Sensors, CPU & Fans Control: Difference between revisions
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= | = Sensors = | ||
== CPU temperature == | |||
* To get CPU temperature, kernel modules are needed. I2C support in particular is generally required (compile '''I2C_CHARDEV'''). | |||
* In addition, the correct modules corresponding to your chip should be added in the Hardware Monitoring support and I2C sections. One good technique is to compile everything available, then run '''sensors-detect''', which will find the correct module. Then you can delete all the other modules and rebuild the kernel. | |||
* For a recent Intel Core CPU, compile in the '''SENSORS_CORETEMP''' module (Device Drivers -> Hardware Monitoring support). | |||
* In user space, you need to emerge lm-sensors. | |||
* A KDE widget (plasmoid) is available to display current CPU temperature. You need to emerge ksysguard with the lm_sensors USE flag in order for it to work. It's not very beautiful but functional. | |||
* For an Intel i7-11700, CPU temperatures of 40-60 degrees when doing standard operations (Firefox opened with 30 tabs, Dolphin, Konsole, a few other programs) seem standard. You should reach 35-45 degrees when completely idle (with a summer outside temperature). More is not normal and can indicate a CPU cooler issue or ventilation issue. | |||
* | == Fan metrics == | ||
* lm-sensors is also needed, along with some kernel modules (same procedure as for CPU temperature above). | |||
* You may need to add the '''acpi_enforce_resources=lax''' command-line kernel boot parameter for some ASUS motherboards (like the ROG Strix Z590-I). | |||
* You can then get the current fan RPM by running the '''sensors''' program. | |||
== Asus == | |||
* On some ASUS motherboards you may need to build the Asus atk0110 ACPI module. You don't need anything else but this module is not detected by sensors-detect; you must load it manually in the configuration file, see below. | |||
* If you use the Asus atk0110 module, enter the following in /etc/conf.d/lm_sensors: | |||
MODULE_0=asus_atk0110 | |||
= Fan Control = | |||
* Fan control is better done in the BIOS. Normally it will allow you to set a fan profile, which associates a given CPU temperature with a given rotation speed. Usually you will want to keep rotation speed low to minimize noise, even if the CPU gets hot. In particular, running the fan at full speed produces a lot of noise at least on Noctua fans. | |||
* CPU temperature should be less than 45 degrees while idling, 75 degrees under normal load, and 95 degrees under heavy load (gaming). | |||
== Pulse-Width Modulation == | |||
* Modern fans implement this interface, and in theory this makes it possible to control the fan speed from the OS rather than the BIOS. In practice, I think it's hard to do so and I was not able to even obtain metrics via PWM. | |||
* Kernel modules that might be needed for this include Device Drivers -> Pulse-Width Modulation and Device Drivers -> Hardware Monitoring support -> PWM fan. | |||
= CPU Control = | |||
* Modern CPUs implement frequency scaling, which means they run at higher clocks under load and run slower when idle or under light load. | |||
* In the Linux kernel, software support is implemented in the Power management and ACPI options -> CPU frequency scaling sections. | |||
== Intel processors == | |||
* Modern Intel CPUs (recent Core models) use the P-state driver. [https://www.kernel.org/doc/html/v5.16/admin-guide/pm/intel_pstate.html Documentation is available here.] | |||
* This driver only support two governors: performance and powersave. Building other governors into the kernel is useless, they won't be used. | |||
* The performance governor produces high CPU temperatures that generally send the fans to high speeds, while powersave produces temperatures lower than 50 degrees. | |||
* You can switch the current used governor by using the cpupower program: | |||
cpupower frequency-set -g powersave | |||
* You can obtain the currently running frequency and used governor by running: | |||
cat /sys/devices/system/cpu/cpufreq/policy*/scaling_cur_freq | |||
cat /sys/devices/system/cpu/cpufreq/policy*/scaling_governor | |||
=== Updating CPU microcode === | |||
* It is recommended to update the CPU microcode at boot. With initramfs it can be done easily; add the initramfs USE flag and emerge sys-firmware/intel-microcode. It will automatically copy an '''intel-uc.img''' file to /boot. GRUB can then load this file via an initrd line normally. | |||
* It's also possible to update the CPU microcode without initramfs support. In that case the correct firmware must be identified and built into the kernel. [https://wiki.gentoo.org/wiki/Intel_microcode#New_method_without_initram-fs.2Fdisk_.28efistub_compatible.29 See this page for details.] | |||
* In any case, you can check if microcode was correctly loaded by looking at dmesg (should be the first log line). | |||
= Potential important kernel modules = | |||
* Some modules in the ACPI section (mostly for CPU frequency scaling). | |||
* Some modules in Device Drivers -> Multifunction device drivers (in particular the Intel LPSS modules?). | |||
* Some modules in Device Drivers -> X86 Platform specific drivers (Intel ones?). |
Latest revision as of 15:38, 13 July 2023
Sensors
CPU temperature
- To get CPU temperature, kernel modules are needed. I2C support in particular is generally required (compile I2C_CHARDEV).
