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We've been seeing hard-to-trigger psi crashes when running inside VM instances: divide error: 0000 [#1] SMP PTI Modules linked in: [...] CPU: 0 PID: 212 Comm: kworker/0:2 Not tainted 4.16.18-119_fbk9_3817_gfe944c98d695 #119 Hardware name: QEMU Standard PC (i440FX + PIIX, 1996), BIOS 0.0.0 02/06/2015 Workqueue: events psi_clock RIP: 0010:psi_update_stats+0x270/0x490 RSP: 0018:ffffc90001117e10 EFLAGS: 00010246 RAX: 0000000000000000 RBX: 0000000000000000 RCX: ffff8800a35a13f8 RDX: 0000000000000000 RSI: ffff8800a35a1340 RDI: 0000000000000000 RBP: 0000000000000658 R08: ffff8800a35a1470 R09: 0000000000000000 R10: 0000000000000000 R11: 0000000000000000 R12: 0000000000000000 R13: 0000000000000000 R14: 0000000000000000 R15: 00000000000f8502 FS: 0000000000000000(0000) GS:ffff88023fc00000(0000) knlGS:0000000000000000 CS: 0010 DS: 0000 ES: 0000 CR0: 0000000080050033 CR2: 00007fbe370fa000 CR3: 00000000b1e3a000 CR4: 00000000000006f0 DR0: 0000000000000000 DR1: 0000000000000000 DR2: 0000000000000000 DR3: 0000000000000000 DR6: 00000000fffe0ff0 DR7: 0000000000000400 Call Trace: psi_clock+0x12/0x50 process_one_work+0x1e0/0x390 worker_thread+0x2b/0x3c0 ? rescuer_thread+0x330/0x330 kthread+0x113/0x130 ? kthread_create_worker_on_cpu+0x40/0x40 ? SyS_exit_group+0x10/0x10 ret_from_fork+0x35/0x40 Code: 48 0f 47 c7 48 01 c2 45 85 e4 48 89 16 0f 85 e6 00 00 00 4c 8b 49 10 4c 8b 51 08 49 69 d9 f2 07 00 00 48 6b c0 64 4c 8b 29 31 d2 <48> f7 f7 49 69 d5 8d 06 00 00 48 89 c5 4c 69 f0 00 98 0b 00 48 The Code-line points to `period` being 0 inside update_stats(), and we divide by that when calculating that period's pressure percentage. The elapsed period should never be 0. The reason this can happen is due to an off-by-one in the idle time / missing period calculation combined with a coarse sched_clock() in the virtual machine. The target time for aggregation is advanced into the future on a fixed grid to prevent clock drift. So when an aggregation runs after some idle period, we can not just set it to "now + psi_period", but have to calculate the downtime and advance the target time relative to itself. However, if the aggregator was disabled exactly one psi_period (ns), we drop one idle period in the calculation due to a > when we should do >=. In that case, next_update will be advanced from 'now - psi_period' to 'now' when it should be moved to 'now + psi_period'. The run finishes with last_update == next_update == sched_clock(). With hardware clocks, this exact nanosecond match isn't likely in the first place; but if it does happen, the clock will still have moved on and the period non-zero by the time the worker runs. A pointlessly short period, but besides the extra work, no harm no foul. However, a slow sched_clock() like we have on VMs might not have advanced either by the time the worker runs again. And when we calculate the elapsed period, the result, our pressure divisor, will be 0. Ouch. Fix this by correctly handling the situation when the elapsed time between aggregation runs is precisely two periods, and advance the expiration timestamp correctly to period into the future. Link: http://lkml.kernel.org/r/20190214193157.15788-1-hannes@cmpxchg.org Signed-off-by: Johannes Weiner <hannes@cmpxchg.org> Reported-by: Łukasz Siudut <lsiudut@fb.com Reviewed-by: Andrew Morton <akpm@linux-foundation.org> Cc: Peter Zijlstra <peterz@infradead.org> Signed-off-by: Andrew Morton <akpm@linux-foundation.org> Signed-off-by: Linus Torvalds <torvalds@linux-foundation.org>
786 lines
22 KiB
C
786 lines
22 KiB
C
/*
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* Pressure stall information for CPU, memory and IO
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*
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* Copyright (c) 2018 Facebook, Inc.
