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* pm-cpufreq: cpufreq: intel_pstate: Implement passive mode with HWP enabled
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762 lines
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ReStructuredText
.. SPDX-License-Identifier: GPL-2.0
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.. include:: <isonum.txt>
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===============================================
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``intel_pstate`` CPU Performance Scaling Driver
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===============================================
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:Copyright: |copy| 2017 Intel Corporation
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:Author: Rafael J. Wysocki <rafael.j.wysocki@intel.com>
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General Information
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===================
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``intel_pstate`` is a part of the
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:doc:`CPU performance scaling subsystem <cpufreq>` in the Linux kernel
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(``CPUFreq``). It is a scaling driver for the Sandy Bridge and later
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generations of Intel processors. Note, however, that some of those processors
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may not be supported. [To understand ``intel_pstate`` it is necessary to know
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how ``CPUFreq`` works in general, so this is the time to read :doc:`cpufreq` if
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you have not done that yet.]
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For the processors supported by ``intel_pstate``, the P-state concept is broader
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than just an operating frequency or an operating performance point (see the
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LinuxCon Europe 2015 presentation by Kristen Accardi [1]_ for more
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information about that). For this reason, the representation of P-states used
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by ``intel_pstate`` internally follows the hardware specification (for details
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refer to Intel Software Developer’s Manual [2]_). However, the ``CPUFreq`` core
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uses frequencies for identifying operating performance points of CPUs and
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frequencies are involved in the user space interface exposed by it, so
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``intel_pstate`` maps its internal representation of P-states to frequencies too
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(fortunately, that mapping is unambiguous). At the same time, it would not be
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practical for ``intel_pstate`` to supply the ``CPUFreq`` core with a table of
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available frequencies due to the possible size of it, so the driver does not do
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that. Some functionality of the core is limited by that.
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Since the hardware P-state selection interface used by ``intel_pstate`` is
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available at the logical CPU level, the driver always works with individual
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CPUs. Consequently, if ``intel_pstate`` is in use, every ``CPUFreq`` policy
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object corresponds to one logical CPU and ``CPUFreq`` policies are effectively
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equivalent to CPUs. In particular, this means that they become "inactive" every
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time the corresponding CPU is taken offline and need to be re-initialized when
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it goes back online.
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``intel_pstate`` is not modular, so it cannot be unloaded, which means that the
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only way to pass early-configuration-time parameters to it is via the kernel
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command line. However, its configuration can be adjusted via ``sysfs`` to a
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great extent. In some configurations it even is possible to unregister it via
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``sysfs`` which allows another ``CPUFreq`` scaling driver to be loaded and
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registered (see `below <status_attr_>`_).
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Operation Modes
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===============
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``intel_pstate`` can operate in two different modes, active or passive. In the
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active mode, it uses its own internal performance scaling governor algorithm or
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allows the hardware to do preformance scaling by itself, while in the passive
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mode it responds to requests made by a generic ``CPUFreq`` governor implementing
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a certain performance scaling algorithm. Which of them will be in effect
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depends on what kernel command line options are used and on the capabilities of
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the processor.
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Active Mode
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-----------
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This is the default operation mode of ``intel_pstate`` for processors with
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hardware-managed P-states (HWP) support. If it works in this mode, the
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``scaling_driver`` policy attribute in ``sysfs`` for all ``CPUFreq`` policies
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contains the string "intel_pstate".
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In this mode the driver bypasses the scaling governors layer of ``CPUFreq`` and
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provides its own scaling algorithms for P-state selection. Those algorithms
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can be applied to ``CPUFreq`` policies in the same way as generic scaling
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governors (that is, through the ``scaling_governor`` policy attribute in
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``sysfs``). [Note that different P-state selection algorithms may be chosen for
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different policies, but that is not recommended.]
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They are not generic scaling governors, but their names are the same as the
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names of some of those governors. Moreover, confusingly enough, they generally
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do not work in the same way as the generic governors they share the names with.
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For example, the ``powersave`` P-state selection algorithm provided by
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``intel_pstate`` is not a counterpart of the generic ``powersave`` governor
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(roughly, it corresponds to the ``schedutil`` and ``ondemand`` governors).
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There are two P-state selection algorithms provided by ``intel_pstate`` in the
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active mode: ``powersave`` and ``performance``. The way they both operate
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depends on whether or not the hardware-managed P-states (HWP) feature has been
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enabled in the processor and possibly on the processor model.
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Which of the P-state selection algorithms is used by default depends on the
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:c:macro:`CONFIG_CPU_FREQ_DEFAULT_GOV_PERFORMANCE` kernel configuration option.
