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     CPU frequency and voltage scaling code in the Linux(TM) kernel


		         L i n u x    C P U F r e q

		      C P U F r e q   G o v e r n o r s

		   - information for users and developers -


		    Dominik Brodowski  <linux@brodo.de>
            some additions and corrections by Nico Golde <nico@ngolde.de>



   Clock scaling allows you to change the clock speed of the CPUs on the
    fly. This is a nice method to save battery power, because the lower
            the clock speed, the less power the CPU consumes.


Contents:
---------
1.   What is a CPUFreq Governor?

2.   Governors In the Linux Kernel
2.1  Performance
2.2  Powersave
2.3  Userspace
2.4  Ondemand
2.5  Conservative
2.6  Interactive

3.   The Governor Interface in the CPUfreq Core



1. What Is A CPUFreq Governor?
==============================

Most cpufreq drivers (in fact, all except one, longrun) or even most
cpu frequency scaling algorithms only offer the CPU to be set to one
frequency. In order to offer dynamic frequency scaling, the cpufreq
core must be able to tell these drivers of a "target frequency". So
these specific drivers will be transformed to offer a "->target"
call instead of the existing "->setpolicy" call. For "longrun", all
stays the same, though.

How to decide what frequency within the CPUfreq policy should be used?
That's done using "cpufreq governors". Two are already in this patch
-- they're the already existing "powersave" and "performance" which
set the frequency statically to the lowest or highest frequency,
respectively. At least two more such governors will be ready for
addition in the near future, but likely many more as there are various
different theories and models about dynamic frequency scaling
around. Using such a generic interface as cpufreq offers to scaling
governors, these can be tested extensively, and the best one can be
selected for each specific use.

Basically, it's the following flow graph:

CPU can be set to switch independently	 |	   CPU can only be set
      within specific "limits"		 |       to specific frequencies

                                 "CPUfreq policy"
		consists of frequency limits (policy->{min,max})
  		     and CPUfreq governor to be used
			 /		      \
			/		       \
		       /		       the cpufreq governor decides
		      /			       (dynamically or statically)
		     /			       what target_freq to set within
		    /			       the limits of policy->{min,max}
		   /			            \
		  /				     \
	Using the ->setpolicy call,		 Using the ->target call,
	    the limits and the			  the frequency closest
	     "policy" is set.			  to target_freq is set.
						  It is assured that it
						  is within policy->{min,max}


2. Governors In the Linux Kernel
================================

2.1 Performance
---------------

The CPUfreq governor "performance" sets the CPU statically to the
highest frequency within the borders of scaling_min_freq and
scaling_max_freq.


2.2 Powersave
-------------

The CPUfreq governor "powersave" sets the CPU statically to the
lowest frequency within the borders of scaling_min_freq and
scaling_max_freq.


2.3 Userspace
-------------

The CPUfreq governor "userspace" allows the user, or any userspace
program running with UID "root", to set the CPU to a specific frequency
by making a sysfs file "scaling_setspeed" available in the CPU-device
directory.


2.4 Ondemand
------------

The CPUfreq governor "ondemand" sets the CPU depending on the
current usage. To do this the CPU must have the capability to
switch the frequency very quickly.  There are a number of sysfs file
accessible parameters:

sampling_rate: measured in uS (10^-6 seconds), this is how often you
want the kernel to look at the CPU usage and to make decisions on
what to do about the frequency.  Typically this is set to values of
around '10000' or more. It's default value is (cmp. with users-guide.txt):
transition_latency * 1000
Be aware that transition latency is in ns and sampling_rate is in us, so you
get the same sysfs value by default.
Sampling rate should always get adjusted considering the transition latency
To set the sampling rate 750 times as high as the transition latency
in the bash (as said, 1000 is default), do:
echo `$(($(cat cpuinfo_transition_latency) * 750 / 1000)) \
    >ondemand/sampling_rate

sampling_rate_min:
The sampling rate is limited by the HW transition latency:
transition_latency * 100
Or by kernel restrictions:
If CONFIG_NO_HZ is set, the limit is 10ms fixed.
If CONFIG_NO_HZ is not set or nohz=off boot parameter is used, the
limits depend on the CONFIG_HZ option:
HZ=1000: min=20000us  (20ms)
HZ=250:  min=80000us  (80ms)
HZ=100:  min=200000us (200ms)
The highest value of kernel and HW latency restrictions is shown and
used as the minimum sampling rate.