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* Author: Johannes Weiner <hannes@cmpxchg.org>
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*
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* When CPU, memory and IO are contended, tasks experience delays that
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* reduce throughput and introduce latencies into the workload. Memory
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* and IO contention, in addition, can cause a full loss of forward
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* progress in which the CPU goes idle.
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*
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* This code aggregates individual task delays into resource pressure
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* metrics that indicate problems with both workload health and
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* resource utilization.
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*
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* Model
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*
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* The time in which a task can execute on a CPU is our baseline for
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* productivity. Pressure expresses the amount of time in which this
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* potential cannot be realized due to resource contention.
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*
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* This concept of productivity has two components: the workload and
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* the CPU. To measure the impact of pressure on both, we define two
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* contention states for a resource: SOME and FULL.
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*
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* In the SOME state of a given resource, one or more tasks are
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* delayed on that resource. This affects the workload's ability to
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* perform work, but the CPU may still be executing other tasks.
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*
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* In the FULL state of a given resource, all non-idle tasks are
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* delayed on that resource such that nobody is advancing and the CPU
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* goes idle. This leaves both workload and CPU unproductive.
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*
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* (Naturally, the FULL state doesn't exist for the CPU resource.)
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*
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* SOME = nr_delayed_tasks != 0
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* FULL = nr_delayed_tasks != 0 && nr_running_tasks == 0
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*
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* The percentage of wallclock time spent in those compound stall
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* states gives pressure numbers between 0 and 100 for each resource,
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* where the SOME percentage indicates workload slowdowns and the FULL
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* percentage indicates reduced CPU utilization:
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*
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* %SOME = time(SOME) / period
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* %FULL = time(FULL) / period
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*
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* Multiple CPUs
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*
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* The more tasks and available CPUs there are, the more work can be
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* performed concurrently. This means that the potential that can go
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* unrealized due to resource contention *also* scales with non-idle
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* tasks and CPUs.
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*
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* Consider a scenario where 257 number crunching tasks are trying to
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* run concurrently on 256 CPUs. If we simply aggregated the task
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* states, we would have to conclude a CPU SOME pressure number of
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* 100%, since *somebody* is waiting on a runqueue at all
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* times. However, that is clearly not the amount of contention the
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* workload is experiencing: only one out of 256 possible exceution
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* threads will be contended at any given time, or about 0.4%.
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*
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* Conversely, consider a scenario of 4 tasks and 4 CPUs where at any
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* given time *one* of the tasks is delayed due to a lack of memory.
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* Again, looking purely at the task state would yield a memory FULL
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* pressure number of 0%, since *somebody* is always making forward
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* progress. But again this wouldn't capture the amount of execution
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* potential lost, which is 1 out of 4 CPUs, or 25%.
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*
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* To calculate wasted potential (pressure) with multiple processors,
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* we have to base our calculation on the number of non-idle tasks in
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* conjunction with the number of available CPUs, which is the number
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* of potential execution threads. SOME becomes then the proportion of
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* delayed tasks to possibe threads, and FULL is the share of possible
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* threads that are unproductive due to delays:
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*
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* threads = min(nr_nonidle_tasks, nr_cpus)
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* SOME = min(nr_delayed_tasks / threads, 1)
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* FULL = (threads - min(nr_running_tasks, threads)) / threads
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*
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* For the 257 number crunchers on 256 CPUs, this yields:
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*
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* threads = min(257, 256)
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* SOME = min(1 / 256, 1) = 0.4%
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* FULL = (256 - min(257, 256)) / 256 = 0%
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*
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* For the 1 out of 4 memory-delayed tasks, this yields:
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*
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* threads = min(4, 4)
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* SOME = min(1 / 4, 1) = 25%
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* FULL = (4 - min(3, 4)) / 4 = 25%
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*
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* [ Substitute nr_cpus with 1, and you can see that it's a natural
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* extension of the single-CPU model. ]
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*
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* Implementation
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*
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* To assess the precise time spent in each such state, we would have
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* to freeze the system on task changes and start/stop the state
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* clocks accordingly. Obviously that doesn't scale in practice.
