Under the predicted climate change scenarios, many of Taiwan’s endemic conifers may shift their distribution ranges in response. The first step in assessing the likely impacts of climate change on a species’ distribution is to develop a distribution model that relates the species’ current observed distribution to a set of possible climatic variables. In this study, a generalized additive modeling (GAM) approach was used to establish the distribution models for six dominant conifer species in the montane regions of Taiwan. The presence/absence data for each species were extracted from the inventory plot information of The Third Forest Resources and Land Use Inventory in Taiwan. Only plots with an elevation of at least 1000 m a.s.l. were included in this study. Climatic data were from available weather stations. A set of climate surfaces for mean monthly temperatures and precipitations was first developed by using thin-plate smoothing splines. The fitted climate surfaces were then used to estimate climatic parameters for each plot. A stepwise procedure was used to select the best climatic predictors for each species. Model performance was evaluated by area under the receiver-operating characteristic (AUC) curve, Kappa statistic, sensitivity, and specificity. The results showed that annual mean temperature was the only predictor included in all models, suggesting that the distributions of the six conifer species all were controlled by annual mean temperature. An increase in temperature would reduce the presence probability of the six species at a given site. In contrast, none of the models included annual mean precipitation, likely due to the abundant amount of precipitation in Taiwan. However, the influence of seasonal precipitation was important to some of the conifer species. Model performance criteria suggested the models for Taiwan fir and Taiwan hemlock had a good performance. Based on the AUC criterion, all the models reached the level of useful applications.