Under global climate changes, extreme hydrological events, such as drought and flood, occurred more frequently in Taiwan, which both events can induce water supply problems. During flood events, a flood carries loose stones to a reservoir and increase water turbidity. The high turbidity then reduces the water treatment efficiency and causes water deficit problems. Moreover, the uncertainties of hydrological conditions make water allocation more difficult. It is essentially a stochastic problem and both the drought and flood conditions should be considered simultaneously. However, most of the previous studies investigate the water deficit problems caused by those two conditions separately by applying deterministic analysis only. Hence, this study uses the Monte Carlo Simulation to analyze water deficit problem considering both the drought and flood situations. The proposed method was applied to Shihmen Reservoir to demonstrate its feasibility. Monte Carlo Simulation requires large number of data for repeated analysis. This study proposes Conditional Weather Generation Downscaling Model (CWGDM) to synthesize long-term rainfall data and uses Latin Hypercube Sampling (LHS) to generate short-term (flood event) rainfall data. The rainfall data are transformed into runoff data by rainfall-runoff model, those runoff data are the input of long-term and short-term water allocation models. The short-term water allocation model must consider the high water turbidity treatment and reservoir flood mitigation operation simultaneously. The study proposes Unit Characteristic Hydrograph (UCH) to predict reservoir turbidity and uses Puls Mehtod to estimate the reservoir overflow. Through simulation of water allocation models, we can obtain serial water shortage data that can be used to estimate the water deficit risk by Weibull Plotting Method. The simulation results are based on the predictive rainfall data by ECHAM5. The risk analysis results indicate that climate changes decrease the water deficit risk caused by drought condition but increase the risk caused by high turbidity. In summary, the annual water deficit risk has decreased slightly under climate change. The rainfall synthesis results demonstrate the proposed CWGDM model can well predict the long-term rainfall. The turbidity simulation results demonstrate that the UCH well predict reservoir turbidity based on reservoir inflow and outflow. Although the study is applied to Shihmen Reservoir, the proposed concepts and procedure can be easily applied to other areas.