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*
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* Because the scheduler aims to distribute the compute load evenly
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* among the available CPUs, we can track task state locally to each
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* CPU and, at much lower frequency, extrapolate the global state for
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* the cumulative stall times and the running averages.
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*
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* For each runqueue, we track:
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*
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* tSOME[cpu] = time(nr_delayed_tasks[cpu] != 0)
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* tFULL[cpu] = time(nr_delayed_tasks[cpu] && !nr_running_tasks[cpu])
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* tNONIDLE[cpu] = time(nr_nonidle_tasks[cpu] != 0)
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*
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* and then periodically aggregate:
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*
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* tNONIDLE = sum(tNONIDLE[i])
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*
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* tSOME = sum(tSOME[i] * tNONIDLE[i]) / tNONIDLE
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* tFULL = sum(tFULL[i] * tNONIDLE[i]) / tNONIDLE
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*
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* %SOME = tSOME / period
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* %FULL = tFULL / period
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*
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* This gives us an approximation of pressure that is practical
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* cost-wise, yet way more sensitive and accurate than periodic
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* sampling of the aggregate task states would be.
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*/
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#include "../workqueue_internal.h"
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#include <linux/sched/loadavg.h>
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#include <linux/seq_file.h>
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#include <linux/proc_fs.h>
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#include <linux/seqlock.h>
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#include <linux/cgroup.h>
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#include <linux/module.h>
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#include <linux/sched.h>
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#include <linux/psi.h>
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#include "sched.h"
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static int psi_bug __read_mostly;
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DEFINE_STATIC_KEY_FALSE(psi_disabled);
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#ifdef CONFIG_PSI_DEFAULT_DISABLED
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bool psi_enable;
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#else
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bool psi_enable = true;
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#endif
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static int __init setup_psi(char *str)
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{
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return kstrtobool(str, &psi_enable) == 0;
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}
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__setup("psi=", setup_psi);
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/* Running averages - we need to be higher-res than loadavg */
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#define PSI_FREQ (2*HZ+1) /* 2 sec intervals */
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#define EXP_10s 1677 /* 1/exp(2s/10s) as fixed-point */
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#define EXP_60s 1981 /* 1/exp(2s/60s) */
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#define EXP_300s 2034 /* 1/exp(2s/300s) */
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/* Sampling frequency in nanoseconds */
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static u64 psi_period __read_mostly;
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/* System-level pressure and stall tracking */
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static DEFINE_PER_CPU(struct psi_group_cpu, system_group_pcpu);
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static struct psi_group psi_system = {
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.pcpu = &system_group_pcpu,
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};
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static void psi_update_work(struct work_struct *work);
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static void group_init(struct psi_group *group)
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{
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int cpu;
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for_each_possible_cpu(cpu)
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seqcount_init(&per_cpu_ptr(group->pcpu, cpu)->seq);
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group->next_update = sched_clock() + psi_period;
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INIT_DELAYED_WORK(&group->clock_work, psi_update_work);
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mutex_init(&group->stat_lock);
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}
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void __init psi_init(void)
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{
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if (!psi_enable) {
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static_branch_enable(&psi_disabled);
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return;
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}
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psi_period = jiffies_to_nsecs(PSI_FREQ);
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group_init(&psi_system);
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}
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static bool test_state(unsigned int *tasks, enum psi_states state)
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{
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switch (state) {
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case PSI_IO_SOME:
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return tasks[NR_IOWAIT];
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case PSI_IO_FULL:
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return tasks[NR_IOWAIT] && !tasks[NR_RUNNING];
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case PSI_MEM_SOME:
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return tasks[NR_MEMSTALL];
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case PSI_MEM_FULL:
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return tasks[NR_MEMSTALL] && !tasks[NR_RUNNING];
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case PSI_CPU_SOME:
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return tasks[NR_RUNNING] > 1;
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case PSI_NONIDLE:
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return tasks[NR_IOWAIT] || tasks[NR_MEMSTALL] ||
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tasks[NR_RUNNING];
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default:
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return false;
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}
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}
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static void get_recent_times(struct psi_group *group, int cpu, u32 *times)
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{
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struct psi_group_cpu *groupc = per_cpu_ptr(group->pcpu, cpu);
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unsigned int tasks[NR_PSI_TASK_COUNTS];
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u64 now, state_start;
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unsigned int seq;
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int s;
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/* Snapshot a coherent view of the CPU state */
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do {
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seq = read_seqcount_begin(&groupc->seq);
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now = cpu_clock(cpu);
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memcpy(times, groupc->times, sizeof(groupc->times));
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memcpy(tasks, groupc->tasks, sizeof(groupc->tasks));
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state_start = groupc->state_start;
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} while (read_seqcount_retry(&groupc->seq, seq));
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/* Calculate state time deltas against the previous snapshot */
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for (s = 0; s < NR_PSI_STATES; s++) {
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u32 delta;
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/*
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* In addition to already concluded states, we also
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* incorporate currently active states on the CPU,
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* since states may last for many sampling periods.
