In this paper we develop a two-dimensional modelling framework suitable to study the morphological evolution of vegetated braided rivers. The mathematical model features a unisize-sediment morphological model, which includes accounting for bank erosion, and a vegetation model. While these model components had already appeared separately in different contexts, here we improve and tailor them for modelling vegetated braided river dynamics. We implement a numerical solution to this problem in the framework of the pre-existing morphological model GIAMT2D. We devise a hydrograph-splitting technique to avoid excessive run times in the multi-decadal applications needed to appreciate vegetation-driven morphological change. This hydrograph-splitting technique uses the full model to solve for flood periods, while applying a fixed-bed approximation and only updating vegetation density during low-flow periods. Finally, we apply the developed formulation, tools and techniques to simulate an idealised reach of the Lower Waitaki River (Aotearoa – New Zealand), where we reproduce vegetation encroachment and morphological change observed between 1936 and 1964.