When solving elliptic boundary value problems using integral

equation methods one may need to evaluate potentials represented by

a convolution of discretized layer density sources against a kernel.

Standard quadrature accelerated with a fast hierarchical method for

potential field evaluation gives accurate results far away from the

sources. Close to the sources this is not so. Cancellation and

nearly singular kernels may cause serious degradation. This paper

presents a new scheme based on a mix of composite polynomial

quadrature, layer density interpolation, kernel approximation,

rational quadrature, high polynomial order corrected interpolation

and differentiation, temporary panel mergers and splits, and a

particular implementation of the GMRES solver. Criteria for which

mix is fastest and most accurate in various situations are also

supplied. The paper focuses on the solution of the Dirichlet problem

for Laplace's equation in the plane. In a series of examples we

demonstrate the efficiency of the new scheme for interior domains

and domains exterior to up to 2000 close-to-touching contours.

Densities are computed and potentials are evaluated, rapidly and

accurate to almost machine precision, at points that lie arbitrarily

close to the boundaries.