Currently: rewrite of CPU_Frequency_Scaling#CPU_frequency_driver
CPU frequency scaling enables the operating system to scale the CPU speed up or down in order to save power. CPU frequencies can be scaled automatically depending on the system load, in response to ACPI events, or manually by userspace programs.
- 1 Introduction
- 2 The CPU frequency driver
- 3 Scaling governors
- 4 Fine-tuning governors
- 5 User-space tools
- 6 Troubleshooting
- 7 External Links
Configuration of CPU frequency scaling is done through three mechanics:
- The CPU frequency driver
- The scaling governor
- Fine-tuning of the governor through user-space tools
Since kernel 3.4 the necessary CPU frequency driver modules are loaded automatically and the recommended ondemand governor is enabled by default. This leaves the user with a functional, on-demand, CPU frequency scaling setup requiring no intervention from user-space.
User-space applications like cpupower, acpid, laptop-mode-tools, or GUI tools provided for your desktop environment, may still be used for advanced configuration.
The CPU frequency driver
In order for frequency scaling to work properly, the operating system must first know the CPU(s) specification. To accomplish this, a kernel module must be loaded that can read and manage the CPU p(ower)-states.
- CPUFreq driver which utilizes the ACPI Processor Performance States. This driver also supports Intel Enhanced SpeedStep (previously supported by the deprecated speedstep-centrino module).
- CPUFreq driver for certain mobile Intel Pentium III (Coppermine), all mobile Intel Pentium III-M (Tualatin) and all mobile Intel Pentium 4 P4-M on systems which have an Intel ICH2, ICH3 or ICH4 southbridge.
- CPUFreq driver for certain mobile Intel Pentium III (Coppermine), all mobile Intel Pentium III-M (Tualatin) on systems which have an Intel 440BX/ZX/MX southbridge.
- CPUFreq driver for K8/K10 Athlon64/Opteron/Phenom processors.
- CPUFreq driver for mobile AMD K7 mobile processors.
- CPUFreq driver for FSB changing on nVidia nForce2 platforms. (AMD K7, Socket A)
- This driver supports Processor Clocking Control interface by Hewlett-Packard and Microsoft Corporation which is useful on some Proliant servers.
- CPUFreq driver for Intel Pentium 4 / Xeon / Celeron processors. When enabled it will lower CPU temperature by skipping clocks. You probably want to use a Speedstep driver instead.
You can check if the appropriate module for your processor has been loaded with
lsmod, part of .
[user@host ~]$ dmesg | grep powernow [ 4.748680] powernow-k8: Found 1 AMD Phenom(tm) II X4 955 Processor (4 cpu cores) (version 2.20.00) [ 4.748709] powernow-k8: 0 : pstate 0 (3200 MHz) [ 4.748710] powernow-k8: 1 : pstate 1 (2500 MHz) [ 4.748711] powernow-k8: 2 : pstate 2 (2100 MHz) [ 4.748712] powernow-k8: 3 : pstate 3 (800 MHz)
Governors can be thought of as pre-configured power schemes for the CPU, they alter the CPU's predefined power state that is exposed through the CPU frequency scaling driver. These governors can be built into the kernel or be made available as separate modules which must be loaded to be seen by user space applications. Users can load as many governors as desired, only one will be active on a CPU at any given time.
For Desktops and most systems, the ondemand governor can provide the best compromise between heat emission, power consumption, performance, and manageability. For Laptops or other mobile systems, the conservative governor can provide significant savings in power consumption.
- Dynamically switches between the CPU(s) available clock speeds based on system load
- The performance governor runs the CPU(s) at maximum clock speed
- Similar to
ondemand, but the CPU(s) clock speed switches gradually through all its available frequencies based on system load
- Runs the CPU(s) at minimum speed
- Manually configured clock speeds by user
The governors ondemand and performance are built into the kernel and do not need to be loaded as modules to be activated. If you want to use one of the other governors, you have to load them with modprobe. For example:
# modprobe cpufreq_powersave # modprobe cpufreq_userspace
You can check the available governors:
The currently active governor can also be determined:
Improving on-demand performance
With the out-of-the-box configuration, the ondemand governor will result in a slight but measurable and noticeable loss of performance. It will not clock up the CPU when it is at lower than 95% usage, and will sample the usage at the fastest possible frequency when at full clock speeds in order to clock back down as soon as possible.
Tuning the governor for your needs can reduce the performance loss to the point where it is negligible/non-existent if you are willing to lose a lot of the power savings. If you just want to save power while idle, lowering the up_threshold to 11% and raising the sample_down_factor by an order of magnitude can accomplish this.
