Scheduling tree dags on parallel architectures

Abstract

We provide optimal within a constant explicit upper bounds on the makespan of schedules for tree-structured programs on mesh arrays of processors, and provide polynomial-time algorithms to find schedules with makespan matching these bounds. In particular, we show how to find, in polynomial time, a (nonpreemptive) schedule for a binary tree dag withn unit execution time tasks and heighth on ad-dimensional mesh array withm processors and links of unit bandwidth and unit propagation delay whose makespan isO(n/m+n1/(d+1)+h), i.e., optimal within a constant factor. Further, we extend these schedules to bounded degree forest dags with arbitrary positive integer execution time tasks and to meshes when the propagation delay of all the links is an arbitrary positive integer. Thus, we provide a polynomial-time approximation algorithm for an NP-hard problem, with a performance ratio that is a constant.