oasis

CybOX™ Version 2.1.1. Part 07: API Object

Committee Specification Draft 01 /
Public Review Draft 01

20 June 2016

Specification URIs

This version:

http://docs.oasis-open.org/cti/cybox/v2.1.1/csprd01/part07-api/cybox-v2.1.1-csprd01-part07-api.docx (Authoritative)

http://docs.oasis-open.org/cti/cybox/v2.1.1/csprd01/part07-api/cybox-v2.1.1-csprd01-part07-api.html

http://docs.oasis-open.org/cti/cybox/v2.1.1/csprd01/part07-api/cybox-v2.1.1-csprd01-part07-api.pdf

Previous version:

N/A

Latest version:

http://docs.oasis-open.org/cti/cybox/v2.1.1/part07-api/cybox-v2.1.1-part07-api.docx (Authoritative)

http://docs.oasis-open.org/cti/cybox/v2.1.1/part07-api/cybox-v2.1.1-part07-api.html

http://docs.oasis-open.org/cti/cybox/v2.1.1/part07-api/cybox-v2.1.1-part07-api.pdf

Technical Committee:

OASIS Cyber Threat Intelligence (CTI) TC

Chair:

Richard Struse (Richard.Struse@HQ.DHS.GOV), DHS Office of Cybersecurity and Communications (CS&C)

Editors:

Desiree Beck (dbeck@mitre.org), MITRE Corporation

Trey Darley (trey@kingfisherops.com), Individual member

Ivan Kirillov (ikirillov@mitre.org), MITRE Corporation

Rich Piazza (rpiazza@mitre.org), MITRE Corporation

Additional artifacts:

This prose specification is one component of a Work Product whose components are listed in http://docs.oasis-open.org/cti/cybox/v2.1.1/csprd01/cybox-v2.1.1-csprd01-additional-artifacts.html.

Related work:

This specification is related to:

·         STIX™ Version 1.2.1. Edited by Sean Barnum, Desiree Beck, Aharon Chernin, and Rich Piazza. 05 May 2016. OASIS Committee Specification 01. http://docs.oasis-open.org/cti/stix/v1.2.1/cs01/part1-overview/stix-v1.2.1-cs01-part1-overview.html.

Abstract:

The Cyber Observable Expression (CybOX) is a standardized language for encoding and communicating high-fidelity information about cyber observables, whether dynamic events or stateful measures that are observable in the operational cyber domain. By specifying a common structured schematic mechanism for these cyber observables, the intent is to enable the potential for detailed automatable sharing, mapping, detection and analysis heuristics. This specification document defines the API Object data model, which is one of the Object data models for CybOX content.

Status:

This document was last revised or approved by the OASIS Cyber Threat Intelligence (CTI) TC on the above date. The level of approval is also listed above. Check the “Latest version” location noted above for possible later revisions of this document. Any other numbered Versions and other technical work produced by the Technical Committee (TC) are listed at https://www.oasis-open.org/committees/tc_home.php?wg_abbrev=cti#technical.

TC members should send comments on this specification to the TC’s email list. Others should send comments to the TC’s public comment list, after subscribing to it by following the instructions at the “Send A Comment” button on the TC’s web page at https://www.oasis-open.org/committees/cti/.

For information on whether any patents have been disclosed that may be essential to implementing this specification, and any offers of patent licensing terms, please refer to the Intellectual Property Rights section of the TC’s web page (https://www.oasis-open.org/committees/cti/ipr.php).

Citation format:

When referencing this specification the following citation format should be used:

[CybOX-v2.1.1-api]

CybOX™ Version 2.1.1. Part 07: API Object. Edited by Desiree Beck, Trey Darley, Ivan Kirillov, and Rich Piazza. 20 June 2016. OASIS Committee Specification Draft 01 / Public Review Draft 01. http://docs.oasis-open.org/cti/cybox/v2.1.1/csprd01/part07-api/cybox-v2.1.1-csprd01-part07-api.html. Latest version: http://docs.oasis-open.org/cti/cybox/v2.1.1/part07-api/cybox-v2.1.1-part07-api.html.

