An extended kinematic wave model is proposed for the simulation of flood propagation in the simple or compound channels with variable cross-sectional properties, including channel width, bed slope, and friction coefficient. The model considers the distinctive effects and multiple wave types induced by the compound channel and variable cross-sectional properties but disregards the multi-dimensional and dynamic flood motions. First, the study derives an explicit analytical kinematic wave model for regular channels with variable cross-sectional properties by changed variable method. It implies that the flood propagation can be solved as in the channel with constant cross-sectional properties primarily and then transformed into the solution for variable cross-sectional properties. The analytical model is applied to the well-documented flood due to the Tangjiashan Landslide Dam failure, Sichuan, in 2008 and presents satisfactory agreements with the recorded data. Second, the study derives an explicit numerical kinematic wave model for compound channels by HLL Finite Volume numerical method. The numerical model is validated and assessed by the analytical model and the historical data of the flood due to the failure of Teton Dam in Idaho, in 1976. Based on these comparisons, the model is shown capable of performing dam failure flood simulations with good efficiency and accuracy. Last, the model is used to simulate different dam failure scenarios for the Shihmen Dam in Taiwan. This application shows clearly how flood behavior is affected by compound channel geometry, width and slope changes, and the gradual or sudden character of the dam failure.