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*
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* This way we keep our delta sampling buckets small
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* (u32) and our reported pressure close to what's
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* actually happening.
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*/
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if (test_state(tasks, s))
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times[s] += now - state_start;
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delta = times[s] - groupc->times_prev[s];
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groupc->times_prev[s] = times[s];
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times[s] = delta;
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}
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}
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static void calc_avgs(unsigned long avg[3], int missed_periods,
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u64 time, u64 period)
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{
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unsigned long pct;
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/* Fill in zeroes for periods of no activity */
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if (missed_periods) {
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avg[0] = calc_load_n(avg[0], EXP_10s, 0, missed_periods);
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avg[1] = calc_load_n(avg[1], EXP_60s, 0, missed_periods);
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avg[2] = calc_load_n(avg[2], EXP_300s, 0, missed_periods);
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}
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/* Sample the most recent active period */
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pct = div_u64(time * 100, period);
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pct *= FIXED_1;
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avg[0] = calc_load(avg[0], EXP_10s, pct);
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avg[1] = calc_load(avg[1], EXP_60s, pct);
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avg[2] = calc_load(avg[2], EXP_300s, pct);
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}
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static bool update_stats(struct psi_group *group)
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{
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u64 deltas[NR_PSI_STATES - 1] = { 0, };
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unsigned long missed_periods = 0;
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unsigned long nonidle_total = 0;
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u64 now, expires, period;
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int cpu;
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int s;
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mutex_lock(&group->stat_lock);
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/*
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* Collect the per-cpu time buckets and average them into a
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* single time sample that is normalized to wallclock time.
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*
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* For averaging, each CPU is weighted by its non-idle time in
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* the sampling period. This eliminates artifacts from uneven
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* loading, or even entirely idle CPUs.
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*/
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for_each_possible_cpu(cpu) {
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u32 times[NR_PSI_STATES];
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u32 nonidle;
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get_recent_times(group, cpu, times);
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nonidle = nsecs_to_jiffies(times[PSI_NONIDLE]);
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nonidle_total += nonidle;
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for (s = 0; s < PSI_NONIDLE; s++)
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deltas[s] += (u64)times[s] * nonidle;
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}
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/*
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* Integrate the sample into the running statistics that are
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* reported to userspace: the cumulative stall times and the
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* decaying averages.
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*
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* Pressure percentages are sampled at PSI_FREQ. We might be
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* called more often when the user polls more frequently than
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* that; we might be called less often when there is no task
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* activity, thus no data, and clock ticks are sporadic. The
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* below handles both.
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*/
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/* total= */
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for (s = 0; s < NR_PSI_STATES - 1; s++)
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group->total[s] += div_u64(deltas[s], max(nonidle_total, 1UL));
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/* avgX= */
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now = sched_clock();
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expires = group->next_update;
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if (now < expires)
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goto out;
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if (now - expires >= psi_period)
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missed_periods = div_u64(now - expires, psi_period);
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/*
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* The periodic clock tick can get delayed for various
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* reasons, especially on loaded systems. To avoid clock
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* drift, we schedule the clock in fixed psi_period intervals.
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* But the deltas we sample out of the per-cpu buckets above
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* are based on the actual time elapsing between clock ticks.