Tunables are available in
/sys/devices/system/cpu/cpufreq/ondemand/ once the governor is loaded and selected and can be preserved at reboot using
Starting the cpupower daemon in the background (i.e. with an
/etc/rc.conf) will likely cause
/etc/rc.local to be processed before the cpupower daemon has a chance to change the governor. Make sure that the cpupower daemon script will have finished running before the tunables are set. Example:
(sleep 10 && echo -n 25 > /sys/devices/system/cpu/cpufreq/ondemand/up_threshold) &
Changing the on-demand governor's threshold
To change when the
ondemand governor switches to a higher multiplier, one can manipulate
/sys/devices/system/cpu/cpufreq/ondemand/up_threshold. Determine the current setting by issuing the following command as root:
# cat /sys/devices/system/cpu/cpufreq/ondemand/up_threshold
The value returned should be
95, the default setting as of kernel version 3.0. This means that the
ondemand governor currently increases the clock rate if a core reaches 95% utilization. This can be changed, for example:
# echo -n 15 > /sys/devices/system/cpu/cpufreq/ondemand/up_threshold
On-demand governor sampling_down_factor
sampling_down_factor is another global ondemand global tunable.
sampling_down_factor set to
1 makes no changes from existing behavior, but having
sampling_down_factor set to a value greater than 1 (e.g. 100) causes it to act as a multiplier for the scheduling interval for re-evaluating load when the CPU is at its highest clock frequency due to high load. This improves performance by reducing the overhead of load evaluation and helping the CPU stay at its highest clock frequency when it is truly busy, rather than shifting back and forth in speed. This tunable has no effect on behavior at lower frequencies/lower CPU loads.
Read the value (default: 1):
# cat /sys/devices/system/cpu/cpufreq/ondemand/sampling_down_factor
Set the value:
# echo -n 10 > /sys/devices/system/cpu/cpufreq/ondemand/sampling_down_factor
Tuning conservative governor
Changing the conservative governor's thresholds
Determine the current
up_threshold setting by issuing the following command as root:
# cat /sys/devices/system/cpu/cpufreq/conservative/up_threshold
The value returned should be
75, the default setting as of kernel version 3.0. This means that the
conservative governor currently increases the clock rate to the next highest speed if a core reaches 75% utilization. The can be changed, for example:
# echo -n 40 > /sys/devices/system/cpu/cpufreq/conservative/up_threshold
down_threshold value can be read and modified via
/sys/devices/system/cpu/cpufreq/conservative/down_threshold. The default value should be
20 as of kernel version 3.0. This means that the
conservative governor decreases the clock rate to the next lowest speed if a core falls to 20% utilization, which is a sensible default.
While the down sampling rate can also be adjusted for the
conservative governor, increasing it may only help with occasional low usage CPU spikes during high usage applications, as the
down_threshold is a much more direct control for down scaling which does not exist on the
Be aware that setting
down_threshold too close to
up_threshold may result in constant CPU switching, which might be something desirable for certain users and not for others. Setting
up_threshold too low may result in the CPU being clocked higher than it needs sacrificing power saving for performance, and setting
up_threshold too high may result in decreased performance, but reduced power consumption. Experiment to find the optimal values for your system and your needs.
Interaction with ACPI events
Users may configure scaling governors to switch automatically based on different ACPI events such as connecting the AC adapter or closing a laptop lid. A quick example is given below, however it may be worth reading full article on acpid.
Events are defined in
/etc/acpi/handler.sh. If the package is installed, the file should already exist and be executable. For example, to change the scaling governor from
conservative when the AC adapter is disconnected and change it back if reconnected:
[...] ac_adapter) case "$2" in AC*) case "$4" in 00000000) echo "conservative" >/sys/devices/system/cpu/cpu0/cpufreq/scaling_governor echo -n $minspeed >$setspeed #/etc/laptop-mode/laptop-mode start ;; 00000001) echo "performance" >/sys/devices/system/cpu/cpu0/cpufreq/scaling_governor echo -n $maxspeed >$setspeed #/etc/laptop-mode/laptop-mode stop ;; esac ;; *) logger "ACPI action undefined: $2" ;; esac ;; [...]
Changing the CPU frequency scaling properties from the defaults set during boot can be done through several user-space tools. Features include the automated switching between governors, setting specific governors during boot and other possibly usefull command-line applications.
Official repositories, is a set of user space utilities designed to assist with CPU frequency scaling. The package is not required to use scaling, but is highly recommended because it provides useful command-line utilities and a daemon script to set the governor at boot., available in the
If the appropriate frequency scaling driver has been loaded, detailed information can be displayed:
$ cpupower frequency-info
analyzing CPU 0: driver: acpi-cpufreq CPUs which run at the same hardware frequency: 0 1 2 3 CPUs which need to have their frequency coordinated by software: 0 maximum transition latency: 10.0 us. hardware limits: 1.20 GHz - 2.40 GHz available frequency steps: 2.40 GHz, 2.40 GHz, 2.27 GHz, 2.13 GHz, 2.00 GHz, 1.87 GHz, 1.73 GHz, 1.60 GHz, 1.47 GHz, 1.33 GHz, 1.20 GHz available cpufreq governors: ondemand, performance current policy: frequency should be within 1.20 GHz and 2.40 GHz. The governor "ondemand" may decide which speed to use within this range. current CPU frequency is 1.20 GHz. boost state support: Supported: yes Active: yes 25500 MHz max turbo 4 active cores 25500 MHz max turbo 3 active cores 25500 MHz max turbo 2 active cores 25500 MHz max turbo 1 active cores
cpupower as a daemon
The cpupower daemon is capable of setting a custom configuration during boot. Available options are to be configured by editing
- governor= specify the governor to be set, see Scaling governors for a list of available governors.
- min_freq= and max_freq= set a lower and upper limit for frequency scaling.
- freq= specifies a frequency which should be held stable, governor= should not be set when using this.
- mc_scheduler=, smp_scheduler= and perf_bias= are deprecated since linux-3.5 and should not be used.
cpufrequtils has been deprecated and dropped from the official repositories in favor ofwhich has a similar configuration and provides some additional features.