- In addition, the correct modules corresponding to your chip should be added in the Hardware Monitoring support and I2C sections. One good technique is to compile everything available, then run sensors-detect, which will find the correct module. Then you can delete all the other modules and rebuild the kernel.
- For a recent Intel Core CPU, compile in the SENSORS_CORETEMP module (Device Drivers -> Hardware Monitoring support).
- In user space, you need to emerge lm-sensors.
- A KDE widget (plasmoid) is available to display current CPU temperature. You need to emerge ksysguard with the lm_sensors USE flag in order for it to work. It's not very beautiful but functional.
- For an Intel i7-11700, CPU temperatures of 40-60 degrees when doing standard operations (Firefox opened with 30 tabs, Dolphin, Konsole, a few other programs) seem standard. You should reach 35-45 degrees when completely idle (with a summer outside temperature). More is not normal and can indicate a CPU cooler issue or ventilation issue.
Fan metrics
- lm-sensors is also needed, along with some kernel modules (same procedure as for CPU temperature above).
- You may need to add the acpi_enforce_resources=lax command-line kernel boot parameter for some ASUS motherboards (like the ROG Strix Z590-I).
- You can then get the current fan RPM by running the sensors program.
Asus
- On some ASUS motherboards you may need to build the Asus atk0110 ACPI module. You don't need anything else but this module is not detected by sensors-detect; you must load it manually in the configuration file, see below.
- If you use the Asus atk0110 module, enter the following in /etc/conf.d/lm_sensors:
MODULE_0=asus_atk0110
Fan Control
- Fan control is better done in the BIOS. Normally it will allow you to set a fan profile, which associates a given CPU temperature with a given rotation speed. Usually you will want to keep rotation speed low to minimize noise, even if the CPU gets hot. In particular, running the fan at full speed produces a lot of noise at least on Noctua fans.
- CPU temperature should be less than 45 degrees while idling, 75 degrees under normal load, and 95 degrees under heavy load (gaming).
Pulse-Width Modulation
- Modern fans implement this interface, and in theory this makes it possible to control the fan speed from the OS rather than the BIOS. In practice, I think it's hard to do so and I was not able to even obtain metrics via PWM.
- Kernel modules that might be needed for this include Device Drivers -> Pulse-Width Modulation and Device Drivers -> Hardware Monitoring support -> PWM fan.
CPU Control
- Modern CPUs implement frequency scaling, which means they run at higher clocks under load and run slower when idle or under light load.
- In the Linux kernel, software support is implemented in the Power management and ACPI options -> CPU frequency scaling sections.
Intel processors
- Modern Intel CPUs (recent Core models) use the P-state driver. Documentation is available here.
- This driver only support two governors: performance and powersave. Building other governors into the kernel is useless, they won't be used.
- The performance governor produces high CPU temperatures that generally send the fans to high speeds, while powersave produces temperatures lower than 50 degrees.
- You can switch the current used governor by using the cpupower program:
cpupower frequency-set -g powersave
- You can obtain the currently running frequency and used governor by running:
cat /sys/devices/system/cpu/cpufreq/policy*/scaling_cur_freq cat /sys/devices/system/cpu/cpufreq/policy*/scaling_governor
Updating CPU microcode
- It is recommended to update the CPU microcode at boot. With initramfs it can be done easily; add the initramfs USE flag and emerge sys-firmware/intel-microcode. It will automatically copy an intel-uc.img file to /boot. GRUB can then load this file via an initrd line normally.
- It's also possible to update the CPU microcode without initramfs support. In that case the correct firmware must be identified and built into the kernel. See this page for details.
- In any case, you can check if microcode was correctly loaded by looking at dmesg (should be the first log line).
Potential important kernel modules
- Some modules in the ACPI section (mostly for CPU frequency scaling).
- Some modules in Device Drivers -> Multifunction device drivers (in particular the Intel LPSS modules?).
- Some modules in Device Drivers -> X86 Platform specific drivers (Intel ones?).