China has suffered some of the effects of global warming, and one of the potential implications of climate warming is the alteration of the temporal-spatial patterns of water resources. Based on the long-term (1960–2012) water budget data and climate projections from 28 Global Climate Models (GCMs) of the Coupled Model Intercomparison Project Phase 5 (CMIP5), this study investigated the responses of runoff (<i>R</i>) to historical and future climate variability in China at both grid and catchment scales using the Budyko-based elasticity method. Results show that there is a large spatial variation in precipitation (<i>P</i>) elasticity (from 1.2 to 3.3) and potential evaporation (<i>PET</i>) elasticity (from −2.3 to −0.2) across China. The <i>P</i> elasticity is larger in northeast and western China than in southern China, while the opposite occurs for PET elasticity. The catchment properties elasticity of <i>R</i> appears to have a strong non-linear relationship with the mean annual aridity index and tends to be more significant in more arid regions. For the period 1960–2012, the climate contribution to <i>R</i> ranges from −2.4 % a<sup>−1</sup> to 3.3 % a<sup>−1</sup> across China, with the negative contribution in the North China plain and the positive contribution in western China and some parts of the southwest. The results of climate projections indicate that although there is large uncertainty involved in the 28 GCMs, most project a consistent change in <i>P</i> (or <i>PET</i>) in China at the annual scale. For the period 2071–2100, the mean annual <i>P</i> will likely increase in most parts of China, especially the western regions, while the mean annual <i>PET</i> will likely increase in all of China, particularly the southern regions. Furthermore, greater increases are projected for higher emission scenarios. Overall, due to climate change, the arid regions and humid regions of China will likely become wetter and drier in the period 2071–2100, respectively (relative to the baseline 1971–2000).