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Namely, if that option is set, the ``performance`` algorithm will be used by
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default, and the other one will be used by default if it is not set.
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Active Mode With HWP
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~~~~~~~~~~~~~~~~~~~~
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If the processor supports the HWP feature, it will be enabled during the
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processor initialization and cannot be disabled after that. It is possible
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to avoid enabling it by passing the ``intel_pstate=no_hwp`` argument to the
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kernel in the command line.
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If the HWP feature has been enabled, ``intel_pstate`` relies on the processor to
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select P-states by itself, but still it can give hints to the processor's
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internal P-state selection logic. What those hints are depends on which P-state
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selection algorithm has been applied to the given policy (or to the CPU it
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corresponds to).
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Even though the P-state selection is carried out by the processor automatically,
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``intel_pstate`` registers utilization update callbacks with the CPU scheduler
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in this mode. However, they are not used for running a P-state selection
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algorithm, but for periodic updates of the current CPU frequency information to
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be made available from the ``scaling_cur_freq`` policy attribute in ``sysfs``.
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HWP + ``performance``
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.....................
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In this configuration ``intel_pstate`` will write 0 to the processor's
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Energy-Performance Preference (EPP) knob (if supported) or its
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Energy-Performance Bias (EPB) knob (otherwise), which means that the processor's
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internal P-state selection logic is expected to focus entirely on performance.
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This will override the EPP/EPB setting coming from the ``sysfs`` interface
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(see `Energy vs Performance Hints`_ below).
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Also, in this configuration the range of P-states available to the processor's
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internal P-state selection logic is always restricted to the upper boundary
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(that is, the maximum P-state that the driver is allowed to use).
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HWP + ``powersave``
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...................
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In this configuration ``intel_pstate`` will set the processor's
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Energy-Performance Preference (EPP) knob (if supported) or its
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Energy-Performance Bias (EPB) knob (otherwise) to whatever value it was
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previously set to via ``sysfs`` (or whatever default value it was
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set to by the platform firmware). This usually causes the processor's
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internal P-state selection logic to be less performance-focused.
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Active Mode Without HWP
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~~~~~~~~~~~~~~~~~~~~~~~
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This operation mode is optional for processors that do not support the HWP
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feature or when the ``intel_pstate=no_hwp`` argument is passed to the kernel in
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the command line. The active mode is used in those cases if the
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``intel_pstate=active`` argument is passed to the kernel in the command line.
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In this mode ``intel_pstate`` may refuse to work with processors that are not
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recognized by it. [Note that ``intel_pstate`` will never refuse to work with
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any processor with the HWP feature enabled.]
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In this mode ``intel_pstate`` registers utilization update callbacks with the
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CPU scheduler in order to run a P-state selection algorithm, either
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``powersave`` or ``performance``, depending on the ``scaling_governor`` policy
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setting in ``sysfs``. The current CPU frequency information to be made
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available from the ``scaling_cur_freq`` policy attribute in ``sysfs`` is
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periodically updated by those utilization update callbacks too.
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``performance``
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...............
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Without HWP, this P-state selection algorithm is always the same regardless of
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the processor model and platform configuration.
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It selects the maximum P-state it is allowed to use, subject to limits set via
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``sysfs``, every time the driver configuration for the given CPU is updated
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(e.g. via ``sysfs``).
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This is the default P-state selection algorithm if the
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:c:macro:`CONFIG_CPU_FREQ_DEFAULT_GOV_PERFORMANCE` kernel configuration option
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is set.
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``powersave``
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.............
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Without HWP, this P-state selection algorithm is similar to the algorithm
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implemented by the generic ``schedutil`` scaling governor except that the
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utilization metric used by it is based on numbers coming from feedback
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registers of the CPU. It generally selects P-states proportional to the
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current CPU utilization.
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This algorithm is run by the driver's utilization update callback for the
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given CPU when it is invoked by the CPU scheduler, but not more often than
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every 10 ms. Like in the ``performance`` case, the hardware configuration
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is not touched if the new P-state turns out to be the same as the current
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one.
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This is the default P-state selection algorithm if the
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:c:macro:`CONFIG_CPU_FREQ_DEFAULT_GOV_PERFORMANCE` kernel configuration option
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is not set.
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Passive Mode
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------------
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This is the default operation mode of ``intel_pstate`` for processors without
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hardware-managed P-states (HWP) support. It is always used if the
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``intel_pstate=passive`` argument is passed to the kernel in the command line
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regardless of whether or not the given processor supports HWP. [Note that the
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``intel_pstate=no_hwp`` setting causes the driver to start in the passive mode
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if it is not combined with ``intel_pstate=active``.] Like in the active mode
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without HWP support, in this mode ``intel_pstate`` may refuse to work with
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processors that are not recognized by it if HWP is prevented from being enabled
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through the kernel command line.
