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Linux/Documentation/admin-guide/pm/intel_pstate.rst

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  1 .. SPDX-License-Identifier: GPL-2.0
  2 .. include:: <isonum.txt>
  3 
  4 ===============================================
  5 ``intel_pstate`` CPU Performance Scaling Driver
  6 ===============================================
  7 
  8 :Copyright: |copy| 2017 Intel Corporation
  9 
 10 :Author: Rafael J. Wysocki <rafael.j.wysocki@intel.com>
 11 
 12 
 13 General Information
 14 ===================
 15 
 16 ``intel_pstate`` is a part of the
 17 :doc:`CPU performance scaling subsystem <cpufreq>` in the Linux kernel
 18 (``CPUFreq``).  It is a scaling driver for the Sandy Bridge and later
 19 generations of Intel processors.  Note, however, that some of those processors
 20 may not be supported.  [To understand ``intel_pstate`` it is necessary to know
 21 how ``CPUFreq`` works in general, so this is the time to read
 22 Documentation/admin-guide/pm/cpufreq.rst if you have not done that yet.]
 23 
 24 For the processors supported by ``intel_pstate``, the P-state concept is broader
 25 than just an operating frequency or an operating performance point (see the
 26 LinuxCon Europe 2015 presentation by Kristen Accardi [1]_ for more
 27 information about that).  For this reason, the representation of P-states used
 28 by ``intel_pstate`` internally follows the hardware specification (for details
 29 refer to Intel Software Developer’s Manual [2]_).  However, the ``CPUFreq`` core
 30 uses frequencies for identifying operating performance points of CPUs and
 31 frequencies are involved in the user space interface exposed by it, so
 32 ``intel_pstate`` maps its internal representation of P-states to frequencies too
 33 (fortunately, that mapping is unambiguous).  At the same time, it would not be
 34 practical for ``intel_pstate`` to supply the ``CPUFreq`` core with a table of
 35 available frequencies due to the possible size of it, so the driver does not do
 36 that.  Some functionality of the core is limited by that.
 37 
 38 Since the hardware P-state selection interface used by ``intel_pstate`` is
 39 available at the logical CPU level, the driver always works with individual
 40 CPUs.  Consequently, if ``intel_pstate`` is in use, every ``CPUFreq`` policy
 41 object corresponds to one logical CPU and ``CPUFreq`` policies are effectively
 42 equivalent to CPUs.  In particular, this means that they become "inactive" every
 43 time the corresponding CPU is taken offline and need to be re-initialized when
 44 it goes back online.
 45 
 46 ``intel_pstate`` is not modular, so it cannot be unloaded, which means that the
 47 only way to pass early-configuration-time parameters to it is via the kernel
 48 command line.  However, its configuration can be adjusted via ``sysfs`` to a
 49 great extent.  In some configurations it even is possible to unregister it via
 50 ``sysfs`` which allows another ``CPUFreq`` scaling driver to be loaded and
 51 registered (see `below <status_attr_>`_).
 52 
 53 
 54 Operation Modes
 55 ===============
 56 
 57 ``intel_pstate`` can operate in two different modes, active or passive.  In the
 58 active mode, it uses its own internal performance scaling governor algorithm or
 59 allows the hardware to do performance scaling by itself, while in the passive
 60 mode it responds to requests made by a generic ``CPUFreq`` governor implementing
 61 a certain performance scaling algorithm.  Which of them will be in effect
 62 depends on what kernel command line options are used and on the capabilities of
 63 the processor.
 64 
 65 Active Mode
 66 -----------
 67 
 68 This is the default operation mode of ``intel_pstate`` for processors with
 69 hardware-managed P-states (HWP) support.  If it works in this mode, the
 70 ``scaling_driver`` policy attribute in ``sysfs`` for all ``CPUFreq`` policies
 71 contains the string "intel_pstate".
 72 
 73 In this mode the driver bypasses the scaling governors layer of ``CPUFreq`` and
 74 provides its own scaling algorithms for P-state selection.  Those algorithms
 75 can be applied to ``CPUFreq`` policies in the same way as generic scaling
 76 governors (that is, through the ``scaling_governor`` policy attribute in
 77 ``sysfs``).  [Note that different P-state selection algorithms may be chosen for
 78 different policies, but that is not recommended.]
