One document matched: draft-linowski-netconf-dml-requirements-01.txt
Differences from draft-linowski-netconf-dml-requirements-00.txt
Network Working Group B. Linowski
Internet-Draft M. Storch
Intended status: Informational M. Ersue
Expires: August 21, 2008 M. Lahdensivu
Nokia Siemens Networks
February 18, 2008
NETCONF Data Modeling Language Requirements
draft-linowski-netconf-dml-requirements-01
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Abstract
This document collects requirements for a Data Modeling Language
(DML) and has been prepared as a contribution to the RCDML design
team working on the "Requirements for a Configuration Data Modeling
Language". Comments can be sent to ngo@ietf.org.
Table of Contents
1. Introduction . . . . . . . . . . . . . . . . . . . . . . . . . 4
2. Conventions used in this document . . . . . . . . . . . . . . 5
3. Terminology . . . . . . . . . . . . . . . . . . . . . . . . . 6
4. Requirements . . . . . . . . . . . . . . . . . . . . . . . . . 8
4.1. Basic Requirements . . . . . . . . . . . . . . . . . . . . 8
4.1.1. Base Data Types . . . . . . . . . . . . . . . . . . . 8
4.1.2. Default Values of Defined Types and Attributes . . . . 8
4.1.3. Language Extensibility . . . . . . . . . . . . . . . . 8
4.1.4. Model Modularity . . . . . . . . . . . . . . . . . . . 8
4.1.5. Protocol Independence . . . . . . . . . . . . . . . . 9
4.1.6. Translation to Other Data Definition Languages . . . . 9
4.1.7. Module Conformance . . . . . . . . . . . . . . . . . . 9
4.2. Common Requirements . . . . . . . . . . . . . . . . . . . 10
4.2.1. Model Element Identifiers . . . . . . . . . . . . . . 10
4.2.2. Model Element Documentation Text . . . . . . . . . . . 10
4.2.3. Model Element Presentation Name . . . . . . . . . . . 11
4.3. Model Releases . . . . . . . . . . . . . . . . . . . . . . 11
4.3.1. Release Support . . . . . . . . . . . . . . . . . . . 12
4.3.2. Multiple sub-module revisions in one model . . . . . . 12
4.4. Modeling Feature Requirements . . . . . . . . . . . . . . 13
4.4.1. Concrete Classes . . . . . . . . . . . . . . . . . . . 13
4.4.2. Abstract Classes . . . . . . . . . . . . . . . . . . . 14
4.4.3. Single Class Inheritance . . . . . . . . . . . . . . . 14
4.4.4. Attributes . . . . . . . . . . . . . . . . . . . . . . 15
4.4.5. Attribute Groups . . . . . . . . . . . . . . . . . . . 16
4.4.6. Reference Relationships . . . . . . . . . . . . . . . 17
4.4.7. Containment Relationships . . . . . . . . . . . . . . 17
4.4.8. Calculated Relationships . . . . . . . . . . . . . . . 18
4.4.9. Simple Attribute Constraints . . . . . . . . . . . . . 19
4.5. Extension Mechanisms . . . . . . . . . . . . . . . . . . . 20
4.5.1. Typed Annotations . . . . . . . . . . . . . . . . . . 20
5. IANA Considerations . . . . . . . . . . . . . . . . . . . . . 22
6. Security Considerations . . . . . . . . . . . . . . . . . . . 23
7. Acknowledgements . . . . . . . . . . . . . . . . . . . . . . . 24
8. References . . . . . . . . . . . . . . . . . . . . . . . . . . 25
8.1. Normative References . . . . . . . . . . . . . . . . . . . 25
8.2. Informative References . . . . . . . . . . . . . . . . . . 25
Authors' Addresses . . . . . . . . . . . . . . . . . . . . . . . . 26
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Intellectual Property and Copyright Statements . . . . . . . . . . 27
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1. Introduction
This document collects requirements for a Data Modeling Language
(DML) and has been prepared as additional contribution for the design
team working on the "Requirements for a Configuration Data Modeling
Language" (RCDML) [4].
RCDML design team prepared a requirements document by focusing on the
immediate needs of the OPS area and NETCONF protocol as well as by
taking into consideration the need for extensibility and the
opportunity of providing one data modeling language solution for
different other IETF problems in the APPS area. We think the
requirements in this document are complementary to the requirements
discussion until now and should be seen as an additional input for
the design team work on the RCDML. The requirements in this draft
have been prepared based on the network management modeling
experience of the last two years.
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2. Conventions used in this document
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 [1].