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If the driver works in this mode, the ``scaling_driver`` policy attribute in
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``sysfs`` for all ``CPUFreq`` policies contains the string "intel_cpufreq".
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Then, the driver behaves like a regular ``CPUFreq`` scaling driver. That is,
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it is invoked by generic scaling governors when necessary to talk to the
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hardware in order to change the P-state of a CPU (in particular, the
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``schedutil`` governor can invoke it directly from scheduler context).
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While in this mode, ``intel_pstate`` can be used with all of the (generic)
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scaling governors listed by the ``scaling_available_governors`` policy attribute
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in ``sysfs`` (and the P-state selection algorithms described above are not
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used). Then, it is responsible for the configuration of policy objects
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corresponding to CPUs and provides the ``CPUFreq`` core (and the scaling
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governors attached to the policy objects) with accurate information on the
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maximum and minimum operating frequencies supported by the hardware (including
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the so-called "turbo" frequency ranges). In other words, in the passive mode
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the entire range of available P-states is exposed by ``intel_pstate`` to the
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``CPUFreq`` core. However, in this mode the driver does not register
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utilization update callbacks with the CPU scheduler and the ``scaling_cur_freq``
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information comes from the ``CPUFreq`` core (and is the last frequency selected
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by the current scaling governor for the given policy).
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.. _turbo:
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Turbo P-states Support
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======================
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In the majority of cases, the entire range of P-states available to
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``intel_pstate`` can be divided into two sub-ranges that correspond to
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different types of processor behavior, above and below a boundary that
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will be referred to as the "turbo threshold" in what follows.
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The P-states above the turbo threshold are referred to as "turbo P-states" and
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the whole sub-range of P-states they belong to is referred to as the "turbo
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range". These names are related to the Turbo Boost technology allowing a
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multicore processor to opportunistically increase the P-state of one or more
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cores if there is enough power to do that and if that is not going to cause the
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thermal envelope of the processor package to be exceeded.
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Specifically, if software sets the P-state of a CPU core within the turbo range
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(that is, above the turbo threshold), the processor is permitted to take over
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performance scaling control for that core and put it into turbo P-states of its
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choice going forward. However, that permission is interpreted differently by
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different processor generations. Namely, the Sandy Bridge generation of
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processors will never use any P-states above the last one set by software for
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the given core, even if it is within the turbo range, whereas all of the later
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processor generations will take it as a license to use any P-states from the
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turbo range, even above the one set by software. In other words, on those
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processors setting any P-state from the turbo range will enable the processor
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to put the given core into all turbo P-states up to and including the maximum
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supported one as it sees fit.
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One important property of turbo P-states is that they are not sustainable. More
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precisely, there is no guarantee that any CPUs will be able to stay in any of
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those states indefinitely, because the power distribution within the processor
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package may change over time or the thermal envelope it was designed for might
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be exceeded if a turbo P-state was used for too long.
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In turn, the P-states below the turbo threshold generally are sustainable. In
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fact, if one of them is set by software, the processor is not expected to change
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it to a lower one unless in a thermal stress or a power limit violation
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situation (a higher P-state may still be used if it is set for another CPU in
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the same package at the same time, for example).
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Some processors allow multiple cores to be in turbo P-states at the same time,
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but the maximum P-state that can be set for them generally depends on the number
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of cores running concurrently. The maximum turbo P-state that can be set for 3
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cores at the same time usually is lower than the analogous maximum P-state for
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2 cores, which in turn usually is lower than the maximum turbo P-state that can
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be set for 1 core. The one-core maximum turbo P-state is thus the maximum
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supported one overall.
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The maximum supported turbo P-state, the turbo threshold (the maximum supported
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non-turbo P-state) and the minimum supported P-state are specific to the
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processor model and can be determined by reading the processor's model-specific
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registers (MSRs). Moreover, some processors support the Configurable TDP
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(Thermal Design Power) feature and, when that feature is enabled, the turbo
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threshold effectively becomes a configurable value that can be set by the
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platform firmware.
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Unlike ``_PSS`` objects in the ACPI tables, ``intel_pstate`` always exposes
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the entire range of available P-states, including the whole turbo range, to the
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``CPUFreq`` core and (in the passive mode) to generic scaling governors. This
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generally causes turbo P-states to be set more often when ``intel_pstate`` is
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used relative to ACPI-based CPU performance scaling (see `below <acpi-cpufreq_>`_
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for more information).