up_threshold: defines what the average CPU usage between the samplings
of 'sampling_rate' needs to be for the kernel to make a decision on
whether it should increase the frequency.  For example when it is set
to its default value of '95' it means that between the checking
intervals the CPU needs to be on average more than 95% in use to then
decide that the CPU frequency needs to be increased.  

ignore_nice_load: this parameter takes a value of '0' or '1'. When
set to '0' (its default), all processes are counted towards the
'cpu utilisation' value.  When set to '1', the processes that are
run with a 'nice' value will not count (and thus be ignored) in the
overall usage calculation.  This is useful if you are running a CPU
intensive calculation on your laptop that you do not care how long it
takes to complete as you can 'nice' it and prevent it from taking part
in the deciding process of whether to increase your CPU frequency.

sampling_down_factor: this parameter controls the rate at which the
kernel makes a decision on when to decrease the frequency while running
at top speed. When set to 1 (the default) decisions to reevaluate load
are made at the same interval regardless of current clock speed. But
when set to greater than 1 (e.g. 100) it acts as a multiplier for the
scheduling interval for reevaluating load when the CPU is at its top
speed due to high load. This improves performance by reducing the overhead
of load evaluation and helping the CPU stay at its top speed when truly
busy, rather than shifting back and forth in speed. This tunable has no
effect on behavior at lower speeds/lower CPU loads.


2.5 Conservative
----------------

The CPUfreq governor "conservative", much like the "ondemand"
governor, sets the CPU depending on the current usage.  It differs in
behaviour in that it gracefully increases and decreases the CPU speed
rather than jumping to max speed the moment there is any load on the
CPU.  This behaviour more suitable in a battery powered environment.
The governor is tweaked in the same manner as the "ondemand" governor
through sysfs with the addition of:

freq_step: this describes what percentage steps the cpu freq should be
increased and decreased smoothly by.  By default the cpu frequency will
increase in 5% chunks of your maximum cpu frequency.  You can change this
value to anywhere between 0 and 100 where '0' will effectively lock your
CPU at a speed regardless of its load whilst '100' will, in theory, make
it behave identically to the "ondemand" governor.

down_threshold: same as the 'up_threshold' found for the "ondemand"
governor but for the opposite direction.  For example when set to its
default value of '20' it means that if the CPU usage needs to be below
20% between samples to have the frequency decreased.


2.6 Interactive
---------------

The CPUfreq governor "interactive" is designed for latency-sensitive,
interactive workloads. This governor sets the CPU speed depending on
usage, similar to "ondemand" and "conservative" governors, but with a
different set of configurable behaviors.

The tuneable values for this governor are:

target_loads: CPU load values used to adjust speed to influence the
current CPU load toward that value.  In general, the lower the target
load, the more often the governor will raise CPU speeds to bring load
below the target.  The format is a single target load, optionally
followed by pairs of CPU speeds and CPU loads to target at or above
those speeds.  Colons can be used between the speeds and associated
target loads for readability.  For example:

   85 1000000:90 1700000:99

targets CPU load 85% below speed 1GHz, 90% at or above 1GHz, until
1.7GHz and above, at which load 99% is targeted.  If speeds are
specified these must appear in ascending order.  Higher target load
values are typically specified for higher speeds, that is, target load
values also usually appear in an ascending order. The default is
target load 90% for all speeds.

