In this research, we improve an optical waveguide mode solver based on the fi- nite element method (FEM) and curvilineal hybrid edge/nodal elements, and implement a nonlinear beam propagation method (BPM) numerical model based on the related FEM scheme. The FEM mode solver is incorporated into it the perfectly matched layer (PML) absorbing boundary condition and can solve the leaky waveguide mode very accurately. We refine the algorithms of the mode solver related to rigorous boundary setting involving perfect electric conductor (PEC) and perfect magnetic conductor (PMC) and numerical implementation of PMLs. The mode solver is further generalized to the analysis of nonlinear waveguide modes for working together with the nonlinear BPM model. Another FEM based mode solver for two-dimensional (2-D) linear and nonlinear periodic optical waveguides is also implemented with second order triangular elements. Periodic boundary conditions are properly imposed in the propagation direction for efficient analysis. Numerical examples considered in this research include circular waveguide, 3-D antiresonant reflecting optical waveguide (ARROW), holey fibers of various numbers of air holes, nonlinear directional coupler, and 2-D linear and nonlinear photonic crystal waveguides. We in particular develop a scheme to present power flow diagrams in the cross-sectional plane for leaky modes.