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Scheduling Kernels via Configuration LP
Makespan minimization (on parallel identical or unrelated machines) is
arguably the most natural and studied scheduling problem. A common approach in
practical algorithm design is to reduce the size of a given instance by a fast
preprocessing step while being able to recover key information even after this
reduction. This notion is formally studied as kernelization (or simply, kernel)
-- a polynomial time procedure which yields an equivalent instance whose size
is bounded in terms of some given parameter. It follows from known results that
makespan minimization parameterized by the longest job processing time
has a kernelization yielding a reduced instance whose size is
exponential in . Can this be reduced to polynomial in ?
We answer this affirmatively not only for makespan minimization, but also for
the (more complicated) objective of minimizing the weighted sum of completion
times, also in the setting of unrelated machines when the number of machine
kinds is a parameter. Our algorithm first solves the Configuration LP and based
on its solution constructs a solution of an intermediate problem, called huge
-fold integer programming. This solution is further reduced in size by a
series of steps, until its encoding length is polynomial in the parameters.
Then, we show that huge -fold IP is in NP, which implies that there is a
polynomial reduction back to our scheduling problem, yielding a kernel.
Our technique is highly novel in the context of kernelization, and our
structural theorem about the Configuration LP is of independent interest.
Moreover, we show a polynomial kernel for huge -fold IP conditional on
whether the so-called separation subproblem can be solved in polynomial time.
Considering that integer programming does not admit polynomial kernels except
for quite restricted cases, our "conditional kernel" provides new insight.Comment: 21 page