This study aims to develop a reliability assessment model for water supply from the reservoir (RA_WS_Res) in order to quantify the risk of water supply due to the uncertainty factors. The uncertainty factors group into three types: hydrological factors, reservoir operation rules, and parameters of rainfall-runoff model (i.e. Sacramento Soil Moisture Accounting, SAC-SMA). Specifically, the hydrological factors includes the rainfall characteristics, baseflow, evaporation, and initial water level of dam; the reservoir operation rules involve the flood level, target level and firm storage level. In detail, the proposed RA_WS_Res model primarily employs the multivariate Monte Carlo simulation (Wu et al., 2006) to generate the uncertainty factors in order to produce dam inflow by incorporating with the SAC-SMA model. After that, the water supply at the demand nodes of interest can be obtained from the water-resource allocation model (River Basin Simulation model, Ribasim). Using the simulated uncertainty factors and corresponding estimated water supply, the resulting exceedance probability (i.e. insufficient risk) can be calculated by using the uncertainty and risk analysis (i.e. advanced first-order and second moment, AFOSM). Eventually, this study carries out the logistic regression analysis to establish the relationship between the exceedance probability and average rainfall intensity for various 10-day periods at the specific nodes. This relationship is named the exceedance probability calculation equation. In summary, the proposed RA_WS_Res model is composed of five components: simulation of uncertainty factors, estimation of dam inflow, estimation of water supply, quantification of insufficient risk, and establishment of the exceedance calculation equation. It is expected that the proposed RA_WS_Res model can quantify the effect of variation in uncertainty factors, especially due to climate change, on the reliability of water supply from the reservoir. 　　Shihmen Reservoir watershed is selected as the study area and six demand locations within the watershed are selects as the study nodes. In addition, the hourly rainfall data from 1987 to 2014 and associated hydrological data (i.e. evaporation and baseflow) as well as the operation rules are used in the model development and application. The results indicate that, amond these uncertainty factors, the reliability of water supply is more sensitive to uncertainties in the initial water level, average rainfall intensity in each 10-day period, baseflow and the range between the target level and firm storage level. In detail, the effect of variation in the initial water level to water supply gradually reduces with time (ten days) from the 1st ten-day to the 15th ten-day period in Shihmen Reservoir. Moreover, the average rainfall intensity and baseflow are positively related to water supply; this implies that the baseflow plays an important role in the estimation of water supply, besides the average rainfall intensity. In particular, the range between the target and firm storage levels has significantly influence on the reliability of water supply. This reveals that regulating the operation rules for the reservoir not only focuses on the flood mitigation and prevention, but also takes into account the water-supply reliability. Consequently, the proposed RA_WS_Res model can effectively and reasonably quantify the insufficient risk (i.e. exceedance probability) of water supply attributed to variation in uncertainty factors due to climate change; this can be useful for the water-resource allocation and analysis.