 79 
 80 They are not generic scaling governors, but their names are the same as the
 81 names of some of those governors.  Moreover, confusingly enough, they generally
 82 do not work in the same way as the generic governors they share the names with.
 83 For example, the ``powersave`` P-state selection algorithm provided by
 84 ``intel_pstate`` is not a counterpart of the generic ``powersave`` governor
 85 (roughly, it corresponds to the ``schedutil`` and ``ondemand`` governors).
 86 
 87 There are two P-state selection algorithms provided by ``intel_pstate`` in the
 88 active mode: ``powersave`` and ``performance``.  The way they both operate
 89 depends on whether or not the hardware-managed P-states (HWP) feature has been
 90 enabled in the processor and possibly on the processor model.
 91 
 92 Which of the P-state selection algorithms is used by default depends on the
 93 :c:macro:`CONFIG_CPU_FREQ_DEFAULT_GOV_PERFORMANCE` kernel configuration option.
 94 Namely, if that option is set, the ``performance`` algorithm will be used by
 95 default, and the other one will be used by default if it is not set.
 96 
 97 Active Mode With HWP
 98 ~~~~~~~~~~~~~~~~~~~~
 99 
100 If the processor supports the HWP feature, it will be enabled during the
101 processor initialization and cannot be disabled after that.  It is possible
102 to avoid enabling it by passing the ``intel_pstate=no_hwp`` argument to the
103 kernel in the command line.
104 
105 If the HWP feature has been enabled, ``intel_pstate`` relies on the processor to
106 select P-states by itself, but still it can give hints to the processor's
107 internal P-state selection logic.  What those hints are depends on which P-state
108 selection algorithm has been applied to the given policy (or to the CPU it
109 corresponds to).
110 
111 Even though the P-state selection is carried out by the processor automatically,
112 ``intel_pstate`` registers utilization update callbacks with the CPU scheduler
113 in this mode.  However, they are not used for running a P-state selection
114 algorithm, but for periodic updates of the current CPU frequency information to
115 be made available from the ``scaling_cur_freq`` policy attribute in ``sysfs``.
116 
117 HWP + ``performance``
118 .....................
119 
120 In this configuration ``intel_pstate`` will write 0 to the processor's
121 Energy-Performance Preference (EPP) knob (if supported) or its
122 Energy-Performance Bias (EPB) knob (otherwise), which means that the processor's
123 internal P-state selection logic is expected to focus entirely on performance.
124 
125 This will override the EPP/EPB setting coming from the ``sysfs`` interface
126 (see `Energy vs Performance Hints`_ below).  Moreover, any attempts to change
127 the EPP/EPB to a value different from 0 ("performance") via ``sysfs`` in this
128 configuration will be rejected.
129 
130 Also, in this configuration the range of P-states available to the processor's
131 internal P-state selection logic is always restricted to the upper boundary
132 (that is, the maximum P-state that the driver is allowed to use).
133 
134 HWP + ``powersave``
135 ...................
136 
137 In this configuration ``intel_pstate`` will set the processor's
138 Energy-Performance Preference (EPP) knob (if supported) or its
139 Energy-Performance Bias (EPB) knob (otherwise) to whatever value it was
140 previously set to via ``sysfs`` (or whatever default value it was
141 set to by the platform firmware).  This usually causes the processor's
142 internal P-state selection logic to be less performance-focused.
143 
144 Active Mode Without HWP
145 ~~~~~~~~~~~~~~~~~~~~~~~
146 
147 This operation mode is optional for processors that do not support the HWP
148 feature or when the ``intel_pstate=no_hwp`` argument is passed to the kernel in
149 the command line.  The active mode is used in those cases if the
150 ``intel_pstate=active`` argument is passed to the kernel in the command line.
151 In this mode ``intel_pstate`` may refuse to work with processors that are not
152 recognized by it.  [Note that ``intel_pstate`` will never refuse to work with
153 any processor with the HWP feature enabled.]