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Moreover, since ``intel_pstate`` always knows what the real turbo threshold is
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(even if the Configurable TDP feature is enabled in the processor), its
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``no_turbo`` attribute in ``sysfs`` (described `below <no_turbo_attr_>`_) should
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work as expected in all cases (that is, if set to disable turbo P-states, it
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always should prevent ``intel_pstate`` from using them).
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Processor Support
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=================
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To handle a given processor ``intel_pstate`` requires a number of different
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pieces of information on it to be known, including:
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* The minimum supported P-state.
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* The maximum supported `non-turbo P-state <turbo_>`_.
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* Whether or not turbo P-states are supported at all.
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* The maximum supported `one-core turbo P-state <turbo_>`_ (if turbo P-states
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are supported).
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* The scaling formula to translate the driver's internal representation
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of P-states into frequencies and the other way around.
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Generally, ways to obtain that information are specific to the processor model
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or family. Although it often is possible to obtain all of it from the processor
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itself (using model-specific registers), there are cases in which hardware
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manuals need to be consulted to get to it too.
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For this reason, there is a list of supported processors in ``intel_pstate`` and
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the driver initialization will fail if the detected processor is not in that
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list, unless it supports the HWP feature. [The interface to obtain all of the
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information listed above is the same for all of the processors supporting the
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HWP feature, which is why ``intel_pstate`` works with all of them.]
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User Space Interface in ``sysfs``
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=================================
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Global Attributes
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-----------------
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``intel_pstate`` exposes several global attributes (files) in ``sysfs`` to
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control its functionality at the system level. They are located in the
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``/sys/devices/system/cpu/intel_pstate/`` directory and affect all CPUs.
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Some of them are not present if the ``intel_pstate=per_cpu_perf_limits``
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argument is passed to the kernel in the command line.
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``max_perf_pct``
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Maximum P-state the driver is allowed to set in percent of the
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maximum supported performance level (the highest supported `turbo
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P-state <turbo_>`_).
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This attribute will not be exposed if the
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``intel_pstate=per_cpu_perf_limits`` argument is present in the kernel
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command line.
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``min_perf_pct``
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Minimum P-state the driver is allowed to set in percent of the
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maximum supported performance level (the highest supported `turbo
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P-state <turbo_>`_).
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This attribute will not be exposed if the
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``intel_pstate=per_cpu_perf_limits`` argument is present in the kernel
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command line.
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``num_pstates``
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Number of P-states supported by the processor (between 0 and 255
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inclusive) including both turbo and non-turbo P-states (see
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`Turbo P-states Support`_).
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The value of this attribute is not affected by the ``no_turbo``
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setting described `below <no_turbo_attr_>`_.
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This attribute is read-only.
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``turbo_pct``
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Ratio of the `turbo range <turbo_>`_ size to the size of the entire
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range of supported P-states, in percent.
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This attribute is read-only.
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.. _no_turbo_attr:
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``no_turbo``
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If set (equal to 1), the driver is not allowed to set any turbo P-states
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(see `Turbo P-states Support`_). If unset (equalt to 0, which is the
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default), turbo P-states can be set by the driver.
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[Note that ``intel_pstate`` does not support the general ``boost``
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attribute (supported by some other scaling drivers) which is replaced
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by this one.]
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This attrubute does not affect the maximum supported frequency value
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supplied to the ``CPUFreq`` core and exposed via the policy interface,
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but it affects the maximum possible value of per-policy P-state limits
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(see `Interpretation of Policy Attributes`_ below for details).
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``hwp_dynamic_boost``
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This attribute is only present if ``intel_pstate`` works in the
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`active mode with the HWP feature enabled <Active Mode With HWP_>`_ in
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the processor. If set (equal to 1), it causes the minimum P-state limit
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to be increased dynamically for a short time whenever a task previously
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waiting on I/O is selected to run on a given logical CPU (the purpose
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of this mechanism is to improve performance).
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This setting has no effect on logical CPUs whose minimum P-state limit
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is directly set to the highest non-turbo P-state or above it.
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.. _status_attr:
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``status``
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Operation mode of the driver: "active", "passive" or "off".
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"active"
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The driver is functional and in the `active mode
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<Active Mode_>`_.
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"passive"
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The driver is functional and in the `passive mode
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<Passive Mode_>`_.
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"off"
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The driver is not functional (it is not registered as a scaling
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driver with the ``CPUFreq`` core).