Notices

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STIX™, TAXII™, AND CybOX™ (STANDARD OR STANDARDS) AND THEIR COMPONENT PARTS ARE PROVIDED “AS IS” WITHOUT ANY WARRANTY OF ANY KIND, EITHER EXPRESSED, IMPLIED, OR STATUTORY, INCLUDING, BUT NOT LIMITED TO, ANY WARRANTY THAT THESE STANDARDS OR ANY OF THEIR COMPONENT PARTS WILL CONFORM TO SPECIFICATIONS, ANY IMPLIED WARRANTIES OF MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE, OR FREEDOM FROM INFRINGEMENT, ANY WARRANTY THAT THE STANDARDS OR THEIR COMPONENT PARTS WILL BE ERROR FREE, OR ANY WARRANTY THAT THE DOCUMENTATION, IF PROVIDED, WILL CONFORM TO THE STANDARDS OR THEIR COMPONENT PARTS.  IN NO EVENT SHALL THE UNITED STATES GOVERNMENT OR ITS CONTRACTORS OR SUBCONTRACTORS BE LIABLE FOR ANY DAMAGES, INCLUDING, BUT NOT LIMITED TO, DIRECT, INDIRECT, SPECIAL OR CONSEQUENTIAL DAMAGES, ARISING OUT OF, RESULTING FROM, OR IN ANY WAY CONNECTED WITH THESE STANDARDS OR THEIR COMPONENT PARTS OR ANY PROVIDED DOCUMENTATION, WHETHER OR NOT BASED UPON WARRANTY, CONTRACT, TORT, OR OTHERWISE, WHETHER OR NOT INJURY WAS SUSTAINED BY PERSONS OR PROPERTY OR OTHERWISE, AND WHETHER OR NOT LOSS WAS SUSTAINED FROM, OR AROSE OUT OF THE RESULTS OF, OR USE OF, THE STANDARDS, THEIR COMPONENT PARTS, AND ANY PROVIDED DOCUMENTATION. THE UNITED STATES GOVERNMENT DISCLAIMS ALL WARRANTIES AND LIABILITIES REGARDING THE STANDARDS OR THEIR COMPONENT PARTS ATTRIBUTABLE TO ANY THIRD PARTY, IF PRESENT IN THE STANDARDS OR THEIR COMPONENT PARTS AND DISTRIBUTES IT OR THEM “AS IS.”

Table of Contents

1        Introduction. 6

1.1 CybOXTM Specification Documents. 6

1.2 Document Conventions. 6

1.2.1 Fonts. 6

1.2.2 UML Package References. 7

1.2.3 UML Diagrams. 7

1.2.4 Property Table Notation. 8

1.2.5 Property and Class Descriptions. 8

1.3 Terminology. 9

1.4 Normative References. 9

2        Background Information. 10

2.1 Cyber Observables. 10

2.2 Objects. 10

3        Data Model 11

3.1 APIObjectType Class. 11

4        Conformance. 13

Appendix A. Acknowledgments. 14

Appendix B. Revision History. 18

 

 


1      Introduction

[All text is normative unless otherwise labeled.]

The Cyber Observable Expression (CybOXTM) language provides a common structure for representing cyber observables across and among the operational areas of enterprise cyber security. CybOX improves the consistency, efficiency, and interoperability of deployed tools and processes, and it increases overall situational awareness by enabling the potential for detailed automatable sharing, mapping, detection, and analysis heuristics.

This document serves as the specification for the CybOX API Object Version 2.1.1 data model, which is one of eighty-eight CybOX Object data models.      

In Section 1.1 we discuss additional specification documents, in Section 1.2 we provide document conventions, and in Section 1.3 we provide terminology. References are given in Section 1.4. In Section 2, we give background information necessary to fully understand the API Object data model. We present the API Object data model specification details in Section 3, and conformance information in Section 4.

1.1 CybOXTM Specification Documents

The CybOX specification consists of a formal UML model and a set of textual specification documents that explain the UML model. Specification documents have been written for each of the individual data models that compose the full CybOX UML model. 

CybOX has a modular design comprising two fundamental data models and a collection of Object data models. The fundamental data models – CybOX Core and CybOX Common – provide essential CybOX structure and functionality. The CybOX Objects, defined in individual data models, are precise characterizations of particular types of observable cyber entities (e.g., HTTP session, Windows registry key, DNS query).

Use of the CybOX Core and Common data models is required; however, use of the CybOX Object data models is purely optional: users select and use only those Objects and corresponding data models that are needed. Importing the entire CybOX suite of data models is not necessary.

