research-article

Distributed Feature Composition: A Virtual Architecture for Telecommunications Services

Authors:

Michael Jackson,

Pamela ZaveAuthors Info & Claims

IEEE Transactions on Software Engineering, Volume 24, Issue 10

Pages 831 - 847

https://doi.org/10.1109/32.729683

Published: 01 October 1998 Publication History

Abstract

Distributed Feature Composition (DFC) is a new technology for feature specification and composition, based on a virtual architecture offering benefits analogous to those of a pipe-and-filter architecture. In the DFC architecture, customer calls are processed by dynamically assembled configurations of filter-like components: each component implements an applicable feature, and communicates with its neighbors by featureless internal calls that are connected by the underlying architectural substrate.

References

[1]

I. Aggoun and P. Combes, "Observers in the SCE and SEE to Detect and Resolve Service Interactions," P. Dini et al. eds, Feature Interactions in Telecommunication Networks, vol. 4, pp. 198-212. IOS Press, 1997.

[2]

P.K. Au and J.M. Atlee, "Evaluation of a State-Based Model of Feature Interactions," P. Dini et al., eds, Feature Interactions in Telecommunication Networks, vol. 4, pp. 153-167. IOS Press, 1997.

[3]

Feature Interactions in Telecommunications Systems, L.G. Bouma and H. Velthuijsen, eds. Amsterdam: IOS Press, 1994.

[4]

J. Blom B. Jonsson and L. Kempe, "Using Temporal Logic for Modular Specification of Telephone Services," {3}, pp. 197-216, 1994.

[5]

K.H. Braithwaite and J.M. Atlee, "Towards Automated Detection of Feature Interactions," {3}, pp. 36-59, 1994.

[6]

E.J. Cameron N.D. Griffeth Y.-J. Lin M.E. Nilson W.K. Schnure and H. Velthuijsen, "A Feature Interaction Benchmark for IN and Beyond," {3}, pp. 1-23, 1994.

[7]

Feature Interactions in Telecommunications Systems III, K.E. Cheng and T. Ohta, eds. Amsterdam: IOS Press, 1995.

[8]

P. Combes and S. Pickin, "Formalisation of a User View of Network and Services for Feature Interaction Detection," {3} pp. 120-135, 1994.

[9]

Feature Interactions in Telecommunication Networks, vol. 4, P. Dini, R. Boutaba, and L. Logrippo, eds. Amsterdam: IOS Press, 1997.

[10]

J.M. Duran and J. Visser, "International Standards for Intelligent Networks," IEEE Comm., vol. 30, no. 2, pp. 34-42, Feb. 1992.

Digital Library

[11]

A. Gammelgaard and J.E. Kristensen, "Interaction Detection, A Logical Approach. {3}, pp. 178-196, 1994.

[12]

D. Garlan and M. Shaw, "An Introduction to Software Architecture," V. Ambriola and G. Tortora, eds., Advances in Software Eng. and Knowledge Eng., pp. 1-39. World Scientific, 1993.

[13]

J.J. Garrahan P.A. Russo K. Kitami and R. Kung, "Intelligent Network Overview," IEEE Comm., vol. 31, no. 3, pp. 30-36, Mar. 1993.

Digital Library

[14]

N.D. Griffeth and Y.-J. Lin, "Extending Telecommunications Systems: The Feature-Interaction Problem," Computer, vol. 26, no. 8, pp. 14-18, Aug. 1993.

Digital Library

[15]

N.D. Griffeth and H. Velthuijsen, "The Negotiating Agents Approach to Runtime Feature Interaction Resolution," {3}, pp. 217-235, 1994.

[16]

G.J. Holzmann, "Design and Validation of Protocols: A Tutorial," Computer Networks and ISDN Systems, vol. 25, pp. 981-1,017, 1993.

Digital Library

[17]

F.J. Lin and Y.-J. Lin, "A Building Block Approach to Detecting and Resolving Feature Interactions," {3}, pp. 86-119, 1994.

[18]

J. Kamoun, "Formal Specification and Feature Interaction Detection in the Intelligent Network," Dept. of Computer Science, Univ. of Ottawa, Ontario, 1996.

[19]

T. Ohta and Y. Harada, "Classification, Detection and Resolution of Service Interactions in Telecommunication Services," {3}, pp. 60-72, 1994.

[20]

S. Tsang and E.H. Magill, "Behavior Based Run-Time Feature Interaction Detection and Resolution Approaches for Intelligent Networks," P. Dini et al., eds, Feature Interactions in Telecommunication Networks, vol. 4, pp. 254-270. IOS Press, 1997.

[21]

H. Velthuijsen, "Issues of Non-Monotonicity in Feature-Interaction Detection," K.E. Cheng and T. Ohta, eds, Feature Interactions in Telecommunications Systems, vol. 3, pp. 31-42. IOS Press, 1995.

[22]

M. Weiss T. Gray and A. Diaz, "Experiences with a Service Environment for Distributed Multimedia Applications," {9}, pp. 242-253, 1997.

[23]

J. Woodcock and J. Davies, Using Z: Specification, Refinement and Proof. Prentice Hall Int'l, 1996.

Digital Library

[24]

P. Zave, "Feature Interactions and Formal Specifications in Telecommunications," Computer, vol. 26, no. 8, pp. 20-30, Aug. 1993.

Digital Library

[25]

P. Zave and M. Jackson, "The DFC Virtual Architecture: Scenarios for Use and Plans for Future Work," AT&T Research Technical Memorandum HA6164000-971202-18TM, Murray Hill, N.J., Dec. 1997.

