As you have described it, the logical approach would be to launch a separate kernel for each stage of the calculation. In a non-trivially sized problem, the "computational front" will grow in size rapidly, so that some degree of computational efficiency can be obtained as the solution propagates across the domain.

The "best" method is probably not to sweep across the domain, but rather to solve the *whole domain* iteratively until the solution converges. Jeong and Whittaker published a very good paper on an iterative label correcting method for solving the stationary Eikonal equation (which is a classic upwind sweeping calculation similar to your matrix picture). In their approach, a computational grid is decomposed into blocks and each block containing values which have not converged are recomputed until it converges. When a characteristic crosses a sub block boundary, any values which depend on a changed value are relabelled as unconverged and the process continues until the whole domain converges.

You can see a Youtube video of this algorithm in action on a CUDA GPU here