How Do Developers React to API Evolution? The Pharo Ecosystem Case (ICSME 2015)

Transcript

1. How Do Developers React to API Evolution? The Pharo Ecosystem

   Case André Hora, Romain Robbes, Nicolas Anquetil, Anne Etien, Stéphane Ducasse, Marco Tulio Valente ! ! ! ! ! ICSME, 2015

2. Outline • Context and Problem! • Goal and Research Questions

   • Experiment Design • Experiment Results • Summary and Implications 2

3. Software Evolution In software development, change is the only constant

   New features, bug-fixes, code refactoring Up to 90% of development cost [Pigoski, 1997; Erlikh, 2000] 3

4. 4 Software Evolution: Theory Good practices Backward-compatibility Deprecation with helpful

   messages

5. 5 Software Evolution: Practice Good practices In practice Backward-compatibility Deprecation

   with helpful messages ✖ ✖ [Balaban et al., 2005; Dig e Johnson, 2006; Wu et al., 2010] [Robbes et al., 2012; Brito et al., 2015]

6. API Evolution and Ripple Effect • In Eclipse, 42% of

   the methods in version 1.0 were not in 2.0 [Mileva et al., 2011] • Eclipse clients are impacted 6 “The class StatusDialog has been removed instead of just marked as deprecated. This causes the deployment dialog of the JBoss IDE plugin to fail” Eclipse Issue 103775

7. API Evolution on Ecosystems 7 In this context, managing software

   evolution is a complex and risky task

8. Outline • Context and Problem • Goal and Research Questions!

   • Experiment Design • Experiment Results • Summary and Implications 8

9. Goal To understand:! The real extension of API evolution impact

   How the impact can be alleviated 9

10. Research Questions • RQ1 (Extension): How many systems are affected

    by API changes in an ecosystem? • RQ2 (Magnitude): How many systems react to API changes in an ecosystem? • RQ3 (Duration): How long does it take for systems to react to API changes? • RQ4 (Consistency): Do systems react to an API change in the same way? 10

11. Outline • Context and Problem • Goal and Research Questions

    • Experiment Design! • Experiment Results • Summary and Implications 11

12. Ecosystem Impact Analysis 12 Libraries API changes Clients

13. Ecosystem Impact Analysis 13 Libraries API changes Clients Method replacement

    and improvement Pharo Core Libs Pharo Ecosystem

14. 14 Clear inclusion criteria Comparison with API deprecation Relevant: 3588

    systems, 2874 contributors Equivalent to Java’s JDK! Collections, files, sockets, unit tests, streams, exceptions, graphical interfaces, etc 4 releases, avg 424 KLOC Pharo Ecosystem Pharo Core Libs

15. API Changes 15 old() is replaced by new() ClassOrganizer.default() →

    Protocol.unclassified() 59 method replacements bad() should be replaced by good() ProtoObject.isNil() + Boolean.ifTrue() → ProtoObject.ifNil()! 59 method improvements Method replacement Method improvement

16. API Changes 16 old() is replaced by new() ClassOrganizer.default() →

    Protocol.unclassified() 59 method replacements bad() should be replaced by good() ProtoObject.isNil() + Boolean.ifTrue() → ProtoObject.ifNil()! 59 method improvements Method replacement Method improvement Not about ! API deprecation!!!! [Robbes et al., 2012]

17. Ecosystem Impact Analysis 17 Method replacement and improvement Pharo Core

    Libs Pharo Ecosystem 4 releases 118 API changes 3588 systems

18. Outline • Context and Problem • Goal and Research Questions

    • Experiment Design • Experiment Results! • Summary and Implications 18

19. Results: Extension RQ1 How many systems are affected by API

    changes in the ecosystem? • 61% of systems are affected by API changes • 2,188 systems, 107,549 methods, 1,579 developers 19 affected systems 56 isNil().ifTrue()

20. Results: Magnitude RQ2 How many systems react to API changes

    in the ecosystem? • 8% of systems reacted to API changes • 178 systems, 796 methods, 134 developers • Number of affected systems is higher than reacting systems 20 reacting systems 2 isNil().ifTrue() → ifNil()

21. Results: Magnitude RQ2 How many systems react to API changes

    in the ecosystem? • 8% of systems reacted to API changes • 178 systems, 796 methods, 134 developers • Number of affected systems is higher than reacting systems 21 reacting systems affected systems reacting / affected 2 56 2.5 =

22. Results: Duration RQ3: How long does it take for systems

    to react to API changes? • Median: 34 days (Pharo is a dynamically typed language) • Reaction time for method improvements is longer (47 x 20 days) 22 reacting time improvement x replacement 34 47 20

23. Outline • Context and Problem • Goal and Research Questions

    • Experiment Design • Experiment Results • Summary and Implications 23

24. Summary • 61% of systems are affected by API changes

    • Only 8% of the systems reacted to API changes • Reaction time is not quick (34 days) • Longer for method improvement (47 x 20 days) 24

25. Implications • Deprecation opportunities are missed by developers. Recommenders can

    be built to remind API developers about them. • Reactions to API changes can be partially automated. Most of the API changes can be implemented as rules in static analysis tools. • API changes are not resolved in uniform manner in the ecosystem. Libraries are a more reliable API change extraction source. 25

26. 26 How Do Developers React to API Evolution? The Pharo

    Ecosystem Case