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3. Terminology
Following is the terminology used in this document:
o annotation: Additional metadata that refines semantics of a model
element. A typed annotation consists of elements which have a
type and a value.
o attribute: A named data element that can hold a value (structural
feature).
o attribute group: Group of attributes supposed to be used only to
define the contents of classes (or structures).
o base type: The type from which a refined type was derived, which
may be either a built-in type or another derived type.
o built-in type: A data type defined in the DML, such as uint32 or
string.
o class: A language construct used to describe the structural
features of instances with an own identity and life-cyle.
o data model: A mapping of the contents of an information model into
a form that is specific to a particular type of data store or
repository. A "data model" the rendering of an information model
according to a specific set of mechanisms for representing,
organizing, storing and handling data.
o DML: Data Modeling Language
o enumeration: Data type with an enumerated set of values.
o identifier: Used to uniquely identify a model element (class,
attribute, etc.) in the containing namespace.
o information model: An abstraction and representation of the
entities in a managed environment, their properties, attributes
and operations, and the way that they relate to each other. It is
independent of any specific repository, software usage, protocol,
or platform.
o list: Sequence of elements of the same type.
o managed object: An abstract representation of network resources
that are managed. A managed object may represent a physical
entity, a network service, or an abstraction of a resource that
exists independently of its use.
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o object: Instance of a class
o struct: Set of attributes without own identity
o relationship: Definition of an association between instances of
two classes.
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4. Requirements
4.1. Basic Requirements
4.1.1. Base Data Types
Description:
DML must support the base data types such as int8, int16, int32,
int64, uint8, uint16, uint32, uint64, float32, float64, string,
boolean, enumeration, octet, char, date-time, binary, empty.
Motivation:
Base data types are used frequently and simplify the module
development.
4.1.2. Default Values of Defined Types and Attributes
Description:
DML must support default values to be used for different purposes
such initial, runtime and failure fall-back.
Motivation:
Default values simplify configuration for start-up, failure and other
scenarios.
4.1.3. Language Extensibility
Description:
The language must have characteristics, so that future modules can
contain information of future syntax without breaking original DML
translation tools and parsers.
Motivation:
Achieve language extensibility with downward compatibility.
4.1.4. Model Modularity
Description:
Network element model must be composable from separate sub-models.
Circular dependencies between the model modules should not be
allowed.
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Motivation:
A sub-model can be used to encapsulate a certain management model.
This can be an independent partition or a basic module that provides
definitions for other modules. The whole model for the network
element should be possible to derive from these separate model
modules.
4.1.5. Protocol Independence
From: RFC 3216
Description:
DML must define data definitions in support of Netconf protocol. DML
may define data definitions in support of protocols other than
Netconf.
Motivation:
DML data definitions may be used with multiple protocols and multiple
versions of those protocols.
4.1.6. Translation to Other Data Definition Languages
Description:
DML constructs must be translatable to other basic languages such as
XSD or RelaxNG. DML may not contain constructs which are not
possible to translate to other basic languages.
Motivation:
Use of existing tools based on such as XSD or RelaxNG e.g. for
validation.
4.1.7. Module Conformance
Description:
DML must provide mechanisms to enable the verification of the module
conformance defining minimum requirements implementers must meet for
conformance.
Motivation:
Ability to convey conformance requirements.
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4.2. Common Requirements
4.2.1. Model Element Identifiers
Type: Clarification / Refinement
Description:
Each referable model element must have an identifier that uniquely
identifies it in the scope of the containing model element. This
identifier must start with a letter (a - z, A - Z) and otherwise
consist only of alphanumerical characters, including the underscore
(a - z, A - Z, 0 - 9, _). It must have a limited maximum length.
Identifier equality should be non-case-sensitive.
Motivation:
Needed to create readable, hierarchical names that uniquely identify
individual elements inside the model. The restricted set of legal
characters should enable lossless mapping to languages as well as
storage schema specifications.
Notes:
Limiting the set of allowed characters to alphanumeric characters is
done to facilitate mapping to other domains like other data
definition or data access languages (e.g. DDL, SQL). It should be
taken into account that not all mapping target languages have case-
sensitive identifiers, especially SQL.
4.2.2. Model Element Documentation Text
Type: Clarification / Refinement
Description:
It must be possible to provide a textual documentation (e.g.
description) for each model element.
All kinds of characters, including language specific characters
should be supported.
Motivation:
Model element documentation can be used inside user facing
applications to provide or enrich online help.
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Providing at least basic documentation for a model elements helps to
ensure that it is properly (re)used inside models as well as that
correct instance data is provided for instances of that model
element.
