QoSPolicyRSVPSimpleAction allows control of
the content of RSVP signaling messages. An RSVP message can carry a
preemption policy object [RFC3181] specifying the priority of the
reservation request in comparison to other requests. An RSVP message
can also carry a policy object for authentication purposes. An RSVP
message can carry a DCLASS [DCLASS] object that specifies to the
receiver or sender the particular DSCP value that should be set on
the data traffic. A COPS for RSVP Replacement Data Decision controls
the content of the RSVP message by specifying a set of RSVP objects
replacing or removing the existing ones.
The differentiated Service Architecture [DIFFSERV] was designed to
provide a scalable QoS differentiation without requiring any
signaling protocols running between the hosts and the network. The
QoS actions modeled in QPIM can be used to control all of the
building blocks of the Differentiated Service architecture, including
per-hop behaviors, edge classification, and policing and shaping,
without a need to specify the datapath mechanisms used by PEP
implementations. This provides an abstraction level hiding the
unnecessary details and allowing the network administrator to write
rules that express the network requirements in a more natural form.
In this architecture, as no signaling between the end host and the
network occurs before the sender starts sending information, the QoS
mechanisms should be set up in advance. This usually means that PEPs
need to be provisioned with the set of policy rules in advance.
Policing and Shaping actions are modeled as subclasses of the QoS
admission action. DSCP and CoS marking are modeled by using the
SimplePolicyAction ([PCIMe]) class associated with the appropriate
variables and values. Bandwidth allocation and congestion control
actions are modeled as subclasses of the QpQPolicyPHBAction, which is
itself a subclass PolicyAction class ([PCIM])
Admission Actions (QoSPolicyAdmissionAction and its subclasses) are
used to police and/or shape traffic.
Snir, et al. Standards Track [Page 29]
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Each Admission Action is bound to a traffic profile
(QoSPolicyTrfcProf) via the QoSPolicyTrfcProfInAdmissionAction
association. The traffic profile is used to meter traffic for
purposes of policing or shaping.
An Admission Action carries a scope property (qpAdmissionScope) that
is used to determine whether the action controls individual traffic
flows or aggregate traffic classes. The concepts of "flow" and
"traffic class" are explained in [DIFFSERV] using the terms
'microflow' and 'traffic stream'. Roughly speaking, a flow is a set
of packets carrying an IP header that has the same values for source
IP, destination IP, protocol and layer 4 source and destination
ports. A traffic class is a set of flows. In QPIM, simple and
compound conditions can identify flows and/or traffic classes by
using Boolean terms over the values of IP header fields, including
the value of the ToS byte.
Thus, the interpretation of the scope property is as follows: If the
value of the scope property is 0 (per-flow), each (micro) flow that
can be positively matched with the rule's condition is metered and
policed individually. If the value of the scope property is 1 (per-
class), all flows matched with the rule's condition are metered as a
single aggregate and policed together.
The following example illustrates the use of the scope property.
Using two provisioned policing actions, the following policies can be
enforced:
- Make sure that each HTTP flow will not exceed 64kb/s
- Make sure that the aggregate rate of all HTTP flows will not
exceed 512Kb/s
Both policies are modeled using the same class QoSPolicyPoliceAction
(derived from QoSPolicyAdmissionAction). The first policy has its
scope property set to 'flow', while the second policy has its scope
property set to 'class'. The two policies are modeled using a rule
with two police actions that, in a pseudo-formal definition, looks
like the following:
If (HTTP) Action1=police, Traffic Profile1=64kb/s, Scope1=flow
Action2=police, Traffic Profile2=512kb/s, Scope2=class
The provisioned policing action QoSPolicyPoliceAction has three
associations, QoSPolicyConformAction, QoSPolicyExceedAction and
QoSPolicyViolateAction.
Snir, et al. Standards Track [Page 30]
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To accomplish the desired result stated above, two possible modeling
techniques may be used: The two actions can be part of a single
policy rule using two PolicyActionInPolicyRule [PCIM] associations.
In this case the ExecutionStrategy property of the PolicyRule class
[PCIMe] SHOULD be set to "Do All" so that both individual flows and
aggregate streams are policed.
Alternatively, Action1 and Action2 could be aggregated in a
CompundPolicyAction instance using the PolicyActionInPolicyAction
aggregations [PCIMe]. In this case, in order for both individual
flows and aggregate traffic classes to be policed, the
ExecutionStrategy property of the CompoundPolicyAction class [PCIMe]
SHOULD be set to "Do All".
The policing action is associated with a three-level token bucket
traffic profile carrying rate, burst and excess-burst parameters.
Traffic measured by a meter can be classified as conforming traffic
when the metered rate is below the rate defined by the traffic
profile, as excess traffic when the metered traffic is above the
normal burst and below the excess burst size, and violating traffic
when rate is above the maximum excess burst.
The [DIFF-MIB] defines a two-level meter, and provides a means to
combine two-level meters into more complex meters. In this document,
a three-level traffic profile is defined. This allows construction
of both two-level meters as well as providing an easier definition
for three-level meters needed for creating AF [AF] provisioning
actions.
A policing action that models three-level policing MUST associate
three separate actions with a three-level traffic profile. These
actions are a conforming action, an exceeding action and a violating
action. A policing action that models two-level policing uses a
two-level traffic profile and associates only conforming and
exceeding actions. A policing action with a three-level traffic
profile that specifies an exceed action but does not specify a
violate action implies that the action taken when the traffic is
above the maximum excess burst is identical to the action taken when
the traffic is above the normal burst. A policer determines whether
the profile is being met, while the actions to be performed are
determined by the associations QoSPolicyXXXAction.
Shapers are used to delay some or all of the packets in a traffic
stream, in order to bring the stream into compliance with a traffic
profile. A shaper usually has a finite-sized buffer, and packets may
be discarded if there is not sufficient buffer space to hold the
delayed packets. Shaping is controlled by the QoSPolicyShapeAction
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RFC 3644 Policy QoS Information Model November 2003
class. The only required association is a traffic profile that
specifies the rate and burst parameters that the outgoing flows
should conform with.
Three types of marking control actions are modeled in QPIM:
Differentiated Services Code Point (DSCP) assignment, IP Precedence
(IPP) assignment and layer-2 Class of Service (CoS) assignment.
These assignment actions themselves are modeled by using the
SimplePolicyAction class associated with the appropriate variables
and values.
DSCP assignment sets ("marks" or "colors") the DS field of a packet
header to a particular DS Code Point (DSCP), adding the marked packet
to a particular DS behavior aggregate.
When used in the basic form, "If <condition> then 'DCSP = ds1'", the
assignment action assigns a DSCP value (ds1) to all packets that
result in the condition being evaluated to true.
When used in combination with a policing action, a different
assignment action can be issued via each of the 'conform', 'exceed'
and 'violate' action associations. This way, one may select a PHB in
a PHB group according to the state of a meter.
The semantics of the DSCP assignment is encapsulated in the pairing
of a DSCP variable and a DSCP value within a single
SimplePolicyAction instance via the appropriate associations.
IPP assignment sets the IPP field of a packet header to a particular
IPP value (0 through 7). The semantics of the IPP assignment is
encapsulated in the pairing of a ToS variable (PolicyIPTosVariable)
and a bit string value () (defined in [PCIMe]) within a single
SimplePolicyAction instance via the appropriate associations. The
bit string value is used in its masked bit string format. The mask
indicates the relevant 3 bits of the IPP sub field within the ToS
byte, while the bit string indicates the IPP value to be set.
CoS assignments control the mapping of a per-hop behavior to a
layer-2 Class of Service. For example, mapping of a set of DSCP
values into a 802.1p user priority value can be specified using a
rule with a condition describing the set of DSCP values, and a CoS
assignment action that specifies the required mapping to the given
user priority value. The semantics of the CoS assignment is
encapsulated in the pairing of a CoS variable and a CoS value
(integer in the range of 0 through 7) within a single
SimplePolicyAction instance via the appropriate associations.
Snir, et al. Standards Track [Page 32]
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Assuming that the AF1 behavior aggregate is enforced within a DS
domain, policy rules on the boundaries of the network should mark
packets to one of the AF1x DSCPs, depending on the conformance of the
traffic to a predetermined three-parameter traffic profile. QPIM
models such AF1 policing action as defined in Figure 4.
+-----------------------+ +------------------------------+
| QoSPolicyPoliceAction |====| QoSPolicyTokenBucketTrfcProf |
| scope = class | | rate = x, bc = y, be = z |
+-----------------------+ +------------------------------+
* @ #
* @ #
* @ +--------------------+ +--------------------------+
* @ | SimplePolicyAction |---| PolicyIntegerValue -AF13 |
* @ +--------------------+ +--------------------------+
* @
* +--------------------+ +---------------------------+
* | SimplePolicyAction |---| PolicyIntegerValue - AF12 |
* +--------------------+ +---------------------------+
*
+--------------------+ +---------------------------+
| SimplePolicyAction |---| PolicyIntegerValue - AF11 |
+--------------------+ +---------------------------+
Association and Aggregation Legend:
**** QoSPolicyConformAction
@@@@ QoSPolicyExceedAction
#### QoSPolicyViolateAction
==== QoSTrfcProfInAdmissionAction
---- PolicyValueInSimplePolicyAction ([PCIMe])
&&&& PolicyVariableInSimplePolicyAction ([PCIMe], not shown)
Figure 4. AF Policing and Marking
The AF policing action is composed of a police action, a token bucket
traffic profile and three instances of the SimplePolicyAction class.
