Uniform Confluence in Concurrent Computation
Author: Joachim Niehren
Editor:
Indeterminism is typical for concurrent computation. If
several concurrent actors compete for the same resource then
at most one of them may succeed, whereby the choice of the
successful actor is indeterministic. As a consequence, the
execution of a concurrent program may be nonconfluent. Even
worse, most observables (termination, computational result,
and time complexity) typically depend on the scheduling of
actors created during program execution. This property
contrast concurrent programs from purely functional programs.
A functional program is uniformly confluent in the sense
that all its possible executions coincide modulo reordering
of execution steps. In this paper, we investigate
concurrent programs that are uniformly confluent and
their relation to eager and lazy functional programs.
We study uniform confluence in concurrent computation within the
applicative core of the $\pi$-calculus which is widely used in
different models of concurrent programming (with interleaving
semantics). In particular, the applicative core of the $\pi$-calculus
serves as a kernel in foundations of concurrent constraint programming
with first-class procedures (as provided by the programming language
Oz). We model eager functional programming in the $\lambda$-calculus
with weak call-by-value reduction and lazy functional programming in
the call-by-need amming in the $\lambda$-calculus with standard
reduction. As a measure of time complexity, we count application
steps. We encode the $\lambda$-calculus with both above reduction
strategies into the applicative core of the $\pi$-calculus and show
that time complexity is preserved. Our correctness proofs employs a
new technique based on uniform confluence and simulations. The
strength of our technique is illustrated by proving a folk theorem,
namely that the call-by-need complexity of a functional program is
smaller than its call-by-value complexity.
|