Notes:
Separating basic model documentation from model definition easily
leads to incomplete documentation or even inconsistencies between
model and documentation.
4.2.3. Model Element Presentation Name
Type: New
Description:
It should be possible to add a presentation name for the model
element. The presentation name is for use in interfaces to human end
users.
All kinds of characters, including language specific characters must
be supported.
Motivation:
Technical identifiers become hard to read when they contain
abbreviations or if they were constructed by concatenating several
words, separated only by underscores or alternating lower-case with
upper-case letters. In such cases a separate presentation names
helps to create user friendly end user interfaces.
Notes:
Localizing presentation names could be done "on top" of the model if
needed. But leaving presentation names completely out of the model
often leads to hard to understand GUI's as the technical identifiers
are used for purposes they are not designed for (e.g. data entry
field captions). The other alternatives are to add another
description mechanism on top of the model or to reuse extension
mechanism like annotations. However, such mechanisms lead to a
higher DML usage and model maintenance cost.
4.3. Model Releases
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4.3.1. Release Support
Type: New
Description:
It must be possible to specify the release (version) of the model.
The release of the model supports to distinguish the different
releases of the according network element.
The release implicitly applies to all model elements in the model.
The release identifier should at least allow alphanumeric characters
plus '.' (dot).
Motivation:
Network elements evolve over time; new features are added, existing
ones are enhanced or slightly changed, others are dropped. Already
in networks of moderate size, it is quite common that several
releases of the same type of network element software are used in
parallel.
Typing versions to individual model elements in one release agnostic
(compound-) model wouldn't be practical. For example, sometimes
there is a need to state that a certain feature of a class is not
supported in a particular release. But if that feature is still
supported in other releases, it must still be visible. In general,
reading of a compound-model becomes difficult as a release specific
views must be explicitly constructed.
4.3.2. Multiple sub-module revisions in one model
Type: New
From: Network management layer modeling
Description:
It must be possible to combine multiple revisions of a model into one
cohesive umbrella model without loss of information.
Motivation:
A network management system deals with multiple network elements of
the same type, each of which supports a model on a certain, yet
possibly different revision level. A model of the network management
system - e.g. when defining its management capabilities for a higher-
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level management system - would have to be the union of the
individual models (and revisions) of the network elements.
Notes:
If not available, the network management system has two options:
o provide the latest revision of the network element's model as part
of the own model. Always transform the data complying to earlier
revisions to the latest revision of a model.
o rename the network element models so that different revisions maps
to different model element names. Always transform the data
according to the element renaming rules.
When implemented, imported modules cannot be referenced by their name
only, but need to be referenced by a naming convention including the
revision. If different namespace prefixes are used in the umbrella
model, then the model elements coming from different revisions can be
distinguished.
Also some discriminator on data level would be required,
e.g. <router yang:revision="2007-05-14"> <interface> <tcp/> ...
4.4. Modeling Feature Requirements
4.4.1. Concrete Classes
Type: New
From: Basic network modeling
Description:
It must be possible to define classes as a cohesive package of
metadata that at least define its data structure and its
relationships to other model elements.
Motivation:
Fundamental modeling concept for encapsulating and grouping of
structural features (i.e. attributes) for reuse.
Notes:
The behavioral features of classes as used in object oriented
programming languages might not be of relevance for a data modeling
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language. But aspects such as structural features (attributes,
relationships / associations) and relationship to other classes
(inheritance) are. Therefore introducing the class concept in the
context of a DML makes it highly useful.
4.4.2. Abstract Classes
Type: New
From: Basic network modeling
Description:
It must be possible to define classes which only cover the invariant
structural features of derived, specialized classes. Abstract
classes cannot be instantiated.
Motivation:
It must be possible to model abstract entities which itself cannot be
instantiated but serve as a blueprint for derived, specialized data
groups. This allows defining concepts that are useful for generic
applications without the need to provide an implementation,
respectively without the side-effect that an implementation is
generated in addition.
Notes:
Abstract classes can also be used as the endpoints for relationships.
4.4.3. Single Class Inheritance
Type: New
From: Basic network modeling
Description:
It must be possible to derive a class from at most one superclass.
An is-a relationship is established from the derived class to the
superclass. The derived class inherits all features (attributes,
relationships, constraints) of the superclass. In effect, instances
of the derived class can act as substitutes for instances of the
superclass in all contexts in which the superclass appears (Liskov
substitution principle).
