Taiwania cryptomerioides is a monotypic gymnosperm species, valued for the high decay resistance of its wood. This durability has been attributed to the abundance of terpenoids, especially the sesquiterpenoid cadinene and diterpenoid ferruginol with antifungal and antitermite activity. The important committed step in terpenoid biosynthesis is the backbone formation catalyzed by terpene synthases (TPSs), and to adapt to the environment, plants have evolved their own group of TPSs along with the species evolution. However, the biosynthesis pathways of many Cupressaceae-specific terpenoids remained unknown. To expand our knowleage of terpene biosyntehesis and evolution of TPSs in Cupressaceae, a research included transcriptome, proteome and metabolome is recquired, and T. cryptomerioides can provide a good model for terpenoid research in Cupressaceae species because of its unique evolutionary opposition and high numbers of terepnoids. In this study, we identified unrecognized groups of TPSs in T. cryptomerioides, including monofunctional diTPSs, which suggests a distinct evolutionary divergence of the TPS family in this species. Specifically, twelve TPS functions not previously observed in gymnosperms were characterized, including two monofunctional class II diTPSs ((labda-13-en-8-ol diphosphate synthase (TcCPS2) and (+)-copalyl diphosphate synthase (TcCPS4)), six class I diTPSs (manoyl oxide synthase (TcKSL1, TcKSL3~TcKSL7)，biformene synthase (TcKSL1)，levopimaradiene synthase (TcKSL3) and phyllocladanol synthase (TcKSL5)), and four sesquiterpene synthases (zingiberene synthase (TcTPS1)、germacrene-4-ol synthase (TcTPS4 and TcTPS12) and cedrol synthase (TcTPS6)). Furthermore, TcCPS4 and TcKSL3 likely contribute to abietatriene biosynthesis via levopimaradiene as an intermediate in ferruginol biosynthesis in Taiwania. Notably, diterpene biosynthesis in Pinaceae speciese denpends on bifunctional diterpene synthases to catalylyze two-step reaction on two catalytic sites of an enzyme, but Taiwania employs dominantly pairs of monofunctional diterpene synthases to complete the two-step reaction successively. In addition, the uncharacterized genome structures with intron loss were also observed in a phylogenetically distant group of Taiwania sesquiterpene synthases, suggesting the terpenoid biosynthesis of Taiwania is unique and diverse due to the genome and protein strucuture modification. This study provides deeper insight into the functional landscape and molecular evolution of specialized terpenoid metabolism in gymnosperms as a basis to better understand the role of these metabolites in tree chemical defenses.