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*/
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group->next_update = expires + ((1 + missed_periods) * psi_period);
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period = now - (group->last_update + (missed_periods * psi_period));
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group->last_update = now;
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for (s = 0; s < NR_PSI_STATES - 1; s++) {
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u32 sample;
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sample = group->total[s] - group->total_prev[s];
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/*
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* Due to the lockless sampling of the time buckets,
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* recorded time deltas can slip into the next period,
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* which under full pressure can result in samples in
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* excess of the period length.
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*
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* We don't want to report non-sensical pressures in
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* excess of 100%, nor do we want to drop such events
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* on the floor. Instead we punt any overage into the
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* future until pressure subsides. By doing this we
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* don't underreport the occurring pressure curve, we
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* just report it delayed by one period length.
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*
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* The error isn't cumulative. As soon as another
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* delta slips from a period P to P+1, by definition
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* it frees up its time T in P.
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*/
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if (sample > period)
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sample = period;
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group->total_prev[s] += sample;
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calc_avgs(group->avg[s], missed_periods, sample, period);
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}
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out:
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mutex_unlock(&group->stat_lock);
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return nonidle_total;
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}
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static void psi_update_work(struct work_struct *work)
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{
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struct delayed_work *dwork;
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struct psi_group *group;
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bool nonidle;
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dwork = to_delayed_work(work);
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group = container_of(dwork, struct psi_group, clock_work);
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/*
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* If there is task activity, periodically fold the per-cpu
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* times and feed samples into the running averages. If things
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* are idle and there is no data to process, stop the clock.
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* Once restarted, we'll catch up the running averages in one
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* go - see calc_avgs() and missed_periods.
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*/
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nonidle = update_stats(group);
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if (nonidle) {
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unsigned long delay = 0;
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u64 now;
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now = sched_clock();
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if (group->next_update > now)
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delay = nsecs_to_jiffies(group->next_update - now) + 1;
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schedule_delayed_work(dwork, delay);
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}
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}
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static void record_times(struct psi_group_cpu *groupc, int cpu,
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bool memstall_tick)
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{
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u32 delta;
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u64 now;
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now = cpu_clock(cpu);
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delta = now - groupc->state_start;
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groupc->state_start = now;
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if (test_state(groupc->tasks, PSI_IO_SOME)) {
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groupc->times[PSI_IO_SOME] += delta;
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if (test_state(groupc->tasks, PSI_IO_FULL))
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groupc->times[PSI_IO_FULL] += delta;
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}
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if (test_state(groupc->tasks, PSI_MEM_SOME)) {
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groupc->times[PSI_MEM_SOME] += delta;
|
|
if (test_state(groupc->tasks, PSI_MEM_FULL))
|
|
groupc->times[PSI_MEM_FULL] += delta;
|
|
else if (memstall_tick) {
|
|
u32 sample;
|
|
/*
|
|
* Since we care about lost potential, a
|
|
* memstall is FULL when there are no other
|
|
* working tasks, but also when the CPU is
|
|
* actively reclaiming and nothing productive
|
|
* could run even if it were runnable.
|
|
*
|
|
* When the timer tick sees a reclaiming CPU,
|
|
* regardless of runnable tasks, sample a FULL
|
|
* tick (or less if it hasn't been a full tick
|
|
* since the last state change).
|
|
*/
|
|
sample = min(delta, (u32)jiffies_to_nsecs(1));
|
|
groupc->times[PSI_MEM_FULL] += sample;
|
|
}
|
|
}
|
|
|
|
if (test_state(groupc->tasks, PSI_CPU_SOME))
|
|
groupc->times[PSI_CPU_SOME] += delta;
|
|
|
|
if (test_state(groupc->tasks, PSI_NONIDLE))
|
|
groupc->times[PSI_NONIDLE] += delta;
|
|
}
|
|
|
|
static void psi_group_change(struct psi_group *group, int cpu,
|
|
unsigned int clear, unsigned int set)
|
|
{
|
|
struct psi_group_cpu *groupc;
|
|
unsigned int t, m;
|
|
|
|
groupc = per_cpu_ptr(group->pcpu, cpu);
|
|
|
|
/*
|
|
* First we assess the aggregate resource states this CPU's
|
|
* tasks have been in since the last change, and account any
|
|
* SOME and FULL time these may have resulted in.