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This attribute can be written to in order to change the driver's
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operation mode or to unregister it. The string written to it must be
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one of the possible values of it and, if successful, the write will
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cause the driver to switch over to the operation mode represented by
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that string - or to be unregistered in the "off" case. [Actually,
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switching over from the active mode to the passive mode or the other
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way around causes the driver to be unregistered and registered again
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with a different set of callbacks, so all of its settings (the global
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as well as the per-policy ones) are then reset to their default
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values, possibly depending on the target operation mode.]
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``energy_efficiency``
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This attribute is only present on platforms with CPUs matching the Kaby
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Lake or Coffee Lake desktop CPU model. By default, energy-efficiency
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optimizations are disabled on these CPU models if HWP is enabled.
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Enabling energy-efficiency optimizations may limit maximum operating
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frequency with or without the HWP feature. With HWP enabled, the
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optimizations are done only in the turbo frequency range. Without it,
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they are done in the entire available frequency range. Setting this
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attribute to "1" enables the energy-efficiency optimizations and setting
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to "0" disables them.
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|
||
Interpretation of Policy Attributes
|
||
-----------------------------------
|
||
|
||
The interpretation of some ``CPUFreq`` policy attributes described in
|
||
:doc:`cpufreq` is special with ``intel_pstate`` as the current scaling driver
|
||
and it generally depends on the driver's `operation mode <Operation Modes_>`_.
|
||
|
||
First of all, the values of the ``cpuinfo_max_freq``, ``cpuinfo_min_freq`` and
|
||
``scaling_cur_freq`` attributes are produced by applying a processor-specific
|
||
multiplier to the internal P-state representation used by ``intel_pstate``.
|
||
Also, the values of the ``scaling_max_freq`` and ``scaling_min_freq``
|
||
attributes are capped by the frequency corresponding to the maximum P-state that
|
||
the driver is allowed to set.
|
||
|
||
If the ``no_turbo`` `global attribute <no_turbo_attr_>`_ is set, the driver is
|
||
not allowed to use turbo P-states, so the maximum value of ``scaling_max_freq``
|
||
and ``scaling_min_freq`` is limited to the maximum non-turbo P-state frequency.
|
||
Accordingly, setting ``no_turbo`` causes ``scaling_max_freq`` and
|
||
``scaling_min_freq`` to go down to that value if they were above it before.
|
||
However, the old values of ``scaling_max_freq`` and ``scaling_min_freq`` will be
|
||
restored after unsetting ``no_turbo``, unless these attributes have been written
|
||
to after ``no_turbo`` was set.
|
||
|
||
If ``no_turbo`` is not set, the maximum possible value of ``scaling_max_freq``
|
||
and ``scaling_min_freq`` corresponds to the maximum supported turbo P-state,
|
||
which also is the value of ``cpuinfo_max_freq`` in either case.
|
||
|
||
Next, the following policy attributes have special meaning if
|
||
``intel_pstate`` works in the `active mode <Active Mode_>`_:
|
||
|
||
``scaling_available_governors``
|
||
List of P-state selection algorithms provided by ``intel_pstate``.
|
||
|
||
``scaling_governor``
|
||
P-state selection algorithm provided by ``intel_pstate`` currently in
|
||
use with the given policy.
|
||
|
||
``scaling_cur_freq``
|
||
Frequency of the average P-state of the CPU represented by the given
|
||
policy for the time interval between the last two invocations of the
|
||
driver's utilization update callback by the CPU scheduler for that CPU.
|
||
|
||
One more policy attribute is present if the HWP feature is enabled in the
|
||
processor:
|
||
|
||
``base_frequency``
|
||
Shows the base frequency of the CPU. Any frequency above this will be
|
||
in the turbo frequency range.
|
||
|
||
The meaning of these attributes in the `passive mode <Passive Mode_>`_ is the
|
||
same as for other scaling drivers.
|
||
|
||
Additionally, the value of the ``scaling_driver`` attribute for ``intel_pstate``
|
||
depends on the operation mode of the driver. Namely, it is either
|
||
"intel_pstate" (in the `active mode <Active Mode_>`_) or "intel_cpufreq" (in the
|
||
`passive mode <Passive Mode_>`_).
|
||
|
||
Coordination of P-State Limits
|
||
------------------------------
|
||
|
||
``intel_pstate`` allows P-state limits to be set in two ways: with the help of
|
||
the ``max_perf_pct`` and ``min_perf_pct`` `global attributes
|
||
<Global Attributes_>`_ or via the ``scaling_max_freq`` and ``scaling_min_freq``
|
||
``CPUFreq`` policy attributes. The coordination between those limits is based
|
||
on the following rules, regardless of the current operation mode of the driver:
|
||
|
||
1. All CPUs are affected by the global limits (that is, none of them can be
|
||
requested to run faster than the global maximum and none of them can be
|
||
requested to run slower than the global minimum).
