Due to the rich diversity of the architectures, miktoarm star polymers possess the ability of directed self-assembly into various morphologies which have potential applications for nanolithography. In this study, many-body dissipative particle dynamics is used to explore the microstructure and the stability of the thin film formed by the ABC miktoarm star terpolymers on substrate surfaces. The effects of attraction interaction between a polymer and the substrate and the conformation of miktoarm star polymers on the behavior of the thin film are also investigated. For a polymer melt spread on a nonselective substrate surface, different ordered structures such as lamellae and Archimedean-tiling patterns are discovered as the conformations of miktoarm star polymers varies. Polymer films on selective substrate surfaces can exhibit microstructures that are distinct from those formed on the nonselective substrate surface. In order to examine the stability of the polymer thin films, a dry hole is imposed on it. Three types of scenarios are identified, (i) self-healing, (ii) stable hole, and (iii) nucleation and growth. The outcome depends on the radius of the dry hole, the conformation of miktoarm star polymer, and the surface interaction. Finally, we also study the effect of the polymer brushes on the morphological behaviors of the polymer thin film . By altering the composition of the polymer brushes, it is possible to manipulate the surfaces to mimic the affinity of nonselective or selective substrates.