One document matched: draft-ietf-policy-pcim-ext-08.txt-222065.txt
Differences from 08.txt-07.txt
Policy Framework Working Group B. Moore, Editor
INTERNET-DRAFT IBM
Updates: RFC 3060 May, 2002
Category: Standards Track
Policy Core Information Model Extensions
<draft-ietf-policy-pcim-ext-08.txt>
Tuesday, May 28, 2002, 8:03 AM
Status of this Memo
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Copyright Notice
Copyright (C) The Internet Society (2002). All Rights Reserved.
Abstract
This document specifies a number of changes to the Policy Core
Information Model (PCIM, RFC 3060). Two types of changes are included.
First, several completely new elements are introduced, for example,
classes for header filtering, that extend PCIM into areas that it did not
previously cover. Second, there are cases where elements of PCIM (for
example, policy rule priorities) are deprecated, and replacement elements
are defined (in this case, priorities tied to associations that refer to
policy rules). Both types of changes are done in such a way that, to the
extent possible, interoperability with implementations of the original
PCIM model is preserved. This document updates RFC 3060.
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Table of Contents
1. Introduction......................................................5
2. Changes since RFC 3060............................................5
3. Overview of the Changes...........................................6
3.1. How to Change an Information Model...........................6
3.2. List of Changes to the Model.................................6
3.2.1. Changes to PolicyRepository................................6
3.2.2. Additional Associations and Additional Reusable Elements...7
3.2.3. Priorities and Decision Strategies.........................7
3.2.4. Policy Roles...............................................7
3.2.5. CompoundPolicyConditions and CompoundPolicyActions.........8
3.2.6. Variables and Values.......................................8
3.2.7. Domain-Level Packet Filtering..............................8
3.2.8. Device-Level Packet Filtering..............................8
4. The Updated Class and Association Class Hierarchies...............9
5. Areas of Extension to PCIM.......................................13
5.1. Policy Scope................................................14
5.1.1. Levels of Abstraction: Domain- and Device-Level Policies..14
5.1.2. Administrative and Functional Scopes......................14
5.2. Reusable Policy Elements....................................15
5.3. Policy Sets.................................................16
5.4. Nested Policy Rules.........................................16
5.4.1. Usage Rules for Nested Rules..............................16
5.4.2. Motivation................................................17
5.5. Priorities and Decision Strategies..........................18
5.5.1. Structuring Decision Strategies...........................19
5.5.2. Side Effects..............................................20
5.5.3. Multiple PolicySet Trees For a Resource...................21
5.5.4. Deterministic Decisions...................................22
5.6. Policy Roles................................................23
5.6.1. Comparison of Roles in PCIM with Roles in snmpconf........23
5.6.2. Addition of PolicyRoleCollection to PCIMe.................23
5.6.3. Roles for PolicyGroups....................................24
5.7. Compound Policy Conditions and Compound Policy Actions......26
5.7.1. Compound Policy Conditions................................26
5.7.2. Compound Policy Actions...................................26
5.8. Variables and Values........................................27
5.8.1. Simple Policy Conditions..................................27
5.8.2. Using Simple Policy Conditions............................28
5.8.3. The Simple Condition Operator.............................29
5.8.4. SimplePolicyActions.......................................32
5.8.5. Policy Variables..........................................33
5.8.6. Explicitly Bound Policy Variables.........................34
5.8.7. Implicitly Bound Policy Variables.........................35
5.8.8. Structure and Usage of Pre-Defined Variables..............36
5.8.9. Rationale for Modeling Implicit Variables as Classes......37
5.8.10. Policy Values............................................38
5.9. Packet Filtering............................................38
5.9.1. Domain-Level Packet Filters...............................39
5.9.2. Device-Level Packet Filters...............................40
5.10. Conformance to PCIM and PCIMe..............................40
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6. Class Definitions................................................41
6.1. The Abstract Class "PolicySet"..............................41
6.2. Update PCIM's Class "PolicyGroup"...........................42
6.3. Update PCIM's Class "PolicyRule"............................42
6.4. The Class "SimplePolicyCondition"...........................43
6.5. The Class "CompoundPolicyCondition".........................44
6.6. The Class "CompoundFilterCondition".........................44
6.7. The Class "SimplePolicyAction"..............................45
6.8. The Class "CompoundPolicyAction"............................45
6.9. The Abstract Class "PolicyVariable".........................47
6.10. The Class "PolicyExplicitVariable".........................47
6.10.1. The Single-Valued Property "ModelClass"..................47
6.10.2. The Single-Valued Property ModelProperty.................48
6.11. The Abstract Class "PolicyImplicitVariable"................48
6.11.1. The Multi-Valued Property "ValueTypes"...................48
6.12. Subclasses of "PolicyImplicitVariable" Specified in PCIMe..48
6.12.1. The Class "PolicySourceIPv4Variable".....................49
6.12.2. The Class "PolicySourceIPv6Variable".....................49
6.12.3. The Class "PolicyDestinationIPv4Variable"................49
6.12.4. The Class "PolicyDestinationIPv6Variable"................49
6.12.5. The Class "PolicySourcePortVariable".....................50
6.12.6. The Class "PolicyDestinationPortVariable"................50
6.12.7. The Class "PolicyIPProtocolVariable".....................50
6.12.8. The Class "PolicyIPVersionVariable"......................51
6.12.9. The Class "PolicyIPToSVariable"..........................51
6.12.10. The Class "PolicyDSCPVariable"..........................51
6.12.11. The Class "PolicyFlowIdVariable"........................51
6.12.12. The Class "PolicySourceMACVariable".....................52
6.12.13. The Class "PolicyDestinationMACVariable"................52
6.12.14. The Class "PolicyVLANVariable"..........................52
6.12.15. The Class "PolicyCoSVariable"...........................52
6.12.16. The Class "PolicyEthertypeVariable".....................53
6.12.17. The Class "PolicySourceSAPVariable".....................53
6.12.18. The Class "PolicyDestinationSAPVariable"................53
6.12.19. The Class "PolicySNAPOUIVariable".......................54
6.12.20. The Class "PolicySNAPTypeVariable"......................54
6.12.21. The Class "PolicyFlowDirectionVariable".................54
6.13. The Abstract Class "PolicyValue"...........................55
6.14. Subclasses of "PolicyValue" Specified in PCIMe.............55
6.14.1. The Class "PolicyIPv4AddrValue"..........................55
6.14.2. The Class "PolicyIPv6AddrValue...........................56
6.14.3. The Class "PolicyMACAddrValue"...........................57
6.14.4. The Class "PolicyStringValue"............................58
6.14.5. The Class "PolicyBitStringValue".........................58
6.14.6. The Class "PolicyIntegerValue"...........................59
6.14.7. The Class "PolicyBooleanValue"...........................60
6.15. The Class "PolicyRoleCollection"...........................60
6.15.1. The Single-Valued Property "PolicyRole"..................61
6.16. The Class "ReusablePolicyContainer"........................61
6.17. Deprecate PCIM's Class "PolicyRepository"..................61
6.18. The Abstract Class "FilterEntryBase".......................61
6.19. The Class "IpHeadersFilter"................................62
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6.19.1. The Property HdrIpVersion................................62
6.19.2. The Property HdrSrcAddress...............................63
6.19.3. The Property HdrSrcAddressEndOfRange.....................63
6.19.4. The Property HdrSrcMask..................................63
6.19.5. The Property HdrDestAddress..............................64
6.19.6. The Property HdrDestAddressEndOfRange....................64
6.19.7. The Property HdrDestMask.................................64
6.19.8. The Property HdrProtocolID...............................64
6.19.9. The Property HdrSrcPortStart.............................65
6.19.10. The Property HdrSrcPortEnd..............................65
6.19.11. The Property HdrDestPortStart...........................65
6.19.12. The Property HdrDestPortEnd.............................66
6.19.13. The Property HdrDSCP....................................66
6.19.14. The Property HdrFlowLabel...............................66
6.20. The Class "8021Filter".....................................66
6.20.1. The Property 8021HdrSrcMACAddr...........................67
6.20.2. The Property 8021HdrSrcMACMask...........................67
6.20.3. The Property 8021HdrDestMACAddr..........................67
6.20.4. The Property 8021HdrDestMACMask..........................67
6.20.5. The Property 8021HdrProtocolID...........................68
6.20.6. The Property 8021HdrPriorityValue........................68
6.20.7. The Property 8021HdrVLANID...............................68
6.21. The Class FilterList.......................................68
6.21.1. The Property Direction...................................69
7. Association and Aggregation Definitions..........................69
7.1. The Aggregation "PolicySetComponent"........................69
7.2. Deprecate PCIM's Aggregation "PolicyGroupInPolicyGroup".....70
7.3. Deprecate PCIM's Aggregation "PolicyRuleInPolicyGroup"......70
7.4. The Abstract Association "PolicySetInSystem"................71
7.5. Update PCIM's Weak Association "PolicyGroupInSystem"........71
7.6. Update PCIM's Weak Association "PolicyRuleInSystem".........72
7.7. The Abstract Aggregation "PolicyConditionStructure".........72
7.8. Update PCIM's Aggregation "PolicyConditionInPolicyRule".....73
7.9. The Aggregation "PolicyConditionInPolicyCondition"..........73
7.10. The Abstract Aggregation "PolicyActionStructure"...........73
7.11. Update PCIM's Aggregation "PolicyActionInPolicyRule".......73
7.12. The Aggregation "PolicyActionInPolicyAction"...............74
7.13. The Aggregation "PolicyVariableInSimplePolicyCondition"....74
7.14. The Aggregation "PolicyValueInSimplePolicyCondition".......75
7.15. The Aggregation "PolicyVariableInSimplePolicyAction".......75
7.16. The Aggregation "PolicyValueInSimplePolicyAction"..........76
7.17. The Association "ReusablePolicy"...........................77
7.18. Deprecate PCIM's "PolicyConditionInPolicyRepository".......77
7.19. Deprecate PCIM's "PolicyActionInPolicyRepository"..........77
7.20. The Association ExpectedPolicyValuesForVariable............77
7.21. The Aggregation "ContainedDomain"..........................78
7.22. Deprecate PCIM's "PolicyRepositoryInPolicyRepository"......78
7.23. The Aggregation "EntriesInFilterList"......................79
7.23.1. The Reference GroupComponent.............................79
7.23.2. The Reference PartComponent..............................79
7.23.3. The Property EntrySequence...............................80
7.24. The Aggregation "ElementInPolicyRoleCollection"............80
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7.25. The Weak Association "PolicyRoleCollectionInSystem"........80
8. Intellectual Property............................................81
9. Acknowledgements.................................................81
10. Contributors....................................................81
11. Security Considerations.........................................83
12. Normative References............................................83
13. Informative References..........................................83
14. Editor's Address................................................84
15. Full Copyright Statement........................................84
16. Appendix A: Closed Issues.......................................85
1. Introduction
This document specifies a number of changes to the Policy Core
Information Model (PCIM, RFC 3060 [1]). Two types of changes are
included. First, several completely new elements are introduced, for
example, classes for header filtering, that extend PCIM into areas that
it did not previously cover. Second, there are cases where elements of
PCIM (for example, policy rule priorities) are deprecated, and
replacement elements are defined (in this case, priorities tied to
associations that refer to policy rules). Both types of changes are done
in such a way that, to the extent possible, interoperability with
implementations of the original PCIM model is preserved.
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 RFC 2119, reference [8].
2. Changes since RFC 3060
Section 3.2 contains a short discussion of the changes that this document
makes to the RFC 3060 information model. Here is a very brief list of
the changes:
1. Deprecate and replace PolicyRepository and its associations.
2. Clarify and expand the ways that PolicyRules and PolicyGroups are
aggregated.
3. Change how prioritization for PolicyRules is represented, and
introduce administrator-specified decision strategies for rule
evaluation.
4. Expand the role of PolicyRoles, and introduce a means of
associating a PolicyRole with a resource.
5. Introduce compound policy conditions and compound policy actions
into the model.
6. Introduce variables and values into the model.
7. Introduce variable and value subclasses for packet-header
filtering.
8. Introduce classes for device-level packet-header filtering.
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3. Overview of the Changes
3.1. How to Change an Information Model
The Policy Core Information Model is closely aligned with the DMTF's CIM
Core Policy model. Since there is no separately documented set of rules
for specifying IETF information models such as PCIM, it is reasonable to
look to the CIM specifications for guidance on how to modify and extend
the model. Among the CIM rules for changing an information model are the
following. Note that everything said here about "classes" applies to
association classes (including aggregations) as well as to non-
association classes.
o Properties may be added to existing classes.
o Classes, and individual properties, may be marked as DEPRECATED.
If there is a replacement feature for the deprecated class or
property, it is identified explicitly. Otherwise the notation "No
value" is used. In this document, the notation "DEPRECATED FOR
<feature-name>" is used to indicate that a feature has been
deprecated, and to identify its replacement feature.
o Classes may be inserted into the inheritance hierarchy above
existing classes, and properties from the existing classes may
then be "pulled up" into the new classes. The net effect is that
the existing classes have exactly the same properties they had
before, but the properties are inherited rather than defined
explicitly in the classes.
o New subclasses may be defined below existing classes.
3.2. List of Changes to the Model
The following subsections provide a very brief overview of the changes to
PCIM defined in PCIMe. In several cases, the origin of the change is
noted, as QPIM [11], ICPM [12], or QDDIM [15].
3.2.1. Changes to PolicyRepository
Because of the potential for confusion with the Policy Framework
component Policy Repository (from the four-box picture: Policy Management
Tool, Policy Repository, PDP, PEP), "PolicyRepository" is a bad name for
the PCIM class representing a container of reusable policy elements.
Thus the class PolicyRepository is being replaced with the class
ReusablePolicyContainer. To accomplish this change, it is necessary to
deprecate the PCIM class PolicyRepository and its three associations, and
replace them with a new class ReusablePolicyContainer and new
associations.
As a separate change, the associations for ReusablePolicyContainer are
being broadened, to allow a ReusablePolicyContainer to contain any
reusable policy elements. In PCIM, the only associations defined for a
PolicyRepository were for it to contain reusable policy conditions and
policy actions.
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3.2.2. Additional Associations and Additional Reusable Elements
The PolicyRuleInPolicyRule and PolicyGroupInPolicyRule aggregations have,
in effect, been imported from QPIM. ("In effect" because these two
aggregations, as well as PCIM'e two aggregations PolicyGroupInPolicyGroup
and PolicyRuleInPolicyGroup, are all being combined into a single
aggregation PolicySetComponent.) These aggregations make it possible to
define larger "chunks" of reusable policy to place in a
ReusablePolicyContainer. These aggregations also introduce new semantics
representing the contextual implications of having one PolicyRule
executing within the scope of another PolicyRule.
3.2.3. Priorities and Decision Strategies
Drawing from both QPIM and ICPM, the Priority property has been
deprecated in PolicyRule, and placed instead on the aggregation
PolicySetComponent. The QPIM rules for resolving relative priorities
across nested PolicyGroups and PolicyRules have been incorporated into
PCIMe as well. With the removal of the Priority property from
PolicyRule, a new modeling dependency is introduced. In order to
prioritize a PolicyRule/PolicyGroup relative to other
PolicyRules/PolicyGroups, the elements being prioritized must all reside
in one of three places: in a common PolicyGroup, in a common PolicyRule,
or in a common System.
In the absence of any clear, general criterion for detecting policy
conflicts, the PCIM restriction stating that priorities are relevant only
in the case of conflicts is being removed. In its place, a
PolicyDecisionStrategy property has been added to the PolicyGroup and
PolicyRule classes. This property allows policy administrator to select
one of two behaviors with respect to rule evaluation: either perform the
actions for all PolicyRules whose conditions evaluate to TRUE, or perform
the actions only for the highest-priority PolicyRule whose conditions
evaluate to TRUE. (This is accomplished by placing the
PolicyDecisionStrategy property in an abstract class PolicySet, from
which PolicyGroup and PolicyRule are derived.) The QPIM rules for
applying decision strategies to a nested set of PolicyGroups and
PolicyRules have also been imported.
3.2.4. Policy Roles
The concept of policy roles is added to PolicyGroups (being present
already in the PolicyRule class). This is accomplished via a new
superclass for both PolicyRules and PolicyGroups - PolicySet. For nested
PolicyRules and PolicyGroups, any roles associated with the outer rule or
group are automatically "inherited" by the nested one. Additional roles
may be added at the level of a nested rule or group.
It was also observed that there is no mechanism in PCIM for assigning
roles to resources. For example, while it is possible in PCIM to
associate a PolicyRule with the role "FrameRelay&&WAN", there is no way
to indicate which interfaces match this criterion. A new
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PolicyRoleCollection class has been defined in PCIMe, representing the
collection of resources associated with a particular role. The linkage
between a PolicyRule or PolicyGroup and a set of resources is then
represented by an instance of PolicyRoleCollection. Equivalent values
should be defined in the PolicyRoles property of PolicyRules and
PolicyGroups, and in the PolicyRole property in PolicyRoleCollection.
3.2.5. CompoundPolicyConditions and CompoundPolicyActions
The concept of a CompoundPolicyCondition has also been imported into
PCIMe from QPIM, and broadened to include a parallel
CompoundPolicyAction. In both cases the idea is to create reusable
"chunks" of policy that can exist as named elements in a
ReusablePolicyContainer. The "Compound" classes and their associations
incorporate the condition and action semantics that PCIM defined at the
PolicyRule level: DNF/CNF for conditions, and ordering for actions.
Compound conditions and actions are defined to work with any component
conditions and actions. In other words, while the components may be
instances, respectively, of SimplePolicyCondition and SimplePolicyAction
(discussed immediately below), they need not be.
3.2.6. Variables and Values
The SimplePolicyCondition / PolicyVariable / PolicyValue structure has
been imported into PCIMe from QPIM. A list of PCIMe-level variables is
defined, as well as a list of PCIMe-level values. Other variables and
values may, if necessary, be defined in submodels of PCIMe. For example,
QPIM defines a set of implicit variables corresponding to fields in RSVP
flows.
A corresponding SimplePolicyAction / PolicyVariable / PolicyValue
structure is also defined. While the semantics of a
SimplePolicyCondition are "variable matches value", a SimplePolicyAction
has the semantics "set variable to value".
3.2.7. Domain-Level Packet Filtering
For packet filtering specified at the domain level, a set of
PolicyVariables and PolicyValues are defined, corresponding to the fields
in an IP packet header plus the most common Layer 2 frame header fields.
It is expected that domain-level policy conditions that filter on these
header fields will be expressed in terms of CompoundPolicyConditions
built up from SimplePolicyConditions that use these variables and values.
An additional PolicyVariable, PacketDirection, is also defined, to
indicate whether a packet being filtered is traveling inbound or outbound
on an interface.
3.2.8. Device-Level Packet Filtering
For packet filtering expressed at the device level, including the packet
classifier filters modeled in QDDIM, the variables and values discussed
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in Section 3.2.7 need not be used. Filter classes derived from the CIM
FilterEntryBase class hierarchy are available for use in these contexts.
These latter classes have two important differences from the domain-level
classes:
o They support specification of filters for all of the fields in a
particular protocol header in a single object instance. With the
domain-level classes, separate instances are needed for each
header field.
o They provide native representations for the filter values, as
opposed to the string representation used by the domain-level
classes.
Device-level filter classes for the IP-related headers (IP, UDP, and TCP)
and the 802 MAC headers are defined, respectively, in Sections 6.19 and
6.20.
4. The Updated Class and Association Class Hierarchies
The following figure shows the class inheritance hierarchy for PCIMe.
Changes from the PCIM hierarchy are noted parenthetically.