The CybOX™ Version 2.1.1 Part 1: Overview document provides a comprehensive overview of the full set of CybOX data models, which in addition to the Core, Common, and numerous Object data models, includes various extension data models and a vocabularies data model, which contains a set of default controlled vocabularies. CybOX™ Version 2.1.1 Part 1: Overview also summarizes the relationship of CybOX to other languages, and outlines general CybOX data model conventions.

1.2 Document Conventions

The following conventions are used in this document.

1.2.1 Fonts

The following font and font style conventions are used in the document:

·         Capitalization is used for CybOX high-level concepts, which are defined in CybOX™ Version 2.1.1 Part 1: Overview.

 

Examples: Action, Object, Event, Property

 

·         The Courier New font is used for writing UML objects.

 

Examples: ActionType, cyboxCommon:BaseObjectPropertyType

 

Note that all high-level concepts have a corresponding UML object. For example, the Action high-level concept is associated with a UML class named, ActionType.

 

·         The ‘italic’ font (with single quotes) is used for noting actual, explicit values for CybOX Language properties. The italic font (without quotes) is used for noting example values.

Example:  ‘HashNameVocab-1.0,’ high, medium, low

1.2.2 UML Package References

Each CybOX data model is captured in a different UML package (e.g., Core package) where the packages together compose the full CybOX UML model. To refer to a particular class of a specific package, we use the format package_prefix:class, where package_prefix corresponds to the appropriate UML package.

The package_prefix for the API data model is APIObj. Note that in this specification document, we do not explicitly specify the package prefix for any classes that originate from the API Object data model. 

1.2.3 UML Diagrams

This specification makes use of UML diagrams to visually depict relationships between CybOX Language constructs. Note that the diagrams have been extracted directly from the full UML model for CybOX; they have not been constructed purely for inclusion in the specification documents. Typically, diagrams are included for the primary class of a data model, and for any other class where the visualization of its relationships between other classes would be useful. This implies that there will be very few diagrams for classes whose only properties are either a data type or a class from the CybOX Common data model. Other diagrams that are included correspond to classes that specialize a superclass and abstract, or generalized classes that are extended by one or more subclasses.

In UML diagrams, classes are often presented with their attributes elided, to avoid clutter. The fully described class can usually be found in a related diagram. A class presented with an empty section at the bottom of the icon indicates that there are no attributes other than those that are visualized using associations.

1.2.3.1 Class Properties

Generally, a class property can be shown in a UML diagram as either an attribute or an association (i.e., the distinction between attributes and associations is somewhat subjective). In order to make the size of UML diagrams in the specifications manageable, we have chosen to capture most properties as attributes and to capture only higher-level properties as associations, especially in the main top-level component diagrams. In particular, we will always capture properties of UML data types as attributes. 

1.2.3.2 Diagram Icons and Arrow Types

Diagram icons are used in a UML diagram to indicate whether a shape is a class, enumeration, or a data type, and decorative icons are used to indicate whether an element is an attribute of a class or an enumeration literal. In addition, two different arrow styles indicate either a directed association relationship (regular arrowhead) or a generalization relationship (triangle-shaped arrowhead). The icons and arrow styles we use are shown and described in Table 1‑1.

Table 1‑1.  UML diagram icons

Icon

Description

This diagram icon indicates a class. If the name is in italics, it is an abstract class.

This diagram icon indicates an enumeration.

This diagram icon indicates a data type.

This decorator icon indicates an attribute of a class. The green circle means its visibility is public. If the circle is red or yellow, it means its visibility is private or protected.

This decorator icon indicates an enumeration literal.

This arrow type indicates a directed association relationship.

This arrow type indicates a generalization relationship. 

 

1.2.4 Property Table Notation

Throughout Section 3, tables are used to describe the properties of each data model class. Each property table consists of a column of names to identify the property, a type column to reflect the datatype of the property, a multiplicity column to reflect the allowed number of occurrences of the property, and a description column that describes the property. Package prefixes are provided for classes outside of the API Object data model (see Section 1.2.2). 

Note that if a class is a specialization of a superclass, only the properties that constitute the specialization are shown in the property table (i.e., properties of the superclass will not be shown). However, details of the superclass may be shown in the UML diagram.    