154 
155 In this mode ``intel_pstate`` registers utilization update callbacks with the
156 CPU scheduler in order to run a P-state selection algorithm, either
157 ``powersave`` or ``performance``, depending on the ``scaling_governor`` policy
158 setting in ``sysfs``.  The current CPU frequency information to be made
159 available from the ``scaling_cur_freq`` policy attribute in ``sysfs`` is
160 periodically updated by those utilization update callbacks too.
161 
162 ``performance``
163 ...............
164 
165 Without HWP, this P-state selection algorithm is always the same regardless of
166 the processor model and platform configuration.
167 
168 It selects the maximum P-state it is allowed to use, subject to limits set via
169 ``sysfs``, every time the driver configuration for the given CPU is updated
170 (e.g. via ``sysfs``).
171 
172 This is the default P-state selection algorithm if the
173 :c:macro:`CONFIG_CPU_FREQ_DEFAULT_GOV_PERFORMANCE` kernel configuration option
174 is set.
175 
176 ``powersave``
177 .............
178 
179 Without HWP, this P-state selection algorithm is similar to the algorithm
180 implemented by the generic ``schedutil`` scaling governor except that the
181 utilization metric used by it is based on numbers coming from feedback
182 registers of the CPU.  It generally selects P-states proportional to the
183 current CPU utilization.
184 
185 This algorithm is run by the driver's utilization update callback for the
186 given CPU when it is invoked by the CPU scheduler, but not more often than
187 every 10 ms.  Like in the ``performance`` case, the hardware configuration
188 is not touched if the new P-state turns out to be the same as the current
189 one.
190 
191 This is the default P-state selection algorithm if the
192 :c:macro:`CONFIG_CPU_FREQ_DEFAULT_GOV_PERFORMANCE` kernel configuration option
193 is not set.
194 
195 Passive Mode
196 ------------
197 
198 This is the default operation mode of ``intel_pstate`` for processors without
199 hardware-managed P-states (HWP) support.  It is always used if the
200 ``intel_pstate=passive`` argument is passed to the kernel in the command line
201 regardless of whether or not the given processor supports HWP.  [Note that the
202 ``intel_pstate=no_hwp`` setting causes the driver to start in the passive mode
203 if it is not combined with ``intel_pstate=active``.]  Like in the active mode
204 without HWP support, in this mode ``intel_pstate`` may refuse to work with
205 processors that are not recognized by it if HWP is prevented from being enabled
206 through the kernel command line.
207 
208 If the driver works in this mode, the ``scaling_driver`` policy attribute in
209 ``sysfs`` for all ``CPUFreq`` policies contains the string "intel_cpufreq".
210 Then, the driver behaves like a regular ``CPUFreq`` scaling driver.  That is,
211 it is invoked by generic scaling governors when necessary to talk to the
212 hardware in order to change the P-state of a CPU (in particular, the
213 ``schedutil`` governor can invoke it directly from scheduler context).
214 
215 While in this mode, ``intel_pstate`` can be used with all of the (generic)
216 scaling governors listed by the ``scaling_available_governors`` policy attribute
217 in ``sysfs`` (and the P-state selection algorithms described above are not
218 used).  Then, it is responsible for the configuration of policy objects
219 corresponding to CPUs and provides the ``CPUFreq`` core (and the scaling
220 governors attached to the policy objects) with accurate information on the
221 maximum and minimum operating frequencies supported by the hardware (including
222 the so-called "turbo" frequency ranges).  In other words, in the passive mode
223 the entire range of available P-states is exposed by ``intel_pstate`` to the
224 ``CPUFreq`` core.  However, in this mode the driver does not register
225 utilization update callbacks with the CPU scheduler and the ``scaling_cur_freq``
226 information comes from the ``CPUFreq`` core (and is the last frequency selected
227 by the current scaling governor for the given policy).
228 
229 
230 .. _turbo:
231 
232 Turbo P-states Support
233 ======================
234 
235 In the majority of cases, the entire range of P-states available to
236 ``intel_pstate`` can be divided into two sub-ranges that correspond to
237 different types of processor behavior, above and below a boundary that
238 will be referred to as the "turbo threshold" in what follows.