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ManagedElement (abstract)
|
+--Policy (abstract)
| |
| +---PolicySet (abstract -- new - 5.3)
| | |
| | +---PolicyGroup (moved - 5.3)
| | |
| | +---PolicyRule (moved - 5.3)
| |
| +---PolicyCondition (abstract)
| | |
| | +---PolicyTimePeriodCondition
| | |
| | +---VendorPolicyCondition
| | |
| | +---SimplePolicyCondition (new - 5.8.1)
| | |
| | +---CompoundPolicyCondition (new - 5.7.1)
| | |
| | +---CompoundFilterCondition (new - 5.9)
| |
| +---PolicyAction (abstract)
| | |
| | +---VendorPolicyAction
| | |
| | +---SimplePolicyAction (new - 5.8.4)
| | |
| | +---CompoundPolicyAction (new - 5.7.2)
| |
| +---PolicyVariable (abstract -- new - 5.8.5)
| | |
| | +---PolicyExplicitVariable (new - 5.8.6)
| | |
| | +---PolicyImplicitVariable (abstract -- new - 5.8.7)
| | |
| | +---(subtree of more specific classes -- new - 6.12)
| |
| +---PolicyValue (abstract -- new - 5.8.10)
| |
| +---(subtree of more specific classes -- new - 6.14)
|
+--Collection (abstract -- newly referenced)
| |
| +--PolicyRoleCollection (new - 5.6.2)
(continued on following page)
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(continued from previous page)
ManagedElement(abstract)
|
+--ManagedSystemElement (abstract)
|
+--LogicalElement (abstract)
|
+--System (abstract)
| |
| +--AdminDomain (abstract)
| |
| +---ReusablePolicyContainer (new - 5.2)
| |
| +---PolicyRepository (deprecated - 5.2)
|
+--FilterEntryBase (abstract -- new - 6.18)
| |
| +--IpHeadersFilter (new - 6.19)
| |
| +--8021Filter (new - 6.20)
|
+--FilterList (new - 6.21)
Figure 1. Class Inheritance Hierarchy for PCIMe
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The following figure shows the association class hierarchy for PCIMe. As
before, changes from PCIM are noted parenthetically.
[unrooted]
|
+---PolicyComponent (abstract)
| |
| +---PolicySetComponent (new - 5.3)
| |
| +---PolicyGroupInPolicyGroup (deprecated - 5.3)
| |
| +---PolicyRuleInPolicyGroup (deprecated - 5.3)
| |
| +---PolicyConditionStructure (abstract -- new - 5.7.1)
| | |
| | +---PolicyConditionInPolicyRule (moved - 5.7.1)
| | |
| | +---PolicyConditionInPolicyCondition (new - 5.7.1)
| |
| +---PolicyRuleValidityPeriod
| |
| +---PolicyActionStructure (abstract -- new - 5.7.2)
| | |
| | +---PolicyActionInPolicyRule (moved - 5.7.2)
| | |
| | +---PolicyActionInPolicyAction (new - 5.7.2)
| |
| +---PolicyVariableInSimplePolicyCondition (new - 5.8.2)
| |
| +---PolicyValueInSimplePolicyCondition (new - 5.8.2)
| |
| +---PolicyVariableInSimplePolicyAction (new - 5.8.4)
| |
| +---PolicyValueInSimplePolicyAction (new - 5.8.4)
(continued on following page)
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(continued from previous page)
[unrooted]
|
+---Dependency (abstract)
| |
| +---PolicyInSystem (abstract)
| | |
| | +---PolicySetInSystem (abstract, new - 5.3)
| | | |
| | | +---PolicyGroupInSystem
| | | |
| | | +---PolicyRuleInSystem
| | |
| | +---ReusablePolicy (new - 5.2)
| | |
| | +---PolicyConditionInPolicyRepository (deprecated - 5.2)
| | |
| | +---PolicyActionInPolicyRepository (deprecated - 5.2)
| |
| +---ExpectedPolicyValuesForVariable (new - 5.8)
| |
| +---PolicyRoleCollectionInSystem (new - 5.6.2)
|
+---Component (abstract)
| |
| +---SystemComponent
| | |
| | +---ContainedDomain (new - 5.2)
| | |
| | +---PolicyRepositoryInPolicyRepository (deprecated - 5.2)
| |
| +---EntriesInFilterList (new - 7.23)
|
+---MemberOfCollection (newly referenced)
|
+--- ElementInPolicyRoleCollection (new - 5.6.2)
Figure 2. Association Class Inheritance Hierarchy for PCIMe
In addition to these changes that show up at the class and association
class level, there are other changes from PCIM involving individual class
properties. In some cases new properties are introduced into existing
classes, and in other cases existing properties are deprecated (without
deprecating the classes that contain them).
5. Areas of Extension to PCIM
The following subsections describe each of the areas for which PCIM
extensions are being defined.
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5.1. Policy Scope
Policy scopes may be thought of in two dimensions: 1) the level of
abstraction of the policy specification and 2) the applicability of
policies to a set of managed resources.
5.1.1. Levels of Abstraction: Domain- and Device-Level Policies
Policies vary in level of abstraction, from the business-level expression
of service level agreements (SLAs) to the specification of a set of rules
that apply to devices in a network. Those latter policies can,
themselves, be classified into at least two groups: those policies
consumed by a Policy Decision Point (PDP) that specify the rules for an
administrative and functional domain, and those policies consumed by a
Policy Enforcement Point (PEP) that specify the device-specific rules for
a functional domain. The higher-level rules consumed by a PDP, called
domain-level policies, may have late binding variables unspecified, or
specified by a classification, whereas the device-level rules are likely
to have fewer unresolved bindings.
There is a relationship between these levels of policy specification that
is out of scope for this standards effort, but that is necessary in the
development and deployment of a usable policy-based configuration system.
An SLA-level policy transformation to the domain-level policy may be
thought of as analogous to a visual builder that takes human input and
develops a programmatic rule specification. The relationship between the
domain-level policy and the device-level policy may be thought of as
analogous to that of a compiler and linkage editor that translates the
rules into specific instructions that can be executed on a specific type
of platform.
PCIM and PCIMe may be used to specify rules at any and all of these
levels of abstraction. However, at different levels of abstraction,
different mechanisms may be more or less appropriate.
5.1.2. Administrative and Functional Scopes
Administrative scopes for policy are represented in PCIM and in these
extensions to PCIM as System subclass instances. Typically, a domain-
level policy would be scoped by an AdminDomain instance (or by a
hierarchy of AdminDomain instances) whereas a device-level policy might
be scoped by a System instance that represents the PEP (e.g., an instance
of ComputerSystem, see CIM [2]). In addition to collecting policies into
an administrative domain, these System classes may also aggregate the
resources to which the policies apply.
Functional scopes (sometimes referred to as functional domains) are
generally defined by the submodels derived from PCIM and PCIMe, and
correspond to the service or services to which the policies apply. So,
for example, Quality of Service may be thought of as a functional scope,
or Diffserv and Intserv may each be thought of as functional scopes.
These scoping decisions are represented by the structure of the submodels
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derived from PCIM and PCIMe, and may be reflected in the number and types
of PEP policy client(s), services, and the interaction between policies.
Policies in different functional scopes are organized into disjoint sets
of policy rules. Different functional domains may share some roles, some
conditions, and even some actions. The rules from different functional
domains may even be enforced at the same managed resource, but for the
purposes of policy evaluation they are separate. See section 5.5.3 for
more information.
The functional scopes MAY be reflected in administrative scopes. That
is, deployments of policy may have different administrative scopes for
different functional scopes, but there is no requirement to do so.
5.2. Reusable Policy Elements
In PCIM, a distinction was drawn between reusable PolicyConditions and
PolicyActions and rule-specific ones. The PolicyRepository class was
also defined, to serve as a container for these reusable elements. The
name "PolicyRepository" has proven to be an unfortunate choice for the
class that serves as a container for reusable policy elements. This term
is already used in documents like the Policy Framework, to denote the
location from which the PDP retrieves all policy specifications, and into
which the Policy Management Tool places all policy specifications.
Consequently, the PolicyRepository class is being deprecated, in favor of
a new class ReusablePolicyContainer.
When a class is deprecated, any associations that refer to it must also
be deprecated. So replacements are needed for the two associations
PolicyConditionInPolicyRepository and PolicyActionInPolicyRepository, as
well as for the aggregation PolicyRepositoryInPolicyRepository. In
addition to renaming the PolicyRepository class to
ReusablePolicyContainer, however, PCIMe is also broadening the types of
policy elements that can be reusable. Consequently, rather than
providing one-for-one replacements for the two associations, a single
higher-level association ReusablePolicy is defined. This new association
allows any policy element (that is, an instance of any subclass of the
abstract class Policy) to be placed in a ReusablePolicyContainer.
Summarizing, the following changes in Sections 6 and 7 are the result of
this item:
o The class ReusablePolicyContainer is defined.
o PCIM's PolicyRepository class is deprecated.
o The association ReusablePolicy is defined.
o PCIM's PolicyConditionInPolicyRepository association is deprecated.
o PCIM's PolicyActionInPolicyRepository association is deprecated.
o The aggregation ContainedDomain is defined.
o PCIM's PolicyRepositoryInPolicyRepository aggregation is deprecated.
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5.3. Policy Sets
A "policy" can be thought of as a coherent set of rules to administer,
manage, and control access to network resources ("Policy Terminology",
reference [10]). The structuring of these coherent sets of rules into
subsets is enhanced in this document. In Section 5.4, we discuss the new
options for the nesting of policy rules.
A new abstract class, PolicySet, is introduced to provide an abstraction
for a set of rules. It is derived from Policy, and it is inserted into
the inheritance hierarchy above both PolicyGroup and PolicyRule. This
reflects the additional structural flexibility and semantic capability of
both subclasses.
Two properties are defined in PolicySet: PolicyDecisionStrategy and
PolicyRoles. The PolicyDecisionStrategy property is included in
PolicySet to define the evaluation relationship among the rules in the
policy set. See Section 5.5 for more information. The PolicyRoles
property is included in PolicySet to characterize the resources to which
the PolicySet applies. See Section 5.6 for more information.
Along with the definition of the PolicySet class, a new concrete
aggregation class is defined that will also be discussed in the following
sections. PolicySetComponent is defined as a subclass of
PolicyComponent; it provides the containment relationship for a PolicySet
in a PolicySet. PolicySetComponent replaces the two PCIM aggregations
PolicyGroupInPolicyGroup and PolicyRuleInPolicyGroup, so these two
aggregations are deprecated.
A PolicySet's relationship to an AdminDomain or other administrative
scoping system (for example, a ComputerSystem) is represented by the
PolicySetInSystem abstract association. This new association is derived
from PolicyInSystem, and the PolicyGroupInSystem and PolicyRuleInSystem
associations are now derived from PolicySetInSystem instead of directly
from PolicyInSystem. The PolicySetInSystem.Priority property is
discussed in Section 5.5.3.
5.4. Nested Policy Rules
As previously discussed, policy is described by a set of policy rules
that may be grouped into subsets. In this section we introduce the
notion of nested rules, or the ability to define rules within rules.
Nested rules are also called sub-rules, and we use both terms in this
document interchangeably. The aggregation PolicySetComponent is used to
represent the nesting of a policy rule in another policy rule.
5.4.1. Usage Rules for Nested Rules
The relationship between rules and sub-rules is defined as follows:
o The parent rule's condition clause is a condition for evaluation
of all nested rules; that is, the conditions of the parent are
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logically ANDed to the conditions of the sub-rules. If the parent
rule's condition clause evaluates to FALSE, sub-rules MAY be
skipped since they also evaluate to FALSE.
o If the parent rule's condition evaluates to TRUE, the set of sub-
rules SHALL BE evaluated according to the decision strategy and
priorities as discussed in Section 5.5.
o If the parent rule's condition evaluates to TRUE, the parent
rule's set of actions is executed BEFORE execution of the sub-
rulesÆ actions. The parent rule's actions are not to be confused
with default actions. A default action is one that is to be
executed only if none of the more specific sub-rules are executed.
If a default action needs to be specified, it needs to be defined
as an action that is part of a catchall sub-rule associated with
the parent rule. The association linking the default action(s) in
this special sub-rule should have the lowest priority relative to
all other sub-rule associations:
if parent-condition then parent rule's action
if condA then actA
if condB then ActB
if True then default action
Such a default action functions as a default when FirstMatching
decision strategies are in effect (see section 5.5). If
AllMatching applies, the "default" action is always performed.
o Policy rules have a context in which they are executed. The rule
engine evaluates and applies the policy rules in the context of
the managed resource(s) that are identified by the policy roles
(or by an explicit association). Submodels MAY add additional
context to policy rules based on rule structure; any such
additional context is defined by the semantics of the action
classes of the submodel.
5.4.2. Motivation
Rule nesting enhances Policy readability, expressiveness and reusability.
The ability to nest policy rules and form sub-rules is important for
manageability and scalability, as it enables complex policy rules to be
constructed from multiple simpler policy rules. These enhancements ease
the policy management tools' task, allowing policy rules to be expressed
in a way closer to how humans think.
Although rule nesting can be used to suggest optimizations in the way
policy rules are evaluated, as discussed in section 5.5.2 "Side Effects,"
nesting does not specify nor does it require any particular order of
evaluation of conditions. Optimization of rule evaluation can be done in
the PDP or in the PEP by dedicated code. This is similar to the relation
between a high level programming language like C and machine code. An
optimizer can create a more efficient machine code than any optimization
done by the programmer within the source code. Nevertheless, if the PEP
or PDP does not do optimization, the administrator writing the policy may
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be able to influence the evaluation of the policy rules for execution
using rule nesting.
Nested rules are not designed for policy repository retrieval
optimization. It is assumed that all rules and groups that are assigned
to a role are retrieved by the PDP or PEP from the policy repository and
enforced. Optimizing the number of rules retrieved should be done by
clever selection of roles.
5.5. Priorities and Decision Strategies
A "decision strategy" is used to specify the evaluation method for the
policies in a PolicySet. Two decision strategies are defined:
"FirstMatching" and "AllMatching." The FirstMatching strategy is used to
cause the evaluation of the rules in a set such that the only actions
enforced on a given examination of the PolicySet are those for the first
rule (that is, the rule with the highest priority) that has its
conditions evaluate to TRUE. The AllMatching strategy is used to cause
the evaluation of all rules in a set; for all of the rules whose
conditions evaluate to TRUE, the actions are enforced. Implementations
MUST support the FirstMatching decision strategy; implementations MAY
support the AllMatching decision strategy.
As previously discussed, the PolicySet subclasses are PolicyGroup and
PolicyRule: either subclass may contain PolicySets of either subclass.
Loops, including the degenerate case of a PolicySet that contains itself,
are not allowed when PolicySets contain other PolicySets. The
containment relationship is specified using the PolicySetComponent
aggregation.
The relative priority within a PolicySet is established by the Priority
property of the PolicySetComponent aggregation of the contained
PolicyGroup and PolicyRule instances. The use of PCIM's
PolicyRule.Priority property is deprecated in favor of this new property.
The separation of the priority property from the rule has two advantages.
First, it generalizes the concept of priority, so that it can be used for
both groups and rules. Second, it places the priority on the
relationship between the parent policy set and the subordinate policy
group or rule. The assignment of a priority value then becomes much
easier, in that the value is used only in relationship to other
priorities in the same set.
Together, the PolicySet.PolicyDecisionStrategy and
PolicySetComponent.Priority determine the processing for the rules
contained in a PolicySet. As before, the larger priority value
represents the higher priority. Unlike the earlier definition,
PolicySetComponent.Priority MUST have a unique value when compared with
others defined for the same aggregating PolicySet. Thus, the evaluation
of rules within a set is deterministically specified.
For a FirstMatching decision strategy, the first rule (that is, the one
with the highest priority) in the set that evaluates to True, is the only
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rule whose actions are enforced for a particular evaluation pass through
the PolicySet.
For an AllMatching decision strategy, all of the matching rules are
enforced. The relative priority of the rules is used to determine the
order in which the actions are to be executed by the enforcement point:
the actions of the higher priority rules are executed first. Since the
actions of higher priority rules are executed first, lower priority rules
that also match may get the "last word," and thus produce a counter-
intuitive result. So, for example, if two rules both evaluate to True,
and the higher priority rule sets the DSCP to 3 and the lower priority
rule sets the DSCP to 4, the action of the lower priority rule will be
executed later and, therefore, will "win," in this example, setting the
DSCP to 4. Thus, conflicts between rules are resolved by this execution
order.
An implementation of the rule engine need not provide the action
sequencing but the actions MUST be sequenced by the PEP or PDP on its
behalf. So, for example, the rule engine may provide an ordered list of
actions to be executed by the PEP and any required serialization is then
provided by the service configured by the rule engine. See Section 5.5.2
for a discussion of side effects.
5.5.1. Structuring Decision Strategies
As discussed in Sections 5.3 and 5.4, PolicySet instances may be nested
arbitrarily. For a FirstMatching decision strategy on a PolicySet, any
contained PolicySet that matches satisfies the termination criteria for
the FirstMatching strategy. A PolicySet is considered to match if it is
a PolicyRule and its conditions evaluate to True, or if the PolicySet is
a PolicyGroup and at least one of its contained PolicyGroups or
PolicyRules match. The priority associated with contained PolicySets,
then, determines when to terminate rule evaluation in the structured set
of rules.
In the example shown in Figure 3, the relative priorities for the nested
rules, high to low, are 1A, 1B1, 1X2, 1B3, 1C, 1C1, 1X2 and 1C3. (Note
that PolicyRule 1X2 is included in both PolicyGroup 1B and PolicyRule 1C,
but with different priorities.) Of course, which rules are enforced is
also dependent on which rules, if any, match.
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PolicyGroup 1: FirstMatching
|
+-- Pri=6 -- PolicyRule 1A
|
+-- Pri=5 -- PolicyGroup 1B: AllMatching
| |
| +-- Pri=5 -- PolicyGroup 1B1: AllMatching
| | |
| | +---- etc.
| |
| +-- Pri=4 -- PolicyRule 1X2
| |
| +-- Pri=3 -- PolicyRule 1B3: FirstMatching
| |
| +---- etc.
|
+-- Pri=4 -- PolicyRule 1C: FirstMatching
|
+-- Pri=4 -- PolicyRule 1C1
|
+-- Pri=3 -- PolicyRule 1X2
|
+-- Pri=2 -- PolicyRule 1C3
Figure 3. Nested PolicySets with Different Decision Strategies
o Because PolicyGroup 1 has a FirstMatching decision strategy, if
the conditions of PolicyRule 1A match, its actions are enforced
and the evaluation stops.
o If it does not match, PolicyGroup 1B is evaluated using an
AllMatching strategy. Since PolicyGroup 1B1 also has an
AllMatching strategy all of the rules and groups of rules
contained in PolicyGroup 1B1 are evaluated and enforced as
appropriate. PolicyRule 1X2 and PolicyRule 1B3 are also evaluated
and enforced as appropriate. If any of the sub-rules in the
subtrees of PolicyGroup 1B evaluate to True, then PolicyRule 1C is
not evaluated because the FirstMatching strategy of PolicyGroup 1
has been satisfied.
o If neither PolicyRule 1A nor PolicyGroup 1B yield a match, then
PolicyRule 1C is evaluated. Since it is first matching, rules
1C1, 1X2, and 1C3 are evaluated until the first match, if any.
5.5.2. Side Effects
Although evaluation of conditions is sometimes discussed as an ordered
set of operations, the rule engine need not be implemented as a
procedural language interpreter. Any side effects of condition evaluation
or the execution of actions MUST NOT affect the result of the evaluation
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of other conditions evaluated by the rule engine in the same evaluation
pass. That is, an implementation of a rule engine MAY evaluate all
conditions in any order before applying the priority and determining
which actions are to be executed.
So, regardless of how a rule engine is implemented, it MUST NOT include
any side effects of condition evaluation in the evaluation of conditions
for either of the decision strategies. For both the AllMatching decision
strategy and for the nesting of rules within rules (either directly or
indirectly) where the actions of more than one rule may be enforced, any
side effects of the enforcement of actions MUST NOT be included in
condition evaluation on the same evaluation pass.
5.5.3. Multiple PolicySet Trees For a Resource
As shown in the example in Figure 3. , PolicySet trees are defined by the
PolicySet subclass instances and the PolicySetComponent aggregation
instances between them. Each PolicySet tree has a defined set of
decision strategies and evaluation priorities. In section 5.6 we discuss
some improvements in the use of PolicyRoles that cause the parent
PolicySet.PolicyRoles to be applied to all contained PolicySet instances.
However, a given resource may still have multiple, disjoint PolicySet
trees regardless of how they are collected. These top-level PolicySet
instances are called "unrooted" relative to the given resource.
So, a PolicySet instance is defined to be rooted or unrooted in the
context of a particular managed element; the relationship to the managed
element is usually established by the policy roles of the PolicySet
instance and of the managed element (see 5.6 "Policy Roles"). A
PolicySet instance is unrooted in that context if and only if there is no
PolicySetComponent association to a parent PolicySet that is also related
to the same managed element. These PolicySetComponent aggregations are
traversed up the tree without regard to how a PolicySet instance came to
be related with the ManagedElement. Figure 4. shows an example where
instance A has role A, instance B has role B and so on. In this example,
in the context of interface X, instances B, and C are unrooted and
instances D, E, and F are all rooted. In the context of interface Y,
instance A is unrooted and instances B, C, D, E and F are all rooted.
