1 research outputs found
Even Faster SNN Simulation with Lazy+Event-driven Plasticity and Shared Atomics
We present two novel optimizations that accelerate clock-based spiking neural
network (SNN) simulators. The first one targets spike timing dependent
plasticity (STDP). It combines lazy- with event-driven plasticity and
efficiently facilitates the computation of pre- and post-synaptic spikes using
bitfields and integer intrinsics. It offers higher bandwidth than event-driven
plasticity alone and achieves a 1.5x-2x speedup over our closest competitor.
The second optimization targets spike delivery. We partition our graph
representation in a way that bounds the number of neurons that need be updated
at any given time which allows us to perform said update in shared memory
instead of global memory. This is 2x-2.5x faster than our closest competitor.
Both optimizations represent the final evolutionary stages of years of
iteration on STDP and spike delivery inside "Spice" (/spaIk/), our state of the
art SNN simulator. The proposed optimizations are not exclusive to our graph
representation or pipeline but are applicable to a multitude of simulator
designs. We evaluate our performance on three well-established models and
compare ourselves against three other state of the art simulators.Comment: Submitted to IEEE-HPEC 202