Supermassive black holes (BHs) at the centres of galaxies can rapidly change their mass and spin by gas accretion and mergers. Using hydrodynamical cosmological simulations, with prescriptions for BH growth and feedback from active galactic nuclei, we study how the evolution of BH mass growth is driven by gas accretion and mergers. Using a semi-analytical approach to evolve spins, we also highlight the mechanisms responsible for driving the magnitude and the direction of spins as a function of cosmic time. We find that in the high-redshift universe galaxies maintain large values of gas accretion on to BHs, which therefore is the main driver of their mass and spin evolution. Sustained accretion of cold gas at high redshift tends to align BH spins with the angular momentum of the surrounding gas and maximize their magnitude. Conversely, at low redshift, as BHs get more massive and galaxies more gas poor, the contribution from binary coalescences to the total BH mass growth increases, especially at the high-mass end, and tends to decrease the magnitude of spins and change their direction.