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+---+ +-----------+ +-----------+
| A | | I/F X | | I/F Y |
+---+ | has roles | | has roles |
/ \ | B & C | | A & B |
/ \ +-----------+ +-----------+
+---+ +---+
| B | | C |
+---+ +---+
/ \ \
/ \ \
+---+ +---+ +---+
| D | | E | | F |
+---+ +---+ +---+
Figure 4. Unrooted PolicySet Instances
For those cases where there are multiple unrooted PolicySet instances
that apply to the same managed resource (i.e., not in a common
PolicySetComponent tree), the decision strategy among these disjoint
PolicySet instances is the FirstMatching strategy. The priority used
with this FirstMatching strategy is defined in the PolicySetInSystem
association. The PolicySetInSystem subclass instances are present for all
PolicySet instances (it is a required association) but the priority is
only used as a default for unrooted PolicySet instances in a given
ManagedElement context.
The FirstMatching strategy is used among all unrooted PolicySet instances
that apply to a given resource for a given functional domain. So, for
example, the PolicySet instances that are used for QoS policy and the
instances that are used for IKE policy, although they are disjoint, are
not joined in a FirstMatching decision strategy. Instead, they are
evaluated independently of one another.
5.5.4. Deterministic Decisions
As previously discussed, PolicySetComponent.Priority values MUST be
unique within a containing PolicySet and PolicySetInSystem.Priority
values MUST be unique for an associated System. Each PolicySet, then, has
a deterministic behavior based upon the decision strategy and uniquely
defined priority.
There are certainly cases where rules need not have a unique priority
value (i.e., where evaluation and execution priority is not important).
However, it is believed that the flexibility gained by this capability is
not sufficiently beneficial to justify the possible variations in
implementation behavior and the resulting confusion that might occur.
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5.6. Policy Roles
A policy role is defined in [10] as "an administratively specified
characteristic of a managed element (for example, an interface). It is a
selector for policy rules and PRovisioning Classes (PRCs), to determine
the applicability of the rule/PRC to a particular managed element."
In PCIMe, PolicyRoles is defined as a property of PolicySet, which is
inherited by both PolicyRules and PolicyGroups. In this draft, we also
add PolicyRole as the identifying name of a collection of resources
(PolicyRoleCollection), where each element in the collection has the
specified role characteristic.
5.6.1. Comparison of Roles in PCIM with Roles in snmpconf
In the Configuration Management with SNMP (snmpconf) working group's
Policy Based Management MIB [14], policy rules are of the form
if <policyFilter> then <policyAction>
where <policyFilter> is a set of conditions that are used to determine
whether or not the policy applies to an object instance. The policy
filter can perform comparison operations on SNMP variables already
defined in MIBS (e.g., "ifType == ethernet").
The policy management MIB defined in [14] defines a Role table that
enables one to associate Roles with elements, where roles have the same
semantics as in PCIM. Then, since the policyFilter in a policy allows one
to define conditions based on the comparison of the values of SNMP
variables, one can filter elements based on their roles as defined in the
Role group.
This approach differs from that adopted in PCIM in the following ways.
First, in PCIM, a set of role(s) is associated with a policy rule as the
values of the PolicyRoles property of a policy rule. The semantics of
role(s) are then expected to be implemented by the PDP (i.e. policies are
applied to the elements with the appropriate roles). In [14], however,
no special processing is required for realizing the semantics of roles;
roles are treated just as any other SNMP variables and comparisons of
role values can be included in the policy filter of a policy rule.
Secondly, in PCIM, there is no formally defined way of associating a role
with an object instance, whereas in [14] this is done via the use of the
Role tables (pmRoleESTable and pmRoleSETable). The Role tables associate
Role values with elements.
5.6.2. Addition of PolicyRoleCollection to PCIMe
In order to remedy the latter shortcoming in PCIM (the lack of a way of
associating a role with an object instance), PCIMe has a new class
PolicyRoleCollection derived from the CIM Collection class. Resources
that share a common role are aggregated by a PolicyRoleCollection
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instance, via the ElementInPolicyRoleCollection aggregation. The role is
specified in the PolicyRole property of the aggregating
PolicyRoleCollection instance.
A PolicyRoleCollection always exists in the context of a system. As was
done in PCIM for PolicyRules and PolicyGroups, an association,
PolicyRoleCollectionInSystem, captures this relationship. Remember that
in CIM, System is a base class for describing network devices and
administrative domains.
The association between a PolicyRoleCollection and a system should be
consistent with the associations that scope the policy rules/groups that
are applied to the resources in that collection. Specifically, a
PolicyRoleCollection should be associated with the same System as the
applicable PolicyRules and/or PolicyGroups, or to a System higher in the
tree formed by the SystemComponent association. When a PEP belongs to
multiple Systems (i.e., AdminDomains), and scoping by a single domain is
impractical, two alternatives exist. One is to arbitrarily limit domain
membership to one System/AdminDomain. The other option is to define a
more global AdminDomain that simply includes the others, and/or that
spans the business or enterprise.
As an example, suppose that there are 20 traffic trunks in a network, and
that an administrator would like to assign three of them to provide
"gold" service. Also, the administrator has defined several policy rules
which specify how the "gold" service is delivered. For these rules, the
PolicyRoles property (inherited from PolicySet) is set to "Gold Service".
In order to associate three traffic trunks with "gold" service, an
instance of the PolicyRoleCollection class is created and its PolicyRole
property is also set to "Gold Service". Following this, the
administrator associates three traffic trunks with the new instance of
PolicyRoleCollection via the ElementInPolicyRoleCollection aggregation.
This enables a PDP to determine that the "Gold Service" policy rules
apply to the three aggregated traffic trunks.
Note that roles are used to optimize policy retrieval. It is not
mandatory to implement roles or, if they have been implemented, to group
elements in a PolicyRoleCollection. However, if roles are used, then
either the collection approach should be implemented, or elements should
be capable of reporting their "pre-programmed" roles (as is done in
COPS).
5.6.3. Roles for PolicyGroups
In PCIM, role(s) are only associated with policy rules. However, it may
be desirable to associate role(s) with groups of policy rules. For
example, a network administrator may want to define a group of rules that
apply only to Ethernet interfaces. A policy group can be defined with a
role-combination="Ethernet", and all the relevant policy rules can be
placed in this policy group. (Note that in PCIMe, role(s) are made
available to PolicyGroups as well as to PolicyRules by moving PCIM's
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PolicyRoles property up from PolicyRule to the new abstract class
PolicySet. The property is then inherited by both PolicyGroup and
PolicyRule.) Then every policy rule in this policy group implicitly
inherits this role-combination from the containing policy group. A
similar implicit inheritance applies to nested policy groups.
There is no explicit copying of role(s) from container to contained
entity. Obviously, this implicit inheritance of role(s) leads to the
possibility of defining inconsistent role(s) (as explained in the example
below); the handling of such inconsistencies is beyond the scope of
PCIMe.
As an example, suppose that there is a PolicyGroup PG1 that contains
three PolicyRules, PR1, PR2, and PR3. Assume that PG1 has the roles
"Ethernet" and "Fast". Also, assume that the contained policy rules have
the role(s) shown below:
+------------------------------+
| PolicyGroup PG1 |
| PolicyRoles = Ethernet, Fast |
+------------------------------+
|
| +------------------------+
| | PolicyRule PR1 |
|--------| PolicyRoles = Ethernet |
| +------------------------+
|
| +--------------------------+
| | PolicyRule PR2 |
|--------| PolicyRoles = <undefined>|
| +--------------------------+
|
| +------------------------+
| | PolicyRule PR3 |
|--------| PolicyRoles = Slow |
+------------------------+
Figure 5. Inheritance of Roles
In this example, the PolicyRoles property value for PR1 is consistent
with the value in PG1, and in fact, did not need to be redefined. The
value of PolicyRoles for PR2 is undefined. Its roles are implicitly
inherited from PG1. Lastly, the value of PolicyRoles for PR3 is "Slow".
This appears to be in conflict with the role, "Fast," defined in PG1.
However, whether these roles are actually in conflict is not clear. In
one scenario, the policy administrator may have wanted only "Fast"-
"Ethernet" rules in the policy group. In another scenario, the
administrator may be indicating that PR3 applies to all "Ethernet"
interfaces regardless of whether they are "Fast" or "Slow." Only in the
former scenario (only "Fast"-"Ethernet" rules in the policy group) is
there a role conflict.
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Note that it is possible to override implicitly inherited roles via
appropriate conditions on a PolicyRule. For example, suppose that PR3
above had defined the following conditions:
(interface is not "Fast") and (interface is "Slow")
This results in unambiguous semantics for PR3.
5.7. Compound Policy Conditions and Compound Policy Actions
Compound policy conditions and compound policy actions are introduced to
provide additional reusable "chunks" of policy.
5.7.1. Compound Policy Conditions
A CompoundPolicyCondition is a PolicyCondition representing a Boolean
combination of simpler conditions. The conditions being combined may be
SimplePolicyConditions (discussed below in Section 6.4), but the utility
of reusable combinations of policy conditions is not necessarily limited
to the case where the component conditions are simple ones.
The PCIM extensions to introduce compound policy conditions are
relatively straightforward. Since the purpose of the extension is to
apply the DNF / CNF logic from PCIM's PolicyConditionInPolicyRule
aggregation to a compound condition that aggregates simpler conditions,
the following changes are required:
o Create a new aggregation PolicyConditionInPolicyCondition, with the
same GroupNumber and ConditionNegated properties as
PolicyConditionInPolicyRule. The cleanest way to do this is to
move the properties up to a new abstract aggregation superclass
PolicyConditionStructure, from which the existing aggregation
PolicyConditionInPolicyRule and a new aggregation
PolicyConditionInPolicyCondition are derived. For now there is no
need to re-document the properties themselves, since they are
already documented in PCIM as part of the definition of the
PolicyConditionInPolicyRule aggregation.
o It is also necessary to define a concrete subclass
CompoundPolicyCondition of PolicyCondition, to introduce the
ConditionListType property. This property has the same function,
and works in exactly the same way, as the corresponding property
currently defined in PCIM for the PolicyRule class.
The class and property definitions for representing compound policy
conditions are below, in Section 6.
5.7.2. Compound Policy Actions
A compound action is a convenient construct to represent a sequence of
actions to be applied as a single atomic action within a policy rule. In
many cases, actions are related to each other and should be looked upon
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as sub-actions of one "logical" action. An example of such a logical
action is "shape & mark" (i.e., shape a certain stream to a set of
predefined bandwidth characteristics and then mark these packets with a
certain DSCP value). This logical action is actually composed of two
different QoS actions, which should be performed in a well-defined order
and as a complete set.
The CompoundPolicyAction construct allows one to create a logical
relationship between a number of actions, and to define the activation
logic associated with this logical action.
The CompoundPolicyAction construct allows the reusability of these
complex actions, by storing them in a ReusablePolicyContainer and reusing
them in different policy rules. Note that a compound action may also be
aggregated by another compound action.
As was the case with CompoundPolicyCondition, the PCIM extensions to
introduce compound policy actions are relatively straightforward. This
time the goal is to apply the property ActionOrder from PCIM's
PolicyActionInPolicyRule aggregation to a compound action that aggregates
simpler actions. The following changes are required:
o Create a new aggregation PolicyActionInPolicyAction, with the same
ActionOrder property as PolicyActionInPolicyRule. The cleanest way
to do this is to move the property up to a new abstract aggregation
superclass PolicyActionStructure, from which the existing
aggregation PolicyActionInPolicyRule and a new aggregation
PolicyActionInPolicyAction are derived.
o It is also necessary to define a concrete subclass
CompoundPolicyAction of PolicyAction, to introduce the
SequencedActions property. This property has the same function,
and works in exactly the same way, as the corresponding property
currently defined in PCIM for the PolicyRule class.
o Finally, a new property ExecutionStrategy is needed for both the
PCIM class PolicyRule and the new class CompoundPolicyAction. This
property allows the policy administrator to specify how the PEP
should behave in the case where there are multiple actions
aggregated by a PolicyRule or by a CompoundPolicyAction.
The class and property definitions for representing compound policy
actions are below, in Section 6.
5.8. Variables and Values
The following subsections introduce several related concepts, including
PolicyVariables and PolicyValues (and their numerous subclasses),
SimplePolicyConditions, and SimplePolicyActions.
5.8.1. Simple Policy Conditions
The SimplePolicyCondition class models elementary Boolean expressions of
the form: "(<variable> MATCH <value>)". The relationship 'MATCH', which
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is implicit in the model, is interpreted based on the variable and the
value. Section 5.8.3 explains the semantics of the 'MATCH' operator.
Arbitrarily complex Boolean expressions can be formed by chaining
together any number of simple conditions using relational operators.
Individual simple conditions can be negated as well. Arbitrarily complex
Boolean expressions are modeled by the class CompoundPolicyCondition
(described in Section 5.7.1).
For example, the expression "SourcePort == 80" can be modeled by a simple
condition. In this example, 'SourcePort' is a variable, '==' is the
relational operator denoting the equality relationship (which is
generalized by PCIMe to a "MATCH" relationship), and '80' is an integer
value. The complete interpretation of a simple condition depends on the
binding of the variable. Section 5.8.5 describes variables and their
binding rules.
The SimplePolicyCondition class refines the basic structure of the
PolicyCondition class defined in PCIM by using the pair (<variable>,
<value>) to form the condition. Note that the operator between the
variable and the value is always implied in PCIMe: it is not a part of
the formal notation.
The variable specifies the attribute of an object that should be matched
when evaluating the condition. For example, for a QoS model, this object
could represent the flow that is being conditioned. A set of predefined
variables that cover network attributes commonly used for filtering is
introduced in PCIMe, to encourage interoperability. This list covers
layer 3 IP attributes such as IP network addresses, protocols and ports,
as well as a set of layer 2 attributes (e.g., MAC addresses).
The bound variable is matched against a value to produce the Boolean
result. For example, in the condition "The source IP address of the flow
belongs to the 10.1.x.x subnet", a source IP address variable is matched
against a 10.1.x.x subnet value.
5.8.2. Using Simple Policy Conditions
Simple conditions can be used in policy rules directly, or as building
blocks for creating compound policy conditions.
Simple condition composition MUST enforce the following data-type
conformance rule: The ValueTypes property of the variable must be
compatible with the type of the value class used. The simplest (and
friendliest, from a user point-of-view) way to do this is to equate the
type of the value class with the name of the class. By ensuring that the
ValueTypes property of the variable matches the name of the value class
used, we know that the variable and value instance values are compatible
with each other.
Composing a simple condition requires that an instance of the class
SimplePolicyCondition be created, and that instances of the variable and
value classes that it uses also exist. Note that the variable and/or
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value instances may already exist as reusable objects in an appropriate
ReusablePolicyContainer.
Two aggregations are used in order to create the pair (<variable>,
<value>). The aggregation PolicyVariableInSimplePolicyCondition relates
a SimplePolicyCondition to a single variable instance. Similarly, the
aggregation PolicyValueInSimplePolicyCondition relates a
SimplePolicyCondition to a single value instance. Both aggregations are
defined in this document.
Figure 6. depicts a SimplePolicyCondition with its associated variable
and value. Also shown are two PolicyValue instances that identify the
values that the variable can assume.
+-----------------------+
| SimplePolicyCondition |
+-----------------------+
* @
* @
+------------------+ * @ +---------------+
| (PolicyVariable) |*** @@@| (PolicyValue) |
+------------------+ +---------------+
# #
# ooo #
# #
+---------------+ +---------------+
| (PolicyValue) | ooo | (PolicyValue) |
+---------------+ +---------------+
Aggregation Legend:
**** PolicyVariableInSimplePolicyCondition
@@@@ PolicyValueInSimplePolicyCondition
#### ExpectedPolicyValuesForVariable
Figure 6. SimplePolicyCondition
Note: The class names in parenthesis denote subclasses. The classes
named in the figure are abstract, and thus cannot themselves be
instantiated.
5.8.3. The Simple Condition Operator
A simple condition models an elementary Boolean expression of the form
"variable MATCHes value". However, the formal notation of the
SimplePolicyCondition, together with its associations, models only a
pair, (<variable>, <value>). The 'MATCH' operator is not directly
modeled -- it is implied. Furthermore, this implied 'MATCH' operator
carries overloaded semantics.
For example, in the simple condition "DestinationPort MATCH '80'", the
interpretation of the 'MATCH' operator is equality (the 'equal'
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operator). Clearly, a different interpretation is needed in the
following cases:
o "DestinationPort MATCH {'80', '8080'}" -- operator is 'IS SET
MEMBER'
o "DestinationPort MATCH {'1 to 255'}" -- operator is 'IN INTEGER
RANGE'
o "SourceIPAddress MATCH 'MyCompany.com'" -- operator is 'IP ADDRESS
AS RESOLVED BY DNS'
The examples above illustrate the implicit, context-dependant nature of
the 'MATCH' operator. The interpretation depends on the actual variable
and value instances in the simple condition. The interpretation is
always derived from the bound variable and the value instance associated
with the simple condition. Text accompanying the value class and
implicit variable definition is used for interpreting the semantics of
the 'MATCH' relationship. In the following list, we define generic
(type-independent) matching.
PolicyValues may be multi-fielded, where each field may contain a range
of values. The same equally holds for PolicyVariables. Basically, we
have to deal with single values (singleton), ranges ([lower bound ..
upper bound]), and sets (a,b,c). So independent of the variable and
value type, the following set of generic matching rules for the 'MATCH'
operator are defined.
o singleton matches singleton -> the matching rule is defined in the
type
o singleton matches range [lower bound .. upper bound] -> the
matching evaluates to true, if the singleton matches the lower
bound or the upper bound or a value in between
o singleton matches set -> the matching evaluates to true, if the
value of the singleton matches one of the components in the set,
where a component may be a singleton or range again
o ranges [A..B] matches singleton -> is true if A matches B matches
singleton
o range [A..B] matches range [X..Y] -> the matching evaluates to
true, if all values of the range [A..B] are also in the range
[X..Y]. For instance, [3..5] match [1..6] evaluates to true,
whereas [3..5] match [4..6] evaluates to false.
o range [A..B] matches set (a,b,c, ...) -> the matching evaluates to
true, if all values in the range [A..B] are part of the set. For
instance, range [2..3] match set ([1..2],3) evaluates to true, as
well as range [2..3] match set (2,3), and range [2..3] match set
([1..2],[3..5]).
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o set (a,b,c, ...) match singleton -> is true if a match b match c
match ... match singleton
o set match range -> the matching evaluates to true, if all values
in the set are part of the range. For example, set (2,3) match
range [1..4] evaluates to true.
o set (a,b,c,...) match set (x,y,z,...) -> the matching evaluates to
true, if all values in the set (a,b,c,...) are part of the set
(x,y,z,...). For example, set (1,2,3) match set (1,2,3,4)
evaluates to true. Set (1,2,3) match set (1,2) evaluates to
false.
Variables may contain various types (Section 6.11.1). When not stated
otherwise, the type of the value bound to the variable at condition
evaluation time and the value type of the PolicyValue instance need to be
of the same type. If they differ, then the condition evaluates to FALSE.
The ExpectedPolicyValuesForVariable association specifies an expected set
of values that can be matched with a variable within a simple condition.
Using this association, a source or destination port can be limited to
the range 0-200, a source or destination IP address can be limited to a
specified list of IPv4 address values, etc.
+-----------------------+
| SimplePolicyCondition |
+-----------------------+
* @
* @
* @
+-----------------------------------+ +--------------------------+
| Name=SmallSourcePorts | | Name=Port300 |
| Class=PolicySourcePortVariable | | Class=PolicyIntegerValue |
| ValueTypes=[PolicyIntegerValue] | | IntegerList = [300] |
+-----------------------------------+ +--------------------------+
#
#
#
+-------------------------+
|Name=SmallPortsValues |
|Class=PolicyIntegerValue |
|IntegerList=[1..200] |
+-------------------------+
Aggregation Legend:
**** PolicyVariableInSimplePolicyCondition
@@@@ PolicyValueInSimplePolicyCondition
#### ExpectedPolicyValuesForVariable
Figure 7. An Invalid SimplePolicyCondition
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The ability to express these limitations appears in the model to support
validation of a SimplePolicyCondition prior to its deployment to an
enforcement point. A Policy Management Tool, for example SHOULD NOT
accept the SimplePolicyCondition shown in Figure 7. If, however, a
policy rule containing this condition does appear at an enforcement
point, the expected values play no role in the determination of whether
the condition evaluates to True or False. Thus in this example, the
SimplePolicyCondition evaluates to True if the source port for the packet
under consideration is 300, and it evaluates to False otherwise.