min_sample_time: The minimum amount of time to spend at the current
frequency before ramping down. Default is 80000 uS.

hispeed_freq: An intermediate "hi speed" at which to initially ramp
when CPU load hits the value specified in go_hispeed_load.  If load
stays high for the amount of time specified in above_hispeed_delay,
then speed may be bumped higher.  Default is the maximum speed
allowed by the policy at governor initialization time.

go_hispeed_load: The CPU load at which to ramp to hispeed_freq.
Default is 99%.

above_hispeed_delay: When speed is at or above hispeed_freq, wait for
this long before raising speed in response to continued high load.
Default is 20000 uS.

timer_rate: Sample rate for reevaluating CPU load when the CPU is not
idle.  A deferrable timer is used, such that the CPU will not be woken
from idle to service this timer until something else needs to run.
(The maximum time to allow deferring this timer when not running at
minimum speed is configurable via timer_slack.)  Default is 20000 uS.

timer_slack: Maximum additional time to defer handling the governor
sampling timer beyond timer_rate when running at speeds above the
minimum.  For platforms that consume additional power at idle when
CPUs are running at speeds greater than minimum, this places an upper
bound on how long the timer will be deferred prior to re-evaluating
load and dropping speed.  For example, if timer_rate is 20000uS and
timer_slack is 10000uS then timers will be deferred for up to 30msec
when not at lowest speed.  A value of -1 means defer timers
indefinitely at all speeds.  Default is 80000 uS.

boost: If non-zero, immediately boost speed of all CPUs to at least
hispeed_freq until zero is written to this attribute.  If zero, allow
CPU speeds to drop below hispeed_freq according to load as usual.
Default is zero.

boostpulse: On each write, immediately boost speed of all CPUs to
hispeed_freq for at least the period of time specified by
boostpulse_duration, after which speeds are allowed to drop below
hispeed_freq according to load as usual.

boostpulse_duration: Length of time to hold CPU speed at hispeed_freq
on a write to boostpulse, before allowing speed to drop according to
load as usual.  Default is 80000 uS.


3. The Governor Interface in the CPUfreq Core
=============================================

A new governor must register itself with the CPUfreq core using
"cpufreq_register_governor". The struct cpufreq_governor, which has to
be passed to that function, must contain the following values:

governor->name -	    A unique name for this governor
governor->governor -	    The governor callback function
governor->owner	-	    .THIS_MODULE for the governor module (if 
			    appropriate)

The governor->governor callback is called with the current (or to-be-set)
cpufreq_policy struct for that CPU, and an unsigned int event. The
following events are currently defined:

CPUFREQ_GOV_START:   This governor shall start its duty for the CPU
		     policy->cpu
CPUFREQ_GOV_STOP:    This governor shall end its duty for the CPU
		     policy->cpu
CPUFREQ_GOV_LIMITS:  The limits for CPU policy->cpu have changed to
		     policy->min and policy->max.

If you need other "events" externally of your driver, _only_ use the
cpufreq_governor_l(unsigned int cpu, unsigned int event) call to the
CPUfreq core to ensure proper locking.


The CPUfreq governor may call the CPU processor driver using one of
these two functions:

int cpufreq_driver_target(struct cpufreq_policy *policy,
                                 unsigned int target_freq,
                                 unsigned int relation);

int __cpufreq_driver_target(struct cpufreq_policy *policy,
                                   unsigned int target_freq,
                                   unsigned int relation);

target_freq must be within policy->min and policy->max, of course.
What's the difference between these two functions? When your governor
still is in a direct code path of a call to governor->governor, the
per-CPU cpufreq lock is still held in the cpufreq core, and there's
no need to lock it again (in fact, this would cause a deadlock). So
use __cpufreq_driver_target only in these cases. In all other cases 
(for example, when there's a "daemonized" function that wakes up 
every second), use cpufreq_driver_target to lock the cpufreq per-CPU
lock before the command is passed to the cpufreq processor driver.