Organic and inorganic hybrid perovskites have attracted significant attentions due to their impressive optoelectronic properties. MAPbBr(3), one of the most popular members in MAPbX(3) (MA = methyl ammonium and X = Cl, Br, I) family, is considered as new generation optoelectronic materials, especially in the field of solar cells. Compared to polycrystalline films, MAPbBr(3) single crystal is deemed more ideal for optoelectronic device because of fewer grain boundaries. To realize a controlled crystal growth, a thorough understanding of its growth mechanism, especially the role of surface structures played in growth kinetics, is of paramount importance. In this paper, hillocks on (100) facet of MAPbBr(3) crystal were observed using atomic force microscopy when grown from N-dimethylformamide (DMF) solution. The results revealed that the growth of (100) facet was controlled by 2D nucleation at low concentration, which derived plenty of elementary steps whose height was about 0.59 nm, equivalent to one unit cell. Then the growth transferred to step flow model along [011] direction. Step flow ceased when encountering holes on the terraces. The optical morphologies validated that cubic plates were prone to growing along [011] directions, which were in a layer-by-layer model. Moreover, the temperature reverse solubility of MAPbBr(3) in DMF solution was measured. In terms of the solubility and growth mechanism of MAPbBr(3), a series of MAPbBr(3) single crystals were successfully grown from thin cubic plates to thick and perfect cubes via temperature controlling rising method ultimately.