Pure-dephasing spin-boson model resides the property that it’s propagator can be obtained, with Magnus expansion, and the model so is exactly solvable. The quantum Zeno effect is a situation that if the measurements imposed upon the unstable particle are frequent enough, the state evolution of the particle can be frozen. Subsequently it was predicted that an enhancement of decay due to frequent but not sufficiently frequent measurements could lead to the so-called anti-Zeno effect, i.e. the increase of measuring frequency will decrease the survival probability. We study the quantum Zeno effect and anti-Zeno effect on the pure-dephasing spin-boson model. Here we evaluate the decay rate of the system frequently measured by the initial projective operator. Since the total system and environment propagator is known, we can derive the exact analytic form of the probability of the system to remain in its initial state after N times of measurement on the condition that the initial environment is in thermal equilibrium. Given the condition that the environment is in thermal equilibrium mixed state, we know that partial traced density matrices of the system will gradually dephase to mixed state if the initial state is in superposition state. We use the derived equation to investigate the competition between the dephasing ability triggered by the environment and the freezing capability of the successive measurements on the system. We find that the survival probability is highly related to the frequency of the measurements, the coupling strength and the bath correlation time.