Each of the simple policy action instances models a different marking
action. Each SimplePolicyAction uses the aggregation
PolicyVariableInSimplePolicyAction to specify that the associated
PolicyDSCPVariable is set to the appropriate integer value. This is
done using the PolicyValueInSimplePolicyAction aggregation. The
three PolicyVariableInSimplePolicyAction aggregations which connect
the appropriate SimplePolicyActions with the appropriate DSCP
Snir, et al. Standards Track [Page 33]
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Variables, are not shown in this figure for simplicity. AF11 is
marked on detecting conforming traffic; AF12 is marked on detecting
exceeding traffic, and AF13 on detecting violating traffic.
The second example, shown in Figure 5, is the simplest policing
action. Traffic below a two-parameter traffic profile is unmodified,
while traffic exceeding the traffic profile is discarded.
+-----------------------+ +------------------------------+
| QoSPolicyPoliceAction |====| QoSPolicyTokenBucketTrfcProf |
| scope = class | | rate = x, bc = y |
+-----------------------+ +------------------------------+
@
@
+-------------------------+
| QoSPolicyDiscardAction |
+-------------------------+
Association and Aggregation Legend:
**** QoSPolicyConformAction (not used)
@@@@ QoSPolicyExceedAction
#### QoSPolicyViolateAction (not used)
==== QoSTrfcProfInAdmissionAction
Figure 5. A Simple Policing Action
A Per-Hop Behavior (PHB) is a description of the externally
observable forwarding behavior of a DS node applied to a particular
DS behavior aggregate [DIFFSERV]. The approach taken here is that a
PHB action specifies both observable forwarding behavior (e.g., loss,
delay, jitter) as well as specifying the buffer and bandwidth
resources that need to be allocated to each of the behavior
aggregates in order to achieve this behavior. That is, a rule with a
set of PHB actions can specify that an EF packet must not be delayed
more than 20 msec in each hop. The same rule may also specify that
EF packets need to be treated with preemptive forwarding (e.g., with
priority queuing), and specify the maximum bandwidth for this class,
as well as the maximum buffer resources. PHB actions can therefore
be used both to represent the final requirements from PHBs and to
provide enough detail to be able to map the PHB actions into a set of
configuration parameters to configure queues, schedulers, droppers
and other mechanisms.
The QoSPolicyPHBAction abstract class has two subclasses. The
QoSPolicyBandwidthAction class is used to control bandwidth, delay
and forwarding behavior, while the QoSPolicyCongestionControlAction
Snir, et al. Standards Track [Page 34]
RFC 3644 Policy QoS Information Model November 2003
class is used to control queue size, thresholds and congestion
algorithms. The qpMaxPacketSize property of the QoSPolicyPHBAction
class specifies the packet size in bytes, and is needed when
translating the bandwidth and congestion control actions into actual
implementation configurations. For example, an implementation
measuring queue length in bytes will need to use this property to map
the qpQueueSize property into the desired queue length in bytes.
QoSPolicyBandwidthAction allows specifying the minimal bandwidth that
should be reserved for a class of traffic. The property
qpMinBandwidth can be specified either in Kb/sec or as a percentage
of the total available bandwidth. The property qpBandwidthUnits is
used to determine whether percentages or fixed values are used.
The property qpForwardingPriority is used whenever preemptive
forwarding is required. A policy rule that defines the EF PHB should
indicate a non-zero forwarding priority. The qpForwardingPriority
property holds an integer value to enable multiple levels of
preemptive forwarding where higher values are used to specify higher
priority.
The property qpMaxBandwidth specifies the maximum bandwidth that
should be allocated to a class of traffic. This property may be
specified in PHB actions with non-zero forwarding priority in order
to guard against starvation of other PHBs.
The properties qpMaxDelay and qpMaxJitter specify limits on the per-
hop delay and jitter in milliseconds for any given packet within a
traffic class. Enforcement of the maximum delay and jitter may
require use of preemptive forwarding as well as minimum and maximum
bandwidth controls. Enforcement of low max delay and jitter values
may also require fragmentation and interleave mechanisms over low
speed links.
The Boolean property qpFairness indicates whether flows should have a
fair chance to be forwarded without drop or delay. A way to enforce
a bandwidth action with qpFairness set to TRUE would be to build a
queue per flow for the class of traffic specified in the rule's
filter. In this way, interactive flows like terminal access will not
be queued behind a bursty flow (like FTP) and therefore have a
reasonable response time.
The QoSPolicyCongestionControlAction class controls queue length,
thresholds and congestion control algorithms.
Snir, et al. Standards Track [Page 35]
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A PEP should be able to keep in its queues qpQueueSize packets
matching the rule's condition. In order to provide a link-speed
independent queue size, the qpQueueSize property can also be measured
in milliseconds. The time interval specifies the time needed to
transmit all packets within the queue if the link speed is dedicated
entirely for transmission of packets within this queue. The property
qpQueueSizeUnit determines whether queue size is measured in number
of packets or in milliseconds. The property qpDropMethod selects
either tail-drop, head-drop or random-drop algorithms. The set of
maximum and minimum threshold values can be specified as well, using
qpDropMinThresholdValue and qpDropMaxThresholdValue properties,
either in packets or in percentage of the total available queue size
as specified by the qpDropThresholdUnits property.
Hierarchical policy definition is a primary tool in the QoS Policy
information model. Rule nesting introduced in [PCIMe] allows
specification of hierarchical policies controlling RSVP requests,
hierarchical shaping, policing and marking actions, as well as
hierarchical schedulers and definition of the differences in PHB
groups.
This example provides a set of rules that specify PHBs enforced
within a Differentiated Service domain. The network administrator
chose to enforce the EF, AF11 and AF13 and Best Effort PHBs. For
simplicity, AF12 is not differentiated. The set of rules takes the
form:
If (EF) then do EF actions
If (AF1) then do AF1 actions
If (AF11) then do AF11 actions
If (AF12) then do AF12 actions
If (AF13) then do AF13 actions
If (default) then do Default actions.
EF, AF1, AF11, AF12 and AF13 are conditions that filter traffic
according to DSCP values. The AF1 condition matches the entire AF1
PHB group including the AF11, AF12 and AF13 DSCP values. The default
rule specifies the Best Effort rules. The nesting of the AF1x rules
within the AF1 rule specifies that there are further refinements on
how AF1x traffic should be treated relative to the entire AF1 PHB
group. The set of rules reside in a PolicyGroup with a decision
strategy property set to 'FirstMatching'.
The class instances below specify the set of actions used to describe
each of the PHBs. Queue sizes are not specified, but can easily be
added to the example.
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The actions used to describe the Best Effort PHB are simple. No
bandwidth is allocated to Best Effort traffic. The first action
specifies that Best Effort traffic class should have fairness.
QoSPolicyBandwidthAction BE-B:
qpFairness: TRUE
The second action specifies that the congestion algorithm for the
Best Effort traffic class should be random, and specifies the
thresholds in percentage of the default queue size.
QoSPolicyCongestionControlAction BE-C:
qpDropMethod: random
qpDropThresholdUnits %
qpDropMinThreshold: 10%
qpDropMaxThreshold: 70%
EF requires preemptive forwarding. The maximum bandwidth is also
specified to make sure that the EF class does not starve the other
classes. EF PHB uses tail drop as the applications using EF are
supposed to be UDP-based and therefore would not benefit from a
random dropper.
QoSPolicyBandwidthAction EF-B:
qpForwardingPriority: 1
qpBandwidthUnits: %
qpMaxBandwidth 50%
qpFairness: FALSE
QoSPolicyCongestionControlAction EF-C:
qpDropMethod: tail-drop
qpDropThresholdUnits packet
qpDropMaxThreshold: 3 packets
The AF1 actions define the bandwidth allocations for the entire PHB
group:
QoSPolicyBandwidthAction AF1-B:
qpBandwidthUnits: %
qpMinBandwidth: 30%
The AF1i actions specifies the differentiating refinement for the
AF1x PHBs within the AF1 PHB group. The different threshold values
provide the difference in discard probability of the AF1x PHBs within
the AF1 PHB group.
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QoSPolicyCongestionControlAction AF11-C:
qpDropMethod: random
qpDropThresholdUnits packet
qpDropMinThreshold: 6 packets
qpDropMaxThreshold: 16 packets
QoSPolicyCongestionControlAction AF12-C:
qpDropMethod: random
qpDropThresholdUnits packet
qpDropMinThreshold: 4 packets
qpDropMaxThreshold: 13 packets
QoSPolicyCongestionControlAction AF13-C:
qpDropMethod: random
qpDropThresholdUnits packet
qpDropMinThreshold: 2 packets
qpDropMaxThreshold: 10 packets
Meters measure the temporal state of a flow or a set of flows against
a traffic profile. In this document, traffic profiles are modeled by
the QoSPolicyTrfcProf class. The association QoSPolicyTrfcProf
InAdmissionAction binds the traffic profile to the admission action
using it. Two traffic profiles are derived from the abstract class
QoSPolicyTrfcProf. The first is a Token Bucket provisioning traffic
profile carrying rate and burst parameters. The second is an RSVP
traffic profile, which enables flows to be compared with RSVP TSPEC
and FLOWSPEC parameters.