1.2.5 Property and Class Descriptions

Each class and property defined in CybOX is described using the format, “The X property verb Y.” For example, in the specification for the CybOX Core data model, we write, “The id property specifies a globally unique identifier for the Action.”  In fact, the verb “specifies” could have been replaced by any number of alternatives: “defines,” “describes,” “contains,” “references,” etc.

However, we thought that using a wide variety of verb phrases might confuse a reader of a specification document because the meaning of each verb could be interpreted slightly differently. On the other hand, we didn’t want to use a single, generic verb, such as “describes,” because although the different verb choices may or may not be meaningful from an implementation standpoint, a distinction could be useful to those interested in the modeling aspect of CybOX. 

Consequently, we have preferred to use the three verbs, defined as follows, in class and property descriptions:

Verb

CybOX Definition

captures

Used to record and preserve information without implying anything about the structure of a class or property. Often used for properties that encompass general content. This is the least precise of the three verbs.

 

Examples:

The Observable_Source property characterizes the source of the Observable information. Examples of details captured include identifying characteristics, time-related attributes, and a list of the tools used to collect the information.

The Description property captures a textual description of the Action.

characterizes

Describes the distinctive nature or features of a class or property. Often used to describe classes and properties that themselves comprise one or more other properties.

 

Examples:

The Action property characterizes a cyber observable Action.

The Obfuscation_Technique property characterizes a technique an attacker could potentially leverage to obfuscate the Observable.

specifies

Used to clearly and precisely identify particular instances or values associated with a property. Often used for properties that are defined by a controlled vocabulary or enumeration; typically used for properties that take on only a single value.

 

Example:

The cybox_major_version property specifies the major version of the CybOX language used for the set of Observables.

1.3 Terminology

The key words “MUST”, “MUST NOT”, “REQUIRED”, “SHALL”, “SHALL NOT”, “SHOULD”, “SHOULD NOT”, “RECOMMENDED”, “MAY”, and “OPTIONAL” in this document are to be interpreted as described in [RFC2119].

1.4 Normative References

[RFC2119]               Bradner, S., “Key words for use in RFCs to Indicate Requirement Levels”, BCP 14, RFC 2119, March 1997. http://www.ietf.org/rfc/rfc2119.txt.

2      Background Information

In this section, we provide high-level information about the API Object data model that is necessary to fully understand the specification details given in Section 3.

2.1 Cyber Observables

A cyber observable is a dynamic event or a stateful property that occurs, or may occur, in the operational cyber domain. Examples of stateful properties include the value of a registry key, the MD5 hash of a file, and an IP address. Examples of events include the deletion of a file, the receipt of an HTTP GET request, and the creation of a remote thread.

A cyber observable is different than a cyber indicator. A cyber observable is a statement of fact, capturing what was observed or could be observed in the cyber operational domain. Cyber indicators are cyber observable patterns, such as a registry key value associated with a known bad actor or a spoofed email address used on a particular date.

2.2 Objects

Cyber observable objects (Files, IP Addresses, etc) in CybOX are characterized with a combination of two levels of data models.

The first level is the Object data model which specifies a base set of properties universal to all types of Objects and enables them to integrate with the overall cyber observable framework specified in the CybOX Core data model.

The second level are the object property models which specify the properties of a particular type of Object via individual data models each focused on a particular cyber entity, such as a Windows registry key, or an Email Message. Accordingly, each release of the CybOX language includes a particular set of Objects that are part of the release. The data model for each of these Objects is defined by its own specification that describes the context-specific classes and properties that compose the Object.

Any specific instance of an Object is represented utilizing the particular object properties data model within the general Object data model.


3      Data Model

3.1 APIObjectType Class

The APIObjectType class is intended to characterize a specific Application Programming Interface. The UML diagram corresponding to the APIObjectType class is shown in Figure 3‑1.

Figure 3‑1. UML diagram of the APIObjectType class

The property table of the APIObjectType class is given in Table 3‑1.

Table 3‑1. Properties of the APIObjectType class

Name

Type

Multiplicity

Description

Description

cyboxCommon:StructuredTextType

0..1

The Description property captures a technical description of the APIObject. Any length is permitted. Optional formatting is supported via the structuring_format property of the StructuredTextType class.

Function_Name

cyboxCommon:

StringObjectPropertyType

0..1

The function_name property contains the exact name of the API function called, e.g., CreateFileEx.

