xref: /linux/Documentation/scheduler/schedutil.rst (revision da1d9caf95def6f0320819cf941c9fd1069ba9e1)
1=========
2Schedutil
3=========
4
5.. note::
6
7   All this assumes a linear relation between frequency and work capacity,
8   we know this is flawed, but it is the best workable approximation.
9
10
11PELT (Per Entity Load Tracking)
12===============================
13
14With PELT we track some metrics across the various scheduler entities, from
15individual tasks to task-group slices to CPU runqueues. As the basis for this
16we use an Exponentially Weighted Moving Average (EWMA), each period (1024us)
17is decayed such that y^32 = 0.5. That is, the most recent 32ms contribute
18half, while the rest of history contribute the other half.
19
20Specifically:
21
22  ewma_sum(u) := u_0 + u_1*y + u_2*y^2 + ...
23
24  ewma(u) = ewma_sum(u) / ewma_sum(1)
25
26Since this is essentially a progression of an infinite geometric series, the
27results are composable, that is ewma(A) + ewma(B) = ewma(A+B). This property
28is key, since it gives the ability to recompose the averages when tasks move
29around.
30
31Note that blocked tasks still contribute to the aggregates (task-group slices
32and CPU runqueues), which reflects their expected contribution when they
33resume running.
34
35Using this we track 2 key metrics: 'running' and 'runnable'. 'Running'
36reflects the time an entity spends on the CPU, while 'runnable' reflects the
37time an entity spends on the runqueue. When there is only a single task these
38two metrics are the same, but once there is contention for the CPU 'running'
39will decrease to reflect the fraction of time each task spends on the CPU
40while 'runnable' will increase to reflect the amount of contention.
41
42For more detail see: kernel/sched/pelt.c
43
44
45Frequency / CPU Invariance
46==========================
47
48Because consuming the CPU for 50% at 1GHz is not the same as consuming the CPU
49for 50% at 2GHz, nor is running 50% on a LITTLE CPU the same as running 50% on
50a big CPU, we allow architectures to scale the time delta with two ratios, one
51Dynamic Voltage and Frequency Scaling (DVFS) ratio and one microarch ratio.
52
53For simple DVFS architectures (where software is in full control) we trivially
54compute the ratio as::
55
56	    f_cur
57  r_dvfs := -----
58            f_max
59
60For more dynamic systems where the hardware is in control of DVFS we use
61hardware counters (Intel APERF/MPERF, ARMv8.4-AMU) to provide us this ratio.
62For Intel specifically, we use::
63
64	   APERF
65  f_cur := ----- * P0
66	   MPERF
67
68	     4C-turbo;	if available and turbo enabled
69  f_max := { 1C-turbo;	if turbo enabled
70	     P0;	otherwise
71
72                    f_cur
73  r_dvfs := min( 1, ----- )
74                    f_max
75
76We pick 4C turbo over 1C turbo to make it slightly more sustainable.
77
78r_cpu is determined as the ratio of highest performance level of the current
79CPU vs the highest performance level of any other CPU in the system.
80
81  r_tot = r_dvfs * r_cpu
82
83The result is that the above 'running' and 'runnable' metrics become invariant
84of DVFS and CPU type. IOW. we can transfer and compare them between CPUs.
85
86For more detail see:
87
88 - kernel/sched/pelt.h:update_rq_clock_pelt()
89 - arch/x86/kernel/smpboot.c:"APERF/MPERF frequency ratio computation."
90 - Documentation/scheduler/sched-capacity.rst:"1. CPU Capacity + 2. Task utilization"
91
92
93UTIL_EST / UTIL_EST_FASTUP
94==========================
95
96Because periodic tasks have their averages decayed while they sleep, even
97though when running their expected utilization will be the same, they suffer a
98(DVFS) ramp-up after they are running again.
99
100To alleviate this (a default enabled option) UTIL_EST drives an Infinite
101Impulse Response (IIR) EWMA with the 'running' value on dequeue -- when it is
102highest. A further default enabled option UTIL_EST_FASTUP modifies the IIR
103filter to instantly increase and only decay on decrease.
104
105A further runqueue wide sum (of runnable tasks) is maintained of:
106
107  util_est := \Sum_t max( t_running, t_util_est_ewma )
108
109For more detail see: kernel/sched/fair.c:util_est_dequeue()
110
111
112UCLAMP
113======
114
115It is possible to set effective u_min and u_max clamps on each CFS or RT task;
116the runqueue keeps an max aggregate of these clamps for all running tasks.
117
118For more detail see: include/uapi/linux/sched/types.h
119
120
121Schedutil / DVFS
122================
123
124Every time the scheduler load tracking is updated (task wakeup, task
125migration, time progression) we call out to schedutil to update the hardware
126DVFS state.
127
128The basis is the CPU runqueue's 'running' metric, which per the above it is
129the frequency invariant utilization estimate of the CPU. From this we compute
130a desired frequency like::
131
132             max( running, util_est );	if UTIL_EST
133  u_cfs := { running;			otherwise
134
135               clamp( u_cfs + u_rt , u_min, u_max );	if UCLAMP_TASK
136  u_clamp := { u_cfs + u_rt;				otherwise
137
138  u := u_clamp + u_irq + u_dl;		[approx. see source for more detail]
139
140  f_des := min( f_max, 1.25 u * f_max )
141
142XXX IO-wait: when the update is due to a task wakeup from IO-completion we
143boost 'u' above.
144
145This frequency is then used to select a P-state/OPP or directly munged into a
146CPPC style request to the hardware.
147
148XXX: deadline tasks (Sporadic Task Model) allows us to calculate a hard f_min
149required to satisfy the workload.
150
151Because these callbacks are directly from the scheduler, the DVFS hardware
152interaction should be 'fast' and non-blocking. Schedutil supports
153rate-limiting DVFS requests for when hardware interaction is slow and
154expensive, this reduces effectiveness.
155
156For more information see: kernel/sched/cpufreq_schedutil.c
157
158
159NOTES
160=====
161
162 - On low-load scenarios, where DVFS is most relevant, the 'running' numbers
163   will closely reflect utilization.
164
165 - In saturated scenarios task movement will cause some transient dips,
166   suppose we have a CPU saturated with 4 tasks, then when we migrate a task
167   to an idle CPU, the old CPU will have a 'running' value of 0.75 while the
168   new CPU will gain 0.25. This is inevitable and time progression will
169   correct this. XXX do we still guarantee f_max due to no idle-time?
170
171 - Much of the above is about avoiding DVFS dips, and independent DVFS domains
172   having to re-learn / ramp-up when load shifts.
173
174