A Simple Congestion-Aware Algorithm for Load Balancing in Datacenter Networks

Abstract

We study the problem of load balancing in datacenter networks, namely, assigning the end-to-end data flows among the available paths in order to efficiently balance the load in the network. The solutions used today rely typically on an equal-cost multi path (ECMP) mechanism, which essentially attempts to balance the load in the network by hashing the flows to the available shortest paths. However, it is well-known that the ECMP performs poorly when there is asymmetry either in the network topology or the flow sizes, and thus, there has been much interest recently in alternative mechanisms to address these shortcomings. In this paper, we consider a general network topology where each link has a cost, which is a convex function of the link congestions. Flows among the various source–destination pairs are generated dynamically over time, each with a size (bandwidth requirement) and a duration. Once a flow is assigned to a path in the network, it consumes bandwidth equal to its size from all the links along its path for its duration. We consider low-complexity congestion-aware algorithms that assign the flows to the available paths in an online fashion and without splitting . Specifically, we propose a myopic algorithm that assigns every arriving flow to an available path with the minimum marginal cost (i.e., the path which yields the minimum increase in the network cost after assignment) and prove that it asymptotically minimizes the total network cost. Extensive simulation results are presented to verify the performance of the myopic algorithm under a wide range of traffic conditions and under different datacenter architectures. Furthermore, we propose randomized versions of our myopic algorithm, which have much lower complexity and empirically show that they can still perform very well in symmetric network topologies.