Provisioned Admission Actions, including shaping and policing, are
specified using a two- or three-parameter token bucket traffic
profile. The QoSPolicyTokenBucketTrfcProf class includes the
following properties:
1. Rate measured in kbits/sec
2. Normal burst measured in bytes
3. Excess burst measured in bytes
Rate determines the long-term average transmission rate. Traffic
that falls under this rate is conforming, as long as the normal burst
is not exceeded at any time. Traffic exceeding the normal burst but
still below the excess burst is exceeding the traffic profile.
Traffic beyond the excess burst is said to be violating the traffic
profile.
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Excess burst size is measured in bytes in addition to the burst size.
A zero excess burst size indicates that no excess burst is allowed.
RSVP admission policy can condition the decision whether to accept or
deny an RSVP request based on the traffic specification of the flow
(TSPEC) or the amount of QoS resources requested (FLOWSPEC). The
admission decision can be based on matching individual RSVP requests
against a traffic profile or by matching the aggregated sum of all
FLOWSPECs (TSPECs) currently admitted, as determined by the
qpAdmissionScope property in an associated
QoSPolicyRSVPAdmissionAction.
The QoSPolicyIntservTrfcProf class models both such traffic profiles.
This class has the following properties:
1. Token Rate (r) measured in bits/sec
2. Peak Rate (p) measured in bits/sec
3. Bucket Size (b) measured in bytes
4. Min Policed unit (m) measured in bytes
5. Max packet size (M) measured in bytes
6. Resv Rate (R) measured in bits/sec
7. Slack term (s) measured in microseconds
The first five parameters are the traffic specification parameters
used in the Integrated Service architecture ([INTSERV]). These
parameters are used to define a sender TSPEC as well as a FLOWSPEC
for the Controlled-Load service [CL]. For a definition and full
explanation of their meanings, please refer to [RSVP-IS].
Parameters 6 and 7 are the additional parameters used for
specification of the Guaranteed Service FLOWSPEC [GS].
A partial order is defined between TSPECs (and FLOWSPECs). The TSPEC
A is larger than the TSPEC B if and only if rA>rB, pA>pB, bA>bB,
mA<mB and MA>MB. A TSPEC (FLOWSPEC) measured against a traffic
profile uses the same ordering rule. An RSVP message is accepted
only if its TSPEC (FLOWSPEC) is either smaller or equal to the
traffic profile. Only parameters specified in the traffic profile
are compared.
The GS FLOWSPEC is compared against the rate R and the slack term s.
The term R should not be larger than the traffic profile R parameter,
while the FLOWSPEC slack term should not be smaller than that
specified in the slack term.
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TSPECs as well as FLOWSPECs can be added. The sum of two TSPECs is
computed by summing the rate r, the peak rate p, the bucket size b,
and by taking the minimum value of the minimum policed unit m and the
maximum value of the maximum packet size M. GS FLOWSPECs are summed
by adding the Resv rate and minimizing the slack term s. These rules
are used to compute the temporal state of admitted RSVP states
matching the traffic class defined by the rule condition. This state
is compared with the traffic profile to arrive at an admission
decision when the scope of the QoSPolicyRSVPAdmissionAction is set to
'class'.
Pre-defined variables are necessary for ensuring interoperability
among policy servers and policy management tools from different
vendors. The purpose of this section is to define frequently used
variables in QoS policy domains.
Notice that this section only adds to the variable classes as defined
in [PCIMe] and reuses the mechanism defined there.
The QoS policy information model specifies a set of pre-defined
variable classes to support a set of fundamental QoS terms that are
commonly used to form conditions and actions and are missing from the
[PCIMe]. Examples of these include RSVP related variables. All
variable classes defined in this document extend the
QoSPolicyRSVPVariable class (defined in this document), which itself
extends the PolicyImplictVariable class, defined in [PCIMe].
Subclasses specify the data type and semantics of the policy
variables.
This document defines the following RSVP variable classes; for
details, see their class definitions:
RSVP related Variables:
1. QoSPolicyRSVPSourceIPv4Variable - The source IPv4 address of the
RSVP signaled flow, as defined in the RSVP PATH SENDER_TEMPLATE
and RSVP RESV FILTER_SPEC [RSVP] objects.
2. QoSPolicyRSVPDestinationIPv4Variable - The destination port of
the RSVP signaled flow, as defined in the RSVP PATH and RESV
SESSION [RSVP] objects (for IPv4 traffic).
3. QoSPolicyRSVPSourceIPv6Variable - The source IPv6 address of the
RSVP signaled flow, as defied in the RSVP PATH SENDER_TEMPLATE
and RSVP RESV FILTER_SPEC [RSVP] objects.
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4. QoSPolicyRSVPDestinationIPv6Variable - The destination port of
the RSVP signaled flow, as defined in the RSVP PATH and RESV
SESSION [RSVP] objects (for IPv6 traffic).
5. QoSPolicyRSVPSourcePortVariable - The source port of the RSVP
signaled flow, as defined in the RSVP PATH SENDER_TEMPLATE and
RSVP RESV FILTER_SPEC [RSVP] objects.
6. QoSPolicyRSVPDestinationPortVariable - The destination port of
the RSVP signaled flow, as defined in the RSVP PATH and RESV
SESSION [RSVP] objects.
7. QoSPolicyRSVPIPProtocolVariable - The IP Protocol of the RSVP
signaled flow, as defined in the RSVP PATH and RESV SESSION
[RSVP] objects.
8. QoSPolicyRSVPIPVersionVariable - The version of the IP addresses
carrying the RSVP signaled flow, as defined in the RSVP PATH and
RESV SESSION [RSVP] objects.
9. QoSPolicyRSVPDCLASSVariable - The DSCP value as defined in the
RSVP DCLASS [DCLASS] object.
10. QoSPolicyRSVPStyleVariable - The reservation style (FF, SE, WF)
as defined in the RSVP RESV message [RSVP].
11. QoSPolicyRSVPIntServVariable - The type of Integrated Service
(CL, GS, NULL) requested in the RSVP Reservation message, as
defined in the FLOWSPEC RSVP Object [RSVP].
12. QoSPolicyRSVPMessageTypeVariable - The RSVP message type, either
PATH, PATHTEAR, RESV, RESVTEAR, RESVERR, CONF or PATHERR [RSVP].
13. QoSPolicyRSVPPreemptionPriorityVariable - The RSVP reservation
priority as defined in [RFC3181].
14. QoSPolicyRSVPPreemptionDefPriorityVariable - The RSVP preemption
reservation defending priority as defined in [RFC3181].
15. QoSPolicyRSVPUserVariable - The ID of the user that initiated
the flow as defined in the User Locator string in the Identity
Policy Object [RFC3182].
16. QoSPolicyRSVPApplicationVariable - The ID of the application
that generated the flow as defined in the application locator
string in the Application policy object [RFC2872].
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17. QoSPolicyRSVPAuthMethodVariable - The RSVP Authentication type
used in the Identity Policy Object [RFC3182].
Each class restricts the possible value types associated with a
specific variable. For example, the QoSPolicyRSVPSourcePortVariable
class is used to define the source port of the RSVP signaled flow.
The value associated with this variable is of type
PolicyIntegerValue.
Values are used in the information model as building blocks for the
policy conditions and policy actions, as described in [PCIM] and
[PCIMe]. This section defines a set of auxiliary values that are
used for QoS policies as well as other policy domains.
All value classes extend the PolicyValue class [PCIMe]. The
subclasses specify specific data/value types that are not defined in
[PCIMe].
This document defines the following two subclasses of the PolicyValue
class:
QoSPolicyDNValue This class is used to represent a single or
set of Distinguished Name [DNDEF] values,
including wildcards. A Distinguished Name
is a name that can be used as a key to
retrieve an object from a directory
service. This value can be used in
comparison to reference values carried in
RSVP policy objects, as specified in
[RFC3182]. This class is defined in
Section 8.31.
QoSPolicyAttributeValue A condition term uses the form "Variable
matches Value", and an action term uses the
form "set Variable to Value" ([PCIMe]).
This class is used to represent a single or
set of property values for the "Value" term
in either a condition or an action. This
value can be used in conjunction with
reference values carried in RSVP objects,
as specified in [RFC3182]. This class is
defined in section 8.12.
The property name is used to specify which of the properties in the
QoSPolicyAttributeValue class instance is being used in the condition
or action term. The value of this property or properties will then
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be retrieved. In the case of a condition, a match (which is
dependent on the property name) will be used to see if the condition
is satisfied or not. In the case of an action, the semantics are
instead "set the variable to this value".