Normalized_Function_Name

cyboxCommon:

StringObjectPropertyType

0..1

The normalized_function_name property contains the normalized name of the API function called, e.g., CreateFile.

Platform

cyboxCommon:

PlatformSpecificationType

0..1

The Platform property specifies the relevant platform for this API.

Address

cyboxCommon:

HexBinaryObjectPropertyType

0..1

The Address property contains the address of the API call in the binary.

 


4      Conformance

Implementations have discretion over which parts (components, properties, extensions, controlled vocabularies, etc.) of CybOX they implement (e.g., Observable/Object).

 

[1] Conformant implementations must conform to all normative structural specifications of the UML model or additional normative statements within this document that apply to the portions of CybOX they implement (e.g., implementers of the entire Observable class must conform to all normative structural specifications of the UML model regarding the Observable class or additional normative statements contained in the document that describes the Observable class).

 

 

[2] Conformant implementations are free to ignore normative structural specifications of the UML model or additional normative statements within this document that do not apply to the portions of CybOX they implement (e.g., non-implementers of any particular properties of the Observable class are free to ignore all normative structural specifications of the UML model regarding those properties of the Observable class or additional normative statements contained in the document that describes the Observable class).

 

The conformance section of this document is intentionally broad and attempts to reiterate what already exists in this document.

Appendix A. Acknowledgments

The following individuals have participated in the creation of this specification and are gratefully acknowledged.

Aetna

    David Crawford

AIT Austrian Institute of Technology

    Roman Fiedler

    Florian Skopik

Australia and New Zealand Banking Group (ANZ Bank)

    Dean Thompson

Blue Coat Systems, Inc.

    Owen Johnson

    Bret Jordan

Century Link

    Cory Kennedy

CIRCL

    Alexandre Dulaunoy

    Andras Iklody   

    Raphaël Vinot

Citrix Systems

    Joey Peloquin

Dell

    Will Urbanski

    Jeff Williams

DTCC

    Dan Brown

    Gordon Hundley

    Chris Koutras

EMC

    Robert Griffin

    Jeff Odom

    Ravi Sharda

Financial Services Information Sharing and Analysis Center (FS-ISAC)

    David Eilken

    Chris Ricard

Fortinet Inc.

    Gavin Chow

    Kenichi Terashita

Fujitsu Limited

    Neil Edwards

    Frederick Hirsch

    Ryusuke Masuoka

    Daisuke Murabayashi

Google Inc.

    Mark Risher

Hitachi, Ltd.

    Kazuo Noguchi

    Akihito Sawada

    Masato Terada

iboss, Inc.

    Paul Martini

Individual

    Jerome Athias

    Peter Brown

    Elysa Jones

    Sanjiv Kalkar

    Bar Lockwood

    Terry MacDonald

    Alex Pinto

Intel Corporation

    Tim Casey

    Kent Landfield

JPMorgan Chase Bank, N.A.

    Terrence Driscoll

    David Laurance

LookingGlass

    Allan Thomson

    Lee Vorthman

Mitre Corporation

    Greg Back

    Jonathan Baker

    Sean Barnum

    Desiree Beck

    Nicole Gong

    Jasen Jacobsen

    Ivan Kirillov

    Richard Piazza

    Jon Salwen

    Charles Schmidt

    Emmanuelle Vargas-Gonzalez

    John Wunder

National Council of ISACs (NCI)

    Scott Algeier

    Denise Anderson

    Josh Poster

NEC Corporation

    Takahiro Kakumaru

North American Energy Standards Board

    David Darnell

Object Management Group

    Cory Casanave

Palo Alto Networks

    Vishaal Hariprasad

Queralt, Inc.

    John Tolbert

Resilient Systems, Inc.

    Ted Julian

Securonix

    Igor Baikalov

Siemens AG

    Bernd Grobauer

Soltra

    John Anderson

    Aishwarya Asok Kumar

    Peter Ayasse

    Jeff Beekman

    Michael Butt

    Cynthia Camacho

    Aharon Chernin

    Mark Clancy

    Brady Cotton

    Trey Darley

    Mark Davidson

    Paul Dion

    Daniel Dye

    Robert Hutto

    Raymond Keckler

    Ali Khan

    Chris Kiehl

    Clayton Long

    Michael Pepin

    Natalie Suarez

    David Waters

    Benjamin Yates

Symantec Corp.