5.8.4. SimplePolicyActions
The SimplePolicyAction class models the elementary set operation. "SET
<variable> TO <value>". The set operator MUST overwrite an old value of
the variable. In the case where the variable to be updated is multi-
valued, the only update operation defined is a complete replacement of
all previous values with a new set. In other words, there are no Add or
Remove [to/from the set of values] operations defined for
SimplePolicyActions.
For example, the action "set DSCP to EF" can be modeled by a simple
action. In this example, 'DSCP' is an implicit variable referring to the
IP packet header DSCP field. 'EF' is an integer or bit string value (6
bits). The complete interpretation of a simple action depends on the
binding of the variable.
The SimplePolicyAction class refines the basic structure of the
PolicyAction class defined in PCIM, by specifying the contents of the
action using the (<variable>, <value>) pair to form the action. The
variable specifies the attribute of an object. The value of this
attribute is set to the value specified in <value>. Selection of the
object is a function of the type of variable involved. See Sections
5.8.6 and 5.8.7, respectively, for details on object selection for
explicitly bound and implicitly bound policy variables.
SimplePolicyActions can be used in policy rules directly, or as building
blocks for creating CompoundPolicyActions.
The set operation is only valid if the list of types of the variable
(ValueTypes property of PolicyImplicitVariable) includes the specified
type of the value. Conversion of values from one representation into
another is not defined. For example, a variable of IPv4Address type may
not be set to a string containing a DNS name. Conversions are part of an
implementation-specific mapping of the model.
As was the case with SimplePolicyConditions, the role of expected values
for the variables that appear in SimplePolicyActions is for validation,
prior to the time when an action is executed. Expected values play no
role in action execution.
Composing a simple action requires that an instance of the class
SimplePolicyAction be created, and that instances of the variable and
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value classes that it uses also exist. Note that the variable and/or
value instances may already exist as reusable objects in an appropriate
ReusablePolicyContainer.
Two aggregations are used in order to create the pair (<variable>,
<value>). The aggregation PolicyVariableInSimplePolicyAction relates a
SimplePolicyAction to a single variable instance. Similarly, the
aggregation PolicyValueInSimplePolicyAction relates a SimplePolicyAction
to a single value instance. Both aggregations are defined in this
document.
Figure 8. depicts a SimplePolicyAction with its associated variable and
value.
+-----------------------+
| SimplePolicyAction |
| |
+-----------------------+
* @
* @
+------------------+ * @ +---------------+
| (PolicyVariable) |*** @@@| (PolicyValue) |
+------------------+ +---------------+
# #
# ooo #
# #
+---------------+ +---------------+
| (PolicyValue) | ooo | (PolicyValue) |
+---------------+ +---------------+
Aggregation Legend:
**** PolicyVariableInSimplePolicyAction
@@@@ PolicyValueInSimplePolicyAction
#### ExpectedPolicyValuesForVariable
Figure 8. SimplePolicyAction
5.8.5. Policy Variables
A variable generically represents information that changes (or "varies"),
and that is set or evaluated by software. In policy, conditions and
actions can abstract information as "policy variables" to be evaluated in
logical expressions, or set by actions.
PCIMe defines two types of PolicyVariables, PolicyImplicitVariables and
PolicyExplicitVariables. The semantic difference between these classes
is based on modeling context. Explicit variables are bound to exact
model constructs, while implicit variables are defined and evaluated
outside of a model. For example, one can imagine a PolicyCondition
testing whether a CIM ManagedSystemElement's Status property has the
value "Error." The Status property is an explicitly defined
PolicyVariable (i.e., it is defined in the context of the CIM Schema, and
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evaluated in the context of a specific instance). On the other hand,
network packets are not explicitly modeled or instantiated, since there
is no perceived value (at this time) in managing at the packet level.
Therefore, a PolicyCondition can make no explicit reference to a model
construct that represents a network packet's source address. In this
case, an implicit PolicyVariable is defined, to allow evaluation or
modification of a packet's source address.
5.8.6. Explicitly Bound Policy Variables
Explicitly bound policy variables indicate the class and property names
of the model construct to be evaluated or set. The CIM Schema defines
and constrains "appropriate" values for the variable (i.e., model
property) using data types and other information such as class/property
qualifiers.
A PolicyExplicitVariable is "explicit" because its model semantics are
exactly defined. It is NOT explicit due to an exact binding to a
particular object instance. If PolicyExplicitVariables were tied to
instances (either via associations or by an object identification
property in the class itself), then we would be forcing element-specific
rules. On the other hand, if we only specify the object's model context
(class and property name), but leave the binding to the policy framework
(for example, using policy roles), then greater flexibility results for
either general or element-specific rules.
For example, an element-specific rule is obtained by a condition
((<variable>, <value>) pair) that defines CIM LogicalDevice
DeviceID="12345". Alternately, if a PolicyRule's PolicyRoles is "edge
device" and the condition ((<variable>, <value>) pair) is Status="Error",
then a general rule results for all edge devices in error.
Currently, the only binding for a PolicyExplicitVariable defined in PCIMe
is to the instances selected by policy roles. For each such instance, a
SimplePolicyCondition that aggregates the PolicyExplicitVariable
evaluates to True if and only if ALL of the following are true:
o The instance selected is of the class identified by the variable's
ModelClass property, or of a subclass of this class.
o The instance selected has the property identified by the
variable's ModelProperty property.
o The value of this property in the instance matches the value
specified in the PolicyValue aggregated by the condition.
In all other cases, the SimplePolicyCondition evaluates to False.
For the case where a SimplePolicyAction aggregates a
PolicyExplicitVariable, the indicated property in the selected instance
is set to the value represented by the PolicyValue that the
SimplePolicyAction also aggregates. However, if the selected instance is
not of the class identified by the variable's ModelClass property, or of
a subclass of this class, then the action is not performed. In this case
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the SimplePolicyAction is not treated either as a successfully executed
action (for the execution strategy Do Until Success) or as a failed
action (for the execution strategy Do Until Failure). Instead, the
remaining actions for the policy rule, if any, are executed as if this
SimplePolicyAction were not present at all in the list of actions
aggregated by the rule.
Explicit variables would be more powerful if they could reach beyond the
instances selected by policy roles, to related instances. However, to
represent a policy rule involving such variables in any kind of general
way requires something that starts to resemble very much a complete
policy language. Clearly such a language is outside the scope of PCIMe,
although it might be the subject of a future draft.
By restricting much of the generality, it would be possible for explicit
variables in PCIMe to reach slightly beyond a selected instance. For
example, if a selected instance were related to exactly one instance of
another class via a particular association class, and if the goal of the
policy rule were both to test a property of this related instance and to
set a property of that same instance, then it would be possible to
represent the condition and action of the rule using
PolicyExplicitVariables. Rather than handling this one specific case
with explicit variables, though, it was decided to lump them with the
more general case, and deal with them if and when a policy language is
defined.
Refer to Section 6.10 for the formal definition of the class
PolicyExplicitVariable.
5.8.7. Implicitly Bound Policy Variables
Implicitly bound policy variables define the data type and semantics of a
variable. This determines how the variable is bound to a value in a
condition or an action. Further instructions are provided for specifying
data type and/or value constraints for implicitly bound variables.
PCIMe introduces an abstract class, PolicyImplicitVariable, to model
implicitly bound variables. This class is derived from the abstract
class PolicyVariable also defined in PCIMe. Each of the implicitly bound
variables introduced by PCIMe (and those that are introduced by domain-
specific sub-models) MUST be derived from the PolicyImplicitVariable
class. The rationale for using this mechanism for modeling is explained
below in Section 5.8.9.
A domain-specific policy information model that extends PCIMe may define
additional implicitly bound variables either by deriving them directly
from the class PolicyImplicitVariable, or by further refining an existing
variable class such as SourcePort. When refining a class such as
SourcePort, existing binding rules, type or value constraints may be
narrowed.
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5.8.8. Structure and Usage of Pre-Defined Variables
A class derived from PolicyImplicitVariable to model a particular
implicitly bound variable SHOULD be constructed so that its name depicts
the meaning of the variable. For example, a class defined to model the
source port of a TCP/UDP flow SHOULD have 'SourcePort' in its name.
PCIMe defines one association and one general-purpose mechanism that
together characterize each of the implicitly bound variables that it
introduces:
1. The ExpectedPolicyValuesForVariable association defines the set of
value classes that could be matched to this variable.
2. The list of constraints on the values that the PolicyVariable can
hold (i.e., values that the variable must match) are defined by
the appropriate properties of an associated PolicyValue class.
In the example presented above, a PolicyImplicitVariable represents the
SourcePort of incoming traffic. The ValueTypes property of an instance
of this class will hold the class name PolicyIntegerValue. This by
itself constrains the data type of the SourcePort instance to be an
integer. However, we can further constrain the particular values that
the SourcePort variable can hold by entering valid ranges in the
IntegerList property of the PolicyIntegerValue instance (0 - 65535 in
this document).
The combination of the VariableName and the
ExpectedPolicyValuesForVariable association provide a consistent and
extensible set of metadata that define the semantics of variables that
are used to form policy conditions. Since the
ExpectedPolicyValuesForVariable association points to a PolicyValue
instance, any of the values expressible in the PolicyValue class can be
used to constrain values that the PolicyImplicitVariable can hold. For
example:
o The ValueTypes property can be used to ensure that only proper
classes are used in the expression. For example, the SourcePort
variable will not be allowed to ever be of type
PolicyIPv4AddrValue, since source ports have different semantics
than IP addresses and may not be matched. However, integer value
types are allowed as the property ValueTypes holds the string
"PolicyIntegerValue", which is the class name for integer values.
o The ExpectedPolicyValuesForVariable association also ensures that
variable-specific semantics are enforced (e.g., the SourcePort
variable may include a constraint association to a value object
defining a specific integer range that should be matched).
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5.8.9. Rationale for Modeling Implicit Variables as Classes
An implicitly bound variable can be modeled in one of several ways,
including a single class with an enumerator for each individual
implicitly bound variable and an abstract class extended for each
individual variable. The reasons for using a class inheritance mechanism
for specifying individual implicitly bound variables are these:
1. It is easy to extend. A domain-specific information model can
easily extend the PolicyImplicitVariable class or its subclasses
to define domain-specific and context-specific variables. For
example, a domain-specific QoS policy information model may
introduce an implicitly bound variable class to model applications
by deriving a qosApplicationVariable class from the
PolicyImplicitVariable abstract class.
2. Introduction of a single structural class for implicitly bound
variables would have to include an enumerator property that
contains all possible individual implicitly bound variables. This
means that a domain-specific information model wishing to
introduce an implicitly bound variable must extend the enumerator
itself. This results in multiple definitions of the same class,
differing in the values available in the enumerator class. One
definition, in this document, would include the common implicitly
bound variables' names, while a second definition, in the domain-
specific information model document, may include additional values
('qosApplicationVariable' in the example above). It wouldnÆt even
be obvious to the application developer that multiple class
definitions existed. It would be harder still for the application
developer to actually find the correct class to use.
3. In addition, an enumerator-based definition would require each
additional value to be registered with IANA to ascertain adherence
to standards. This would make the process cumbersome.
4. A possible argument against the inheritance mechanism would cite
the fact that this approach results in an explosion of class
definitions compared to an enumerator class, which only introduces
a single class. While, by itself, this is not a strike against
the approach, it may be argued that data models derived from this
information model may be more difficult to optimize for
applications. This argument is rejected on the grounds that
application optimization is of lesser value for an information
model than clarity and ease of extension. In addition, it is hard
to claim that the inheritance model places an absolute burden on
the optimization. For example, a data model may still use
enumeration to denote instances of pre-defined variables and claim
PCIMe compliance, as long as the data model can be mapped
correctly to the definitions specified in this document.
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5.8.10. Policy Values
The abstract class PolicyValue is used for modeling values and constants
used in policy conditions. Different value types are derived from this
class, to represent the various attributes required. Extensions of the
abstract class PolicyValue, defined in this document, provide a list of
values for basic network attributes. Values can be used to represent
constants as named values. Named values can be kept in a reusable policy
container to be reused by multiple conditions. Examples of constants
include well-known ports, well-known protocols, server addresses, and
other similar concepts.
The PolicyValue subclasses define three basic types of values: scalars,
ranges and sets. For example, a well-known port number could be defined
using the PolicyIntegerValue class, defining a single value (80 for
HTTP), a range (80-88), or a set (80, 82, 8080) of ports, respectively.
For details, please see the class definition for each value type in
Section 6.14 of this document.
PCIMe defines the following subclasses of the abstract class PolicyValue:
Classes for general use:
- PolicyStringValue,
- PolicyIntegerValue,
- PolicyBitStringValue
- PolicyBooleanValue.
Classes for layer 3 Network values:
- PolicyIPv4AddrValue,
- PolicyIPv6AddrValue.
Classes for layer 2 Network values:
- PolicyMACAddrValue.
For details, please see the class definition section of each class in
Section 6.14 of this document.
5.9. Packet Filtering
PCIMe contains two mechanisms for representing packet filters. The more
general of these, termed here the domain-level model, expresses packet
filters in terms of policy variables and policy values. The other
mechanism, termed here the device-level model, expresses packet filters
in a way that maps more directly to the packet fields to which the
filters are being applied. While it is possible to map between these two
representations of packet filters, no mapping is provided in PCIMe
itself.
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5.9.1. Domain-Level Packet Filters
In addition to filling in the holes in the overall Policy infrastructure,
PCIMe proposes a single mechanism for expressing domain-level packet
filters in policy conditions. This is being done in response to concerns
that even though the initial "wave" of submodels derived from PCIM were
all filtering on IP packets, each was doing it in a slightly different
way. PCIMe proposes a common way to express IP packet filters. The
following figure illustrates how packet-filtering conditions are
expressed in PCIMe.
+---------------------------------+
| CompoundFilterCondition |
| - IsMirrored boolean |
| - ConditionListType (DNF|CNF) |
+---------------------------------+
+ + +
+ + +
+ + +
SimplePC SimplePC SimplePC
* @ * @ * @
* @ * @ * @
* @ * @ * @
FlowDirection "In" SrcIP <addr1> DstIP <addr2>
Aggregation Legend:
++++ PolicyConditionInPolicyCondition
**** PolicyVariableInSimplePolicyCondition
@@@@ PolicyValueInSimplePolicyCondition
Figure 9. Packet Filtering in Policy Conditions
In Figure 9. , each SimplePolicyCondition represents a single field to be
filtered on: Source IP address, Destination IP address, Source port, etc.
An additional SimplePolicyCondition indicates the direction that a packet
is traveling on an interface: inbound or outbound. Because of the
FlowDirection condition, care must be taken in aggregating a set of
SimplePolicyConditions into a CompoundFilterCondition. Otherwise, the
resulting CompoundPolicyCondition may match all inbound packets, or all
outbound packets, when this is probably not what was intended.
Individual SimplePolicyConditions may be negated when they are aggregated
by a CompoundFilterCondition.
CompoundFilterCondition is a subclass of CompoundPolicyCondition. It
introduces one additional property, the Boolean property IsMirrored. The
purpose of this property is to allow a single CompoundFilterCondition to
match packets traveling in both directions on a higher-level connection
such as a TCP session. When this property is TRUE, additional packets
match a filter, beyond those that would ordinarily match it. An example
will illustrate how this property works.
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Suppose we have a CompoundFilterCondition that aggregates the following
three filters, which are ANDed together:
o FlowDirection = "In"
o Source IP = 9.1.1.1
o Source Port = 80
Regardless of whether IsMirrored is TRUE or FALSE, inbound packets will
match this CompoundFilterCondition if their Source IP address = 9.1.1.1
and their Source port = 80. If IsMirrored is TRUE, however, an outbound
packet will also match the CompoundFilterCondition if its Destination IP
address = 9.1.1.1 and its Destination port = 80.
IsMirrored "flips" the following Source/Destination packet header fields:
o FlowDirection "In" / FlowDirection "Out"
o Source IP address / Destination IP address
o Source port / Destination port
o Source MAC address / Destination MAC address
o Source [layer-2] SAP / Destination [layer-2] SAP.
5.9.2. Device-Level Packet Filters
At the device level, packet header filters are represented by two
subclasses of the abstract class FilterEntryBase: IpHeadersFilter and
8021Filter. Submodels of PCIMe may define other subclasses of
FilterEntryBase in addition to these two; ICPM [12], for example, defines
subclasses for IPsec-specific filters.
Instances of the subclasses of FilterEntryBase are not used directly as
filters. They are always aggregated into a FilterList, by the
aggregation EntriesInFilterList. For PCIMe and its submodels, the
EntrySequence property in this aggregation always takes its default value
'0', indicating that the aggregated filter entries are ANDed together.
The FilterList class includes an enumeration property Direction,
representing the direction of the traffic flow to which the FilterList is
to be applied. The value Mirrored(4) for Direction represents exactly
the same thing as the IsMirrored boolean does in CompoundFilterCondition.
See Section 5.9.1 for details.
5.10. Conformance to PCIM and PCIMe
Because PCIM and PCIMe provide the core classes for modeling policies,
they are not in general sufficient by themselves for representing actual
policy rules. Submodels, such as QPIM and ICPM, provide the means for
expressing policy rules, by defining subclasses of the classes defined in
PCIM and PCIMe, and/or by indicating how the PolicyVariables and
PolicyValues defined in PCIMe can be used to express conditions and
actions applicable to the submodel.
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A particular submodel will not, in general, need to use every element
defined in PCIM and PCIMe. For the elements it does not use, a submodel
SHOULD remain silent on whether its implementations must support the
element, must not support the element, should support the element, etc.
For the elements it does use, a submodel SHOULD indicate which elements
its implementations must support, which elements they should support, and
which elements they may support.
PCIM and PCIMe themselves simply define elements that may be of use to
submodels. These documents remain silent on whether implementations are
required to support an element, should support it, etc.
This model (and derived submodels) defines conditions and actions that
are used by policy rules. While the conditions and actions defined
herein are straightforward and may be presumed to be widely supported, as
submodels are developed it is likely that situations will arise in which
specific conditions or actions are not supported by some part of the
policy execution system. Similarly, situations may also occur where
rules contain syntactic or semantic errors.
It should be understood that the behavior and effect of undefined or
incorrectly defined conditions or actions is not prescribed by this
information model. While it would be helpful if it were prescribed, the
variations in implementation restrict the ability for this information
model to control the effect. For example, if an implementation only
detected that a PEP could not enforce a given action on that PEP, it
would be very difficult to declare that such a failure should affect
other PEPs, or the PDP process. On the other hand, if the PDP determines
that it cannot properly evaluate a condition, that failure may well
affect all applications of the containing rules.
6. Class Definitions
The following definitions supplement those in PCIM itself. PCIM
definitions that are not DEPRECATED here are still current parts of the
overall Policy Core Information Model.
6.1. The Abstract Class "PolicySet"
PolicySet is an abstract class that may group policies into a structured
set of policies.
NAME PolicySet
DESCRIPTION An abstract class that represents a set of policies
that form a coherent set. The set of contained
policies has a common decision strategy and a common
set of policy roles. Subclasses include PolicyGroup
and PolicyRule.
DERIVED FROM Policy
ABSTRACT TRUE
PROPERTIES PolicyDecisionStrategy
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PolicyRoles
The PolicyDecisionStrategy property specifies the evaluation method for
policy groups and rules contained within the policy set.
NAME PolicyDecisionStrategy
DESCRIPTION The evaluation method used for policies contained in
the PolicySet. FirstMatching enforces the actions of
the first rule that evaluates to TRUE; AllMatching
enforces the actions of all rules that evaluate to
TRUE.
SYNTAX uint16
VALUES 1 [FirstMatching], 2 [AllMatching]
DEFAULT VALUE 1 [FirstMatching]
The definition of PolicyRoles is unchanged from PCIM. It is, however,
moved from the class Policy up to the superclass PolicySet.
6.2. Update PCIM's Class "PolicyGroup"
The PolicyGroup class is moved, so that it is now derived from PolicySet.
NAME PolicyGroup
DESCRIPTION A container for a set of related PolicyRules and
PolicyGroups.
DERIVED FROM PolicySet
ABSTRACT FALSE
PROPERTIES (none)
6.3. Update PCIM's Class "PolicyRule"
The PolicyRule class is moved, so that it is now derived from PolicySet.