For example, suppose the "user" objects in the organization include
several properties, among them:
- First Name
- Last Name
- Login Name
- Department
- Title
A simple condition could be constructed to identify flows by their
RSVP user carried policy object. The simple condition: Last Name =
"Smith" to identify a user named Bill would be constructed in the
following way:
A SimplePolicyCondition [PCIMe] would aggregate a
QoSPolicyRSVPUserVariable [QPIM] object, via the
PolicyVariableInSimplePolicyCondition [PCIMe] aggregation.
The implicit value associated with this condition is created in the
following way:
A QoSPolicyAttributeValue object would be aggregated to the simple
condition object via a PolicyValueInSimplePolicyCondition [PCIMe].
The QoSPolicyAttributeValue attribute qpAttributeName would be set
to "last name" and the qpAttributeValueList would be set to
"Smith".
Another example is a condition that has to do with the user's
organizational department. It can be constructed in the exact same
way, by changing the QoSPolicyAttributeValue attribute
qpAttributeName to "Department" and the qpAttributeValueList would be
set to the particular value that is to be matched (e.g.,
"engineering" or "customer support"). The logical condition would
than be evaluated to true if the user belong to either the
engineering department or the customer support.
Notice that many multiple-attribute objects require the use of the
QoSPolicyAttributeValue class to specify exactly which of its
attributes should be used in the condition match operation.
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This association links a QoSPolicyTrfcProf object (defined in section
8.9), modeling a specific traffic profile, to a
QoSPolicyAdmissionAction object (defined in section 8.2). The class
definition for this association is as follows:
NAME QoSPolicyTrfcProfInAdmissionAction
DESCRIPTION A class representing the association between a
QoS admission action and its traffic profile.
DERIVED FROM Dependency (See [PCIM])
ABSTRACT FALSE
PROPERTIES Antecedent[ref QoSPolicyAdmissionAction [0..n]]
Dependent[ref QoSPolicyTrfcProf [1..1]]
This property is inherited from the Dependency association, defined
in [PCIM]. Its type is overridden to become an object reference to a
QoSPolicyAdmissionAction object. This represents the "independent"
part of the association. The [0..n] cardinality indicates that any
number of QoSPolicyAdmissionAction object(s) may use a given
QoSPolicyTrfcProf.
This property is inherited from the Dependency association, and is
overridden to become an object reference to a QoSPolicyTrfcProf
object. This represents a specific traffic profile that is used by
any number of QoSPolicyAdmissionAction objects. The [1..1]
cardinality means that exactly one object of the QoSPolicyTrfcProf
can be used by a given QoSPolicyAddmissionAction.
This association links a policing action with an object defining an
action to be applied to conforming traffic relative to the associated
traffic profile. The class definition for this association is as
follows:
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NAME PolicyConformAction
DESCRIPTION A class representing the association between a
policing action and the action that should be
applied to traffic conforming to an associated
traffic profile.
DERIVED FROM Dependency (see [PCIM])
ABSTRACT FALSE
PROPERTIES Antecedent[ref QoSPolicyPoliceAction[0..n]]
Dependent[ref PolicyAction [1..1]]
This property is inherited from the Dependency association. Its type
is overridden to become an object reference to a
QoSPolicyPoliceAction object. This represents the "independent" part
of the association. The [0..n] cardinality indicates that any number
of QoSPolicyPoliceAction objects may be given the same action to be
executed as the conforming action.
This property is inherited from the Dependency association, and is
overridden to become an object reference to a PolicyAction object.
This represents a specific policy action that is used by a given
QoSPolicyPoliceAction. The [1..1] cardinality means that exactly one
policy action can be used as the "conform" action for a
QoSPolicyPoliceAction. To execute more than one conforming action,
use the PolicyCompoundAction class to model the conforming action.
This association links a policing action with an object defining an
action to be applied to traffic exceeding the associated traffic
profile. The class definition for this association is as follows:
NAME QoSPolicyExceedAction
DESCRIPTION A class representing the association between a
policing action and the action that should be
applied to traffic exceeding an associated traffic
profile.
DERIVED FROM Dependency (see [PCIM])
ABSTRACT FALSE
PROPERTIES Antecedent[ref QoSPolicePoliceAction[0..n]]
Dependent[ref PolicyAction [1..1]]
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This property is inherited from the Dependency association. Its type
is overridden to become an object reference to a
QoSPolicyPoliceAction object. This represents the "independent" part
of the association. The [0..n] cardinality indicates that any number
of QoSPolicyPoliceAction objects may be given the same action to be
executed as the exceeding action.
This property is inherited from the Dependency association, and is
overridden to become an object reference to a PolicyAction object.
This represents a specific policy action that is used by a given
QoSPolicyPoliceAction. The [1..1] cardinality means that a exactly
one policy action can be used as the "exceed" action by a
QoSPolicyPoliceAction. To execute more than one conforming action,
use the PolicyCompoundAction class to model the exceeding action.
This association links a policing action with an object defining an
action to be applied to traffic violating the associated traffic
profile. The class definition for this association is as follows:
NAME PolicyViolateAction
DESCRIPTION A class representing the association between
a policing action and the action that should be
applied to traffic violating an associated traffic
profile.
DERIVED FROM Dependency (see [PCIM])
ABSTRACT FALSE
PROPERTIES Antecedent[ref QoSPolicePoliceAction[0..n]]
Dependent[ref PolicyAction [1..1]]
This property is inherited from the Dependency association. Its type
is overridden to become an object reference to a
QoSPolicyPoliceAction object. This represents the "independent" part
of the association. The [0..n] cardinality indicates that any number
of QoSPolicyPoliceAction objects may be given the same action to be
executed as the violating action.
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This property is inherited from the Dependency association, and is
overridden to become an object reference to a PolicyAction object.
This represents a specific policy action that is used by a given
QoSPolicyPoliceAction. The [1..1] cardinality means that exactly one
policy action can be used as the "violate" action by a
QoSPolicyPoliceAction. To execute more than one violating action,
use the PolicyCompoundAction class to model the conforming action.
A simple RSVP policy action is represented as a pair {variable,
value}. This aggregation provides the linkage between a
QoSPolicyRSVPSimpleAction instance and a single
QoSPolicyRSVPVariable. The aggregation
PolicyValueInSimplePolicyAction links the QoSPolicyRSVPSimpleAction
to a single PolicyValue.
The class definition for this aggregation is as follows:
NAME QoSPolicyRSVPVariableInRSVPSimplePolicyAction
DERIVED FROM PolicyVariableInSimplePolicyAction
ABSTRACT FALSE
PROPERTIES GroupComponent[ref QoSPolicyRSVPSimpleAction
[0..n]]
PartComponent[ref QoSPolicyRSVPVariable [1..1] ]
The reference property "GroupComponent" is inherited from
PolicyComponent, and overridden to become an object reference to a
QoSPolicyRSVPSimpleAction that contains exactly one
QoSPolicyRSVPVariable. Note that for any single instance of the
aggregation class QoSPolicyRSVPVariableInRSVPSimplePolicyAction, this
property is single-valued. The [0..n] cardinality indicates that
there may be 0, 1, or more QoSPolicyRSVPSimpleAction objects that
contain any given RSVP variable object.
The reference property "PartComponent" is inherited from
PolicyComponent, and overridden to become an object reference to a
QoSPolicyRSVPVariable that is defined within the scope of a
QoSPolicyRSVPSimpleAction. Note that for any single instance of the
association class QoSPolicyRSVPVariableInRSVPSimplePolicyAction, this
property (like all reference properties) is single-valued. The
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[1..1] cardinality indicates that a
QoSPolicyRSVPVariableInRSVPSimplePolicyAction must have exactly one
RSVP variable defined within its scope in order to be meaningful.
This class is used to specify that packets should be discarded. This
is the same as stating that packets should be denied forwarding. The
class definition is as follows:
NAME QoSPolicyDiscardAction
DESCRIPTION This action specifies that packets should be
discarded.
DERIVED FROM PolicyAction (defined in [PCIM])
ABSTRACT FALSEFALSE
PROPERTIES None
This class is the base class for performing admission decisions based
on a comparison of a meter measuring the temporal behavior of a flow
or a set of flow with a traffic profile. The qpAdmissionScope
property controls whether the comparison is done per flow or per
class (of flows). Only packets that conform to the traffic profile
are admitted for further processing; other packets are discarded.
The class definition is as follows:
NAME QoSPolicyAdmissionAction
DESCRIPTION This action controls admission decisions based on
comparison of a meter to a traffic profile.
DERIVED FROM PolicyAction (defined in [PCIM])
ABSTRACT FALSEFALSE
PROPERTIES qpAdmissionScope
This attribute specifies whether the admission decision is done per
flow or per the entire class of flows defined by the rule condition.
If the scope is "flow", the actual or requested rate of each flow is
compared against the traffic profile. If the scope is set to
"class", the aggregate actual or requested rate of all flows matching
the rule condition is measured against the traffic profile. The
property is defined as follows:
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NAME qpAdmissionScope
DESCRIPTION This property specifies whether the admission decision
is done per flow or per the entire class of flows.
SYNTAX Integer
VALUE This is an enumerated integer. A value of 0 specifies
that admission is done on a per-flow basis, and a value
of 1 specifies that admission is done on a per-class
basis.