239 
240 The P-states above the turbo threshold are referred to as "turbo P-states" and
241 the whole sub-range of P-states they belong to is referred to as the "turbo
242 range".  These names are related to the Turbo Boost technology allowing a
243 multicore processor to opportunistically increase the P-state of one or more
244 cores if there is enough power to do that and if that is not going to cause the
245 thermal envelope of the processor package to be exceeded.
246 
247 Specifically, if software sets the P-state of a CPU core within the turbo range
248 (that is, above the turbo threshold), the processor is permitted to take over
249 performance scaling control for that core and put it into turbo P-states of its
250 choice going forward.  However, that permission is interpreted differently by
251 different processor generations.  Namely, the Sandy Bridge generation of
252 processors will never use any P-states above the last one set by software for
253 the given core, even if it is within the turbo range, whereas all of the later
254 processor generations will take it as a license to use any P-states from the
255 turbo range, even above the one set by software.  In other words, on those
256 processors setting any P-state from the turbo range will enable the processor
257 to put the given core into all turbo P-states up to and including the maximum
258 supported one as it sees fit.
259 
260 One important property of turbo P-states is that they are not sustainable.  More
261 precisely, there is no guarantee that any CPUs will be able to stay in any of
262 those states indefinitely, because the power distribution within the processor
263 package may change over time  or the thermal envelope it was designed for might
264 be exceeded if a turbo P-state was used for too long.
265 
266 In turn, the P-states below the turbo threshold generally are sustainable.  In
267 fact, if one of them is set by software, the processor is not expected to change
268 it to a lower one unless in a thermal stress or a power limit violation
269 situation (a higher P-state may still be used if it is set for another CPU in
270 the same package at the same time, for example).
271 
272 Some processors allow multiple cores to be in turbo P-states at the same time,
273 but the maximum P-state that can be set for them generally depends on the number
274 of cores running concurrently.  The maximum turbo P-state that can be set for 3
275 cores at the same time usually is lower than the analogous maximum P-state for
276 2 cores, which in turn usually is lower than the maximum turbo P-state that can
277 be set for 1 core.  The one-core maximum turbo P-state is thus the maximum
278 supported one overall.
279 
280 The maximum supported turbo P-state, the turbo threshold (the maximum supported
281 non-turbo P-state) and the minimum supported P-state are specific to the
282 processor model and can be determined by reading the processor's model-specific
283 registers (MSRs).  Moreover, some processors support the Configurable TDP
284 (Thermal Design Power) feature and, when that feature is enabled, the turbo
285 threshold effectively becomes a configurable value that can be set by the
286 platform firmware.
287 
288 Unlike ``_PSS`` objects in the ACPI tables, ``intel_pstate`` always exposes
289 the entire range of available P-states, including the whole turbo range, to the
290 ``CPUFreq`` core and (in the passive mode) to generic scaling governors.  This
291 generally causes turbo P-states to be set more often when ``intel_pstate`` is
292 used relative to ACPI-based CPU performance scaling (see `below <acpi-cpufreq_>`_
293 for more information).
294 
295 Moreover, since ``intel_pstate`` always knows what the real turbo threshold is
296 (even if the Configurable TDP feature is enabled in the processor), its
297 ``no_turbo`` attribute in ``sysfs`` (described `below <no_turbo_attr_>`_) should
298 work as expected in all cases (that is, if set to disable turbo P-states, it
299 always should prevent ``intel_pstate`` from using them).
300 
301 
302 Processor Support
303 =================
304 
305 To handle a given processor ``intel_pstate`` requires a number of different
306 pieces of information on it to be known, including:
307 
308  * The minimum supported P-state.
309 
310  * The maximum supported `non-turbo P-state <turbo_>`_.
311 
312  * Whether or not turbo P-states are supported at all.
313 
314  * The maximum supported `one-core turbo P-state <turbo_>`_ (if turbo P-states
315    are supported).
316 
317  * The scaling formula to translate the driver's internal representation
318    of P-states into frequencies and the other way around.