|
||
|
||
2. Each individual CPU is affected by its own per-policy limits (that is, it
|
||
cannot be requested to run faster than its own per-policy maximum and it
|
||
cannot be requested to run slower than its own per-policy minimum). The
|
||
effective performance depends on whether the platform supports per core
|
||
P-states, hyper-threading is enabled and on current performance requests
|
||
from other CPUs. When platform doesn't support per core P-states, the
|
||
effective performance can be more than the policy limits set on a CPU, if
|
||
other CPUs are requesting higher performance at that moment. Even with per
|
||
core P-states support, when hyper-threading is enabled, if the sibling CPU
|
||
is requesting higher performance, the other siblings will get higher
|
||
performance than their policy limits.
|
||
|
||
3. The global and per-policy limits can be set independently.
|
||
|
||
In the `active mode with the HWP feature enabled <Active Mode With HWP_>`_, the
|
||
resulting effective values are written into hardware registers whenever the
|
||
limits change in order to request its internal P-state selection logic to always
|
||
set P-states within these limits. Otherwise, the limits are taken into account
|
||
by scaling governors (in the `passive mode <Passive Mode_>`_) and by the driver
|
||
every time before setting a new P-state for a CPU.
|
||
|
||
Additionally, if the ``intel_pstate=per_cpu_perf_limits`` command line argument
|
||
is passed to the kernel, ``max_perf_pct`` and ``min_perf_pct`` are not exposed
|
||
at all and the only way to set the limits is by using the policy attributes.
|
||
|
||
|
||
Energy vs Performance Hints
|
||
---------------------------
|
||
|
||
If the hardware-managed P-states (HWP) is enabled in the processor, additional
|
||
attributes, intended to allow user space to help ``intel_pstate`` to adjust the
|
||
processor's internal P-state selection logic by focusing it on performance or on
|
||
energy-efficiency, or somewhere between the two extremes, are present in every
|
||
``CPUFreq`` policy directory in ``sysfs``. They are :
|
||
|
||
``energy_performance_preference``
|
||
Current value of the energy vs performance hint for the given policy
|
||
(or the CPU represented by it).
|
||
|
||
The hint can be changed by writing to this attribute.
|
||
|
||
``energy_performance_available_preferences``
|
||
List of strings that can be written to the
|
||
``energy_performance_preference`` attribute.
|
||
|
||
They represent different energy vs performance hints and should be
|
||
self-explanatory, except that ``default`` represents whatever hint
|
||
value was set by the platform firmware.
|
||
|
||
Strings written to the ``energy_performance_preference`` attribute are
|
||
internally translated to integer values written to the processor's
|
||
Energy-Performance Preference (EPP) knob (if supported) or its
|
||
Energy-Performance Bias (EPB) knob. It is also possible to write a positive
|
||
integer value between 0 to 255, if the EPP feature is present. If the EPP
|
||
feature is not present, writing integer value to this attribute is not
|
||
supported. In this case, user can use
|
||
"/sys/devices/system/cpu/cpu*/power/energy_perf_bias" interface.
|
||
|
||
[Note that tasks may by migrated from one CPU to another by the scheduler's
|
||
load-balancing algorithm and if different energy vs performance hints are
|
||
set for those CPUs, that may lead to undesirable outcomes. To avoid such
|
||
issues it is better to set the same energy vs performance hint for all CPUs
|
||
or to pin every task potentially sensitive to them to a specific CPU.]
|
||
|
||
.. _acpi-cpufreq:
|
||
|
||
``intel_pstate`` vs ``acpi-cpufreq``
|
||
====================================
|
||
|
||
On the majority of systems supported by ``intel_pstate``, the ACPI tables
|
||
provided by the platform firmware contain ``_PSS`` objects returning information
|
||
that can be used for CPU performance scaling (refer to the ACPI specification
|
||
[3]_ for details on the ``_PSS`` objects and the format of the information
|
||
returned by them).
|
||
|
||
The information returned by the ACPI ``_PSS`` objects is used by the
|
||
``acpi-cpufreq`` scaling driver. On systems supported by ``intel_pstate``
|
||
the ``acpi-cpufreq`` driver uses the same hardware CPU performance scaling
|
||
interface, but the set of P-states it can use is limited by the ``_PSS``
|
||
output.
