In the context of software-defined networking
(SDN), we address a variant of the controller placement
problem (CPP), which takes into account the network
robustness at both control and data plane levels. For given
maximum values of switch-controller and controller-controller
delays at the regular state (i.e., when the network is fully
operational), the aim is to maximize the network robustness
against a set of failure states, each state defined as a possible
malicious attack to multiple nodes. We assume that the
attacker knows the data plane topology and, therefore, can
adopt either one of three commonly considered node centrality
attacks (based on the node degree, closeness or betweenness
centralities), or an attack to the nodes which are the optimal
solution of the critical node detection (CND) problem. We
propose a set of robustness metrics which are used to obtain
the optimal solutions for the robust CPP variant. We present a
set of computational results comparing the average delays and
robustness values of the robust CPP solutions against those
minimizing only the average switch-controller and controller-controller
delays. Moreover, the influence of using the CND
based attack in the robustness evaluation of CPP solutions is
also assessed in the computational results.
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In the context of software-defined networking
(SDN), we address a variant of the controller placement
problem (CPP), which takes into account the network
robustness at both control and data plane levels. For given
maximum values of switch-controller and controller-controller
delays at the regular state (i.e., when the network is fully
operational), the aim is to maximize the network robustness
against a set of failure states, each state defined as a possible
malicious attack to multiple...
»