This is used for defining policing actions (i.e., those actions that
restrict traffic based on a comparison with a traffic profile).
Using the three associations QoSPolicyConformAction,
QoSPolicyExceedAction and QoSPolicyViolateAction, it is possible to
specify different actions to take based on whether the traffic is
conforming, exceeding, or violating a traffic profile. The traffic
profile is specified in a subclass of the QoSPolicyTrfcProf class.
The class definition is as follows:
NAME QoSPolicyPoliceAction
DESCRIPTION This action controls the operation of policers. The
rate of flows is measured against a traffic profile.
The actions that need to be performed on conforming,
exceeding and violating traffic are indicated using
the conform, exceed and violate action associations.
DERIVED FROM QoSPolicyAdmissionAction (defined in this document)
ABSTRACT FALSEFALSE
PROPERTIES None
This class is used for defining shaping actions. Shapers are used to
delay some or all of the packets in a traffic stream in order to
bring a particular traffic stream into compliance with a given
traffic profile. The traffic profile is specified in a subclass of
the QoSPolicyTrfcProf class. The class definition is as follows:
NAME QoSPolicyShapeAction
DESCRIPTION This action indicate that traffic should be shaped to be
conforming with a traffic profile.
DERIVED FROM QoSPolicyAdmissionAction (defined in this document)
ABSTRACT FALSEFALSE
PROPERTIES None
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This class determines whether to accept or reject a given RSVP
request by comparing the RSVP request's TSPEC or RSPEC parameters
against the associated traffic profile and/or by enforcing the pre-
set maximum sessions limit. The traffic profile is specified in the
QoSPolicyIntServTrfcProf class. This class inherits the
qpAdmissionScope property from its superclass. This property
specifies whether admission should be done on a per-flow or per-class
basis. If the traffic profile is not larger than or equal to the
requested reservation, or to the sum of the admitted reservation
merged with the requested reservation, the result is a deny decision.
If no traffic profile is specified, the assumption is that all
traffic can be admitted.
The class definition is as follows:
NAME QoSPolicyRSVPAdmissionAction
DESCRIPTION This action controls the admission of RSVP requests.
Depending on the scope, either a single RSVP request or
the total admitted RSVP requests matching the conditions
are compared against a traffic profile.
DERIVED FROM QoSPolicyAdmissionAction (defined in this document)
ABSTRACT FALSEFALSE
PROPERTIES qpRSVPWarnOnly, qpRSVPMaxSessions
This property is applicable when fulfilling ("admitting") an RSVP
request would violate the policer (traffic profile) limits or when
the maximum number session would be exceeded (or both).
When this property is set to TRUE, the RSVP request is admitted in
spite of the violation, but an RSVP error message carrying a warning
is sent to the originator (sender or receiver). When set to FALSE,
the request would be denied and an error message would be sent back
to the originator. So the meaning of the qpWarnOnly flag is: Based
on property's value (TRUE or FALSE), determine whether to admit but
warn the originator that the request is in violation or to deny the
request altogether (and send back an error).
Specifically, a PATHERR (in response to a Path message) or a RESVERR
(in response of a RESV message) will be sent. This follows the COPS
for RSVP send error flag in the Decision Flags object. This property
is defined as follows:
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NAME qpRSVPWarnOnly
SYNTAX Boolean
Default FALSE
VALUE The value TRUE means that the request should be admitted
AND an RSVP warning message should be sent to the
originator. The value of FALSE means that the request
should be not admitted and an appropriate error message
should be sent back to the originator of the request.
This attribute is used to limit the total number of RSVP requests
admitted for the specified class of traffic. For this property to be
meaningful, the qpAdmissionScope property must be set to class. The
definition of this property is as follows:
NAME qpRSVPMaxSessions
SYNTAX Integer
VALUE Must be greater than 0.
This class is a base class that is used to define the per-hop
behavior that is to be assigned to behavior aggregates. It defines a
common property, qpMaxPacketSize, for use by its subclasses
(QoSPolicyBandwidthAction and QoSPolicyCongestionControlAction). The
class definition is as follows:
NAME QoSPolicyPHBAction
DESCRIPTION This action controls the Per-Hop-Behavior provided to
behavior aggregates.
DERIVED FROM PolicyAction (defined in [PCIM])
ABSTRACT TRUE
PROPERTIES qpMaxPacketSize
This property specifies the maximum packet size in bytes, of packets
in the designated flow. This attribute is used in translation of
QPIM attributes to QoS mechanisms used within a PEP. For example,
queue length may be measured in bytes, while the minimum number of
packets that should be kept in a PEP is defined within QPIM in number
of packets. This property is defined as follows:
NAME qpMaxPacketSize
SYNTAX Integer
Value Must be greater than 0
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This class is used to control the bandwidth, delay, and forwarding
behavior of a PHB. Its class definition is as follows:
NAME QoSPolicyBandwidthAction
DESCRIPTION This action controls the bandwidth, delay, and
forwarding characteristics of the PHB.
DERIVED FROM QoSPolicyPBHAction (defined in this document)
ABSTRACT FALSE
PROPERTIES qpForwardingPriority, qpBandwidthUnits,
qpMinBandwdith, qpMaxBandwidth, qpMaxDelay,
qpMaxJitter, qpFairness
This property defines the forwarding priority for this set of flows.
A non-zero value indicates that preemptive forwarding is required.
Higher values represent higher forwarding priority. This property is
defined as follows:
NAME qpForwardingPriority
SYNTAX Integer
VALUE Must be non-negative. The value 0 means that preemptive
forwarding is not required. A positive value indicates
the priority that is to be assigned for this (set of)
flow(s). Larger values represent higher priorities.
This property defines the units that the properties qpMinBandwidth
and qpMaxBandwidth have. Bandwidth can either be defined in bits/sec
or as a percentage of the available bandwidth or scheduler resources.
This property is defined as follows:
NAME qpBandwidthUnits
SYNTAX Integer
VALUE Two values are possible. The value of 0 is used to
specify units of bits/sec, while the value of 1 is used
to specify units as a percentage of the available
bandwidth. If this property indicates that the bandwidth
units are percentages, then each of the bandwidth
properties expresses a whole-number percentage, and hence
its maximum value is 100.
Snir, et al. Standards Track [Page 52]
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This property defines the minimum bandwidth that should be reserved
for this class of traffic. Both relative (i.e., a percentage of the
bandwidth) and absolute (i.e., bits/second) values can be specified
according to the value of the qpBandwidthUnits property. This
property is defined as follows:
NAME qpMinBandwidth
SYNTAX Integer
VALUE The value must be greater than 0. If the property
qpMaxBandwidth is defined, then the value of
qpMinBandwidth must be less than or equal to the value of
qpMaxBandwidth.
This property defines the maximum bandwidth that should be allocated
to this class of traffic. Both relative (i.e., a percentage of the
bandwidth)and absolute (i.e., bits/second) values can be specified
according to the value of the qpBandwidthUnits property. This
property is defined as follows:
NAME qpMaxBandwidth
SYNTAX Integer
VALUE The value must be greater than 0. If the property
qpMaxBandwidth is defined, then the value of
qpMinBandwidth must be less than or equal to the value of
qpMaxBandwidth.
This property defines the maximal per-hop delay that traffic of this
class should experience while being forwarded through this hop. The
maximum delay is measured in microseconds. This property is defined
as follows:
NAME qpMaxDelay
SYNTAX Integer (microseconds)
VALUE The value must be greater than 0.
This property defines the maximal per-hop delay variance that traffic
of this class should experience while being forwarded through this
hop. The maximum jitter is measured in microseconds. This property
is defined as follows:
Snir, et al. Standards Track [Page 53]
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NAME qpMaxJitter
SYNTAX Integer (microseconds)
VALUE The value must be greater than 0.
This property defines whether fair queuing is required for this class
of traffic. This property is defined as follows:
NAME qpFairness
SYNTAX Boolean
VALUE The value of FALSE means that fair queuing is not
required for this class of traffic, while the value of
TRUE means that fair queuing is required for this class
of traffic.
This class is used to control the characteristics of the congestion
control algorithm being used. The class definition is as follows:
NAME QoSPolicyCongestionControlAction
DESCRIPTION This action control congestion control characteristics
of the PHB.
DERIVED FROM QoSPolicyPBHAction (defined in this document)
ABSTRACT FALSE
PROPERTIES qpQueueSizeUnits, qpQueueSize, qpDropMethod,
qpDropThresholdUnits, qpDropMinThresholdValue,
qpDropMaxThresholdValue
This property specifies the units in which the qpQueueSize attribute
is measured. The queue size is measured either in number of packets
or in units of time. The time interval specifies the time needed to
transmit all packets within the queue if the link speed is dedicated
entirely to transmission of packets within this queue. The property
definition is:
NAME qpQueueSizeUnits
SYNTAX Integer
VALUE This property can have two values. If the value is set
to 0, then the unit of measurement is number of packets.
If the value is set to 1, then the unit of measurement is
milliseconds.
