A comprehensive understanding of glass structure is critical for the design and optimization of advanced functional materials. Unlike crystalline materials, glasses lack long-range order, making it difficult to characterize their atomic structure using conventional experimental or theoretical approaches alone. Over the years, various structural models―such as those developed for predicting the structure of sodium borosilicate glasses, frameworks describing the coordination environment of boron and silicon units, and classifications of network formers, modifiers, and intermediates―have been proposed to describe glass structure, each capturing different aspects of atomic connectivity and medium-range order in multi-component systems. However, these models are often limited in their ability to predict structural features across diverse compositions, particularly in multi-component glass systems. To overcome these limitations, molecular dynamics (MD) simulation has become a powerful computational method, enabling atomistic modeling of short- and medium-range order. The accuracy of MD simulations depends critically on the selection of appropriate forcefields, interatomic potential parameters, integration algorithms, and thermodynamic ensembles. This review outlines these foundational elements and evaluates how each contributes to the physical reliability and predictive power of simulation outcomes in glass research.Furthermore, we review the structure of oxyfluoride glasses by MD simulations, focusing on multi-component systems containing BaF2, BaO, La2O3, and B2O3. Simulation results show that increasing fluoride content leads to a higher fraction of BO4 units (N4), a decrease in non-bridging oxygen (NBO) populations, redistribution of Q units, and a reduction in network ring sizes.