    Curtis Kostrosky

The Boeing Company

    Crystal Hayes

ThreatQuotient, Inc.

    Ryan Trost

U.S. Bank

    Mark Angel

    Brad Butts

    Brian Fay

    Mona Magathan

    Yevgen Sautin

US Department of Defense (DoD)

    James Bohling

    Eoghan Casey

    Gary Katz

    Jeffrey Mates

VeriSign

    Robert Coderre

    Kyle Maxwell

    Eric Osterweil     

Airbus Group SAS

    Joerg Eschweiler

    Marcos Orallo

Anomali

    Ryan Clough

    Wei Huang

    Hugh Njemanze

    Katie Pelusi

    Aaron Shelmire

    Jason Trost

Bank of America

    Alexander Foley

Center for Internet Security (CIS)

    Sarah Kelley

Check Point Software Technologies

    Ron Davidson

Cisco Systems

    Syam Appala

    Ted Bedwell

    David McGrew

    Pavan Reddy

    Omar Santos

    Jyoti Verma

Cyber Threat Intelligence Network, Inc. (CTIN)

    Doug DePeppe

    Jane Ginn

    Ben Othman

DHS Office of Cybersecurity and Communications (CS&C)

    Richard Struse

    Marlon Taylor

EclecticIQ

    Marko Dragoljevic

    Joep Gommers

    Sergey Polzunov

    Rutger Prins

    Andrei Sîrghi

    Raymon van der Velde

eSentire, Inc.

    Jacob Gajek

FireEye, Inc.

    Phillip Boles

    Pavan Gorakav

    Anuj Kumar

    Shyamal Pandya

    Paul Patrick

    Scott Shreve

Fox-IT

    Sarah Brown

Georgetown University

    Eric Burger

Hewlett Packard Enterprise (HPE)

    Tomas Sander

IBM

    Peter Allor

    Eldan Ben-Haim

    Sandra Hernandez

    Jason Keirstead

    John Morris

    Laura Rusu

    Ron Williams

IID

    Chris Richardson

Integrated Networking Technologies, Inc.

    Patrick Maroney

Johns Hopkins University Applied Physics Laboratory

    Karin Marr

    Julie Modlin

    Mark Moss

    Pamela Smith

Kaiser Permanente

    Russell Culpepper

    Beth Pumo

Lumeta Corporation

    Brandon Hoffman

MTG Management Consultants, LLC.

    James Cabral

National Security Agency

    Mike Boyle

    Jessica Fitzgerald-McKay

New Context Services, Inc.

    John-Mark Gurney

    Christian Hunt

    James Moler

    Daniel Riedel

    Andrew Storms

OASIS

    James Bryce Clark

    Robin Cover

    Chet Ensign

Open Identity Exchange

    Don Thibeau

PhishMe Inc.

    Josh Larkins

Raytheon Company-SAS

    Daniel Wyschogrod

Retail Cyber Intelligence Sharing Center (R-CISC)

    Brian Engle

Semper Fortis Solutions

    Joseph Brand

Splunk Inc.

    Cedric LeRoux

    Brian Luger

    Kathy Wang

TELUS

    Greg Reaume

    Alan Steer

Threat Intelligence Pty Ltd

    Tyron Miller

    Andrew van der Stock

ThreatConnect, Inc.

    Wade Baker

    Cole Iliff

    Andrew Pendergast

    Ben Schmoker

    Jason Spies

TruSTAR Technology

    Chris Roblee

United Kingdom Cabinet Office

    Iain Brown

    Adam Cooper

    Mike McLellan

    Chris O’Brien

    James Penman

    Howard Staple

    Chris Taylor

    Laurie Thomson

    Alastair Treharne

    Julian White

    Bethany Yates

US Department of Homeland Security

    Evette Maynard-Noel

    Justin Stekervetz

ViaSat, Inc.

    Lee Chieffalo

    Wilson Figueroa

    Andrew May

Yaana Technologies, LLC

    Anthony Rutkowski

 

The authors would also like to thank the larger CybOX Community for its input and help in reviewing this document.

 

Appendix B. Revision History

Revision

Date

Editor

Changes Made

wd01

15 December 2015

Desiree Beck Trey Darley Ivan Kirillov Rich Piazza

Initial transfer to OASIS template