Аннотация
We introduce a new, high-throughput, synchronous, distributed, data-parallel,
stochastic-gradient-descent learning algorithm. This algorithm uses amortized
inference in a compute-cluster-specific, deep, generative, dynamical model to
perform joint posterior predictive inference of the mini-batch gradient
computation times of all worker-nodes in a parallel computing cluster. We show
that a synchronous parameter server can, by utilizing such a model, choose an
optimal cutoff time beyond which mini-batch gradient messages from slow workers
are ignored that maximizes overall mini-batch gradient computations per second.
In keeping with earlier findings we observe that, under realistic conditions,
eagerly discarding the mini-batch gradient computations of stragglers not only
increases throughput but actually increases the overall rate of convergence as
a function of wall-clock time by virtue of eliminating idleness. The principal
novel contribution and finding of this work goes beyond this by demonstrating
that using the predicted run-times from a generative model of cluster worker
performance to dynamically adjust the cutoff improves substantially over the
static-cutoff prior art, leading to, among other things, significantly reduced
deep neural net training times on large computer clusters.
Описание
High Throughput Synchronous Distributed Stochastic Gradient Descent
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