The cultivation of figs (Ficus carica L.) in Taiwan has been exclusively for fresh markets and completely relied on protected cultivation to avoid the undesirable high precipitation. However, high evapotranspiration, over-fertilization and the lack of nature flushing cause salt accumulation in the soil, thus hindering growth and production. In this study, three concentrations [0%, 0.1% and 0.7%_((wt/medium wt.)) NaCl] were applied to container-grown 'Noire de Caromb fig. Aboveground growth and leaf gas exchange were measured after salinity treatments. Data from net assimilation rate (A) against intercellular CO_2 concentration (C_i) were fitted to FvCB biochemical model. The salinity treatment with 0.1% NaCl slightly reduced the length of shoots and the number of leaves but 0.7% NaCl treatment significantly suppressed the length of shoots and number of leaves, new leaf size, and total leaf area. No difference in photosynthesis among treatments was detected through the 95-day salinity stress period. Significant reduction in stomatal conductance (g_s) and transpiration rate (E), and consequent improving intrinsic water use efficiency (WUEi) were detected at 10 days after treatment (DAT) in plants subjected to 0.7% NaCl. However, the regulation of g_s and the positive response of WUEi appeared temporarily and diminished thereafter. FvCB model fitting outputs showed that photosynthesis efficiency was reduced at 95 days in 0.7% NaCl treatment, due to suppressed maximum rate of rubisco regeneration (V_(cmax)) and maximum rate of electron transport (J_(max)).