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This property specifies the maximum queue size in packets or in
milliseconds, depending on the value of the qpQueueSizeUnits (0
specifies packets, and 1 specifies milliseconds). This property is
defined as follows:
NAME qpQueueSize
SYNTAX Integer
VALUE This value must be greater than 0.
This property specifies the congestion control drop algorithm that
should be used for this type of traffic. This property is defined as
follows:
NAME qpDropMethod
SYNTAX Integer
VALUES Three values are currently defined. The value 0
specifies a random drop algorithm, the value 1 specifies
a tail drop algorithm, and the value 2 specifies a head
drop algorithm.
This property specifies the units in which the two properties
qpDropMinThresholdValue and qpDropMaxThresholdValue are measured.
Thresholds can be measured either in packets or as a percentage of
the available queue sizes. This property is defined as follows:
NAME qpDropThresholdUnits
SYNTAX Integer
VALUES Three values are defined. The value 0 defines the units
as number of packets, the value 1 defines the units as a
percentage of the queue size and the value 2 defines the
units in milliseconds. If this property indicates that
the threshold units are percentages, then each of the
threshold properties expresses a whole-number percentage,
and hence its maximum value is 100.
This property specifies the minimum number of queuing and buffer
resources that should be reserved for this class of flows. The
threshold can be specified as either relative (i.e., a percentage) or
absolute (i.e., number of packets or millisecond) value according to
the value of the qpDropThresholdUnits property. If this property
Snir, et al. Standards Track [Page 55]
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specifies a value of 5 packets, then enough buffer and queuing
resources should be reserved to hold 5 packets before running the
specified congestion control drop algorithm. This property is
defined as follows:
NAME qpDropMinThresholdValue
SYNTAX Integer
VALUE This value must be greater than or equal to 0. If the
property qpDropMaxThresholdValue is defined, then the
value of the qpDropMinThresholdValue property must be
less than or equal to the value of the
qpDropMaxThresholdValue property.
This property specifies the maximum number of queuing and buffer
resources that should be reserved for this class of flows. The
threshold can be specified as either relative (i.e., a percentage) or
absolute (i.e., number of packets or milliseconds) value according to
the value of the qpDropThresholdUnits property. Congestion Control
droppers should not keep more packets than the value specified in
this property. Note, however, that some droppers may calculate queue
occupancy averages, and therefore the actual maximum queue resources
should be larger. This property is defined as follows:
NAME qpDropMaxThresholdValue
SYNTAX Integer
VALUE This value must be greater than or equal to 0. If the
property qpDropMinThresholdValue is defined, then the
value of the qpDropMinThresholdValue property must be
less than or equal to the value of the
qpDropMaxThresholdValue property.
This is an abstract base class that models a traffic profile.
Traffic profiles specify the maximum rate parameters used within
admission decisions. The association
QoSPolicyTrfcProfInAdmissionAction binds the admission decision to
the traffic profile. The class definition is as follows:
NAME QoSPolicyTrfcProf
DERIVED FROM Policy (defined in [PCIM])
ABSTRACT TRUE
PROPERTIES None
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This class models a two- or three-level Token Bucket traffic profile.
Additional profiles can be modeled by cascading multiple instances of
this class (e.g., by connecting the output of one instance to the
input of another instance). This traffic profile carries the policer
or shaper rate values to be enforced on a flow or a set of flows.
The class definition is as follows:
NAME QoSPolicyTokenBucketTrfcProf
DERIVED FROM QoSPolicyTrfcProf (defined in this document)
ABSTRACT FALSE
PROPERTIES qpTBRate, qpTBNormalBurst, qpTBExcessBurst
This is a non-negative integer that defines the token rate in
kilobits per second. A rate of zero means that all packets will be
out of profile. This property is defined as follows:
NAME qpTBRate
SYNTAX Integer
VALUE This value must be greater than to 0
This property is an integer that defines the normal size of a burst
measured in bytes. This property is defined as follows:
NAME qpTBNormalBurst
SYNTAX Integer
VALUE This value must be greater than to 0
This property is an integer that defines the excess burst size
measured in bytes. This property is defined as follows:
NAME qpTBExcessBurst
SYNTAX Integer
VALUE This value must be greater than or equal to
qpTBNormalBurst
This class represents an IntServ traffic profile. Values of IntServ
traffic profiles are compared against Traffic specification (TSPEC)
and QoS Reservation (FLOWSPEC) requests carried in RSVP requests.
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The class definition is as follows:
NAME QoSPolicyIntServTrfcProf
DERIVED FROM QoSPolicyTrfcProf (defined in this document)
ABSTRACT FALSE
PROPERTIES qpISTokenRate, qpISPeakRate, qpISBucketSize,
qpISResvRate, qpISResvSlack, qpISMinPolicedUnit,
qpISMaxPktSize
This property is a non-negative integer that defines the token rate
parameter, measured in kilobits per second. This property is defined
as follows:
NAME qpISTokenRate
SYNTAX Integer
VALUE This value must be greater than or equal to 0
This property is a non-negative integer that defines the peak rate
parameter, measured in kilobits per second. This property is defined
as follows:
NAME qpISPeakRate
SYNTAX Integer
VALUE This value must be greater than or equal to 0
This property is a non-negative integer that defines the token bucket
size parameter, measured in bytes. This property is defined as
follows:
NAME qpISBucketSize
SYNTAX Integer
VALUE This value must be greater than or equal to 0
This property is a non-negative integer that defines the reservation
rate (R-Spec) in the RSVP guaranteed service reservation. It is
measured in kilobits per second. This property is defined as
follows:
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NAME qpISResvRate
SYNTAX Integer
VALUE This value must be greater than or equal to 0
This property is a non-negative integer that defines the RSVP slack
term in the RSVP guaranteed service reservation. It is measured in
microseconds. This property is defined as follows:
NAME qpISResvSlack
SYNTAX Integer
VALUE This value must be greater than or equal to 0
This property is a non-negative integer that defines the minimum RSVP
policed unit, measured in bytes. This property is defined as
follows:
NAME qpISMinPolicedUnit
SYNTAX Integer
VALUE This value must be greater than or equal to 0
This property is a positive integer that defines the maximum allowed
packet size for RSVP messages, measured in bytes. This property is
defined as follows:
NAME qpISMaxPktSize
SYNTAX Integer
VALUE This value must be a positive integer, denoting the
number of bytes in the largest payload packet of an RSVP
signaled flow or class.
This class can be used for representing an indirection in variable
and value references either in a simple condition ("<x> match <y>")
or a simple action ("<x> = <y>"). In both cases, <x> and <y> are
known as the variable and the value of either the condition or
action. The value of the properties qpAttributeName and
qpAttributeValueList are used to substitute <x> and <y> in the
condition or action respectively.
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The substitution is done as follows: The value of the property
qpAttributeName is used to substitute <x> and the value of the
property qpAttributeValueList is used to substitute <y>.
Once the substitution is done, the condition can be evaluated and the
action can be performed.
For example, suppose we want to define a condition over a user name
of the form "user == 'Smith'", using the QoSPolicyRSVPUserVariable
class. The user information in the RSVP message provides a DN. The
DN points to a user objects holding many attributes. If the relevant
attribute is "last name", we would use the QoSPolicyAttributeValue
class with qpAttributeName = "Last Name", qpAttributeValueList =
{"Smith"}.
The class definition is as follows:
NAME QoSPolicyAttributeValue
DERIVED FROM PolicyValue (defined in [PCIMe])
ABSTRACT FALSE
PROPERTIES qpAttributeName, qpAttributeValueList
This property carries the name of the attribute that is to be used to
substitute <x> in a simple condition or simple condition of the forms
"<x> match <y>" or "<x> = <y>" respectively. This property is
defined as follows:
NAME qpAttributeName
SYNTAX String
This property carries a list of values that is to be used to
substitute <y> in a simple condition or simple action of the forms
"<x> match <y>" or "<x> = <y>" respectively.
This property is defined as follows:
NAME qpAttributeValueList
SYNTAX String
This is an abstract class that serves as the base class for all
implicit variables that have to do with RSVP conditioning. The class
definition is as follows:
Snir, et al. Standards Track [Page 60]
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NAME QoSPolicyRSVPVariable
DESCRIPTION An abstract base class used to build other classes
that specify different attributes of an RSVP request
DERIVED FROM PolicyImplicitVariable (defined in [PCIMe])
ABSTRACT TRUE
PROPERTIES None
This is a concrete class that contains the source IPv4 address of the
RSVP signaled flow, as defined in the RSVP PATH SENDER_TEMPLATE and
RSVP RESV FILTER_SPEC [RSVP] objects. The class definition is as
follows:
NAME QoSPolicyRSVPSourceIPv4Variable
DESCRIPTION The source IPv4 address of the RSVP signaled flow, as
defined in the RSVP PATH SENDER_TEMPLATE and RSVP RESV
FILTER_SPEC [RSVP] objects.