Motivation:
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Class inheritance is needed in order to
o enable semantically rich modeling (is-a relationship)
o avoid redundancy (feature inheritance)
o ensure consistent modeling (superclass reuse)
Notes:
Inheritance is one of the key and most widely used concepts for
creating semantically rich yet concise models. Leaving it out of the
DML makes it hardly usable for use cases that require structuring a
model in layers of different abstraction.
4.4.4. Attributes
Type: Clarification / refinement
From: Basic network modeling
Description:
It must be possible to define attributes as members of classes and
attribute groups.
For each attribute following properties must be possible to define:
o The type. Primitive types as well as constructed types
(sequences, structures) must be supported by the DML.
o The initialization mode of the attribute. At least the following
modes must be supported:
* Required: An attribute value must be provided during instance
creation
* Optional: An attribute value may be provided during instance
creation
* None: An attribute value must not be provided during instance
creation ("none" is a correct, meaningful value in case of
read-only attributes; there might be cases when an attribute
can only be set afterwards.)
o Changeability after instance creation
For each attribute following properties should be possible to define:
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o The unit in which attribute values are measured.
o A default value.
Motivation:
Fundamental data modeling concept to describe properties of managed
objects which can be represented with data values.
Notes:
Specifying the unit as part of the attribute definitions allows
describing the actual use of the attribute without having to create a
new datatype that only wraps a primitive type. E.g. an attribute
"acceptableCRCErrors" could just use the primitive datatype "int32"
and set the value of 'unit' to "CRC-Errors / Sec". There is no need
to define a datatype "CRCErrorsRate" that is possibly used only once
in the whole model.
4.4.5. Attribute Groups
Type: Clarification / refinement
From: Basic network modeling
Description:
It must be possible to combine multiple attributes into a group that
can be reused in the definition of classes. It must be possible that
a class can reuse one or more attribute groups.
Motivation:
The purpose of attribute groups is mainly the grouping of related
attributes which are typically always used together. That should
help to avoid an inconsistent modeling of such attributes or having
to copy and paste attribute definitions.
Notes:
Using classes don't establish an is-a relationship to the used
attribute groups. Attribute groups also help to alleviate the lack
of multiple inheritance as it makes mix-in classes superfluous which
are used just to provide commonly used attributes to derived classes.
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4.4.6. Reference Relationships
Type: New
From: Basic network modeling
Description:
It must be possible to describe references between instances of two
classes.
Adding reference relationships must be possible without changing the
definition of the source- or target-end class
Motivation:
Often manageable network resources are associated in some way which
is neither a containment relationship nor can be expressed by
referring to attributes of related classes.
Notes:
Reference relationships can be realized based on XPath statements by
sequencing object node names or by storing object key values of a
referenced object.
Reference relationships are especially important to connect classes
representing configurable resources in the network with rather
abstract and typically network management related concepts.
A simple example is stating the relationship of a port number with
the corresponding sub-network.
Another use case is describing at which geographical location a
network resource was placed, represented by attributes like
longitude, latitude and altitude or city, street, building. But many
network elements do not allow storing such information as part of
their configuration data. This issue can be solved by defining a
location class and associate that class with a reference relationship
to network resource classes.
4.4.7. Containment Relationships
Type: New
From: Basic network modeling
Description:
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It must be possible to define where in a containment hierarchy
instances of a particular class can be placed. In order to do that,
a containment relationship relates the container object class (source
end) with a class of contained objects (target end).
It must be possible to specify the maximum and minimum number of
instances that can be contained in a container class instance.
Adding containment relationships must not require to alter the
container class.
Motivation:
Containment hierarchies are a commonly used organization principle
for manageable resources in network elements as well as for distinct
but related elements in a network.
Notes:
It makes a difference if a containment is defined implicitly
(instances of B are contained in A as the definition of B is placed
inside the definition of A) or if containment relationships are
defined outside of a data containers (classes). The second
alternative has the advantage that new contained elements could be
placed into an existing container without altering the definition of
the container. A coexistence of both approaches is also an option.
4.4.8. Calculated Relationships
Type: New
From: Basic network modeling
Description:
It should be possible to define relationship between instances of two
classes by providing:
o either an expression that enumerates the instances of the target
class that are related to a particular instance of the source-end
class
o or which decides if an instance of the source-end class is related
to an instance of the target-end class.
It should also be possible to name the language in which the
expression is formulated.
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Adding calculated relationships must be possible without altering the
source- or target-end class.
Motivation:
Quite often relationships between manageable resources in a network
are represented in an indirect or non-explicit way.