The Priority property is also deprecated in PolicyRule, and PolicyRoles
is now inherited from the parent class PolicySet. Finally, a new
property ExecutionStrategy is introduced, paralleling the property of the
same name in the class CompoundPolicyAction.
NAME PolicyRule
DESCRIPTION The central class for representing the "If Condition
then Action" semantics associated with a policy rule.
DERIVED FROM PolicySet
ABSTRACT FALSE
PROPERTIES Enabled
ConditionListType
RuleUsage
Priority DEPRECATED FOR PolicySetComponent.Priority
AND FOR PolicySetInSystem.Priority
Mandatory
SequencedActions
ExecutionStrategy
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The property ExecutionStrategy defines the execution strategy to be used
upon the sequenced actions aggregated by this PolicyRule. (An equivalent
ExecutionStrategy property is also defined for the CompoundPolicyAction
class, to provide the same indication for the sequenced actions
aggregated by a CompoundPolicyAction.) This draft defines three
execution strategies:
Do Until Success û execute actions according to predefined order, until
successful execution of a single action.
Do All - execute ALL actions which are part of the modeled
set, according to their predefined order. Continue
doing this, even if one or more of the actions
fails.
Do Until Failure - execute actions according to predefined order, until
the first failure in execution of a single sub-
action.
The property definition is as follows:
NAME ExecutionStrategy
DESCRIPTION An enumeration indicating how to interpret the action
ordering for the actions aggregated by this
PolicyRule.
SYNTAX uint16 (ENUM, {1=Do Until Success, 2=Do All, 3=Do
Until Failure} )
DEFAULT VALUE Do All (2)
6.4. The Class "SimplePolicyCondition"
A simple policy condition is composed of an ordered triplet:
<Variable> MATCH <Value>
No formal modeling of the MATCH operator is provided. The 'match'
relationship is implied. Such simple conditions are evaluated by
answering the question:
Does <variable> match <value>?
The 'match' relationship is to be interpreted by analyzing the variable
and value instances associated with the simple condition.
Simple conditions are building blocks for more complex Boolean
Conditions, modeled by the CompoundPolicyCondition class.
The SimplePolicyCondition class is derived from the PolicyCondition class
defined in PCIM.
A variable and a value must be associated with a simple condition to make
it a meaningful condition, using, respectively, the aggregations
PolicyVariableInSimplePolicyCondition and
PolicyValueInSimplePolicyCondition.
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The class definition is as follows:
NAME SimplePolicyCondition
DERIVED FROM PolicyCondition
ABSTRACT False
PROPERTIES (none)
6.5. The Class "CompoundPolicyCondition"
This class represents a compound policy condition, formed by aggregation
of simpler policy conditions.
NAME CompoundPolicyCondition
DESCRIPTION A subclass of PolicyCondition that introduces the
ConditionListType property, used for assigning DNF /
CNF semantics to subordinate policy conditions.
DERIVED FROM PolicyCondition
ABSTRACT FALSE
PROPERTIES ConditionListType
The ConditionListType property is used to specify whether the list of
policy conditions associated with this compound policy condition is in
disjunctive normal form (DNF) or conjunctive normal form (CNF). If this
property is not present, the list type defaults to DNF. The property
definition is as follows:
NAME ConditionListType
DESCRIPTION Indicates whether the list of policy conditions
associated with this policy rule is in disjunctive
normal form (DNF) or conjunctive normal form (CNF).
SYNTAX uint16
VALUES DNF(1), CNF(2)
DEFAULT VALUE DNF(1)
6.6. The Class "CompoundFilterCondition"
This subclass of CompoundPolicyCondition introduces one additional
property, the boolean IsMirrored. This property turns on or off the
"flipping" of corresponding source and destination fields in a filter
specification.
NAME CompoundFilterCondition
DESCRIPTION A subclass of CompoundPolicyCondition that introduces
the IsMirrored property.
DERIVED FROM CompoundPolicyCondition
ABSTRACT FALSE
PROPERTIES IsMirrored
The IsMirrored property indicates whether packets that "mirror" a
compound filter condition should be treated as matching the filter. The
property definition is as follows:
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NAME IsMirrored
DESCRIPTION Indicates whether packets that mirror the specified
filter are to be treated as matching the filter.
SYNTAX boolean
DEFAULT VALUE FALSE
6.7. The Class "SimplePolicyAction"
The SimplePolicyAction class models the elementary set operation. "SET
<variable> TO <value>". The set operator MUST overwrite an old value of
the variable.
Two aggregations are used in order to create the pair <variable> <value>.
The aggregation PolicyVariableInSimplePolicyAction relates a
SimplePolicyAction to a single variable instance. Similarly, the
aggregation PolicyValueInSimplePolicyAction relates a SimplePolicyAction
to a single value instance. Both aggregations are defined in this
document.
NAME SimplePolicyAction
DESCRIPTION A subclass of PolicyAction that introduces the notion
of "SET variable TO value".
DERIVED FROM PolicyAction
ABSTRACT FALSE
PROPERTIES (none)
6.8. The Class "CompoundPolicyAction"
The CompoundPolicyAction class is used to represent an expression
consisting of an ordered sequence of action terms. Each action term is
represented as a subclass of the PolicyAction class, defined in [PCIM].
Compound actions are constructed by associating dependent action terms
together using the PolicyActionInPolicyAction aggregation.
The class definition is as follows:
NAME CompoundPolicyAction
DESCRIPTION A class for representing sequenced action terms. Each
action term is defined to be a subclass of the
PolicyAction class.
DERIVED FROM PolicyAction
ABSTRACT FALSE
PROPERTIES SequencedActions
ExecutionStrategy
This is a concrete class, and is therefore directly instantiable.
The Property SequencedActions is identical to the SequencedActions
property defined in PCIM for the class PolicyRule.
The property ExecutionStrategy defines the execution strategy to be used
upon the sequenced actions associated with this compound action. (An
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equivalent ExecutionStrategy property is also defined for the PolicyRule
class, to provide the same indication for the sequenced actions
associated with a PolicyRule.) This draft defines three execution
strategies:
Do Until Success û execute actions according to predefined order, until
successful execution of a single sub-action.
Do All - execute ALL actions which are part of the modeled
set, according to their predefined order. Continue
doing this, even if one or more of the sub-actions
fails.
Do Until Failure - execute actions according to predefined order, until
the first failure in execution of a single sub-
action.
Since a CompoundPolicyAction may itself be aggregated either by a
PolicyRule or by another CompoundPolicyAction, its success or failure
will be an input to the aggregating entity's execution strategy.
Consequently, the following rules are specified, for determining whether
a CompoundPolicyAction succeeds or fails:
If the CompoundPolicyAction's ExecutionStrategy is Do Until Success,
then
o If one component action succeeds, then the CompoundPolicyAction
succeeds.
o If all component actions fail, then the CompoundPolicyAction
fails.
If the CompoundPolicyAction's ExecutionStrategy is Do All, then
o If all component actions succeed, then the CompoundPolicyAction
succeeds.
o If at least one component action fails, then the
CompoundPolicyAction fails.
If the CompoundPolicyAction's ExecutionStrategy is Do Until Failure,
then
o If all component actions succeed, then the CompoundPolicyAction
succeeds.
o If at least one component action fails, then the
CompoundPolicyAction fails.
The definition of the ExecutionStrategy property is as follows:
NAME ExecutionStrategy
DESCRIPTION An enumeration indicating how to interpret the action
ordering for the actions aggregated by this
CompoundPolicyAction.
SYNTAX uint16 (ENUM, {1=Do Until Success, 2=Do All, 3=Do
Until Failure} )
DEFAULT VALUE Do All (2)
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6.9. The Abstract Class "PolicyVariable"
Variables are used for building individual conditions. The variable
specifies the property of a flow or an event that should be matched when
evaluating the condition. However, not every combination of a variable
and a value creates a meaningful condition. For example, a source IP
address variable can not be matched against a value that specifies a port
number. A given variable selects the set of matchable value types.
A variable can have constraints that limit the set of values within a
particular value type that can be matched against it in a condition. For
example, a source-port variable limits the set of values to represent
integers to the range of 0-65535. Integers outside this range cannot be
matched to the source-port variable, even though they are of the correct
data type. Constraints for a given variable are indicated through the
ExpectedPolicyValuesForVariable association.
The PolicyVariable is an abstract class. Implicit and explicit context
variable classes are defined as sub classes of the PolicyVariable class.
A set of implicit variables is defined in this document as well.
The class definition is as follows:
NAME PolicyVariable
DERIVED FROM Policy
ABSTRACT TRUE
PROPERTIES (none)
6.10. The Class "PolicyExplicitVariable"
Explicitly defined policy variables are evaluated within the context of
the CIM Schema and its modeling constructs. The PolicyExplicitVariable
class indicates the exact model property to be evaluated or manipulated.
See Section 5.8.6 for a complete discussion of what happens when the
values of the ModelClass and ModelProperty properties in an instance of
this class do not correspond to the characteristics of the model
construct being evaluated or updated.
The class definition is as follows:
NAME PolicyExplicitVariable
DERIVED FROM PolicyVariable
ABSTRACT False
PROPERTIES ModelClass, ModelProperty
6.10.1. The Single-Valued Property "ModelClass"
This property is a string specifying the class name whose property is
evaluated or set as a PolicyVariable.
The property is defined as follows:
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NAME ModelClass
SYNTAX String
6.10.2. The Single-Valued Property ModelProperty
This property is a string specifying the property name, within the
ModelClass, which is evaluated or set as a PolicyVariable. The property
is defined as follows:
NAME ModelProperty
SYNTAX String
6.11. The Abstract Class "PolicyImplicitVariable"
Implicitly defined policy variables are evaluated outside of the context
of the CIM Schema and its modeling constructs. Subclasses specify the
data type and semantics of the PolicyVariables.
Interpretation and evaluation of a PolicyImplicitVariable can vary,
depending on the particular context in which it is used. For example, a
"SourceIP" address may denote the source address field of an IP packet
header, or the sender address delivered by an RSVP PATH message.
The class definition is as follows:
NAME PolicyImplicitVariable
DERIVED FROM PolicyVariable
ABSTRACT True
PROPERTIES ValueTypes[ ]
6.11.1. The Multi-Valued Property "ValueTypes"
This property is a set of strings specifying an unordered list of
possible value/data types that can be used in simple conditions and
actions, with this variable. The value types are specified by their
class names (subclasses of PolicyValue such as PolicyStringValue). The
list of class names enables an application to search on a specific name,
as well as to ensure that the data type of the variable is of the correct
type.
The list of default ValueTypes for each subclass of
PolicyImplicitVariable is specified within that variable's definition.
The property is defined as follows:
NAME ValueTypes
SYNTAX String
6.12. Subclasses of "PolicyImplicitVariable" Specified in PCIMe
The following subclasses of PolicyImplicitVariable are defined in PCIMe.
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6.12.1. The Class "PolicySourceIPv4Variable"
NAME PolicySourceIPv4Variable
DESCRIPTION The source IPv4 address. of the outermost IP packet
header. "Outermost" here refers to the IP packet as
it flows on the wire, before any headers have been
stripped from it.
ALLOWED VALUE TYPES:
- PolicyIPv4AddrValue
DERIVED FROM PolicyImplicitVariable
ABSTRACT FALSE
PROPERTIES (none)
6.12.2. The Class "PolicySourceIPv6Variable"
NAME PolicySourceIPv6Variable
DESCRIPTION The source IPv6 address of the outermost IP packet
header. "Outermost" here refers to the IP packet as
it flows on the wire, before any headers have been
stripped from it.
ALLOWED VALUE TYPES:
- PolicyIPv6AddrValue
DERIVED FROM PolicyImplicitVariable
ABSTRACT FALSE
PROPERTIES (none)
6.12.3. The Class "PolicyDestinationIPv4Variable"
NAME PolicyDestinationIPv4Variable
DESCRIPTION The destination IPv4 address of the outermost IP
packet header. "Outermost" here refers to the IP
packet as it flows on the wire, before any headers
have been stripped from it.
ALLOWED VALUE TYPES:
- PolicyIPv4AddrValue
DERIVED FROM PolicyImplicitVariable
ABSTRACT FALSE
PROPERTIES (none)
6.12.4. The Class "PolicyDestinationIPv6Variable"
NAME PolicyDestinationIPv6Variable
DESCRIPTION The destination IPv6 address of the outermost IP
packet header. "Outermost" here refers to the IP
packet as it flows on the wire, before any headers
have been stripped from it.
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ALLOWED VALUE TYPES:
- PolicyIPv6AddrValue
DERIVED FROM PolicyImplicitVariable
ABSTRACT FALSE
PROPERTIES (none)
6.12.5. The Class "PolicySourcePortVariable"
NAME PolicySourcePortVariable
DESCRIPTION Ports are defined as the abstraction that transport
protocols use to distinguish among multiple
destinations within a given host computer. For TCP
and UDP flows, the PolicySourcePortVariable is
logically bound to the source port field of the
outermost UDP or TCP packet header. "Outermost" here
refers to the IP packet as it flows on the wire,
before any headers have been stripped from it.
ALLOWED VALUE TYPES:
- PolicyIntegerValue (0..65535)
DERIVED FROM PolicyImplicitVariable
ABSTRACT FALSE
PROPERTIES (none)
6.12.6. The Class "PolicyDestinationPortVariable"
NAME PolicyDestinationPortVariable
DESCRIPTION Ports are defined as the abstraction that transport
protocols use to distinguish among multiple
destinations within a given host computer. For TCP
and UDP flows, the PolicyDestinationPortVariable is
logically bound to the destination port field of the
outermost UDP or TCP packet header. "Outermost" here
refers to the IP packet as it flows on the wire,
before any headers have been stripped from it.
ALLOWED VALUE TYPES:
- PolicyIntegerValue (0..65535)
DERIVED FROM PolicyImplicitVariable
ABSTRACT FALSE
PROPERTIES (none)
6.12.7. The Class "PolicyIPProtocolVariable"
NAME PolicyIPProtocolVariable
DESCRIPTION The IP protocol number.
ALLOWED VALUE TYPES:
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- PolicyIntegerValue (0..255)
DERIVED FROM PolicyImplicitVariable
ABSTRACT FALSE
PROPERTIES (none)
6.12.8. The Class "PolicyIPVersionVariable"
NAME PolicyIPVersionVariable
DESCRIPTION The IP version number. The well-known values are 4
and 6.
ALLOWED VALUE TYPES:
- PolicyIntegerValue (0..15)
DERIVED FROM PolicyImplicitVariable
ABSTRACT FALSE
PROPERTIES (none)
6.12.9. The Class "PolicyIPToSVariable"
NAME PolicyIPToSVariable
DESCRIPTION The IP TOS octet.
ALLOWED VALUE TYPES:
- PolicyIntegerValue (0..255)
- PolicyBitStringValue (8 bits)
DERIVED FROM PolicyImplicitVariable
ABSTRACT FALSE
PROPERTIES (none)
6.12.10. The Class "PolicyDSCPVariable"
NAME PolicyDSCPVariable
DESCRIPTION The 6 bit Differentiated Service Code Point.
ALLOWED VALUE TYPES:
- PolicyIntegerValue (0..63)
- PolicyBitStringValue (6 bits)
DERIVED FROM PolicyImplicitVariable
ABSTRACT FALSE
PROPERTIES (none)
6.12.11. The Class "PolicyFlowIdVariable"
NAME PolicyFlowIdVariable
DESCRIPTION The flow identifer of the outermost IPv6 packet
header. "Outermost" here refers to the IP packet as
it flows on the wire, before any headers have been
stripped from it.
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ALLOWED VALUE TYPES:
- PolicyIntegerValue (0..1048575
- PolicyBitStringValue (20 bits)
DERIVED FROM PolicyImplicitVariable
ABSTRACT FALSE
PROPERTIES (none)
6.12.12. The Class "PolicySourceMACVariable"
NAME PolicySourceMACVariable
DESCRIPTION The source MAC address.
ALLOWED VALUE TYPES:
- PolicyMACAddrValue
DERIVED FROM PolicyImplicitVariable
ABSTRACT FALSE
PROPERTIES (none)
6.12.13. The Class "PolicyDestinationMACVariable"
NAME PolicyDestinationMACVariable
DESCRIPTION The destination MAC address.
ALLOWED VALUE TYPES:
- PolicyMACAddrValue
DERIVED FROM PolicyImplicitVariable
ABSTRACT FALSE
PROPERTIES (none)
6.12.14. The Class "PolicyVLANVariable"
NAME PolicyVLANVariable
DESCRIPTION The virtual Bridged Local Area Network Identifier, a
12-bit field as defined in the IEEE 802.1q standard.
ALLOWED VALUE TYPES:
- PolicyIntegerValue (0..4095)
- PolicyBitStringValue (12 bits)
DERIVED FROM PolicyImplicitVariable
ABSTRACT FALSE
PROPERTIES (none)
6.12.15. The Class "PolicyCoSVariable"
NAME PolicyCoSVariable
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DESCRIPTION Class of Service, a 3-bit field, used in the layer 2
header to select the forwarding treatment. Bound to
the IEEE 802.1q user-priority field.
ALLOWED VALUE TYPES:
- PolicyIntegerValue (0..7)
- PolicyBitStringValue (3 bits)
DERIVED FROM PolicyImplicitVariable
ABSTRACT FALSE
PROPERTIES (none)
6.12.16. The Class "PolicyEthertypeVariable"
NAME PolicyEthertypeVariable
DESCRIPTION The Ethertype protocol number of Ethernet frames.
ALLOWED VALUE TYPES:
- PolicyIntegerValue (0..65535)
- PolicyBitStringValue (16 bits)
DERIVED FROM PolicyImplicitVariable
ABSTRACT FALSE
PROPERTIES (none)
6.12.17. The Class "PolicySourceSAPVariable"
NAME PolicySourceSAPVariable
DESCRIPTION The Source Service Access Point (SAP) number of the
IEEE 802.2 LLC header.
ALLOWED VALUE TYPES:
- PolicyIntegerValue (0..255)
- PolicyBitStringValue (8 bits)
DERIVED FROM PolicyImplicitVariable
ABSTRACT FALSE
PROPERTIES (none)
6.12.18. The Class "PolicyDestinationSAPVariable"
NAME PolicyDestinationSAPVariable
DESCRIPTION The Destination Service Access Point (SAP) number of
the IEEE 802.2 LLC header.
ALLOWED VALUE TYPES:
- PolicyIntegerValue (0..255)
- PolicyBitStringValue (8 bits)
DERIVED FROM PolicyImplicitVariable
ABSTRACT FALSE
PROPERTIES (none)
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6.12.19. The Class "PolicySNAPOUIVariable"
NAME PolicySNAPOUIVariable
DESCRIPTION The value of the first three octets of the Sub-Network
Access Protocol (SNAP) Protocol Identifier field for
802.2 SNAP encapsulation, containing an
Organizationally Unique Identifier (OUI). The value
00-00-00 indicates the encapsulation of Ethernet
frames (RFC 1042). OUI value 00-00-F8 indicates the
special encapsulation of Ethernet frames by certain
types of bridges (IEEE 802.1H). Other values are
supported, but are not further defined here. These
OUI. values are to be interpreted according to the
endian-notation conventions of IEEE 802. For either
of the two Ethernet encapsulations, the remainder of
the Protocol Identifier field is represented by the
PolicySNAPTypeVariable.
ALLOWED VALUE TYPES:
- PolicyIntegerValue (0..16777215)
- PolicyBitStringValue (24 bits)
DERIVED FROM PolicyImplicitVariable
ABSTRACT FALSE
PROPERTIES (none)
6.12.20. The Class "PolicySNAPTypeVariable"
NAME PolicySNAPTypeVariable
DESCRIPTION The value of the 4th and 5th octets of the Sub-Network
Access Protocol (SNAP) Protocol Identifier field for
IEEE 802 SNAP encapsulation when the
PolicySNAPOUIVariable indicates one of the two
Encapsulated Ethernet frame formats. This value is
undefined for other values of PolicySNAPOUIVariable.
ALLOWED VALUE TYPES:
- PolicyIntegerValue (0..65535)
- PolicyBitStringValue (16 bits)
DERIVED FROM PolicyImplicitVariable
ABSTRACT FALSE
PROPERTIES (none)
6.12.21. The Class "PolicyFlowDirectionVariable"
NAME PolicyFlowDirectionVariable
DESCRIPTION The direction of a flow relative to a network element.
Direction may be "IN" and/or "OUT".
