1 research outputs found
SERENADE: A Parallel Randomized Algorithm Suite for Crossbar Scheduling in Input-Queued Switches
Most of today's high-speed switches and routers adopt an input-queued
crossbar switch architecture. Such a switch needs to compute a matching
(crossbar schedule) between the input ports and output ports during each
switching cycle (time slot). A key research challenge in designing large (in
number of input/output ports ) input-queued crossbar switches is to develop
crossbar scheduling algorithms that can compute "high quality" matchings --
i.e., those that result in high switch throughput (ideally ) and low
queueing delays for packets -- at line rates. SERENA is one such algorithm: it
outputs excellent matching decisions that result in switch throughput
and reasonably good queueing delays. However, since SERENA is a centralized
algorithm with computational complexity, it cannot support switches that
both are large and have a very high line rate per port. In this work, we
propose SERENADE (SERENA, the Distributed Edition), a parallel iterative
algorithm that emulates SERENA in only iterations between input
ports and output ports, and hence has a time complexity of only per
port. We prove that SERENADE can exactly emulate SERENA. We also propose an
early-stop version of SERENADE, called O-SERENADE, to only approximately
emulate SERENA. Through extensive simulations, we show that O-SERENADE can
achieve 100\% throughput and that it has similar as or slightly better delay
performance than SERENA under various load conditions and traffic patterns