Differential interference contrast (DIC) microscopy has been emerging as a solution to overcome the low contrast interference incurred by significantly unequal intensity of reference and object light beams in conventional optical microscopes. Although DIC was originally used to enhance the contrast of transparent sample images, the ability of quantitative measurement has become very important in industrial applications in recent years. In order to reconstruct the 3D profile of the sample, two orthogonal DIC phase gradient maps must be obtained. A measurement system has been developed based on quantitative simultaneous spatial phase-shifting and differential interference contrast (DIC) technique to measure the 3D profile of the nanoscale reflected samples. Due to the characteristics of common optical path, all the effects of axial vibration can be offset by two beams, so the system introduces high anti-vibration ability. The developed measuring methods employ spatial phase-shifting, light splitting by birefringent crystal and Fourier integration method to achieve the simultaneous measurement of 3D profile. The system used two Savart prisms and simply produced two sets of shear waves. In addition, by combining a polarizing camera with a quarter wave plate, four phase-shifting interference images can be obtained for phase-shifting technique, and phase gradient maps in two vertical directions can be obtained. Finally, Frankot-Chellappa algorithm is used to complete 3D profile reconstruction. The proposed system was theoretically described and verified by step height standard of 70 nm, while the system also measured an industrial product, microlens array, and successfully reconstructed its 3D profile.