ALLOWED VALUE TYPES:
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- PolicyStringValue ('IN", "OUT")
DERIVED FROM PolicyImplicitVariable
ABSTRACT FALSE
PROPERTIES (none)
To match on both inbound and outbound flows, the associated
PolicyStringValue object has two entries in its StringList property: "IN"
and "OUT".
6.13. The Abstract Class "PolicyValue"
This is an abstract class that serves as the base class for all
subclasses that are used to define value objects in the PCIMe. It is
used for defining values and constants used in policy conditions. The
class definition is as follows:
NAME PolicyValue
DERIVED FROM Policy
ABSTRACT True
PROPERTIES (none)
6.14. Subclasses of "PolicyValue" Specified in PCIMe
The following subsections contain the PolicyValue subclasses defined in
PCIMe. Additional subclasses may be defined in models derived from
PCIMe.
6.14.1. The Class "PolicyIPv4AddrValue"
This class is used to provide a list of IPv4Addresses, hostnames and
address range values to be matched against in a policy condition. The
class definition is as follows:
NAME PolicyIPv4AddrValue
DERIVED FROM PolicyValue
ABSTRACT False
PROPERTIES IPv4AddrList[ ]
The IPv4AddrList property provides an unordered list of strings, each
specifying a single IPv4 address, a hostname, or a range of IPv4
addresses, according to the ABNF definition [6] of an IPv4 address, as
specified below:
IPv4address = 1*3DIGIT "." 1*3DIGIT "." 1*3DIGIT "." 1*3DIGIT
IPv4prefix = IPv4address "/" 1*2DIGIT
IPv4range = IPv4address"-"IPv4address
IPv4maskedaddress = IPv4address","IPv4address
Hostname (as defined in [4])
In the above definition, each string entry is either:
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1. A single IPv4address in dot notation, as defined above. Example:
121.1.1.2
2. An IPv4prefix address range, as defined above, specified by an
address and a prefix length, separated by "/". Example:
2.3.128.0/15
3. An IPv4range address range defined above, specified by a starting
address in dot notation and an ending address in dot notation,
separated by "-". The range includes all addresses between the
range's starting and ending addresses, including these two
addresses. Example: 1.1.22.1-1.1.22.5
4. An IPv4maskedaddress address range, as defined above, specified by
an address and mask. The address and mask are represented in dot
notation, separated by a comma ",". The masked address appears
before the comma, and the mask appears after the comma. Example:
2.3.128.0,255.255.248.0.
5. A single Hostname. The Hostname format follows the guidelines and
restrictions specified in [4]. Example: www.bigcompany.com.
Conditions matching IPv4AddrValues evaluate to true according to the
generic matching rules. Additionally, a hostname is matched against
another valid IPv4address representation by resolving the hostname into
an IPv4 address first, and then comparing the addresses afterwards.
Matching hostnames against each other is done using a string comparison
of the two names.
The property definition is as follows:
NAME IPv4AddrList
SYNTAX String
FORMAT IPv4address | IPv4prefix | IPv4range |
IPv4maskedaddress | hostname
6.14.2. The Class "PolicyIPv6AddrValue
This class is used to define a list of IPv6 addresses, hostnames, and
address range values. The class definition is as follows:
NAME PolicyIPv6AddrValue
DERIVED FROM PolicyValue
ABSTRACT False
PROPERTIES IPv6AddrList[ ]
The property IPv6AddrList provides an unordered list of strings, each
specifying an IPv6 address, a hostname, or a range of IPv6 addresses.
IPv6 address format definition uses the standard address format defined
in [7]. The ABNF definition [6] as specified in [7] is:
IPv6address = hexpart [ ":" IPv4address ]
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IPv4address = 1*3DIGIT "." 1*3DIGIT "." 1*3DIGIT "." 1*3DIGIT
IPv6prefix = hexpart "/" 1*2DIGIT
hexpart = hexseq | hexseq "::" [ hexseq ] | "::" [ hexseq ]
hexseq = hex4 *( ":" hex4)
hex4 = 1*4HEXDIG
IPv6range = IPv6address"-"IPv6address
IPv6maskedaddress = IPv6address","IPv6address
Hostname (as defines in [NAMES])
Each string entry is either:
1. A single IPv6address as defined above.
2. A single Hostname. Hostname format follows guidelines and
restrictions specified in [4].
3. An IPv6range address range, specified by a starting address in dot
notation and an ending address in dot notation, separated by "-".
The range includes all addresses between the range's starting and
ending addresses, including these two addresses.
4. An IPv4maskedaddress address range defined above specified by an
address and mask. The address and mask are represented in dot
notation separated by a comma ",".
5. A single IPv6prefix as defined above.
Conditions matching IPv6AddrValues evaluate to true according to the
generic matching rules. Additionally, a hostname is matched against
another valid IPv6address representation by resolving the hostname into
an IPv6 address first, and then comparing the addresses afterwards.
Matching hostnames against each other is done using a string comparison
of the two names.
6.14.3. The Class "PolicyMACAddrValue"
This class is used to define a list of MAC addresses and MAC address
range values. The class definition is as follows:
NAME PolicyMACAddrValue
DERIVED FROM PolicyValue
ABSTRACT False
PROPERTIES MACAddrList[ ]
The property MACAddrList provides an unordered list of strings, each
specifying a MAC address or a range of MAC addresses. The 802 MAC
address canonical format is used. The ABNF definition [6] is:
MACaddress = 1*4HEXDIG ":" 1*4HEXDIG ":" 1*4HEXDIG
MACmaskedaddress = MACaddress","MACaddress
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Each string entry is either:
1. A single MAC address. Example: 0000:00A5:0000
2. A MACmaskedaddress address range defined specified by an address
and mask. The mask specifies the relevant bits in the address.
Example: 0000:00A5:0000,FFFF:FFFF:0000 defines a range of MAC
addresses in which the first four octets are equal to 0000:00A5.
The property definition is as follows:
NAME MACAddrList
SYNTAX String
FORMAT MACaddress | MACmaskedaddress
6.14.4. The Class "PolicyStringValue"
This class is used to represent a single string value, or a set of string
values. Each value can have wildcards. The class definition is as
follows:
NAME PolicyStringValue
DERIVED FROM PolicyValue
ABSTRACT False
PROPERTIES StringList[ ]
The property StringList provides an unordered list of strings, each
representing a single string with wildcards. The asterisk character "*"
is used as a wildcard, and represents an arbitrary substring replacement.
For example, the value "abc*def" matches the string "abcxyzdef", and the
value "abc*def*" matches the string "abcxxxdefyyyzzz". The syntax
definition is identical to the substring assertion syntax defined in [5].
If the asterisk character is required as part of the string value itself,
it MUST be quoted as described in Section 4.3 of [5].
The property definition is as follows:
NAME StringList
SYNTAX String
6.14.5. The Class "PolicyBitStringValue"
This class is used to represent a single bit string value, or a set of
bit string values. The class definition is as follows:
NAME PolicyBitStringValue
DERIVED FROM PolicyValue
ABSTRACT False
PROPERTIES BitStringList[ ]
The property BitStringList provides an unordered list of strings, each
representing a single bit string or a set of bit strings. The number of
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bits specified SHOULD equal the number of bits of the expected variable.
For example, for a one-octet variable, 8 bits should be specified. If
the variable does not have a fixed length, the bit string should be
matched against the variable's most significant bit string. The formal
definition of a bit string is:
binary-digit = "0" / "1"
bitString = 1*binary-digit
maskedBitString = bitString","bitString
Each string entry is either:
1. A single bit string. Example: 00111010
2. A range of bit strings specified using a bit string and a bit
mask. The bit string and mask fields have the same number of bits
specified. The mask bit string specifies the significant bits in
the bit string value. For example, 110110, 100110 and 110111
would match the maskedBitString 100110,101110 but 100100 would
not.
The property definition is as follows:
NAME BitStringList
SYNTAX String
FORMAT bitString | maskedBitString
6.14.6. The Class "PolicyIntegerValue"
This class provides a list of integer and integer range values. Integers
of arbitrary sizes can be represented. The class definition is as
follows:
NAME PolicyIntegerValue
DERIVED FROM PolicyValue
ABSTRACT False
PROPERTIES IntegerList[ ]
The property IntegerList provides an unordered list of integers and
integer range values, represented as strings. The format of this
property takes one of the following forms:
1. An integer value.
2. A range of integers. The range is specified by a starting integer
and an ending integer, separated by '..'. The starting integer
MUST be less than or equal to the ending integer. The range
includes all integers between the starting and ending integers,
including these two integers.
To represent a range of integers that is not bounded, the reserved words
-INFINITY and/or INFINITY can be used in place of the starting and ending
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integers. In addition to ordinary integer matches, INFINITY matches
INFINITY and -INFINITY matches -INFINITY.
The ABNF definition [6] is:
integer = [-]1*DIGIT | "INFINITY" | "-INFINITY"
integerrange = integer".."integer
Using ranges, the operators greater-than, greater-than-or-equal-to, less-
than, and less-than-or-equal-to can be expressed. For example, "X is-
greater-than 5" (where X is an integer) can be translated to "X matches
6-INFINITY". This enables the match condition semantics of the operator
for the SimplePolicyCondition class to be kept simple (i.e., just the
value "match").
The property definition is as follows:
NAME IntegerList
SYNTAX String
FORMAT integer | integerrange
6.14.7. The Class "PolicyBooleanValue"
This class is used to represent a Boolean (TRUE/FALSE) value. The class
definition is as follows:
NAME PolicyBooleanValue
DERIVED FROM PolicyValue
ABSTRACT False
PROPERTIES BooleanValue
The property definition is as follows:
NAME BooleanValue
SYNTAX boolean
6.15. The Class "PolicyRoleCollection"
This class represents a collection of managed elements that share a
common role. The PolicyRoleCollection always exists in the context of a
system, specified using the PolicyRoleCollectionInSystem association.
The value of the PolicyRole property in this class specifies the role,
and can be matched with the value(s) in the PolicyRoles array in
PolicyRules and PolicyGroups. ManagedElements that share the role
defined in this collection are aggregated into the collection via the
association ElementInPolicyRoleCollection.
NAME PolicyRoleCollection
DESCRIPTION A subclass of the CIM Collection class used to group
together managed elements that share a role.
DERIVED FROM Collection
ABSTRACT FALSE
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PROPERTIES PolicyRole
6.15.1. The Single-Valued Property "PolicyRole"
This property represents the role associated with a PolicyRoleCollection.
The property definition is as follows:
NAME PolicyRole
DESCRIPTION A string representing the role associated with a
PolicyRoleCollection.
SYNTAX string
6.16. The Class "ReusablePolicyContainer"
The new class ReusablePolicyContainer is defined as follows:
NAME ReusablePolicyContainer
DESCRIPTION A class representing an administratively defined
container for reusable policy-related information.
This class does not introduce any additional
properties beyond those in its superclass AdminDomain.
It does, however, participate in a number of unique
associations.
DERIVED FROM AdminDomain
ABSTRACT FALSE
PROPERTIES (none)
6.17. Deprecate PCIM's Class "PolicyRepository"
The class definition of PolicyRepository (from PCIM) is updated as
follows, with an indication that the class has been deprecated. Note
that when an element of the model is deprecated, its replacement element
is identified explicitly.
NAME PolicyRepository
DEPRECATED FOR ReusablePolicyContainer
DESCRIPTION A class representing an administratively defined
container for reusable policy-related information.
This class does not introduce any additional
properties beyond those in its superclass AdminDomain.
It does, however, participate in a number of unique
associations.
DERIVED FROM AdminDomain
ABSTRACT FALSE
PROPERTIES (none)
6.18. The Abstract Class "FilterEntryBase"
FilterEntryBase is the abstract base class from which all filter entry
classes are derived. It serves as the endpoint for the
EntriesInFilterList aggregation, which groups filter entries into filter
lists. Its properties include CIM naming attributes and an IsNegated
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boolean property (to easily "NOT" the match information specified in an
instance of one of its subclasses).
The class definition is as follows:
NAME FilterEntryBase
DESCRIPTION An abstract class representing a single
filter that is aggregated into a
FilterList via the aggregation
EntriesInFilterList.
DERIVED FROM LogicalElement
TYPE Abstract
PROPERTIES IsNegated
6.19. The Class "IpHeadersFilter"
This concrete class contains the most commonly required properties for
performing filtering on IP, TCP or UDP headers. Properties not present
in an instance of IPHeadersFilter are treated as 'all values'. A
property HdrIpVersion identifies whether the IP addresses in an instance
are IPv4 or IPv6 addresses. Since the source and destination IP
addresses come from the same packet header, they will always be of the
same type.
The class definition is as follows:
NAME IpHeadersFilter
DESCRIPTION A class representing an entire IP
header filter, or any subset of one.
DERIVED FROM FilterEntryBase
TYPE Concrete
PROPERTIES HdrIpVersion, HdrSrcAddress,
HdrSrcAddressEndOfRange, HdrSrcMask,
HdrDestAddress, HdrDestAddressEndOfRange,
HdrDestMask, HdrProtocolID,
HdrSrcPortStart, HdrSrcPortEnd,
HdrDestPortStart, HdrDestPortEnd, HdrDSCP[ ],
HdrFlowLabel
6.19.1. The Property HdrIpVersion
This property is an 8-bit unsigned integer, identifying the version of
the IP addresses to be filtered on. IP versions are identified as they
are in the Version field of the IP packet header - IPv4 = 4, IPv6 = 6.
These two values are the only ones defined for this property.
The value of this property determines the sizes of the OctetStrings in
the six properties HdrSrcAddress, HdrSrcAddressEndOfRange, HdrSrcMask,
HdrDestAddress, HdrDestAddressEndOfRange, and HdrDestMask, as follows:
o IPv4: OctetString(SIZE (4))
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o IPv6: OctetString(SIZE (16|20)), depending on whether a scope
identifier is present
If a value for this property is not provided, then the filter does not
consider IP version in selecting matching packets, i.e., IP version
matches for all values. In this case, the HdrSrcAddress,
HdrSrcAddressEndOfRange, HdrSrcMask, HdrDestAddress,
HdrDestAddressEndOfRange, and HdrDestMask must also not be present.
6.19.2. The Property HdrSrcAddress
This property is an OctetString, of a size determined by the value of the
HdrIpVersion property, representing a source IP address. When there is
no HdrSrcAddressEndOfRange value, this value is compared to the source
address in the IP header, subject to the mask represented in the
HdrSrcMask property. (Note that the mask is ANDed with the address.)
When there is a HdrSrcAddressEndOfRange value, this value is the start of
the specified range (i.e., the HdrSrcAddress is lower than the
HdrSrcAddressEndOfRange) that is compared to the source address in the IP
header and matches on any value in the range.
If a value for this property is not provided, then the filter does not
consider HdrSrcAddress in selecting matching packets, i.e., HdrSrcAddress
matches for all values.
6.19.3. The Property HdrSrcAddressEndOfRange
This property is an OctetString, of a size determined by the value of the
HdrIpVersion property, representing the end of a range of source IP
addresses (inclusive), where the start of the range is the HdrSrcAddress
property value.
If a value for HdrSrcAddress is not provided, then this property also
MUST NOT be provided. If a value for this property is provided, then
HdrSrcMask MUST NOT be provided.
6.19.4. The Property HdrSrcMask
This property is an OctetString, of a size determined by the value of the
HdrIpVersion property, representing a mask to be used in comparing the
source address in the IP header with the value represented in the
HdrSrcAddress property.
If a value for this property is not provided, then the filter does not
consider HdrSrcMask in selecting matching packets, i.e., the value of
HdrSrcAddress or the source address range must match the source address
in the packet exactly. If a value for this property is provided, then
HdrSrcAddressEndOfRange MUST NOT be provided.
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6.19.5. The Property HdrDestAddress
This property is an OctetString, of a size determined by the value of the
HdrIpVersion property, representing a destination IP address. When there
is no HdrDestAddressEndOfRange value, this value is compared to the
destination address in the IP header, subject to the mask represented in
the HdrDestMask property. (Note that the mask is ANDed with the
address.) When there is a HdrDestAddressEndOfRange value, this value is
the start of the specified range (i.e., the HdrDestAddress is lower than
the HdrDestAddressEndOfRange) that is compared to the destination address
in the IP header and matches on any value in the range.
If a value for this property is not provided, then the filter does not
consider HdrDestAddress in selecting matching packets, i.e.,
HdrDestAddress matches for all values.
6.19.6. The Property HdrDestAddressEndOfRange
This property is an OctetString, of a size determined by the value of the
HdrIpVersion property, representing the end of a range of destination IP
addresses (inclusive), where the start of the range is the HdrDestAddress
property value.
If a value for HdrDestAddress is not provided, then this property also
MUST NOT be provided. If a value for this property is provided, then
HdrDestMask MUST NOT be provided.
6.19.7. The Property HdrDestMask
This property is an OctetString, of a size determined by the value of the
HdrIpVersion property, representing a mask to be used in comparing the
destination address in the IP header with the value represented in the
HdrDestAddress property.
If a value for this property is not provided, then the filter does not
consider HdrDestMask in selecting matching packets, i.e., the value of
HdrDestAddress or the destination address range must match the
destination address in the packet exactly. If a value for this property
is provided, then HdrDestAddressEndOfRange MUST NOT be provided.
6.19.8. The Property HdrProtocolID
This property is an 8-bit unsigned integer, representing an IP protocol
type. This value is compared to the Protocol field in the IP header.
If a value for this property is not provided, then the filter does not
consider HdrProtocolID in selecting matching packets, i.e., HdrProtocolID
matches for all values.
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6.19.9. The Property HdrSrcPortStart
This property is a 16-bit unsigned integer, representing the lower end of
a range of UDP or TCP source ports. The upper end of the range is
represented by the HdrSrcPortEnd property. The value of HdrSrcPortStart
MUST be no greater than the value of HdrSrcPortEnd. A single port is
indicated by equal values for HdrSrcPortStart and HdrSrcPortEnd.
A source port filter is evaluated by testing whether the source port
identified in the IP header falls within the range of values between
HdrSrcPortStart and HdrSrcPortEnd, including these two end points.
If a value for this property is not provided, then the filter does not
consider HdrSrcPortStart in selecting matching packets, i.e., there is no
lower bound in matching source port values.
6.19.10. The Property HdrSrcPortEnd
This property is a 16-bit unsigned integer, representing the upper end of
a range of UDP or TCP source ports. The lower end of the range is
represented by the HdrSrcPortStart property. The value of HdrSrcPortEnd
MUST be no less than the value of HdrSrcPortStart. A single port is
indicated by equal values for HdrSrcPortStart and HdrSrcPortEnd.
A source port filter is evaluated by testing whether the source port
identified in the IP header falls within the range of values between
HdrSrcPortStart and HdrSrcPortEnd, including these two end points.
If a value for this property is not provided, then the filter does not
consider HdrSrcPortEnd in selecting matching packets, i.e., there is no
upper bound in matching source port values.
6.19.11. The Property HdrDestPortStart
This property is a 16-bit unsigned integer, representing the lower end of
a range of UDP or TCP destination ports. The upper end of the range is
represented by the HdrDestPortEnd property. The value of
HdrDestPortStart MUST be no greater than the value of HdrDestPortEnd. A
single port is indicated by equal values for HdrDestPortStart and
HdrDestPortEnd.
A destination port filter is evaluated by testing whether the destination
port identified in the IP header falls within the range of values between
HdrDestPortStart and HdrDestPortEnd, including these two end points.
If a value for this property is not provided, then the filter does not
consider HdrDestPortStart in selecting matching packets, i.e., there is
no lower bound in matching destination port values.
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6.19.12. The Property HdrDestPortEnd
This property is a 16-bit unsigned integer, representing the upper end of
a range of UDP or TCP destination ports. The lower end of the range is
represented by the HdrDestPortStart property. The value of
HdrDestPortEnd MUST be no less than the value of HdrDestPortStart. A
single port is indicated by equal values for HdrDestPortStart and
HdrDestPortEnd.
A destination port filter is evaluated by testing whether the destination
port identified in the IP header falls within the range of values between
HdrDestPortStart and HdrDestPortEnd, including these two end points.
If a value for this property is not provided, then the filter does not
consider HdrDestPortEnd in selecting matching packets, i.e., there is no
upper bound in matching destination port values.
6.19.13. The Property HdrDSCP
The property HdrDSCP is defined as an array of uint8's, restricted to the
range 0..63. Since DSCPs are defined as discrete code points, with no
inherent structure, there is no semantically significant relationship
between different DSCPs. Consequently, there is no provision for
specifying a range of DSCPs in this property. However, a list of
individual DSCPs, which are ORed together to form a filter, is supported
by the array syntax.
