The shear behavior of reinforced concrete beams with Glass Fiber Reinforced Polymer Bars (GFRP) has differences when compared to traditional steel reinforcement. The relative low modulus of elasticity and the lower resistance to transverse loading of GFRP bars change the resistance mechanisms and kinematics of the critical shear crack. In this context, the application of dispersed fibers in the concrete matrix may be used to try to reduce the flexibility of this type of element. Therefore, this work investigates the experimental behavior of four reinforced concrete beams with GFRP bars with and without stirrups and basalt fibers. By using Digital Image Correlation (DIC) technique, the displacement fields of the failure span were mapped and, by means of constitutive models of the shear resistant mechanisms available in the literature, the resistant behavior of the beams was analyzed. The evaluation of resistance mechanisms through the constitutive models showed a satisfactory correlation with the experimental results. In addition, the analysis provided a better understanding of the contribution of each resistant mechanisms at different stages of loading.