Morphable surfaces have the potential to enable new kinds of adaptive systems, but existing fabrication methods have limited ability to achieve high resolution morphing into arbitrarily specified shapes. This work presents a platform and algorithms for toolpath generation to enable freeform structures capable of high-resolution surface morphing. The morphing surfaces were composed of liquid crystal elastomer (LCE), with nematic domains aligned using a scratch post capable of applying adjustable pressure and shear velocity, offering the ability to locally tune actuation strains and thus bending curvature radii from 1.8 mm to 14.4 mm. Patterning toolpaths for multi-layer structures were generated using two alternative algorithms, the results of which were compared using example structures capable of morphing from flat sheets into domes and models of a human faces. This process resulted in morphed human face shapes with structural similarities of up to 84.5% when compared to the original model, demonstrating the high fidelity and reconfigurability of this approach for fabricating complex morphable LCE structures.