We propose an efficient and accurate mode solver for three dimensional subwavelength grating (3D SWG) waveguides with straight and bend structures. Based on the approximated linear dispersion relation of the SWG structures, we utilize the transfer matrix method (TMM) to obtain the equivalent effective index of a SWG structure, and then a 3D SWG waveguide is equivalent to the conventional 3D waveguide. At last, we use the finite element method (FEM) to realize the modal distributions and related properties of this SWG waveguide. To confirm our mode solver, we investigate several straight and bent SWG waveguides with different geometric parameters and compare to the modes calculated by 3D finite difference time domain (FDTD) method by using the overlap integral. We observe the values of overlap integrals are larger than 96 %, showing that our mode solver is highly accurate. Besides, we apply this mode solver to design tapered waveguides and ring resonators. We propose two SWG tapered waveguides by varying the filling factors along the structures. Then the effective medium indices along the structures are varied and thus the mode is converted along the SWG tapered waveguides. The simulated results show that the taper with its length larger than 2 m has its taper loss of less than 0.14 dB. On the other hand, we use the obtained effective indices of a partial SWG bending structure with a radius of 3 m to calculate the resonant wavelengths and the free spectral range (FSR) of the corresponding PSWG ring resonator. The FDTD simulated results show this PSWG ring resonator has extinction ratio of 25.72 dB, quality factor (Q factor) of 1062.3, FWHM of 1.45 nm and FSR of 33 nm.