From patchwork Mon Jul 8 08:43:52 2019 Content-Type: text/plain; charset="utf-8" MIME-Version: 1.0 Content-Transfer-Encoding: 7bit X-Patchwork-Submitter: Patrick Bellasi X-Patchwork-Id: 11034733 Return-Path: Received: from mail.wl.linuxfoundation.org (pdx-wl-mail.web.codeaurora.org [172.30.200.125]) by pdx-korg-patchwork-2.web.codeaurora.org (Postfix) with ESMTP id 63DB617EF for ; Mon, 8 Jul 2019 08:44:35 +0000 (UTC) Received: from mail.wl.linuxfoundation.org (localhost [127.0.0.1]) by mail.wl.linuxfoundation.org (Postfix) with ESMTP id 543DA283CA for ; Mon, 8 Jul 2019 08:44:35 +0000 (UTC) Received: by mail.wl.linuxfoundation.org (Postfix, from userid 486) id 488F1283EE; Mon, 8 Jul 2019 08:44:35 +0000 (UTC) X-Spam-Checker-Version: SpamAssassin 3.3.1 (2010-03-16) on pdx-wl-mail.web.codeaurora.org X-Spam-Level: X-Spam-Status: No, score=-7.9 required=2.0 tests=BAYES_00,MAILING_LIST_MULTI, RCVD_IN_DNSWL_HI autolearn=ham version=3.3.1 Received: from vger.kernel.org (vger.kernel.org [209.132.180.67]) by mail.wl.linuxfoundation.org (Postfix) with ESMTP id AB477283E7 for ; Mon, 8 Jul 2019 08:44:34 +0000 (UTC) Received: (majordomo@vger.kernel.org) by vger.kernel.org via listexpand id S1729571AbfGHIoM (ORCPT ); Mon, 8 Jul 2019 04:44:12 -0400 Received: from foss.arm.com ([217.140.110.172]:41924 "EHLO foss.arm.com" rhost-flags-OK-OK-OK-OK) by vger.kernel.org with ESMTP id S1729564AbfGHIoL (ORCPT ); Mon, 8 Jul 2019 04:44:11 -0400 Received: from usa-sjc-imap-foss1.foss.arm.com (unknown [10.121.207.14]) by usa-sjc-mx-foss1.foss.arm.com (Postfix) with ESMTP id E9EAA360; Mon, 8 Jul 2019 01:44:10 -0700 (PDT) Received: from e110439-lin.cambridge.arm.com (e110439-lin.cambridge.arm.com [10.1.194.43]) by usa-sjc-imap-foss1.foss.arm.com (Postfix) with ESMTPA id 953E23F246; Mon, 8 Jul 2019 01:44:08 -0700 (PDT) From: Patrick Bellasi To: linux-kernel@vger.kernel.org, linux-pm@vger.kernel.org Cc: Ingo Molnar , Peter Zijlstra , Tejun Heo , "Rafael J . Wysocki" , Vincent Guittot , Viresh Kumar , Paul Turner , Quentin Perret , Dietmar Eggemann , Morten Rasmussen , Juri Lelli , Todd Kjos , Joel Fernandes , Steve Muckle , Suren Baghdasaryan , Alessio Balsini Subject: [PATCH v11 0/5] Add utilization clamping support (CGroups API) Date: Mon, 8 Jul 2019 09:43:52 +0100 Message-Id: <20190708084357.12944-1-patrick.bellasi@arm.com> X-Mailer: git-send-email 2.21.0 MIME-Version: 1.0 Sender: linux-pm-owner@vger.kernel.org Precedence: bulk List-ID: X-Mailing-List: linux-pm@vger.kernel.org X-Virus-Scanned: ClamAV using ClamSMTP Hi all, this is a follow up of: https://lore.kernel.org/lkml/20190621084217.8167-1-patrick.bellasi@arm.com/ to respin all the bits not yet queued by PeterZ and addressing all Tejun's requests from previous review: - remove checks for cpu_uclamp_{min,max}_write()s from root group - remove checks on "protections" being smaller then "limits" - rephrase uclamp extension description to avoid explicit mentioning of the bandwidth concept the series is based on top of: tj/cgroup.git for-5.3 tip/tip.git sched/core I hope this version covers all major details about the expected behavior and delegation model. The code however can still benefit from a better review, looking forward for any additional feedback. Cheers, Patrick Series Organization =================== This series contains just the remaining bits of the original posting: - Patches [0-5]: Per task group (secondary) API and it is based on today's tj/cgroup/for-5.3 and tip/sched/core. The full tree is available here: git://linux-arm.org/linux-pb.git lkml/utilclamp_v11 http://www.linux-arm.org/git?p=linux-pb.git;a=shortlog;h=refs/heads/lkml/utilclamp_v11 where you can also get the patches already queued in tip/sched/core - Patches [01-07]: Per task (primary) API - Patches [08-09]: Schedutil integration for FAIR and RT tasks - Patches [10-11]: Integration with EAS's energy_compute() Newcomer's Short Abstract ========================= The Linux scheduler tracks a "utilization" signal for each scheduling entity (SE), e.g. tasks, to know how much CPU time they use. This signal allows the scheduler to know how "big" a task is and, in principle, it can support advanced task placement strategies by selecting the best CPU to run a task. Some of these strategies are represented by the Energy Aware Scheduler [1]. When the schedutil cpufreq governor is in use, the utilization signal allows the Linux scheduler to also drive frequency selection. The CPU utilization signal, which represents the aggregated