|
|
*
|
|
* Then we update the task counts according to the state
|
|
* change requested through the @clear and @set bits.
|
|
*/
|
|
write_seqcount_begin(&groupc->seq);
|
|
|
|
record_times(groupc, cpu, false);
|
|
|
|
for (t = 0, m = clear; m; m &= ~(1 << t), t++) {
|
|
if (!(m & (1 << t)))
|
|
continue;
|
|
if (groupc->tasks[t] == 0 && !psi_bug) {
|
|
printk_deferred(KERN_ERR "psi: task underflow! cpu=%d t=%d tasks=[%u %u %u] clear=%x set=%x\n",
|
|
cpu, t, groupc->tasks[0],
|
|
groupc->tasks[1], groupc->tasks[2],
|
|
clear, set);
|
|
psi_bug = 1;
|
|
}
|
|
groupc->tasks[t]--;
|
|
}
|
|
|
|
for (t = 0; set; set &= ~(1 << t), t++)
|
|
if (set & (1 << t))
|
|
groupc->tasks[t]++;
|
|
|
|
write_seqcount_end(&groupc->seq);
|
|
}
|
|
|
|
static struct psi_group *iterate_groups(struct task_struct *task, void **iter)
|
|
{
|
|
#ifdef CONFIG_CGROUPS
|
|
struct cgroup *cgroup = NULL;
|
|
|
|
if (!*iter)
|
|
cgroup = task->cgroups->dfl_cgrp;
|
|
else if (*iter == &psi_system)
|
|
return NULL;
|
|
else
|
|
cgroup = cgroup_parent(*iter);
|
|
|
|
if (cgroup && cgroup_parent(cgroup)) {
|
|
*iter = cgroup;
|
|
return cgroup_psi(cgroup);
|
|
}
|
|
#else
|
|
if (*iter)
|
|
return NULL;
|
|
#endif
|
|
*iter = &psi_system;
|
|
return &psi_system;
|
|
}
|
|
|
|
void psi_task_change(struct task_struct *task, int clear, int set)
|
|
{
|
|
int cpu = task_cpu(task);
|
|
struct psi_group *group;
|
|
bool wake_clock = true;
|
|
void *iter = NULL;
|
|
|
|
if (!task->pid)
|
|
return;
|
|
|
|
if (((task->psi_flags & set) ||
|
|
(task->psi_flags & clear) != clear) &&
|
|
!psi_bug) {
|
|
printk_deferred(KERN_ERR "psi: inconsistent task state! task=%d:%s cpu=%d psi_flags=%x clear=%x set=%x\n",
|
|
task->pid, task->comm, cpu,
|
|
task->psi_flags, clear, set);
|
|
psi_bug = 1;
|
|
}
|
|
|
|
task->psi_flags &= ~clear;
|
|
task->psi_flags |= set;
|
|
|
|
/*
|
|
* Periodic aggregation shuts off if there is a period of no
|
|
* task changes, so we wake it back up if necessary. However,
|
|
* don't do this if the task change is the aggregation worker
|
|
* itself going to sleep, or we'll ping-pong forever.
|
|
*/
|
|
if (unlikely((clear & TSK_RUNNING) &&
|
|
(task->flags & PF_WQ_WORKER) &&
|
|
wq_worker_last_func(task) == psi_update_work))
|
|
wake_clock = false;
|
|
|
|
while ((group = iterate_groups(task, &iter))) {
|
|
psi_group_change(group, cpu, clear, set);
|
|
if (wake_clock && !delayed_work_pending(&group->clock_work))
|
|
schedule_delayed_work(&group->clock_work, PSI_FREQ);
|
|
}
|
|
}
|
|
|
|
void psi_memstall_tick(struct task_struct *task, int cpu)
|
|
{
|
|
struct psi_group *group;
|
|
void *iter = NULL;
|
|
|
|
while ((group = iterate_groups(task, &iter))) {
|
|
struct psi_group_cpu *groupc;
|
|
|
|
groupc = per_cpu_ptr(group->pcpu, cpu);
|
|
write_seqcount_begin(&groupc->seq);
|
|
record_times(groupc, cpu, true);
|
|
write_seqcount_end(&groupc->seq);
|
|
}
|
|
}
|
|
|
|
/**
|
|
* psi_memstall_enter - mark the beginning of a memory stall section
|
|
* @flags: flags to handle nested sections
|
|
*
|
|
* Marks the calling task as being stalled due to a lack of memory,
|
|
* such as waiting for a refault or performing reclaim.
