The diffusioosmotic flow of an electrolyte solution in the fibrous porous medium constructed by a homogeneous array of parallel charge-regulating circular cylinders with arbitrary electric double layers is analytically studied. The imposed electrolyte concentration gradient is constant and normal to the axes of the cylinders. The charge regulation due to association/dissociation reactions of ionogenic functional groups on the particle surface is approximated by a linearized regulation model, which specifies a linear relationship between the surface charge density and the surface potential. A unit cell model which allows for the overlap of the double layers of adjacent cylinders is employed. The electrokinetic equations that govern the ionic concentration distributions, the electrostatic potential profile, and the fluid flow field in the electrolyte solution surrounding the charge-regulating cylinder in a unit cell are linearized assuming that the system is only slightly distorted from equilibrium. Through the use of a regular perturbation method, these linearized equations are solved with the zeta potential of the cylinder as the small perturbation parameter. An analytical expression for the diffusioosmotic velocity of the electrolyte solution as a function of the porosity of the ordered array of cylinders correct to the second order of their zeta potential is obtained from a balance between the electrostatic and the hydrodynamic forces exerted on each cylinder. Our results indicate that the charge regulation characteristics such as the equilibrium constants of the reactions occurring at the cylinder surfaces and the bulk concentration of the charge-determining ions influence the surface charge density and potential and diffusioosmotic mobility substantially. For the limiting cases of a very thin or very thick electric double layer, the diffusioosmotic mobility is independent of the charge regulation parameter.