utilization of tasks scheduled on that CPU, is used to select the frequency which best fits the workload generated by the tasks. The current translation of utilization values into a frequency selection is simple: we go to max for RT tasks or to the minimum frequency which can accommodate the utilization of DL+FAIR tasks. However, utilization values by themselves cannot convey the desired power/performance behaviors of each task as intended by user-space. As such they are not ideally suited for task placement decisions. Task placement and frequency selection policies in the kernel can be improved by taking into consideration hints coming from authorized user-space elements, like for example the Android middleware or more generally any "System Management Software" (SMS) framework. Utilization clamping is a mechanism which allows to "clamp" (i.e. filter) the utilization generated by RT and FAIR tasks within a range defined by user-space. The clamped utilization value can then be used, for example, to enforce a minimum and/or maximum frequency depending on which tasks are active on a CPU. The main use-cases for utilization clamping are: - boosting: better interactive response for small tasks which are affecting the user experience. Consider for example the case of a small control thread for an external accelerator (e.g. GPU, DSP, other devices). Here, from the task utilization the scheduler does not have a complete view of what the task's requirements are and, if it's a small utilization task, it keeps selecting a more energy efficient CPU, with smaller capacity and lower frequency, thus negatively impacting the overall time required to complete task activations. - capping: increase energy efficiency for background tasks not affecting the user experience. Since running on a lower capacity CPU at a lower frequency is more energy efficient, when the completion time is not a main goal, then capping the utilization considered for certain (maybe big) tasks can have positive effects, both on energy consumption and thermal headroom. This feature allows also to make RT tasks more energy friendly on mobile systems where running them on high capacity CPUs and at the maximum frequency is not required. From these two use-cases, it's worth noticing that frequency selection biasing, introduced by patches 9 and 10 of this series, is just one possible usage of utilization clamping. Another compelling extension of utilization clamping is in helping the scheduler in making tasks placement decisions. Utilization is (also) a task specific property the scheduler uses to know how much CPU bandwidth a task requires, at least as long as there is idle time. Thus, the utilization clamp values, defined either per-task or per-task_group, can represent tasks to the scheduler as being bigger (or smaller) than what they actually are. Utilization clamping thus enables interesting additional optimizations, for example on asymmetric capacity systems like Arm big.LITTLE and DynamIQ CPUs, where: - boosting: try to run small/foreground tasks on higher-capacity CPUs to complete them faster despite being less energy efficient. - capping: try to run big/background tasks on low-capacity CPUs to save power and thermal headroom for more important tasks This series does not present this additional usage of utilization clamping but it's an integral part of the EAS feature set, where [2] is one of its main components. Android kernels use SchedTune, a solution similar to utilization clamping, to bias both 'frequency selection' and 'task placement'. This series provides the foundation to add similar features to mainline while focusing, for the time being, just on schedutil integration. References ========== [1] Energy Aware Scheduling https://git.kernel.org/pub/scm/linux/kernel/git/torvalds/linux.git/tree/Documentation/scheduler/sched-energy.txt?h=v5.1 [2] Expressing per-task/per-cgroup performance hints Linux Plumbers Conference 2018 https://linuxplumbersconf.org/event/2/contributions/128/ Patrick Bellasi (5): sched/core: uclamp: Extend CPU's cgroup controller sched/core: uclamp: Propagate parent clamps sched/core: uclamp: Propagate system defaults to root group sched/core: uclamp: Use TG's clamps to restrict TASK's clamps sched/core: uclamp: Update CPU's refcount on TG's clamp changes Documentation/admin-guide/cgroup-v2.rst | 30 +++ init/Kconfig | 22 ++ kernel/sched/core.c | 335 +++++++++++++++++++++++- kernel/sched/sched.h | 8 + 4 files changed, 392 insertions(+), 3 deletions(-)