319 
320 Generally, ways to obtain that information are specific to the processor model
321 or family.  Although it often is possible to obtain all of it from the processor
322 itself (using model-specific registers), there are cases in which hardware
323 manuals need to be consulted to get to it too.
324 
325 For this reason, there is a list of supported processors in ``intel_pstate`` and
326 the driver initialization will fail if the detected processor is not in that
327 list, unless it supports the HWP feature.  [The interface to obtain all of the
328 information listed above is the same for all of the processors supporting the
329 HWP feature, which is why ``intel_pstate`` works with all of them.]
330 
331 
332 User Space Interface in ``sysfs``
333 =================================
334 
335 Global Attributes
336 -----------------
337 
338 ``intel_pstate`` exposes several global attributes (files) in ``sysfs`` to
339 control its functionality at the system level.  They are located in the
340 ``/sys/devices/system/cpu/intel_pstate/`` directory and affect all CPUs.
341 
342 Some of them are not present if the ``intel_pstate=per_cpu_perf_limits``
343 argument is passed to the kernel in the command line.
344 
345 ``max_perf_pct``
346         Maximum P-state the driver is allowed to set in percent of the
347         maximum supported performance level (the highest supported `turbo
348         P-state <turbo_>`_).
349 
350         This attribute will not be exposed if the
351         ``intel_pstate=per_cpu_perf_limits`` argument is present in the kernel
352         command line.
353 
354 ``min_perf_pct``
355         Minimum P-state the driver is allowed to set in percent of the
356         maximum supported performance level (the highest supported `turbo
357         P-state <turbo_>`_).
358 
359         This attribute will not be exposed if the
360         ``intel_pstate=per_cpu_perf_limits`` argument is present in the kernel
361         command line.
362 
363 ``num_pstates``
364         Number of P-states supported by the processor (between 0 and 255
365         inclusive) including both turbo and non-turbo P-states (see
366         `Turbo P-states Support`_).
367 
368         This attribute is present only if the value exposed by it is the same
369         for all of the CPUs in the system.
370 
371         The value of this attribute is not affected by the ``no_turbo``
372         setting described `below <no_turbo_attr_>`_.
373 
374         This attribute is read-only.
375 
376 ``turbo_pct``
377         Ratio of the `turbo range <turbo_>`_ size to the size of the entire
378         range of supported P-states, in percent.
379 
380         This attribute is present only if the value exposed by it is the same
381         for all of the CPUs in the system.
382 
383         This attribute is read-only.
384 
385 .. _no_turbo_attr:
386 
387 ``no_turbo``
388         If set (equal to 1), the driver is not allowed to set any turbo P-states
389         (see `Turbo P-states Support`_).  If unset (equal to 0, which is the
390         default), turbo P-states can be set by the driver.
391         [Note that ``intel_pstate`` does not support the general ``boost``
392         attribute (supported by some other scaling drivers) which is replaced
393         by this one.]
394 
395         This attribute does not affect the maximum supported frequency value
396         supplied to the ``CPUFreq`` core and exposed via the policy interface,
397         but it affects the maximum possible value of per-policy P-state limits
398         (see `Interpretation of Policy Attributes`_ below for details).
399 
400 ``hwp_dynamic_boost``
401         This attribute is only present if ``intel_pstate`` works in the
402         `active mode with the HWP feature enabled <Active Mode With HWP_>`_ in
403         the processor.  If set (equal to 1), it causes the minimum P-state limit
404         to be increased dynamically for a short time whenever a task previously
405         waiting on I/O is selected to run on a given logical CPU (the purpose
406         of this mechanism is to improve performance).
407 
408         This setting has no effect on logical CPUs whose minimum P-state limit
409         is directly set to the highest non-turbo P-state or above it.
410 
411 .. _status_attr:
412 
413 ``status``
414         Operation mode of the driver: "active", "passive" or "off".
415 
416         "active"
417                 The driver is functional and in the `active mode
418                 <Active Mode_>`_.
419 
420         "passive"
421                 The driver is functional and in the `passive mode
422                 <Passive Mode_>`_.
423 
424         "off"
425                 The driver is not functional (it is not registered as a scaling
426                 driver with the ``CPUFreq`` core).