|
|
*/
|
|
void psi_memstall_enter(unsigned long *flags)
|
|
{
|
|
struct rq_flags rf;
|
|
struct rq *rq;
|
|
|
|
if (static_branch_likely(&psi_disabled))
|
|
return;
|
|
|
|
*flags = current->flags & PF_MEMSTALL;
|
|
if (*flags)
|
|
return;
|
|
/*
|
|
* PF_MEMSTALL setting & accounting needs to be atomic wrt
|
|
* changes to the task's scheduling state, otherwise we can
|
|
* race with CPU migration.
|
|
*/
|
|
rq = this_rq_lock_irq(&rf);
|
|
|
|
current->flags |= PF_MEMSTALL;
|
|
psi_task_change(current, 0, TSK_MEMSTALL);
|
|
|
|
rq_unlock_irq(rq, &rf);
|
|
}
|
|
|
|
/**
|
|
* psi_memstall_leave - mark the end of an memory stall section
|
|
* @flags: flags to handle nested memdelay sections
|
|
*
|
|
* Marks the calling task as no longer stalled due to lack of memory.
|
|
*/
|
|
void psi_memstall_leave(unsigned long *flags)
|
|
{
|
|
struct rq_flags rf;
|
|
struct rq *rq;
|
|
|
|
if (static_branch_likely(&psi_disabled))
|
|
return;
|
|
|
|
if (*flags)
|
|
return;
|
|
/*
|
|
* PF_MEMSTALL clearing & accounting needs to be atomic wrt
|
|
* changes to the task's scheduling state, otherwise we could
|
|
* race with CPU migration.
|
|
*/
|
|
rq = this_rq_lock_irq(&rf);
|
|
|
|
current->flags &= ~PF_MEMSTALL;
|
|
psi_task_change(current, TSK_MEMSTALL, 0);
|
|
|
|
rq_unlock_irq(rq, &rf);
|
|
}
|
|
|
|
#ifdef CONFIG_CGROUPS
|
|
int psi_cgroup_alloc(struct cgroup *cgroup)
|
|
{
|
|
if (static_branch_likely(&psi_disabled))
|
|
return 0;
|
|
|
|
cgroup->psi.pcpu = alloc_percpu(struct psi_group_cpu);
|
|
if (!cgroup->psi.pcpu)
|
|
return -ENOMEM;
|
|
group_init(&cgroup->psi);
|
|
return 0;
|
|
}
|
|
|
|
void psi_cgroup_free(struct cgroup *cgroup)
|
|
{
|
|
if (static_branch_likely(&psi_disabled))
|
|
return;
|
|
|
|
cancel_delayed_work_sync(&cgroup->psi.clock_work);
|
|
free_percpu(cgroup->psi.pcpu);
|
|
}
|
|
|
|
/**
|
|
* cgroup_move_task - move task to a different cgroup
|
|
* @task: the task
|
|
* @to: the target css_set
|
|
*
|
|
* Move task to a new cgroup and safely migrate its associated stall
|
|
* state between the different groups.
|
|
*
|
|
* This function acquires the task's rq lock to lock out concurrent
|
|
* changes to the task's scheduling state and - in case the task is
|
|
* running - concurrent changes to its stall state.
|
|
*/
|
|
void cgroup_move_task(struct task_struct *task, struct css_set *to)
|
|
{
|
|
unsigned int task_flags = 0;
|
|
struct rq_flags rf;
|
|
struct rq *rq;
|
|
|
|
if (static_branch_likely(&psi_disabled)) {
|
|
/*
|
|
* Lame to do this here, but the scheduler cannot be locked
|
|
* from the outside, so we move cgroups from inside sched/.
