Improving Resource Efficiency at Scale with Heracles

Author:

Lo David1ORCID,Cheng Liqun2,Govindaraju Rama2,Ranganathan Parthasarathy2,Kozyrakis Christos3

Affiliation:

1. Google Inc., Stanford University, Mountain View, CA

2. Google Inc., Mountain View, CA

3. Stanford University, Stanford, CA

Abstract

User-facing, latency-sensitive services, such as websearch, underutilize their computing resources during daily periods of low traffic. Reusing those resources for other tasks is rarely done in production services since the contention for shared resources can cause latency spikes that violate the service-level objectives of latency-sensitive tasks. The resulting under-utilization hurts both the affordability and energy efficiency of large-scale datacenters. With the slowdown in technology scaling caused by the sunsetting of Moore’s law, it becomes important to address this opportunity. We present Heracles, a feedback-based controller that enables the safe colocation of best-effort tasks alongside a latency-critical service. Heracles dynamically manages multiple hardware and software isolation mechanisms, such as CPU, memory, and network isolation, to ensure that the latency-sensitive job meets latency targets while maximizing the resources given to best-effort tasks. We evaluate Heracles using production latency-critical and batch workloads from Google and demonstrate average server utilizations of 90% without latency violations across all the load and colocation scenarios that we evaluated.

Funder

Google PhD Fellowship

Stanford Experimental Datacenter Lab

NSF

Google research

Publisher

Association for Computing Machinery (ACM)

Subject

General Computer Science

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