ALLOWED VALUE TYPES: PolicyIPv4AddrValue
DERIVED FROM QoSPolicyRSVPVariable (defined in this document)
ABSTRACT FALSE
PROPERTIES None
This is a concrete class that contains the destination IPv4 address
of the RSVP signaled flow, as defined in the RSVP PATH
SENDER_TEMPLATE and RSVP RESV FILTER_SPEC [RSVP] objects. The class
definition is as follows:
NAME QoSPolicyRSVPDestinationIPv4Variable
DESCRIPTION The destination IPv4 address of the RSVP signaled
flow, as defined in the RSVP PATH and RESV SESSION
[RSVP] objects.
ALLOWED VALUE TYPES: PolicyIPv4AddrValue
DERIVED FROM QoSPolicyRSVPVariable (defined in this document)
ABSTRACT FALSE
PROPERTIES None
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This is a concrete class that contains the source IPv6 address of the
RSVP signaled flow, as defined in the RSVP PATH SENDER_TEMPLATE and
RSVP RESV FILTER_SPEC [RSVP] objects. The class definition is as
follows:
NAME QoSPolicyRSVPSourceIPv6Variable
DESCRIPTION The source IPv6 address of the RSVP signaled flow, as
defined in the RSVP PATH SENDER_TEMPLATE and RSVP RESV
FILTER_SPEC [RSVP] objects.
ALLOWED VALUE TYPES: PolicyIPv6AddrValue
DERIVED FROM QoSPolicyRSVPVariable (defined in this document)
ABSTRACT FALSE
PROPERTIES None
This is a concrete class that contains the destination IPv6 address
of the RSVP signaled flow, as defined in the RSVP PATH
SENDER_TEMPLATE and RSVP RESV FILTER_SPEC [RSVP] objects. The class
definition is as follows:
NAME QoSPolicyRSVPDestinationIPv6Variable
DESCRIPTION The destination IPv6 address of the RSVP signaled
flow, as defined in the RSVP PATH and RESV SESSION
[RSVP] objects.
ALLOWED VALUE TYPES: PolicyIPv6AddrValue
DERIVED FROM QoSPolicyRSVPVariable (defined in this document)
ABSTRACT FALSE
PROPERTIES None
This class contains the source port of the RSVP signaled flow, as
defined in the RSVP PATH SENDER_TEMPLATE and RSVP RESV FILTER_SPEC
[RSVP] objects. The class definition is as follows:
NAME QoSPolicyRSVPSourcePortVariable
DESCRIPTION The source port of the RSVP signaled flow, as defined
in the RSVP PATH SENDER_TEMPLATE and RSVP RESV
FILTER_SPEC [RSVP] objects.
ALLOWED VALUE TYPES: PolicyIntegerValue (0..65535)
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DERIVED FROM QoSPolicyRSVPVariable (defined in this document)
ABSTRACT FALSE
PROPERTIES None
This is a concrete class that contains the destination port of the
RSVP signaled flow, as defined in the RSVP PATH SENDER_TEMPLATE and
RSVP RESV FILTER_SPEC [RSVP] objects. The class definition is as
follows:
NAME QoSPolicyRSVPDestinationPortVariable
DESCRIPTION The destination port of the RSVP signaled flow, as
defined in the RSVP PATH and RESV SESSION [RSVP]
objects.
ALLOWED VALUE TYPES: PolicyIntegerValue (0..65535)
DERIVED FROM QoSPolicyRSVPVariable (defined in this document)
ABSTRACT FALSE
PROPERTIES None
This is a concrete class that contains the IP Protocol number of the
RSVP signaled flow, as defined in the RSVP PATH and RESV SESSION
[RSVP] objects. The class definition is as follows:
NAME QoSPolicyRSVPIPProtocolVariable
DESCRIPTION The IP Protocol number of the RSVP signaled flow, as
defined in the RSVP PATH and RESV SESSION [RSVP]
objects.
ALLOWED VALUE TYPES: PolicyIntegerValue
DERIVED FROM QoSPolicyRSVPVariable (defined in this document)
ABSTRACT FALSE
PROPERTIES None
This is a concrete class that contains the IP Protocol version number
of the RSVP signaled flow, as defined in the RSVP PATH and RESV
SESSION [RSVP] objects. The well-known version numbers are 4 and 6.
This variable allows a policy definition of the type:
"If IP version = IPv4 then ...".
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The class definition is as follows:
NAME QoSPolicyRSVPIPVersionVariable
DESCRIPTION The IP version number of the IP Addresses carried the
RSVP signaled flow, as defined in the RSVP PATH and
RESV SESSION [RSVP] objects.
ALLOWED VALUE TYPES: PolciIntegerValue
DERIVED FROM QoSPolicyRSVPVariable (defined in this document)
ABSTRACT FALSE
PROPERTIES None
This is a concrete class that contains the DSCP value as defined in
the RSVP DCLASS [DCLASS] object. The class definition is as follows:
NAME QoSPolicyRSVPDCLASSVariable
DESCRIPTION The DSCP value as defined in the RSVP DCLASS [DCLASS]
object.
ALLOWED VALUE TYPES: PolicyIntegerValue,
PolicyBitStringValue
DERIVED FROM QoSPolicyRSVPVariable (defined in this document)
ABSTRACT FALSE
PROPERTIES None
This is a concrete class that contains the reservation style as
defined in the RSVP STYLE object in the RESV message [RSVP]. The
class definition is as follows:
NAME QoSPolicyRSVPStyleVariable
DESCRIPTION The reservation style as defined in the RSVP STYLE
object in the RESV message [RSVP].
ALLOWED VALUE TYPES: PolicyBitStringValue,
PolicyIntegerValue (Integer has
an enumeration of
{ Fixed-Filter=1,
Shared-Explicit=2,
Wildcard-Filter=3}
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DERIVED FROM QoSPolicyRSVPVariable (defined in this document)
ABSTRACT FALSE
PROPERTIES None
This is a concrete class that contains the Integrated Service
requested in the RSVP Reservation message, as defined in the FLOWSPEC
RSVP Object [RSVP]. The class definition is as follows:
NAME QoSPolicyRSVPIntServVariable
DESCRIPTION The integrated Service requested in the RSVP
Reservation message, as defined in the FLOWSPEC RSVP
Object [RSVP].
ALLOWED VALUE TYPES: PolicyIntegerValue (An enumerated
value of { CL=1 , GS=2, NULL=3}
DERIVED FROM QoSPolicyRSVPVariable (defined in this document)
ABSTRACT FALSE
PROPERTIES None
This is a concrete class that contains the RSVP message type, as
defined in the RSVP message common header [RSVP] object. The class
definition is as follows:
NAME QoSPolicyRSVPMessageTypeVariable
DESCRIPTION The RSVP message type, as defined in the RSVP message
common header [RSVP] object.
ALLOWED VALUE TYPES: Integer (An enumerated value of
{PATH=1 , PATHTEAR=2, RESV=3,
RESVTEAR=4, RESVERR=5, CONF=6,
PATHERR=7}
DERIVED FROM QoSPolicyRSVPVariable (defined in this document)
ABSTRACT FALSE
PROPERTIES None
This is a concrete class that contains the RSVP reservation priority,
as defined in [RFC3181] object. The class definition is as follows:
NAME QoSPolicyRSVPPreemptionPriorityVariable
DESCRIPTION The RSVP reservation priority as defined in [RFC3181].
Snir, et al. Standards Track [Page 65]
RFC 3644 Policy QoS Information Model November 2003
ALLOWED VALUE TYPES: PolicyIntegerValue
DERIVED FROM QoSPolicyRSVPVariable (defined in this document)
ABSTRACT FALSE
PROPERTIES None
This is a concrete class that contains the RSVP reservation defending
priority, as defined in [RFC3181] object. The class definition is as
follows:
NAME QoSPolicyRSVPPreemptionDefPriorityVariable
DESCRIPTION The RSVP preemption reservation defending priority as
defined in [RFC3181].
ALLOWED VALUE TYPES: PolicyIntegerValue
DERIVED FROM QoSPolicyRSVPVariable (defined in this document)
ABSTRACT FALSE
PROPERTIES None
This is a concrete class that contains the ID of the user that
initiated the flow as defined in the User Locator string in the
Identity Policy Object [RFC3182]. The class definition is as
follows:
NAME QoSPolicyRSVPUserVariable
DESCRIPTION The ID of the user that initiated the flow as defined
in the User Locator string in the Identity Policy
Object [RFC3182].
ALLOWED VALUE TYPES: QoSPolicyDNValue,
PolicyStringValue,
QoSPolicyAttributeValue
DERIVED FROM QoSPolicyRSVPVariable (defined in this document)
ABSTRACT FALSE
PROPERTIES None
This is a concrete class that contains the ID of the application that
generated the flow as defined in the application locator string in
the Application policy object [RFC2872]. The class definition is as
follows:
Snir, et al. Standards Track [Page 66]
RFC 3644 Policy QoS Information Model November 2003
NAME QoSPolicyRSVPApplicationVariable
DESCRIPTION The ID of the application that generated the flow as
defined in the application locator string in the
Application policy object [RFC2872].
ALLOWED VALUE TYPES: QoSPolicyDNValue,
PolicyStringValue,
QoSPolicyAttributeValue
DERIVED FROM QoSPolicyRSVPVariable (defined in this document)
ABSTRACT FALSE
PROPERTIES None
This is a concrete class that contains the type of authentication
used in the Identity Policy Object [RFC3182]. The class definition
is as follows:
NAME QoSPolicyRSVPAuthMethodVariable
DESCRIPTION The RSVP Authentication type used in the Identity
Policy Object [RFC3182].