|
|
*/
|
|
rcu_assign_pointer(task->cgroups, to);
|
|
return;
|
|
}
|
|
|
|
rq = task_rq_lock(task, &rf);
|
|
|
|
if (task_on_rq_queued(task))
|
|
task_flags = TSK_RUNNING;
|
|
else if (task->in_iowait)
|
|
task_flags = TSK_IOWAIT;
|
|
|
|
if (task->flags & PF_MEMSTALL)
|
|
task_flags |= TSK_MEMSTALL;
|
|
|
|
if (task_flags)
|
|
psi_task_change(task, task_flags, 0);
|
|
|
|
/* See comment above */
|
|
rcu_assign_pointer(task->cgroups, to);
|
|
|
|
if (task_flags)
|
|
psi_task_change(task, 0, task_flags);
|
|
|
|
task_rq_unlock(rq, task, &rf);
|
|
}
|
|
#endif /* CONFIG_CGROUPS */
|
|
|
|
int psi_show(struct seq_file *m, struct psi_group *group, enum psi_res res)
|
|
{
|
|
int full;
|
|
|
|
if (static_branch_likely(&psi_disabled))
|
|
return -EOPNOTSUPP;
|
|
|
|
update_stats(group);
|
|
|
|
for (full = 0; full < 2 - (res == PSI_CPU); full++) {
|
|
unsigned long avg[3];
|
|
u64 total;
|
|
int w;
|
|
|
|
for (w = 0; w < 3; w++)
|
|
avg[w] = group->avg[res * 2 + full][w];
|
|
total = div_u64(group->total[res * 2 + full], NSEC_PER_USEC);
|
|
|
|
seq_printf(m, "%s avg10=%lu.%02lu avg60=%lu.%02lu avg300=%lu.%02lu total=%llu\n",
|
|
full ? "full" : "some",
|
|
LOAD_INT(avg[0]), LOAD_FRAC(avg[0]),
|
|
LOAD_INT(avg[1]), LOAD_FRAC(avg[1]),
|
|
LOAD_INT(avg[2]), LOAD_FRAC(avg[2]),
|
|
total);
|
|
}
|
|
|
|
return 0;
|
|
}
|
|
|
|
static int psi_io_show(struct seq_file *m, void *v)
|
|
{
|
|
return psi_show(m, &psi_system, PSI_IO);
|
|
}
|
|
|
|
static int psi_memory_show(struct seq_file *m, void *v)
|
|
{
|
|
return psi_show(m, &psi_system, PSI_MEM);
|
|
}
|
|
|
|
static int psi_cpu_show(struct seq_file *m, void *v)
|
|
{
|
|
return psi_show(m, &psi_system, PSI_CPU);
|
|
}
|
|
|
|
static int psi_io_open(struct inode *inode, struct file *file)
|
|
{
|
|
return single_open(file, psi_io_show, NULL);
|
|
}
|
|
|
|
static int psi_memory_open(struct inode *inode, struct file *file)
|
|
{
|
|
return single_open(file, psi_memory_show, NULL);
|
|
}
|
|
|
|
static int psi_cpu_open(struct inode *inode, struct file *file)
|
|
{
|
|
return single_open(file, psi_cpu_show, NULL);
|
|
}
|
|
|
|
static const struct file_operations psi_io_fops = {
|
|
.open = psi_io_open,
|
|
.read = seq_read,
|
|
.llseek = seq_lseek,
|
|
.release = single_release,
|
|
};
|
|
|
|
static const struct file_operations psi_memory_fops = {
|
|
.open = psi_memory_open,
|
|
.read = seq_read,
|
|
.llseek = seq_lseek,
|
|
.release = single_release,
|
|
};
|
|
|
|
static const struct file_operations psi_cpu_fops = {
|
|
.open = psi_cpu_open,
|
|
.read = seq_read,
|
|
.llseek = seq_lseek,
|
|
.release = single_release,
|
|
};
|
|
|
|
static int __init psi_proc_init(void)
|
|
{
|
|
proc_mkdir("pressure", NULL);
|
|
proc_create("pressure/io", 0, NULL, &psi_io_fops);
|
|
proc_create("pressure/memory", 0, NULL, &psi_memory_fops);
|
|
proc_create("pressure/cpu", 0, NULL, &psi_cpu_fops);
|
|
return 0;
|
|
}
|
|
module_init(psi_proc_init);
|