Multiterminal transport measurements on YBCO crystals in the vortex liquid regime have shown nonlocal conductivity on length scales up to 50 microns. Motivated by these results we explore the wavevector ({\bf k}) dependence of the dc conductivity tensor, $\sigma_{\mu\nu} ({\bf k})$, in the Meissner, vortex lattice, and disordered phases of a type-II superconductor. Our results are based on time-dependent Ginzburg-Landau (TDGL) theory and on phenomenological arguments. We find four qualitatively different types of behavior. First, in the Meissner phase, the conductivity is infinite at $k=0$ and is a continuous function of $k$, monotonically decreasing with increasing $k$. Second, in the vortex lattice phase, in the absence of pinning, the conductivity is finite (due to flux flow) at $k=0$; it is discontinuous there and remains qualitatively like the Meissner phase for $k>0$. Third, in the vortex liquid regime in a magnetic field and at low temperature, the conductivity is finite, smooth and {\it non-monotonic}, first increasing with $k$ at small $k$ and then decreasing at larger $k$. This third behavior is expected to apply at temperatures just above the melting transition of the vortex lattice, where the vortex liquid shows strong short-range order and a large viscosity. Finally, at higher temperatures in the disordered phase, the conductivity is finite, smooth and again monotonically decreasing with $k$. This last, monotonic behavi or applies in zero magnetic field for the entire disordered phase, i.e. at all temperatures above $T_c$, while in