If a value for this property is not provided, then the filter does not
consider HdrDSCP in selecting matching packets, i.e., HdrDSCP matches for
all values.
6.19.14. The Property HdrFlowLabel
The 20-bit Flow Label field in the IPv6 header may be used by a source to
label sequences of packets for which it requests special handling by IPv6
devices, such as non-default quality of service or 'real-time' service.
This property is an octet string of size 3 (that is, 24 bits), in which
the 20-bit Flow Label appears in the rightmost 20 bits, padded on the
left with b'0000'.
If a value for this property is not provided, then the filter does not
consider HdrFlowLabel in selecting matching packets, i.e., HdrFlowLabel
matches for all values.
6.20. The Class "8021Filter"
This concrete class allows 802.1.source and destination MAC addresses, as
well as the 802.1 protocol ID, priority, and VLAN identifier fields, to
be expressed in a single object
The class definition is as follows:
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NAME 8021Filter
DESCRIPTION A class that allows 802.1 source
and destination MAC address and
protocol ID, priority, and VLAN
identifier filters to be
expressed in a single object.
DERIVED FROM FilterEntryBase
TYPE Concrete
PROPERTIES 8021HdrSrcMACAddr, 8021HdrSrcMACMask,
8021HdrDestMACAddr, 8021HdrDestMACMask,
8021HdrProtocolID, 8021HdrPriorityValue,
8021HDRVLANID
6.20.1. The Property 8021HdrSrcMACAddr
This property is an OctetString of size 6, representing a 48-bit source
MAC address in canonical format. This value is compared to the
SourceAddress field in the MAC header, subject to the mask represented in
the 8021HdrSrcMACMask property.
If a value for this property is not provided, then the filter does not
consider 8021HdrSrcMACAddr in selecting matching packets, i.e.,
8021HdrSrcMACAddr matches for all values.
6.20.2. The Property 8021HdrSrcMACMask
This property is an OctetString of size 6, representing a 48-bit mask to
be used in comparing the SourceAddress field in the MAC header with the
value represented in the 8021HdrSrcMACAddr property.
If a value for this property is not provided, then the filter does not
consider 8021HdrSrcMACMask in selecting matching packets, i.e., the value
of 8021HdrSrcMACAddr must match the source MAC address in the packet
exactly.
6.20.3. The Property 8021HdrDestMACAddr
This property is an OctetString of size 6, representing a 48-bit
destination MAC address in canonical format. This value is compared to
the DestinationAddress field in the MAC header, subject to the mask
represented in the 8021HdrDestMACMask property.
If a value for this property is not provided, then the filter does not
consider 8021HdrDestMACAddr in selecting matching packets, i.e.,
8021HdrDestMACAddr matches for all values.
6.20.4. The Property 8021HdrDestMACMask
This property is an OctetString of size 6, representing a 48-bit mask to
be used in comparing the DestinationAddress field in the MAC header with
the value represented in the 8021HdrDestMACAddr property.
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If a value for this property is not provided, then the filter does not
consider 8021HdrDestMACMask in selecting matching packets, i.e., the
value of 8021HdrDestMACAddr must match the destination MAC address in the
packet exactly.
6.20.5. The Property 8021HdrProtocolID
This property is a 16-bit unsigned integer, representing an Ethernet
protocol type. This value is compared to the Ethernet Type field in the
802.3 MAC header.
If a value for this property is not provided, then the filter does not
consider 8021HdrProtocolID in selecting matching packets, i.e.,
8021HdrProtocolID matches for all values.
6.20.6. The Property 8021HdrPriorityValue
This property is an 8-bit unsigned integer, representing an 802.1Q
priority. This value is compared to the Priority field in the 802.1Q
header. Since the 802.1Q Priority field consists of 3 bits, the values
for this property are limited to the range 0..7.
If a value for this property is not provided, then the filter does not
consider 8021HdrPriorityValue in selecting matching packets, i.e.,
8021HdrPriorityValue matches for all values.
6.20.7. The Property 8021HdrVLANID
This property is a 32-bit unsigned integer, representing an 802.1Q VLAN
Identifier. This value is compared to the VLAN ID field in the 802.1Q
header. Since the 802.1Q VLAN ID field consists of 12 bits, the values
for this property are limited to the range 0..4095.
If a value for this property is not provided, then the filter does not
consider 8021HdrVLANID in selecting matching packets, i.e., 8021HdrVLANID
matches for all values.
6.21. The Class FilterList
This is a concrete class that aggregates instances of (subclasses of)
FilterEntryBase via the aggregation EntriesInFilterList. It is possible
to aggregate different types of filters into a single FilterList - for
example, packet header filters (represented by the IpHeadersFilter class)
and security filters (represented by subclasses of FilterEntryBase
defined by IPsec).
The aggregation property EntriesInFilterList.EntrySequence is always set
to 0, to indicate that the aggregated filter entries are ANDed together
to form a selector for a class of traffic.
The class definition is as follows:
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NAME FilterList
DESCRIPTION A concrete class representing
the aggregation of multiple filters.
DERIVED FROM LogicalElement
TYPE Concrete
PROPERTIES Direction
6.21.1. The Property Direction
This property is a 16-bit unsigned integer enumeration, representing the
direction of the traffic flow to which the FilterList is to be applied.
Defined enumeration values are
o NotApplicable(0)
o Input(1)
o Output(2)
o Both(3) - This value is used to indicate that the direction is
immaterial, e.g., to filter on a source subnet regardless of
whether the flow is inbound or outbound
o Mirrored(4) - This value is also applicable to both inbound and
outbound flow processing, but it indicates that the filter criteria
are applied asymmetrically to traffic in both directions and, thus,
specifies the reversal of source and destination criteria (as
opposed to the equality of these criteria as indicated by "Both").
The match conditions in the aggregated FilterEntryBase subclass
instances are defined from the perspective of outbound flows and
applied to inbound flows as well by reversing the source and
destination criteria. So, for example, consider a FilterList with
3 filter entries indicating destination port = 80, and source and
destination addresses of a and b, respectively. Then, for the
outbound direction, the filter entries match as specified and the
'mirror' (for the inbound direction) matches on source port = 80
and source and destination addresses of b and a, respectively.
7. Association and Aggregation Definitions
The following definitions supplement those in PCIM itself. PCIM
definitions that are not DEPRECATED here are still current parts of the
overall Policy Core Information Model.
7.1. The Aggregation "PolicySetComponent"
PolicySetComponent is a new aggregation class that collects instances of
PolicySet subclasses (PolicyGroups and PolicyRules) into coherent sets of
policies.
NAME PolicySetComponent
DESCRIPTION A concrete class representing the components of a
policy set that have the same decision strategy, and
are prioritized within the set.
DERIVED FROM PolicyComponent
ABSTRACT FALSE
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PROPERTIES GroupComponent[ref PolicySet[0..n]]
PartComponent[ref PolicySet[0..n]]
Priority
The definition of the Priority property is unchanged from its previous
definition in [PCIM].
NAME Priority
DESCRIPTION A non-negative integer for prioritizing this PolicySet
component relative to other components of the same
PolicySet. A larger value indicates a higher
priority.
SYNTAX uint16
DEFAULT VALUE 0
7.2. Deprecate PCIM's Aggregation "PolicyGroupInPolicyGroup"
The new aggregation PolicySetComponent is used directly to represent
aggregation of PolicyGroups by a higher-level PolicyGroup. Thus the
aggregation PolicyGroupInPolicyGroup is no longer needed, and can be
deprecated.
NAME PolicyGroupInPolicyGroup
DEPRECATED FOR PolicySetComponent
DESCRIPTION A class representing the aggregation of PolicyGroups
by a higher-level PolicyGroup.
DERIVED FROM PolicyComponent
ABSTRACT FALSE
PROPERTIES GroupComponent[ref PolicyGroup[0..n]]
PartComponent[ref PolicyGroup[0..n]]
7.3. Deprecate PCIM's Aggregation "PolicyRuleInPolicyGroup"
The new aggregation PolicySetComponent is used directly to represent
aggregation of PolicyRules by a PolicyGroup. Thus the aggregation
PolicyRuleInPolicyGroup is no longer needed, and can be deprecated.
NAME PolicyRuleInPolicyGroup
DEPRECATED FOR PolicySetComponent
DESCRIPTION A class representing the aggregation of PolicyRules by
a PolicyGroup.
DERIVED FROM PolicyComponent
ABSTRACT FALSE
PROPERTIES GroupComponent[ref PolicyGroup[0..n]]
PartComponent[ref PolicyRule[0..n]]
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7.4. The Abstract Association "PolicySetInSystem"
PolicySetInSystem is a new association that defines a relationship
between a System and a PolicySet used in the administrative scope of that
system (e.g., AdminDomain, ComputerSystem). The Priority property is
used to assign a relative priority to a PolicySet within the
administrative scope in contexts where it is not a component of another
PolicySet.
NAME PolicySetInSystem
DESCRIPTION An abstract class representing the relationship
between a System and a PolicySet that is used in the
administrative scope of the System.
DERIVED FROM PolicyInSystem
ABSTRACT TRUE
PROPERTIES Antecedent[ref System[0..1]]
Dependent [ref PolicySet[0..n]]
Priority
The Priority property is used to specify the relative priority of the
referenced PolicySet when there are more than one PolicySet instances
applied to a managed resource that are not PolicySetComponents and,
therefore, have no other relative priority defined.
NAME Priority
DESCRIPTION A non-negative integer for prioritizing the referenced
PolicySet among other PolicySet instances that are not
components of a common PolicySet. A larger value
indicates a higher priority.
SYNTAX uint16
DEFAULT VALUE 0
7.5. Update PCIM's Weak Association "PolicyGroupInSystem"
Regardless of whether it a component of another PolicySet, a PolicyGroup
is itself defined within the scope of a System. This association links a
PolicyGroup to the System in whose scope the PolicyGroup is defined. It
is a subclass of the abstract PolicySetInSystem association. The class
definition for the association is as follows:
NAME PolicyGroupInSystem
DESCRIPTION A class representing the fact that a PolicyGroup is
defined within the scope of a System.
DERIVED FROM PolicySetInSystem
ABSTRACT FALSE
PROPERTIES Antecedent[ref System[1..1]]
Dependent [ref PolicyGroup[weak]]
The Reference "Antecedent" is inherited from PolicySetInSystem, and
overridden to restrict its cardinality to [1..1]. It serves as an object
reference to a System that provides a scope for one or more PolicyGroups.
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Since this is a weak association, the cardinality for this object
reference is always 1, that is, a PolicyGroup is always defined within
the scope of exactly one System.
The Reference "Dependent" is inherited from PolicySetInSystem, and
overridden to become an object reference to a PolicyGroup defined within
the scope of a System. Note that for any single instance of the
association class PolicyGroupInSystem, this property (like all reference
properties) is single-valued. The [0..n] cardinality indicates that a
given System may have 0, 1, or more than one PolicyGroups defined within
its scope.
7.6. Update PCIM's Weak Association "PolicyRuleInSystem"
Regardless of whether it a component of another PolicySet, a PolicyRule
is itself defined within the scope of a System. This association links a
PolicyRule to the System in whose scope the PolicyRule is defined. It is
a subclass of the abstract PolicySetInSystem association. The class
definition for the association is as follows:
NAME PolicyRuleInSystem
DESCRIPTION A class representing the fact that a PolicyRule is
defined within the scope of a System.
DERIVED FROM PolicySetInSystem
ABSTRACT FALSE
PROPERTIES Antecedent[ref System[1..1]]
Dependent[ref PolicyRule[weak]]
The Reference "Antecedent" is inherited from PolicySetInSystem, and
overridden to restrict its cardinality to [1..1]. It serves as an object
reference to a System that provides a scope for one or more PolicyRules.
Since this is a weak association, the cardinality for this object
reference is always 1, that is, a PolicyRule is always defined within the
scope of exactly one System.
The Reference "Dependent" is inherited from PolicySetInSystem, and
overridden to become an object reference to a PolicyRule defined within
the scope of a System. Note that for any single instance of the
association class PolicyRuleInSystem, this property (like all Reference
properties) is single-valued. The [0..n] cardinality indicates that a
given System may have 0, 1, or more than one PolicyRules defined within
its scope.
7.7. The Abstract Aggregation "PolicyConditionStructure"
NAME PolicyConditionStructure
DESCRIPTION A class representing the aggregation of
PolicyConditions by an aggregating instance.
DERIVED FROM PolicyComponent
ABSTRACT TRUE
PROPERTIES PartComponent[ref PolicyCondition[0..n]]
GroupNumber
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ConditionNegated
7.8. Update PCIM's Aggregation "PolicyConditionInPolicyRule"
The PCIM aggregation "PolicyConditionInPolicyRule" is updated, to make it
a subclass of the new abstract aggregation PolicyConditionStructure. The
properties GroupNumber and ConditionNegated are now inherited, rather
than specified explicitly as they were in PCIM.
NAME PolicyConditionInPolicyRule
DESCRIPTION A class representing the aggregation of
PolicyConditions by a PolicyRule.
DERIVED FROM PolicyConditionStructure
ABSTRACT FALSE
PROPERTIES GroupComponent[ref PolicyRule[0..n]]
7.9. The Aggregation "PolicyConditionInPolicyCondition"
A second subclass of PolicyConditionStructure is defined, representing
the compounding of policy conditions into a higher-level policy
condition.
NAME PolicyConditionInPolicyCondition
DESCRIPTION A class representing the aggregation of
PolicyConditions by another PolicyCondition.
DERIVED FROM PolicyConditionStructure
ABSTRACT FALSE
PROPERTIES GroupComponent[ref CompoundPolicyCondition[0..n]]
7.10. The Abstract Aggregation "PolicyActionStructure"
NAME PolicyActionStructure
DESCRIPTION A class representing the aggregation of PolicyActions
by an aggregating instance.
DERIVED FROM PolicyComponent
ABSTRACT TRUE
PROPERTIES PartComponent[ref PolicyAction[0..n]]
ActionOrder
The definition of the ActionOrder property appears in Section 7.8.3 of
PCIM [1].
7.11. Update PCIM's Aggregation "PolicyActionInPolicyRule"
The PCIM aggregation "PolicyActionInPolicyRule" is updated, to make it a
subclass of the new abstract aggregation PolicyActionStructure. The
property ActionOrder is now inherited, rather than specified explicitly
as it was in PCIM.
NAME PolicyActionInPolicyRule
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DESCRIPTION A class representing the aggregation of PolicyActions
by a PolicyRule.
DERIVED FROM PolicyActionStructure
ABSTRACT FALSE
PROPERTIES GroupComponent[ref PolicyRule[0..n]]
7.12. The Aggregation "PolicyActionInPolicyAction"
A second subclass of PolicyActionStructure is defined, representing the
compounding of policy actions into a higher-level policy action.
NAME PolicyActionInPolicyAction
DESCRIPTION A class representing the aggregation of PolicyActions
by another PolicyAction.
DERIVED FROM PolicyActionStructure
ABSTRACT FALSE
PROPERTIES GroupComponent[ref CompoundPolicyAction[0..n]]
7.13. The Aggregation "PolicyVariableInSimplePolicyCondition"
A simple policy condition is represented as an ordered triplet {variable,
operator, value}. This aggregation provides the linkage between a
SimplePolicyCondition instance and a single PolicyVariable. The
aggregation PolicyValueInSimplePolicyCondition links the
SimplePolicyCondition to a single PolicyValue. The Operator property of
SimplePolicyCondition represents the third element of the triplet, the
operator.
The class definition for this aggregation is as follows:
NAME PolicyVariableInSimplePolicyCondition
DERIVED FROM PolicyComponent
ABSTRACT False
PROPERTIES GroupComponent[ref SimplePolicyCondition[0..n]]
PartComponent[ref PolicyVariable[1..1] ]
The reference property "GroupComponent" is inherited from
PolicyComponent, and overridden to become an object reference to a
SimplePolicyCondition that contains exactly one PolicyVariable. Note
that for any single instance of the aggregation class
PolicyVariableInSimplePolicyCondition, this property is single-valued.
The [0..n] cardinality indicates that there may be 0, 1, or more
SimplePolicyCondition objects that contain any given policy variable
object.
The reference property "PartComponent" is inherited from PolicyComponent,
and overridden to become an object reference to a PolicyVariable that is
defined within the scope of a SimplePolicyCondition. Note that for any
single instance of the association class
PolicyVariableInSimplePolicyCondition, this property (like all reference
properties) is single-valued. The [1..1] cardinality indicates that a
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SimplePolicyCondition must have exactly one policy variable defined
within its scope in order to be meaningful.
7.14. The Aggregation "PolicyValueInSimplePolicyCondition"
A simple policy condition is represented as an ordered triplet {variable,
operator, value}. This aggregation provides the linkage between a
SimplePolicyCondition instance and a single PolicyValue. The aggregation
PolicyVariableInSimplePolicyCondition links the SimplePolicyCondition to
a single PolicyVariable. The Operator property of SimplePolicyCondition
represents the third element of the triplet, the operator.
The class definition for this aggregation is as follows:
NAME PolicyValueInSimplePolicyCondition
DERIVED FROM PolicyComponent
ABSTRACT False
PROPERTIES GroupComponent[ref SimplePolicyCondition[0..n]]
PartComponent[ref PolicyValue[1..1] ]
The reference property "GroupComponent" is inherited from
PolicyComponent, and overridden to become an object reference to a
SimplePolicyCondition that contains exactly one PolicyValue. Note that
for any single instance of the aggregation class
PolicyValueInSimplePolicyCondition, this property is single-valued. The
[0..n] cardinality indicates that there may be 0, 1, or more
SimplePolicyCondition objects that contain any given policy value object.
The reference property "PartComponent" is inherited from PolicyComponent,
and overridden to become an object reference to a PolicyValue that is
defined within the scope of a SimplePolicyCondition. Note that for any
single instance of the association class
PolicyValueInSimplePolicyCondition, this property (like all reference
properties) is single-valued. The [1..1] cardinality indicates that a
SimplePolicyCondition must have exactly one policy value defined within
its scope in order to be meaningful.
7.15. The Aggregation "PolicyVariableInSimplePolicyAction"
A simple policy action is represented as a pair {variable, value}. This
aggregation provides the linkage between a SimplePolicyAction instance
and a single PolicyVariable. The aggregation
PolicyValueInSimplePolicyAction links the SimplePolicyAction to a single
PolicyValue.
The class definition for this aggregation is as follows:
NAME PolicyVariableInSimplePolicyAction
DERIVED FROM PolicyComponent
ABSTRACT False
PROPERTIES GroupComponent[ref SimplePolicyAction[0..n]]
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PartComponent[ref PolicyVariable[1..1] ]
The reference property "GroupComponent" is inherited from
PolicyComponent, and overridden to become an object reference to a
SimplePolicyAction that contains exactly one PolicyVariable. Note that
for any single instance of the aggregation class
PolicyVariableInSimplePolicyAction, this property is single-valued. The
[0..n] cardinality indicates that there may be 0, 1, or more
SimplePolicyAction objects that contain any given policy variable object.
The reference property "PartComponent" is inherited from PolicyComponent,
and overridden to become an object reference to a PolicyVariable that is
defined within the scope of a SimplePolicyAction. Note that for any
single instance of the association class
PolicyVariableInSimplePolicyAction, this property (like all reference
properties) is single-valued. The [1..1] cardinality indicates that a
SimplePolicyAction must have exactly one policy variable defined within
its scope in order to be meaningful.
7.16. The Aggregation "PolicyValueInSimplePolicyAction"
A simple policy action is represented as a pair {variable, value}. This
aggregation provides the linkage between a SimplePolicyAction instance
and a single PolicyValue. The aggregation
PolicyVariableInSimplePolicyAction links the SimplePolicyAction to a
single PolicyVariable.
The class definition for this aggregation is as follows:
NAME PolicyValueInSimplePolicyAction
DERIVED FROM PolicyComponent
ABSTRACT False
PROPERTIES GroupComponent[ref SimplePolicyAction[0..n]]
PartComponent[ref PolicyValue[1..1] ]
The reference property "GroupComponent" is inherited from
PolicyComponent, and overridden to become an object reference to a
SimplePolicyAction that contains exactly one PolicyValue. Note that for
any single instance of the aggregation class
PolicyValueInSimplePolicyAction, this property is single-valued. The
[0..n] cardinality indicates that there may be 0, 1, or more
SimplePolicyAction objects that contain any given policy value object.
