FORMAL METHODS IN NETWORK VERIFICATION: A SURVEY OF TECHNIQUES, TOOLS, AND FUTURE DIRECTIONS

Software-Defined Networking (SDN) (NFN), Network Function Virtualisation (NFV), and large-scale cloud
infrastructures are examples of contemporary networking technologies that are gaining popularity. Such technologies have
demonstrated the weaknesses of conventional testing and simulation techniques which often fail to ensure security, scalability or
even accuracy. Formal techniques offer a mathematically rigorous, principle-based rationale for the conduct of a network, enabling
protocols, configurations, and policies to be modelled, analysed, and verified. Formal verification explores all possible system
states to guarantee attributes such as safety, liveness, reachability, and isolation, unlike heuristic methods. This review covers
model checking, theorem proving, symbolic execution, static analysis, and hybrid methods, and provides a structured account of
key formal verification methods. Also, it considers popular tools and models such as VeriFlow, NetKAT, Header Space Analysis,
and Batfish, as well as general-purpose provers such as Coq, Isabelle, and HOL. These tools have proven effective at identifying
misconfigurations, routing loops, black holes, and policy inconsistencies across various network settings. The SDN, NFV, and
security policy enforcement are just a few applications where formal methods have demonstrated usefulness in terms of reliability
and correctness guarantees. By amalgamating theoretical background and tool-perspective, the current piece demonstrates the
necessity of formal approaches for promoting safe, reliable, and high-efficiency networked systems.