|
||
|
||
On those systems each ``_PSS`` object returns a list of P-states supported by
|
||
the corresponding CPU which basically is a subset of the P-states range that can
|
||
be used by ``intel_pstate`` on the same system, with one exception: the whole
|
||
`turbo range <turbo_>`_ is represented by one item in it (the topmost one). By
|
||
convention, the frequency returned by ``_PSS`` for that item is greater by 1 MHz
|
||
than the frequency of the highest non-turbo P-state listed by it, but the
|
||
corresponding P-state representation (following the hardware specification)
|
||
returned for it matches the maximum supported turbo P-state (or is the
|
||
special value 255 meaning essentially "go as high as you can get").
|
||
|
||
The list of P-states returned by ``_PSS`` is reflected by the table of
|
||
available frequencies supplied by ``acpi-cpufreq`` to the ``CPUFreq`` core and
|
||
scaling governors and the minimum and maximum supported frequencies reported by
|
||
it come from that list as well. In particular, given the special representation
|
||
of the turbo range described above, this means that the maximum supported
|
||
frequency reported by ``acpi-cpufreq`` is higher by 1 MHz than the frequency
|
||
of the highest supported non-turbo P-state listed by ``_PSS`` which, of course,
|
||
affects decisions made by the scaling governors, except for ``powersave`` and
|
||
``performance``.
|
||
|
||
For example, if a given governor attempts to select a frequency proportional to
|
||
estimated CPU load and maps the load of 100% to the maximum supported frequency
|
||
(possibly multiplied by a constant), then it will tend to choose P-states below
|
||
the turbo threshold if ``acpi-cpufreq`` is used as the scaling driver, because
|
||
in that case the turbo range corresponds to a small fraction of the frequency
|
||
band it can use (1 MHz vs 1 GHz or more). In consequence, it will only go to
|
||
the turbo range for the highest loads and the other loads above 50% that might
|
||
benefit from running at turbo frequencies will be given non-turbo P-states
|
||
instead.
|
||
|
||
One more issue related to that may appear on systems supporting the
|
||
`Configurable TDP feature <turbo_>`_ allowing the platform firmware to set the
|
||
turbo threshold. Namely, if that is not coordinated with the lists of P-states
|
||
returned by ``_PSS`` properly, there may be more than one item corresponding to
|
||
a turbo P-state in those lists and there may be a problem with avoiding the
|
||
turbo range (if desirable or necessary). Usually, to avoid using turbo
|
||
P-states overall, ``acpi-cpufreq`` simply avoids using the topmost state listed
|
||
by ``_PSS``, but that is not sufficient when there are other turbo P-states in
|
||
the list returned by it.
|
||
|
||
Apart from the above, ``acpi-cpufreq`` works like ``intel_pstate`` in the
|
||
`passive mode <Passive Mode_>`_, except that the number of P-states it can set
|
||
is limited to the ones listed by the ACPI ``_PSS`` objects.
|
||
|
||
|
||
Kernel Command Line Options for ``intel_pstate``
|
||
================================================
|
||
|
||
Several kernel command line options can be used to pass early-configuration-time
|
||
parameters to ``intel_pstate`` in order to enforce specific behavior of it. All
|
||
of them have to be prepended with the ``intel_pstate=`` prefix.
|
||
|
||
``disable``
|
||
Do not register ``intel_pstate`` as the scaling driver even if the
|
||
processor is supported by it.
|
||
|
||
``active``
|
||
Register ``intel_pstate`` in the `active mode <Active Mode_>`_ to start
|
||
with.
|
||
|
||
``passive``
|
||
Register ``intel_pstate`` in the `passive mode <Passive Mode_>`_ to
|
||
start with.
|
||
|
||
``force``
|
||
Register ``intel_pstate`` as the scaling driver instead of
|
||
``acpi-cpufreq`` even if the latter is preferred on the given system.
|
||
|
||
This may prevent some platform features (such as thermal controls and
|
||
power capping) that rely on the availability of ACPI P-states
|
||
information from functioning as expected, so it should be used with
|
||
caution.
|
||
|
||
This option does not work with processors that are not supported by
|
||
``intel_pstate`` and on platforms where the ``pcc-cpufreq`` scaling
|
||
driver is used instead of ``acpi-cpufreq``.
|
||
|
||
``no_hwp``
|
||
Do not enable the hardware-managed P-states (HWP) feature even if it is
|
||
supported by the processor.
|
||
|
||
``hwp_only``
|
||
Register ``intel_pstate`` as the scaling driver only if the
|
||
hardware-managed P-states (HWP) feature is supported by the processor.