The reference property "PartComponent" is inherited from PolicyComponent,
and overridden to become an object reference to a PolicyValue that is
defined within the scope of a SimplePolicyAction. Note that for any
single instance of the association class PolicyValueInSimplePolicyAction,
this property (like all reference properties) is single-valued. The
[1..1] cardinality indicates that a SimplePolicyAction must have exactly
one policy value defined within its scope in order to be meaningful.
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7.17. The Association "ReusablePolicy"
The association ReusablePolicy makes it possible to include any subclass
of the abstract class "Policy" in a ReusablePolicyContainer.
NAME ReusablePolicy
DESCRIPTION A class representing the inclusion of a reusable
policy element in a ReusablePolicyContainer. Reusable
elements may be PolicyGroups, PolicyRules,
PolicyConditions, PolicyActions, PolicyVariables,
PolicyValues, or instances of any other subclasses of
the abstract class Policy.
DERIVED FROM PolicyInSystem
ABSTRACT FALSE
PROPERTIES Antecedent[ref ReusablePolicyContainer[0..1]]
7.18. Deprecate PCIM's "PolicyConditionInPolicyRepository"
NAME PolicyConditionInPolicyRepository
DEPRECATED FOR ReusablePolicy
DESCRIPTION A class representing the inclusion of a reusable
PolicyCondition in a PolicyRepository.
DERIVED FROM PolicyInSystem
ABSTRACT FALSE
PROPERTIES Antecedent[ref PolicyRepository[0..1]]
Dependent[ref PolicyCondition[0..n]]
7.19. Deprecate PCIM's "PolicyActionInPolicyRepository"
NAME PolicyActionInPolicyRepository
DEPRECATED FOR ReusablePolicy
DESCRIPTION A class representing the inclusion of a reusable
PolicyAction in a PolicyRepository.
DERIVED FROM PolicyInSystem
ABSTRACT FALSE
PROPERTIES Antecedent[ref PolicyRepository[0..1]]
Dependent[ref PolicyAction[0..n]]
7.20. The Association ExpectedPolicyValuesForVariable
This association links a PolicyValue object to a PolicyVariable object,
modeling the set of expected values for that PolicyVariable. Using this
association, a variable (instance) may be constrained to be bound-
to/assigned only a set of allowed values. For example, modeling an
enumerated source port variable, one creates an instance of the
PolicySourcePortVariable class and associates with it the set of values
(integers) representing the allowed enumeration, using appropriate number
of instances of the ExpectedPolicyValuesForVariable association.
Note that a single variable instance may be constrained by any number of
values, and a single value may be used to constrain any number of
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variables. These relationships are manifested by the n-to-m cardinality
of the association.
The purpose of this association is to support validation of simple policy
conditions and simple policy actions, prior to their deployment to an
enforcement point. This association, and the PolicyValue object that it
refers to, plays no role when a PDP or a PEP is evaluating a simple
policy condition, or executing a simple policy action. See Section 5.8.3
for more details on this point.
The class definition for the association is as follows:
NAME ExpectedPolicyValuesForVariable
DESCRIPTION A class representing the association of a set of
expected values to a variable object.
DERIVED FROM Dependency
ABSTRACT FALSE
PROPERTIES Antecedent [ref PolicyVariable[0..n]]
Dependent [ref PolicyValue [0..n]]
The reference property Antecedent is inherited from Dependency. Its type
and cardinality are overridden to provide the semantics of a variable
optionally having value constraints. The [0..n] cardinality indicates
that any number of variables may be constrained by a given value.
The reference property "Dependent" is inherited from Dependency, and
overridden to become an object reference to a PolicyValue representing
the values that a particular PolicyVariable can have. The [0..n]
cardinality indicates that a given policy variable may have 0, 1 or more
than one PolicyValues defined to model the set(s) of values that the
policy variable can take.
7.21. The Aggregation "ContainedDomain"
The aggregation ContainedDomain provides a means of nesting of one
ReusablePolicyContainer inside another one. The aggregation is defined
at the level of ReusablePolicyContainer's superclass, AdminDomain, to
give it applicability to areas other than Core Policy.
NAME ContainedDomain
DESCRIPTION A class representing the aggregation of lower level
administrative domains by a higher-level AdminDomain.
DERIVED FROM SystemComponent
ABSTRACT FALSE
PROPERTIES GroupComponent[ref AdminDomain [0..n]]
PartComponent[ref AdminDomain [0..n]]
7.22. Deprecate PCIM's "PolicyRepositoryInPolicyRepository"
NAME PolicyRepositoryInPolicyRepository
DEPRECATED FOR ContainedDomain
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DESCRIPTION A class representing the aggregation of
PolicyRepositories by a higher-level PolicyRepository.
DERIVED FROM SystemComponent
ABSTRACT FALSE
PROPERTIES GroupComponent[ref PolicyRepository[0..n]]
PartComponent[ref PolicyRepository[0..n]]
7.23. The Aggregation "EntriesInFilterList"
This aggregation is a specialization of the Component aggregation; it is
used to define a set of filter entries (subclasses of FilterEntryBase)
that are aggregated by a FilterList.
The cardinalities of the aggregation itself are 0..1 on the FilterList
end, and 0..n on the FilterEntryBase end. Thus in the general case, a
filter entry can exist without being aggregated into any FilterList.
However, the only way a filter entry can figure in the PCIMe model is by
being aggregated into a FilterList by this aggregation.
The class definition for the aggregation is as follows:
NAME EntriesInFilterList
DESCRIPTION An aggregation used to define a set of
filter entries (subclasses of
FilterEntryBase) that are aggregated by
a particular FilterList.
DERIVED FROM Component
ABSTRACT False
PROPERTIES GroupComponent[ref
FilterList[0..1]],
PartComponent[ref
FilterEntryBase[0..n],
EntrySequence
7.23.1. The Reference GroupComponent
This property is overridden in this aggregation to represent an object
reference to a FilterList object (instead of to the more generic
ManagedSystemElement object defined in its superclass). It also
restricts the cardinality of the aggregate to 0..1 (instead of the more
generic 0-or-more), representing the fact that a filter entry always
exists within the context of at most one FilterList.
7.23.2. The Reference PartComponent
This property is overridden in this aggregation to represent an object
reference to a FilterEntryBase object (instead of to the more generic
ManagedSystemElement object defined in its superclass). This object
represents a single filter entry, which may be aggregated with other
filter entries to form the FilterList.
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7.23.3. The Property EntrySequence
An unsigned 16-bit integer indicating the order of the filter entry
relative to all others in the FilterList. The default value '0'
indicates that order is not significant, because the entries in this
FilterList are ANDed together.
7.24. The Aggregation "ElementInPolicyRoleCollection"
The following aggregation is used to associate ManagedElements with a
PolicyRoleCollection object that represents a role played by these
ManagedElements.
NAME ElementInPolicyRoleCollection
DESCRIPTION A class representing the inclusion of a ManagedElement
in a collection, specified as having a given role.
All the managed elements in the collection share the
same role.
DERIVED FROM MemberOfCollection
ABSTRACT FALSE
PROPERTIES Collection[ref PolicyRoleCollection [0..n]]
Member[ref ManagedElement [0..n]]
7.25. The Weak Association "PolicyRoleCollectionInSystem"
A PolicyRoleCollection is defined within the scope of a System. This
association links a PolicyRoleCollection to the System in whose scope it
is defined.
When associating a PolicyRoleCollection with a System, this should be
done consistently with the system that scopes the policy rules/groups
that are applied to the resources in that collection. A
PolicyRoleCollection is associated with the same system as the applicable
PolicyRules and/or PolicyGroups, or to a System higher in the tree formed
by the SystemComponent association.
The class definition for the association is as follows:
NAME PolicyRoleCollectionInSystem
DESCRIPTION A class representing the fact that a
PolicyRoleCollection is defined within the scope of a
System.
DERIVED FROM Dependency
ABSTRACT FALSE
PROPERTIES Antecedent[ref System[1..1]]
Dependent[ref PolicyRoleCollection[weak]]
The reference property Antecedent is inherited from Dependency, and
overridden to become an object reference to a System, and to restrict its
cardinality to [1..1]. It serves as an object reference to a System that
provides a scope for one or more PolicyRoleCollections. Since this is a
weak association, the cardinality for this object reference is always 1,
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that is, a PolicyRoleCollection is always defined within the scope of
exactly one System.
The reference property Dependent is inherited from Dependency, and
overridden to become an object reference to a PolicyRoleCollection
defined within the scope of a System. Note that for any single instance
of the association class PolicyRoleCollectionInSystem, this property
(like all Reference properties) is single-valued. The [0..n] cardinality
indicates that a given System may have 0, 1, or more than one
PolicyRoleCollections defined within its scope.
8. Intellectual Property
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.
9. Acknowledgements
The starting point for this document was PCIM itself [1], and the first
three submodels derived from it [11], [12], [13]. The authors of these
documents created the extensions to PCIM, and asked the questions about
PCIM, that are reflected in PCIMe.
10. Contributors
This document includes text written by a number of authors (including the
editor), that was subsequently merged by the editor. The following
people contributed text to this document:
Lee Rafalow
IBM Corporation, BRQA/501
4205 S. Miami Blvd.
Research Triangle Park, NC 27709
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Phone: +1 919-254-4455
Fax: +1 919-254-6243
E-mail: rafalow@us.ibm.com
Yoram Ramberg
Cisco Systems
4 Maskit Street
Herzliya Pituach, Israel 46766
Phone: +972-9-970-0081
Fax: +972-9-970-0219
E-mail: yramberg@cisco.com
Yoram Snir
Cisco Systems
4 Maskit Street
Herzliya Pituach, Israel 46766
Phone: +972-9-970-0085
Fax: +972-9-970-0366
E-mail: ysnir@cisco.com
Andrea Westerinen
Cisco Systems
Building 20
725 Alder Drive
Milpitas, CA 95035
Phone: +1-408-853-8294
Fax: +1-408-527-6351
E-mail: andreaw@cisco.com
Ritu Chadha
Telcordia Technologies
MCC 1J-218R
445 South Street
Morristown NJ 07960.
Phone: +1-973-829-4869
Fax: +1-973-829-5889
E-mail: chadha@research.telcordia.com
Marcus Brunner
NEC Europe Ltd.
C&C Research Laboratories
Adenauerplatz 6
D-69115 Heidelberg, Germany
Phone: +49 (0)6221 9051129
Fax: +49 (0)6221 9051155
E-mail: brunner@ccrle.nec.de
Ron Cohen
Ntear LLC
E-mail: ronc@ntear.com
John Strassner
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INTELLIDEN, Inc.
90 South Cascade Avenue
Colorado Springs, CO 80903
Phone: +1-719-785-0648
E-mail: john.strassner@intelliden.com
11. Security Considerations
The Policy Core Information Model (PCIM) [1] 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.
12. Normative References
[1] Strassner, J., and E. Ellesson, B. Moore, A. Westerinen, "Policy Core
Information Model -- Version 1 Specification", RFC 3060, February
2001.
[2] Distributed Management Task Force, Inc., "DMTF Technologies: CIM
Standards û CIM Schema: Version 2.5", available at
http://www.dmtf.org/standards/cim_schema_v25.php.
[3] Distributed Management Task Force, Inc., "Common Information Model
(CIM) Specification: Version 2.2", June 14, 1999, available at
http://www.dmtf.org/standards/documents/CIM/DSP0004.pdf.
[4] P. Mockapetris, "DOMAIN NAMES - IMPLEMENTATION AND SPECIFICATION", RFC
1035, November 1987.
[5] M. Wahl, A. Coulbeck, "Lightweight Directory Access Protocol (v3):
Attribute Syntax Definitions", RFC 2252, December 1997.
[6] Crocker, D., and P. Overell, "Augmented BNF for Syntax Specifications:
ABNF", RFC 2234, November 1997.
[7] R. Hinden, S. Deering, "IP Version 6 Addressing Architecture", RFC
2373, July 1998.
13. Informative References
[8] Bradner, S., "Key words for use in RFCs to Indicate Requirement
Levels", BCP 14, RFC 2119, March 1997.
[9] Hovey, R., and S. Bradner, "The Organizations Involved in the IETF
Standards Process", BCP 11, RFC 2028, October 1996.
[10] A. Westerinen, et al., "Terminology for Policy-Based Management", RFC
3198, November 2001.
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[11] Snir, Y., and Y. Ramberg, J. Strassner, R. Cohen, "Policy QoS
Information Model", work in progress, draft-ietf-policy-qos-info-
model-04.txt, November 2001.
[12] Jason, J., and L. Rafalow, E. Vyncke, "IPsec Configuration Policy
Model", work in progress, draft-ietf-ipsp-config-policy-model-04.txt,
November 2001.
[13] Chadha, R., and M. Brunner, M. Yoshida, J. Quittek, G. Mykoniatis, A.
Poylisher, R. Vaidyanathan, A. Kind, F. Reichmeyer, "Policy Framework
MPLS Information Model for QoS and TE", work in progress, draft-
chadha-policy-mpls-te-01.txt, December 2000.
[14] S. Waldbusser, and J. Saperia, T. Hongal, "Policy Based Management
MIB", work in progress, <draft-ietf-snmpconf-pm-09.txt>, November
2001.
[15] B. Moore, and D. Durham, J. Halpern, J. Strassner, A. Westerinen, W.
Weiss, "Information Model for Describing Network Device QoS Datapath
Mechanisms", work in progress, <draft-ietf-policy-qos-device-info-
model-07.txt>, March 2002.
14. Editor's Address
Bob Moore
IBM Corporation, BRQA/501
4205 S. Miami Blvd.
Research Triangle Park, NC 27709
Phone: +1 919-254-4436
Fax: +1 919-254-6243
E-mail: remoore@us.ibm.com
15. Full Copyright Statement
Copyright (C) The Internet Society (2002). All Rights Reserved.
This document and translations of it may be copied and furnished to
others, and derivative works that comment on or otherwise explain it or
assist in its implementation may be prepared, copied, published and
distributed, in whole or in part, without restriction of any kind,
provided that the above copyright notice and this paragraph are included
on all such copies and derivative works. However, this document itself
may not be modified in any way, such as by removing the copyright notice
or references to the Internet Society or other Internet organizations,
except as needed for the purpose of developing Internet standards in
which case the procedures for copyrights defined in the Internet
Standards process must be followed, or as required to translate it into
languages other than English.
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The limited permissions granted above are perpetual and will not be
revoked by the Internet Society or its successors or assigns.
This document and the information contained herein is provided on an "AS
IS" basis and THE INTERNET SOCIETY AND THE INTERNET ENGINEERING TASK
FORCE DISCLAIMS ALL WARRANTIES, EXPRESS OR IMPLIED, INCLUDING BUT NOT
LIMITED TO ANY WARRANTY THAT THE USE OF THE INFORMATION HEREIN WILL NOT
INFRINGE ANY RIGHTS OR ANY IMPLIED WARRANTIES OF MERCHANTABILITY OR
FITNESS FOR A PARTICULAR PURPOSE.
16. Appendix A: Closed Issues
EDITOR'S NOTE: The following list captures the major technical issues
that were resolved during the course of progressing PCIMe from initial
draft to Proposed Standard. This appendix will be removed for submission
to the RFC Editor (unless there is a consensus to preserve it in the
RFC), but it should be archived somewhere.
1. Unrestricted use of DNF/CNF for CompoundPolicyConditions.
Alternative: for the conditions aggregated by a
CompoundPolicyCondition, allow only ANDing, with negation of
individual conditions. Note that this is sufficient to build
multi-field packet filters from single-field
SimplePolicyConditions.
RESOLUTION: The same DNF/CNF capabilities present for aggregating
PolicyConditions into a PolicyRule have been retained for
aggregating PolicyConditions into a CompoundPolicyCondition.
2. For a PolicyVariable in a SimplePolicyCondition, restrict the set
of possible values both via associated PolicyValue objects (tied
in with the ExpectedPolicyValuesForVariable association) and via
the ValueTypes property in the PolicyVariable class. Alternative:
restrict values only via associated PolicyValue objects.
RESOLUTION: PCIMe continues to allow both mechanisms for
restricting the values of a PolicyVariable.
3. Transactional semantics, including rollback, for the
ExecutionStrategy property in PolicyRule and in
CompoundPolicyAction. Alternative: have only 'Do until success'
and 'Do all'.
RESOLUTION: No transactional semantics for action execution. The
value 'Mandatory Do All(1)' has been removed from the two
ExecutionStrategy properties.
4. Stating that CompoundFilterConditions are the preferred way to do
packet filtering in a PolicyCondition. Alternative: make
CompoundFilterConditions and FilterEntries available to submodels,
with no stated (or implied) preference.
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RESOLUTION: Recommendations for use of CompoundFilterConditions
and FilterEntries are retained, but they have been recast
slightly. CompoundFilterConditions are now positioned as the
recommended approach for domain-level models. FilterEntries are
the recommended approach for device-level models.
5. Prohibiting equal values for Priority within a PolicySet.
Alternative: allow equal values, with resulting indeterminacy in
PEP behavior.
RESOLUTION: PCIMe will continue to prohibit equal Priority values.
6. Modeling a SimplePolicyAction with just a related PolicyVariable
and PolicyValue -- the "set" or "apply" operation is implicit.
Alternative: include an Operation property in SimplePolicyAction,
similar to the Operation property in SimplePolicyCondition.
RESOLUTION: This issue has been resolved by a change in the
opposite direction. The operations are now implicit for BOTH
SimplePolicyCondition and SimplePolicyAction. See Sections 5.8.3
and 5.8.4, respectively, for discussions of
SimplePolicyCondition's implicit MATCH operator and
SimplePolicyAction's implicit SET operator.
7. Representation of PolicyValues: should values like IPv4 addresses
be represented only as strings (as in LDAP), or natively (e.g., an
IPv4 address would be a four-octet field) with mappings to other
representations such as strings?
RESOLUTION: Mappings have been eliminated. Each value type has a
single representation specified for it.
8. The nesting of rules and groups within rules introduces
significant change and complexity in the model. This nesting
introduces program state (procedural language) into the model
(heretofore a declarative model) as well as implicit hierarchical
contexts on which the rules operate. These require a much more
sophisticated rule-evaluation engine than in the past.
Alternative: Maintain the declarative model, by prohibiting
program state in rule evaluation (i.e., no rules within rules).
RESOLUTION: Nesting of rules and groups within rules has been
retained, but with a significant new limitation: actions
associated with a rule do not have side effects that would impact
condition evaluation for subsequent rules. "Subsequent rules"
here includes both rules nested within the rule whose actions are
under discussion, and rules at the same nesting level as this rule
that are evaluated after it. Note that it has been a feature of
PCIM (RFC 3060) all along that condition evaluation has no side
effects that would influence condition evaluation for subsequent
rules.
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There is also one modeling detail associated with nesting that has
been changed. Rather than having separate aggregations
(PolicyGroupInPolicyGroup, etc.) for each of the four nesting
varieties, the single aggregation PolicySetComponent is now used
as a concrete aggregation class.
9. Need to specify a join algorithm for disjoint rule sets.
RESOLUTION: PCIMe now states that for different functional domains
(e.g., QoS and IKE), there is no join algorithm. Each domain, in
effect, has its own rule engine, which operates independently of
the other domains' engine(s). Within a functional domain,
disjoint PolicySets are joined by the Priority property in the
PolicySetInSystem association. In this case the decision strategy
is specified to be FirstMatching.
10. Clarify PolicyImplicitVariables.
RESOLUTION: Each subclass of PolicyImplicitVariable will identify
the exact source of the variable data. For example, there will be
a subclass of PolicyImplicitVariable that specifically identifies
the IPv4 source address in the outermost packet header. IPv4 and
IPv6 addresses will require separate subclasses of
PolicyImplicitVariable. We understand the downside of this
approach: a potential explosion in the number of subclasses of
PolicyImplicitVariable.
11. Clarify PolicyExplicitVariables.
NON-RESOLUTION (in PCIMe-01): This issue is still not resolved at
all. The authors continue to believe that we need the capability
of indicating that a condition should compare against (or an
action should set) a particular property in a particular object
instance. But we do not believe that the current mechanism of
specifying a target object class and property name is sufficient.
For the next version of PCIMe, we need to either find a way to
make this work in general; or find a way to make it work in some
cases, and then describe clearly what these cases are; or remove
PolicyExplicitVariables from PCIMe entirely.
RESOLUTION (in PCIMe-02): From the list of choices above, we took
the path of making explicit variables work in a specific case, and
indicating clearly that they work only in this case. See Section
5.8.6
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