郭肇强  等:基于信息检索的缺陷定位:问题、进展与挑战                                                      2851


         [65]    Youm KC, Ahn J, Kim J, Lee E. Bug localization based on code changes histories and bug reports. In: Proc. of the Asia-Pacific
             Software Engineering Conf. 2015. 190−197. [doi: 10.1109/APSEC.2015.23]
         [66]    Thomas  SW, Nagappan M, Blostein D, Hassan AE.  The  impact  of classifier configuration and classifier combination  on  bug
             localization. IEEE Trans. on Software Engineering, 2013,39(10):1427−1443. [doi: 10.1109/TSE.2013.27]
         [67]    Hoang T, Oentaryo RJ, Le TDB, Lo D. Network-Clustered multi-modal bug localization. IEEE Trans. on Software Engineering,
             2019, 45(10):1002−1023. [doi: 10.1109/TSE.2018.2810892]
         [68]    Koyuncu A, Bissyande TF, Kim DS, Liu K, Klein J, Monperrus M, Traon YL. D&C: A divide-and-conquer approach to IR-based
             bug localization. arXiv Preprint arXiv:1902.02703, 2019
         [69]    Huo X, Thung F, Li M, Lo D, Shi ST. Deep transfer bug localization. IEEE Trans. on Software Engineering, 2019:1−12. [doi:
             10.1109/ TSE.2019.2920771]
         [70]    Zimmermann T, Premraj R, Bettenburg N, Just S, Schröter A, Weiss C. What makes a good bug report? IEEE Trans. on Software
             Engineering, 2010,36(5):618−643. [doi: 10.1109/TSE.2010.63]
         [71]    Kim DS, Tao YD, Kim SH, Zeller A. Where should we fix this bug? A two-phase recommendation model. IEEE Trans. on Software
             Engineering, 2013,39(11):1597−1610. [doi: 10.1109/TSE.2013.24]
         [72]    Le TDB, Thung F, Lo D. Will this localization tool be effective for this bug? Mitigating the impact of unreliability of information
             retrieval based bug localization tools. Empirical Software Engineering, 2017,22(4): 2237−2279. [doi: 10.1007/s10664-016-9484-y]
         [73]    Chaparro  O, Florez JM,  Marcus  A.  Using bug descriptions to reformulate queries during text-retrieval-based bug localization.
             Empirical Software Engineering, 2019,25(4):2947−3007. [doi: 10.1007/s10664-018-9672-z]
         [74]    Youm KC, Ahn J, Lee E. Improved bug localization based on code change histories and bug reports. Information and Software
             Technology, 2017,82:177−192. [doi: 10.1016/j.infsof.2016.11.002]
         [75]    Khatiwada S,  Tushev M, Mahmoud A. Just  enough semantics:  An information theoretic  approach for IR-based software bug
             localization. Information and Software Technology, 2018,93:45−57. [doi: 10.1016/j.infsof.2017.08.012]
         [76]    Tantithamthavorn  C, Abebe SL,  Hassan  AE, Ihara A,  Matsumoto  K.  The impact of IR-based  classifier  configuration on the
             performance  and the  effort of  method-level bug localization. Information  and Software  Technology, 2018,102:160−174. [doi:
             10.1016/j.infsof.2018.06.001]
         [77]    Xiao Y, Keung J, Bennin KE, Mi Q. Improving bug localization with word embedding and enhanced convolutional neural networks.
             Information and Software Technology, 2019,105:17−29. [doi: 10.1016/j.infsof.2018.08.002]
         [78]    Zhang W, Li ZQ, Wang Q, Li J. FineLocator: A novel approach to method-level fine-grained bug localization by query expansion.
             Information and Software Technology, 2019,110:121−135. [doi: 10.1016/j.infsof.2019.03.001]
         [79]    Dilshener T, Wermelinger M, Yu YJ. Locating bugs without looking back. Automated Software Engineering, 2018,25(3):383−434.
             [doi: 10.1007/s10515-017-0226-1]
         [80]    Wang SW, Lo D. AmaLgam+: Composing rich information sources for accurate bug localization. Journal of Software: Evolution
             and Process, 2016,28(10):921−942. [doi: 10.1002/smr.1801]
         [81]    Dit  B,  Revelle M,  Gethers M, Poshyvanyk  D. Feature location  in source  code:  A  taxonomy  and survey. Journal of Software:
             Evolution and Process, 2013:53−95. [doi: 10.1002/smr.567]
         [82]    Arcega L,  Font  J, Haugen Ø, Cetina C. An approach  for  bug  localization  in models  using  two  levels: Model and metamodel.
             Software and Systems Modeling, 2019,18(6):3551−3576. [doi: 10.1007/s10270-019-00727-y]
         [83]    Rath M, Rempel P, Mader P. The IlmSeven dataset. In: Proc. of the Int’l Requirements Engineering Conf. 2017. 516−519. [doi:
             10.1109/RE.2017.18]
         [84]    Rath  M,  Mäder P. Structured information  in bug report descriptions—Influence on IR-based bug localization  and developers.
             Software Quality Journal, 2019,27(3):1315−1337. [doi: 10.1007/s11219-019-09445-6]
         [85]    Chen  IX, Li CH, Yang CZ. Mining co-location  relationships among  bug reports  to  localize  fault-prone modules.  IEICE
             Transactions on Information and Systems, 2011,93-D(5):1154−1161. [doi: 10.1587/transinf.E93.D.1154]
         [86]    Le TDB, Thung F, Lo D. Predicting effectiveness of IR-based bug localization techniques. In: Proc. of the Int’l Symp. on Software
             Reliability Engineering. 2014. 335−345. [doi: 10.1109/ISSRE.2014.39]