ALLOWED VALUE TYPES: PolicyIntegerValue (An enumeration
of { NONE=0, PLAIN-TEXT=1,
DIGITAL-SIG = 2, KERBEROS_TKT=3,
X509_V3_CERT=4, PGP_CERT=5}
DERIVED FROM QoSPolicyRSVPVariable (defined in this document)
ABSTRACT FALSE
PROPERTIES None
This class is used to represent a single or set of Distinguished Name
[DNDEF] values, including wildcards. A Distinguished Name is a name
that can be used as a key to retrieve an object from a directory
service. This value can be used in comparison to reference values
carried in RSVP policy objects, as specified in [RFC3182]. The class
definition is as follows:
NAME QoSPolicyDNValue
DERIVED FROM PolicyValue
ABSTRACT FALSE
PROPERTIES qpDNList
Snir, et al. Standards Track [Page 67]
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This attribute provides an unordered list of strings, each
representing a Distinguished Name (DN) with wildcards. The format of
a DN is defined in [DNDEF]. The asterisk character ("*") is used as
wildcard for either a single attribute value or a wildcard for an
RDN. The order of RDNs is significant. For example: A qpDNList
attribute carrying the following value:
"CN=*, OU=Sales, O=Widget Inc., *, C=US" matches:
"CN=J. Smith, OU=Sales, O=Widget Inc, C=US"
and also matches:
"CN=J. Smith, OU=Sales, O=Widget Inc, L=CA, C=US".
The attribute is defined as follows:
NAME qpDNList
SYNTAX List of Distinguished Names implemented as strings, each of
which serves as a reference to another object.
This action controls the content of RSVP messages and the way RSVP
requests are admitted. Depending on the value of its
qpRSVPActionType property, this action directly translates into
either a COPS Replace Decision or a COPS Stateless Decision, or both
as defined in COPS for RSVP. Only variables that are subclasses of
the QoSPolicyRSVPVariable are allowed to be associated with this
action. The property definition is as follows:
NAME QoSPolicyRSVPSimpleAction
DESCRIPTION This action controls the content of RSVP messages and
the way RSVP requests are admitted.
DERIVED FROM SimplePolicyAction (defined in [PCIMe])
ABSTRACT FALSE
PROPERTIES qpRSVPActionType
This property is an enumerated integer denoting the type(s) of RSVP
action. The value 'REPLACE' denotes a COPS Replace Decision action.
The value 'STATELESS' denotes a COPS Stateless Decision action. The
value REPLACEANDSTATELESS denotes both decision actions. Refer to
[RFC2749] for details.
Snir, et al. Standards Track [Page 68]
RFC 3644 Policy QoS Information Model November 2003
NAME qpRSVPActionType
DESCRIPTION This property specifies whether the action type is for
COPS Replace, Stateless, or both types of decisions.
SYNTAX Integer
VALUE This is an enumerated integer. A value of 0 specifies
a COPS Replace decision. A value of 1 specifies a COPS
Stateless Decision. A value of 2 specifies both COPS
Replace and COPS Stateless decisions.
The IETF takes no position regarding the validity or scope of any
intellectual property or other rights that might be claimed to
pertain to the implementation or use of the technology described in
this document or the extent to which any license under such rights
might or might not be available; neither does it represent that it
has made any effort to identify any such rights. Information on the
IETF's procedures with respect to rights in standards-track and
standards-related documentation can be found in BCP-11.
Copies of claims of rights made available for publication and any
assurances of licenses to be made available, or the result of an
attempt made to obtain a general license or permission for the use of
such proprietary rights by implementers or users of this
specification can be obtained from the IETF Secretariat.
The IETF invites any interested party to bring to its attention any
copyrights, patents or patent applications, or other proprietary
rights which may cover technology that may be required to practice
this standard. Please address the information to the IETF Executive
Director.
The authors wish to thank the input of the participants of the Policy
Framework working group, and especially the combined group of the
PCIMe coauthors, Lee Rafalow, Andrea Westerinen, Ritu Chadha and
Marcus Brunner. In addition, we'd like to acknowledge the valuable
contribution from Ed Ellesson, Joel Halpern and Mircea Pana. Thank
you all for your comments, critique, ideas and general contribution.
The Policy Core Information Model [PCIM] describes the general
security considerations related to the general core policy model.
The extensions defined in this document do not introduce any
additional considerations related to security.
Snir, et al. Standards Track [Page 69]
RFC 3644 Policy QoS Information Model November 2003
[KEYWORDS] Bradner, S., "Key words for use in RFCs to Indicate
Requirement Levels", BCP 14, RFC 2119, March 1997.
[PCIM] Moore, B., Ellesson, E., Strassner, J. and A. Westerinen,
"Policy Core Information Model -- Version 1
Specification", RFC 3060, February 2001.
[PCIMe] Moore, B., Ed., "Policy Core Information Model
Extensions", RFC 3460, January 2003.
[TERMS] Westerinen, A., Schnizlein, J., Strassner, J., Scherling,
M., Quinn, B., Herzog, S., Huynh, A., Carlson, M., Perry,
J. and M. Waldbusser, "Terminology for Policy-based
Management", RFC 3198, November 2001.
[DIFFSERV] Blake, S., Black, D., Carlson, M., Davies, E., Wang, Z.
and W. Weiss, "An Architecture for Differentiated
Services", RFC 2475, December 1998.
[INTSERV] Braden, R., Clark, D. and S. Shenker, "Integrated Services
in the Internet Architecture: an Overview", RFC 1633, June
1994.
[RSVP] Braden, R., Ed., Zhang, L., Berson, S., Herzog, S. and S.
Jamin, "Resource ReSerVation Protocol (RSVP) -- Version 1
Functional Specification", RFC 2205, September 1997.
[RFC2749] Herzog, S., Ed., Boyle, J., Cohen, R., Durham, D., Rajan,
R. and A. Sastry, "COPS usage for RSVP", RFC 2749, January
2000.
[RFC3181] Herzog, S., "Signaled Preemption Priority Policy Element",
RFC 3181, October 2001.
[DIFF-MIB] Baker, F., Chan, K. and A. Smith, "Management Information
Base for the Differentiated Services Architecture", RFC
3289, May 2002.
[AF] Heinanen, J., Baker, F., Weiss, W. and J. Wroclawski,
"Assured Forwarding PHB Group", RFC 2597, June 1999.
Snir, et al. Standards Track [Page 70]
RFC 3644 Policy QoS Information Model November 2003
[CL] Wroclawski, J., "Specification of the Controlled-Load
Network Element Service", RFC 2211, September 1997.
[RSVP-IS] Wroclawski, J., "The Use of RSVP with IETF Integrated
Services", RFC 2210, September 1997.
[GS] Shenker, S., Partridge, C. and R. Guerin, "Specification
of the Guaranteed Quality of Service", RFC 2212, September
1997.
[DCLASS] Bernet, Y., "Format of the RSVP DCLASS Object", RFC 2996,
November 2000.
[RFC3182] Yadav, S., Yavatkar, R., Pabbati, R., Ford, P., Moore, T.,
Herzog, S. and R. Hess, "Identity Representation for
RSVP", RFC 3182, October 2001.
[RFC2872] Bernet, Y. and R. Pabbati, "Application and Sub
Application Identity Policy Element for Use with RSVP",
RFC 2872, June 2000.
[DNDEF] Wahl, M., Kille, S. and T. Howes, "Lightweight Directory
Access Protocol (v3): UTF-8 String Representation of
Distinguished Names", RFC 2253, December 1997.
Snir, et al. Standards Track [Page 71]
RFC 3644 Policy QoS Information Model November 2003
Yoram Ramberg
Cisco Systems
4 Maskit Street
Herzliya Pituach, Israel 46766
Phone: +972-9-970-0081
Fax: +972-9-970-0219
EMail: yramberg@cisco.com
Yoram Snir
Cisco Systems
300 East Tasman Drive
San Jose, CA 95134
Phone: +1 408-853-4053
Fax: +1 408 526-7864
EMail: ysnir@cisco.com
John Strassner
Intelliden Corporation
90 South Cascade Avenue
Colorado Springs, Colorado 80903
Phone: +1-719-785-0648
Fax: +1-719-785-0644
EMail: john.strassner@intelliden.com
Ron Cohen
Ntear LLC
Phone: +972-8-9402586
Fax: +972-9-9717798
EMail: ronc@lyciumnetworks.com
Bob Moore
IBM Corporation
P. O. Box 12195, BRQA/501/G206
3039 Cornwallis Rd.
Research Triangle Park, NC 27709-2195
Phone: +1 919-254-4436
Fax: +1 919-254-6243
EMail: remoore@us.ibm.com
Snir, et al. Standards Track [Page 72]
RFC 3644 Policy QoS Information Model November 2003
Copyright (C) The Internet Society (2003). All Rights Reserved.
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Snir, et al. Standards Track [Page 73]