[26]

I. Zibman C. Woolf P. O'Reilly L. Strickland D. Willis and J. Visser, "Minimizing Feature Interactions: An Architecture and Processing Model Approach," {7}, pp. 65-83, 1995.

Cited By

Schröder MKevic KGopstein DMurphy BBeckmann JRoychoudhury ACadar CKim M(2022)Discovering feature flag interdependencies in Microsoft officeProceedings of the 30th ACM Joint European Software Engineering Conference and Symposium on the Foundations of Software Engineering10.1145/3540250.3558942(1419-1429)Online publication date: 7-Nov-2022
https://dl.acm.org/doi/10.1145/3540250.3558942
Meinicke JWong CVasilescu BKästner CRothermel GBae D(2020)Exploring differences and commonalities between feature flags and configuration optionsProceedings of the ACM/IEEE 42nd International Conference on Software Engineering: Software Engineering in Practice10.1145/3377813.3381366(233-242)Online publication date: 27-Jun-2020
https://dl.acm.org/doi/10.1145/3377813.3381366
Trimananda RAqajari SChuang JDemsky BXu GLu SDevanbu PCohen MZimmermann T(2020)Understanding and automatically detecting conflicting interactions between smart home IoT applicationsProceedings of the 28th ACM Joint Meeting on European Software Engineering Conference and Symposium on the Foundations of Software Engineering10.1145/3368089.3409682(1215-1227)Online publication date: 8-Nov-2020
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Distributed Feature Composition: A Virtual Architecture for Telecommunications Services

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Information

Published In

cover image IEEE Transactions on Software Engineering

IEEE Transactions on Software Engineering Volume 24, Issue 10

October 1998

126 pages

ISSN:0098-5589

Editor:
Richard A. Kemmerer
Univ. of California, Santa Barbara

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Copyright © Copyright © 1998 IEEE. All Rights Reserved.

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IEEE Press

Publication History

Published: 01 October 1998

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Cited By

Schröder MKevic KGopstein DMurphy BBeckmann JRoychoudhury ACadar CKim M(2022)Discovering feature flag interdependencies in Microsoft officeProceedings of the 30th ACM Joint European Software Engineering Conference and Symposium on the Foundations of Software Engineering10.1145/3540250.3558942(1419-1429)Online publication date: 7-Nov-2022
https://dl.acm.org/doi/10.1145/3540250.3558942
Meinicke JWong CVasilescu BKästner CRothermel GBae D(2020)Exploring differences and commonalities between feature flags and configuration optionsProceedings of the ACM/IEEE 42nd International Conference on Software Engineering: Software Engineering in Practice10.1145/3377813.3381366(233-242)Online publication date: 27-Jun-2020
https://dl.acm.org/doi/10.1145/3377813.3381366
Trimananda RAqajari SChuang JDemsky BXu GLu SDevanbu PCohen MZimmermann T(2020)Understanding and automatically detecting conflicting interactions between smart home IoT applicationsProceedings of the 28th ACM Joint Meeting on European Software Engineering Conference and Symposium on the Foundations of Software Engineering10.1145/3368089.3409682(1215-1227)Online publication date: 8-Nov-2020
https://dl.acm.org/doi/10.1145/3368089.3409682
Reiss S(2019)IoT end user programming modelsProceedings of the 1st International Workshop on Software Engineering Research & Practices for the Internet of Things10.1109/SERP4IoT.2019.00008(1-8)Online publication date: 27-May-2019
https://dl.acm.org/doi/10.1109/SERP4IoT.2019.00008
Reineke JStergiou CTripakis S(2019)Basic problems in multi-view modelingSoftware and Systems Modeling (SoSyM)10.1007/s10270-017-0638-118:3(1577-1611)Online publication date: 1-Jun-2019
https://dl.acm.org/doi/10.1007/s10270-017-0638-1
Al-Hajjaji MThüm TLochau MMeinicke JSaake G(2019)Effective product-line testing using similarity-based product prioritizationSoftware and Systems Modeling (SoSyM)10.1007/s10270-016-0569-218:1(499-521)Online publication date: 1-Feb-2019
https://dl.acm.org/doi/10.1007/s10270-016-0569-2
Abdessalem RPanichella ANejati SBriand LStifter THuchard MKästner CFraser G(2018)Testing autonomous cars for feature interaction failures using many-objective searchProceedings of the 33rd ACM/IEEE International Conference on Automated Software Engineering10.1145/3238147.3238192(143-154)Online publication date: 3-Sep-2018
https://dl.acm.org/doi/10.1145/3238147.3238192
Kaminski TVan Wyk ECombemale BMernik MRumpe B(2017)Ensuring non-interference of composable language extensionsProceedings of the 10th ACM SIGPLAN International Conference on Software Language Engineering10.1145/3136014.3136023(163-174)Online publication date: 23-Oct-2017
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Zibaeenejad MZhang CAtlee JBodden ESchäfer WDeursen AZisman A(2017)Continuous variable-specific resolutions of feature interactionsProceedings of the 2017 11th Joint Meeting on Foundations of Software Engineering10.1145/3106237.3106302(408-418)Online publication date: 21-Aug-2017
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Al-Hajjaji MMeinicke JKrieter SSchröter RThüm TLeich TSaake G(2016)Tool demo: testing configurable systems with FeatureIDEACM SIGPLAN Notices10.1145/3093335.299325452:3(173-177)Online publication date: 20-Oct-2016
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