|
||
|
||
``support_acpi_ppc``
|
||
Take ACPI ``_PPC`` performance limits into account.
|
||
|
||
If the preferred power management profile in the FADT (Fixed ACPI
|
||
Description Table) is set to "Enterprise Server" or "Performance
|
||
Server", the ACPI ``_PPC`` limits are taken into account by default
|
||
and this option has no effect.
|
||
|
||
``per_cpu_perf_limits``
|
||
Use per-logical-CPU P-State limits (see `Coordination of P-state
|
||
Limits`_ for details).
|
||
|
||
|
||
Diagnostics and Tuning
|
||
======================
|
||
|
||
Trace Events
|
||
------------
|
||
|
||
There are two static trace events that can be used for ``intel_pstate``
|
||
diagnostics. One of them is the ``cpu_frequency`` trace event generally used
|
||
by ``CPUFreq``, and the other one is the ``pstate_sample`` trace event specific
|
||
to ``intel_pstate``. Both of them are triggered by ``intel_pstate`` only if
|
||
it works in the `active mode <Active Mode_>`_.
|
||
|
||
The following sequence of shell commands can be used to enable them and see
|
||
their output (if the kernel is generally configured to support event tracing)::
|
||
|
||
# cd /sys/kernel/debug/tracing/
|
||
# echo 1 > events/power/pstate_sample/enable
|
||
# echo 1 > events/power/cpu_frequency/enable
|
||
# cat trace
|
||
gnome-terminal--4510 [001] ..s. 1177.680733: pstate_sample: core_busy=107 scaled=94 from=26 to=26 mperf=1143818 aperf=1230607 tsc=29838618 freq=2474476
|
||
cat-5235 [002] ..s. 1177.681723: cpu_frequency: state=2900000 cpu_id=2
|
||
|
||
If ``intel_pstate`` works in the `passive mode <Passive Mode_>`_, the
|
||
``cpu_frequency`` trace event will be triggered either by the ``schedutil``
|
||
scaling governor (for the policies it is attached to), or by the ``CPUFreq``
|
||
core (for the policies with other scaling governors).
|
||
|
||
``ftrace``
|
||
----------
|
||
|
||
The ``ftrace`` interface can be used for low-level diagnostics of
|
||
``intel_pstate``. For example, to check how often the function to set a
|
||
P-state is called, the ``ftrace`` filter can be set to
|
||
:c:func:`intel_pstate_set_pstate`::
|
||
|
||
# cd /sys/kernel/debug/tracing/
|
||
# cat available_filter_functions | grep -i pstate
|
||
intel_pstate_set_pstate
|
||
intel_pstate_cpu_init
|
||
...
|
||
# echo intel_pstate_set_pstate > set_ftrace_filter
|
||
# echo function > current_tracer
|
||
# cat trace | head -15
|
||
# tracer: function
|
||
#
|
||
# entries-in-buffer/entries-written: 80/80 #P:4
|
||
#
|
||
# _-----=> irqs-off
|
||
# / _----=> need-resched
|
||
# | / _---=> hardirq/softirq
|
||
# || / _--=> preempt-depth
|
||
# ||| / delay
|
||
# TASK-PID CPU# |||| TIMESTAMP FUNCTION
|
||
# | | | |||| | |
|
||
Xorg-3129 [000] ..s. 2537.644844: intel_pstate_set_pstate <-intel_pstate_timer_func
|
||
gnome-terminal--4510 [002] ..s. 2537.649844: intel_pstate_set_pstate <-intel_pstate_timer_func
|
||
gnome-shell-3409 [001] ..s. 2537.650850: intel_pstate_set_pstate <-intel_pstate_timer_func
|
||
<idle>-0 [000] ..s. 2537.654843: intel_pstate_set_pstate <-intel_pstate_timer_func
|
||
|
||
|
||
References
|
||
==========
|
||
|
||
.. [1] Kristen Accardi, *Balancing Power and Performance in the Linux Kernel*,
|
||
https://events.static.linuxfound.org/sites/events/files/slides/LinuxConEurope_2015.pdf
|
||
|
||
.. [2] *Intel® 64 and IA-32 Architectures Software Developer’s Manual Volume 3: System Programming Guide*,
|
||
https://www.intel.com/content/www/us/en/architecture-and-technology/64-ia-32-architectures-software-developer-system-programming-manual-325384.html
|
||
|
||
.. [3] *Advanced Configuration and Power Interface Specification*,
|
||
https://uefi.org/sites/default/files/resources/ACPI_6_3_final_Jan30.pdf
|