dc.description.abstract | In software engineering there are many expensive tasks that are performed during development
and maintenance activities. Therefore, there has been a lot of e ort to try to automate these
tasks in order to signi cantly reduce the development and maintenance cost of software, since
the automation would require less human resources. One of the most used way to make such
an automation is the Search-Based Software Engineering (SBSE), which reformulates traditional
software engineering tasks as search problems. In SBSE the set of all candidate solutions to the
problem de nes the search space while a tness function di erentiates between candidate solutions
providing a guidance to the optimization process. After the reformulation of software engineering
tasks as optimization problems, search algorithms are used to solve them. Several search algorithms
have been used in literature, such as genetic algorithms, genetic programming, simulated annealing,
hill climbing (gradient descent), greedy algorithms, particle swarm and ant colony.
This thesis investigates and proposes the usage of search based approaches to reduce the e ort
of software maintenance and software testing with particular attention to four main activities: (i)
program comprehension; (ii) defect prediction; (iii) test data generation and (iv) test suite optimiza-
tion for regression testing. For program comprehension and defect prediction, this thesis provided
their rst formulations as optimization problems and then proposed the usage of genetic algorithms
to solve them. More precisely, this thesis investigates the peculiarity of source code against textual
documents written in natural language and proposes the usage of Genetic Algorithms (GAs) in
order to calibrate and assemble IR-techniques for di erent software engineering tasks. This thesis
also investigates and proposes the usage of Multi-Objective Genetic Algorithms (MOGAs) in or-
der to build multi-objective defect prediction models that allows to identify defect-prone software
components by taking into account multiple and practical software engineering criteria.
Test data generation and test suite optimization have been extensively investigated as search-
based problems in literature . However, despite the huge body of works on search algorithms
applied to software testing, both (i) automatic test data generation and (ii) test suite optimization
present several limitations and not always produce satisfying results. The success of evolutionary
software testing techniques in general, and GAs in particular, depends on several factors. One of
these factors is the level of diversity among the individuals in the population, which directly a ects
the exploration ability of the search. For example, evolutionary test case generation techniques that
employ GAs could be severely a ected by genetic drift, i.e., a loss of diversity between solutions,
which lead to a premature convergence of GAs towards some local optima. For these reasons,
this thesis investigate the role played by diversity preserving mechanisms on the performance of
GAs and proposed a novel diversity mechanism based on Singular Value Decomposition and linear
algebra. Then, this mechanism has been integrated within the standard GAs and evaluated for
evolutionary test data generation. It has been also integrated within MOGAs and empirically
evaluated for regression testing. [edited by author] | en_US |