2,487 research outputs found
Code smells detection and visualization: A systematic literature review
Context: Code smells (CS) tend to compromise software quality and also demand
more effort by developers to maintain and evolve the application throughout its
life-cycle. They have long been catalogued with corresponding mitigating
solutions called refactoring operations. Objective: This SLR has a twofold
goal: the first is to identify the main code smells detection techniques and
tools discussed in the literature, and the second is to analyze to which extent
visual techniques have been applied to support the former. Method: Over 83
primary studies indexed in major scientific repositories were identified by our
search string in this SLR. Then, following existing best practices for
secondary studies, we applied inclusion/exclusion criteria to select the most
relevant works, extract their features and classify them. Results: We found
that the most commonly used approaches to code smells detection are
search-based (30.1%), and metric-based (24.1%). Most of the studies (83.1%) use
open-source software, with the Java language occupying the first position
(77.1%). In terms of code smells, God Class (51.8%), Feature Envy (33.7%), and
Long Method (26.5%) are the most covered ones. Machine learning techniques are
used in 35% of the studies. Around 80% of the studies only detect code smells,
without providing visualization techniques. In visualization-based approaches
several methods are used, such as: city metaphors, 3D visualization techniques.
Conclusions: We confirm that the detection of CS is a non trivial task, and
there is still a lot of work to be done in terms of: reducing the subjectivity
associated with the definition and detection of CS; increasing the diversity of
detected CS and of supported programming languages; constructing and sharing
oracles and datasets to facilitate the replication of CS detection and
visualization techniques validation experiments.Comment: submitted to ARC
30 Years of Software Refactoring Research:A Systematic Literature Review
Due to the growing complexity of software systems, there has been a dramatic
increase and industry demand for tools and techniques on software refactoring
in the last ten years, defined traditionally as a set of program
transformations intended to improve the system design while preserving the
behavior. Refactoring studies are expanded beyond code-level restructuring to
be applied at different levels (architecture, model, requirements, etc.),
adopted in many domains beyond the object-oriented paradigm (cloud computing,
mobile, web, etc.), used in industrial settings and considered objectives
beyond improving the design to include other non-functional requirements (e.g.,
improve performance, security, etc.). Thus, challenges to be addressed by
refactoring work are, nowadays, beyond code transformation to include, but not
limited to, scheduling the opportune time to carry refactoring, recommendations
of specific refactoring activities, detection of refactoring opportunities, and
testing the correctness of applied refactorings. Therefore, the refactoring
research efforts are fragmented over several research communities, various
domains, and objectives. To structure the field and existing research results,
this paper provides a systematic literature review and analyzes the results of
3183 research papers on refactoring covering the last three decades to offer
the most scalable and comprehensive literature review of existing refactoring
research studies. Based on this survey, we created a taxonomy to classify the
existing research, identified research trends, and highlighted gaps in the
literature and avenues for further research.Comment: 23 page
30 Years of Software Refactoring Research: A Systematic Literature Review
Peer Reviewedhttps://deepblue.lib.umich.edu/bitstream/2027.42/155872/4/30YRefactoring.pd
Code smells detection and visualization: A systematic literature review
Context: Code smells (CS) tend to compromise software quality and also demand more effort by developers to maintain and evolve the application throughout its life-cycle. They have long been cataloged with corresponding mitigating solutions called refactoring operations. Objective: This SLR has a twofold goal: the first is to identify the main code smells detection techniques and tools discussed in the literature, and the second is to analyze to which extent visual techniques have been applied to support the former. Method: Over 83 primary studies indexed in major scientific repositories were identified by our search string in this SLR. Then, following existing best practices for secondary studies, we applied inclusion/exclusion criteria to select the most relevant works, extract their features and classify them. Results: We found that the most commonly used approaches to code smells detection are search-based (30.1%), and metric-based (24.1%). Most of the studies (83.1%) use open-source software, with the Java language occupying the first position (77.1%). In terms of code smells, God Class (51.8%), Feature Envy (33.7%), and Long Method (26.5%) are the most covered ones. Machine learning techniques are used in 35% of the studies. Around 80% of the studies only detect code smells, without providing visualization techniques. In visualization-based approaches, several methods are used, such as city metaphors, 3D visualization techniques. Conclusions: We confirm that the detection of CS is a non-trivial task, and there is still a lot of work to be done in terms of: reducing the subjectivity associated with the definition and detection of CS; increasing the diversity of detected CS and of supported programming languages; constructing and sharing oracles and datasets to facilitate the replication of CS detection and visualization techniques validation experiments.info:eu-repo/semantics/acceptedVersio
Grand Challenges of Traceability: The Next Ten Years
In 2007, the software and systems traceability community met at the first
Natural Bridge symposium on the Grand Challenges of Traceability to establish
and address research goals for achieving effective, trustworthy, and ubiquitous
traceability. Ten years later, in 2017, the community came together to evaluate
a decade of progress towards achieving these goals. These proceedings document
some of that progress. They include a series of short position papers,
representing current work in the community organized across four process axes
of traceability practice. The sessions covered topics from Trace Strategizing,
Trace Link Creation and Evolution, Trace Link Usage, real-world applications of
Traceability, and Traceability Datasets and benchmarks. Two breakout groups
focused on the importance of creating and sharing traceability datasets within
the research community, and discussed challenges related to the adoption of
tracing techniques in industrial practice. Members of the research community
are engaged in many active, ongoing, and impactful research projects. Our hope
is that ten years from now we will be able to look back at a productive decade
of research and claim that we have achieved the overarching Grand Challenge of
Traceability, which seeks for traceability to be always present, built into the
engineering process, and for it to have "effectively disappeared without a
trace". We hope that others will see the potential that traceability has for
empowering software and systems engineers to develop higher-quality products at
increasing levels of complexity and scale, and that they will join the active
community of Software and Systems traceability researchers as we move forward
into the next decade of research
Grand Challenges of Traceability: The Next Ten Years
In 2007, the software and systems traceability community met at the first
Natural Bridge symposium on the Grand Challenges of Traceability to establish
and address research goals for achieving effective, trustworthy, and ubiquitous
traceability. Ten years later, in 2017, the community came together to evaluate
a decade of progress towards achieving these goals. These proceedings document
some of that progress. They include a series of short position papers,
representing current work in the community organized across four process axes
of traceability practice. The sessions covered topics from Trace Strategizing,
Trace Link Creation and Evolution, Trace Link Usage, real-world applications of
Traceability, and Traceability Datasets and benchmarks. Two breakout groups
focused on the importance of creating and sharing traceability datasets within
the research community, and discussed challenges related to the adoption of
tracing techniques in industrial practice. Members of the research community
are engaged in many active, ongoing, and impactful research projects. Our hope
is that ten years from now we will be able to look back at a productive decade
of research and claim that we have achieved the overarching Grand Challenge of
Traceability, which seeks for traceability to be always present, built into the
engineering process, and for it to have "effectively disappeared without a
trace". We hope that others will see the potential that traceability has for
empowering software and systems engineers to develop higher-quality products at
increasing levels of complexity and scale, and that they will join the active
community of Software and Systems traceability researchers as we move forward
into the next decade of research
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