For example, the relationship "isProtectedBy" which defines by which
spare-card a particular card is protected in case of a hardware
failure might be represented by an attribute which contains the slot
number of the spare card, assuming that card and spare card are
mounted in the same sub-rack. In this case, an expression that
defines this relationship could be:
Card1.subrack == card2.subrack and card1.protectionUnitSlot ==
card2.slot
Notes:
The fact that calculated relationships have to be evaluated at
runtime and can change as side effect of configuration changes is a
benefit and a challenge at the same time. On one hand, evaluating
calculated relationships is more time and resource consuming than
accessing explicitly represented relationships. But on the other
hand it alleviates the need to maintain references in addition to the
basic configuration data.
4.4.9. Simple Attribute Constraints
Type: Clarification / Refinement
From:
Description:
It must be possible to constrain / refine the set of legal values for
simple type attributes. The constraint specification language must
at least support
o Length constraints for string / text-types
o Regular expression pattern constraints (e.g.
"(+|-)\d+\s*(mm|cm|m|km)")
o Numeric range constraints ([mix ... max])
It should be possible to combine several basic attribute constraints
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into a constraints expression by using the logical operators 'and',
'or' and 'not'.
Motivation:
Helps to avoid the input or use of invalid configuration data.
Simple Attribute Constraints Expressions allow specifying constraints
that can be easily formulated by combining two simple constraints.
This is useful for addressing cases where configuration parameters
have a value range representing the normal mode of operation and one
or more special values (e.g. "0", "-1", "", "-" "*") that represent
special states.
Notes:
Supporting such constraints explicitly in a model has the advantage
that evaluating them is possible wherever there is access to the
model (metadata). E.g. checking such constraints is very useful - or
rather expected - in GUI components that allow editing the
configuration of network resources. Tools can check the constraints
on the fly, preventing the provision of erroneous values.
4.5. Extension Mechanisms
4.5.1. Typed Annotations
Type: New
From: Basic network modeling
Description:
It must be possible to define typed annotations with multiple
annotation elements (tagged values). In order to ensure correct use
of annotations, it must be possible to define:
o To what types of model elements an annotation can be attached
o Whether an annotation element (for each model element of defined
types) is required or optional (alternatively minimum and maximum
occurrence)
o The type of an annotation element. Alternatively a regular
expression that specifies the allowed values for the sting
representation of the annotation element value.
Motivation:
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Annotations allow enriching the model with additional information
that might be necessary to take full advantage of the model
respectively of data that instantiates the model. A typical use case
is to refine the semantics of a model element. In that role
annotations fulfill the same purpose as Stereotypes in UML.
Annotations can also help to support maintenance and to achieve
backward compatibility to other metadata.
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5. IANA Considerations
Requirements on a Data Modeling Language are not IANA relevant.
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6. Security Considerations
Requirements on a Data Modeling Language are not security relevant.
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7. Acknowledgements
We would like to thank to Leo Hippelainen for his contributions and
review.
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8. References
8.1. Normative References
[1] Bradner, S., "Key words for use in RFCs to Indicate Requirement
Levels", BCP 14, RFC 2119, March 1997.
8.2. Informative References
[2] Sanchez, L., McCloghrie, K., and J. Saperia, "Requirements for
Configuration Management of IP-based Networks", RFC 3139,
June 2001.
[3] Elliott, C., Harrington, D., Jason, J., Schoenwaelder, J.,
Strauss, F., and W. Weiss, "SMIng Objectives", RFC 3216,
December 2001.
[4] Presuhn, R., "Requirements for a Configuration Data Modeling
Language", January 2008, <draft-presuhn-rcdml-00 (work in
progress)>.
[5] Bjorklund, M., "YANG - A data modeling language for NETCONF",
draft-bjorklund-netconf-yang-00 (work in progress),
November 2007.
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Authors' Addresses
Bernd Linowski
Nokia Siemens Networks
Heltorfer Strasse 1
40472 Duesseldorf
Germany
Email: bernd.linowski@nsn.com
Martin Storch
Nokia Siemens Networks
Heltorfer Strasse 1
40472 Duesseldorf
Germany
Email: martin.storch@nsn.com
Mehmet Ersue
Nokia Siemens Networks
St.-Martin-Strasse 76
81541 Munich
Germany
Email: mehmet.ersue@nsn.com
Mikko Lahdensivu
Nokia Siemens Networks
Hatanpaeaen valtatie 30
33100 Tampere
Finland
Email: mikko.lahdensivu@nsn.com
Linowski, et al. Expires August 21, 2008 [Page 26]
Internet-Draft DML-Requirements February 2008
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