427 
428         This attribute can be written to in order to change the driver's
429         operation mode or to unregister it.  The string written to it must be
430         one of the possible values of it and, if successful, the write will
431         cause the driver to switch over to the operation mode represented by
432         that string - or to be unregistered in the "off" case.  [Actually,
433         switching over from the active mode to the passive mode or the other
434         way around causes the driver to be unregistered and registered again
435         with a different set of callbacks, so all of its settings (the global
436         as well as the per-policy ones) are then reset to their default
437         values, possibly depending on the target operation mode.]
438 
439 ``energy_efficiency``
440         This attribute is only present on platforms with CPUs matching the Kaby
441         Lake or Coffee Lake desktop CPU model. By default, energy-efficiency
442         optimizations are disabled on these CPU models if HWP is enabled.
443         Enabling energy-efficiency optimizations may limit maximum operating
444         frequency with or without the HWP feature.  With HWP enabled, the
445         optimizations are done only in the turbo frequency range.  Without it,
446         they are done in the entire available frequency range.  Setting this
447         attribute to "1" enables the energy-efficiency optimizations and setting
448         to "0" disables them.
449 
450 Interpretation of Policy Attributes
451 -----------------------------------
452 
453 The interpretation of some ``CPUFreq`` policy attributes described in
454 Documentation/admin-guide/pm/cpufreq.rst is special with ``intel_pstate``
455 as the current scaling driver and it generally depends on the driver's
456 `operation mode <Operation Modes_>`_.
457 
458 First of all, the values of the ``cpuinfo_max_freq``, ``cpuinfo_min_freq`` and
459 ``scaling_cur_freq`` attributes are produced by applying a processor-specific
460 multiplier to the internal P-state representation used by ``intel_pstate``.
461 Also, the values of the ``scaling_max_freq`` and ``scaling_min_freq``
462 attributes are capped by the frequency corresponding to the maximum P-state that
463 the driver is allowed to set.
464 
465 If the ``no_turbo`` `global attribute <no_turbo_attr_>`_ is set, the driver is
466 not allowed to use turbo P-states, so the maximum value of ``scaling_max_freq``
467 and ``scaling_min_freq`` is limited to the maximum non-turbo P-state frequency.
468 Accordingly, setting ``no_turbo`` causes ``scaling_max_freq`` and
469 ``scaling_min_freq`` to go down to that value if they were above it before.
470 However, the old values of ``scaling_max_freq`` and ``scaling_min_freq`` will be
471 restored after unsetting ``no_turbo``, unless these attributes have been written
472 to after ``no_turbo`` was set.
473 
474 If ``no_turbo`` is not set, the maximum possible value of ``scaling_max_freq``
475 and ``scaling_min_freq`` corresponds to the maximum supported turbo P-state,
476 which also is the value of ``cpuinfo_max_freq`` in either case.
477 
478 Next, the following policy attributes have special meaning if
479 ``intel_pstate`` works in the `active mode <Active Mode_>`_:
480 
481 ``scaling_available_governors``
482         List of P-state selection algorithms provided by ``intel_pstate``.
483 
484 ``scaling_governor``
485         P-state selection algorithm provided by ``intel_pstate`` currently in
486         use with the given policy.
487 
488 ``scaling_cur_freq``
489         Frequency of the average P-state of the CPU represented by the given
490         policy for the time interval between the last two invocations of the
491         driver's utilization update callback by the CPU scheduler for that CPU.
492 
493 One more policy attribute is present if the HWP feature is enabled in the
494 processor:
495 
496 ``base_frequency``
497         Shows the base frequency of the CPU. Any frequency above this will be
498         in the turbo frequency range.
499 
500 The meaning of these attributes in the `passive mode <Passive Mode_>`_ is the
501 same as for other scaling drivers.
502 
503 Additionally, the value of the ``scaling_driver`` attribute for ``intel_pstate``
504 depends on the operation mode of the driver.  Namely, it is either
505 "intel_pstate" (in the `active mode <Active Mode_>`_) or "intel_cpufreq" (in the
506 `passive mode <Passive Mode_>`_).
507 
508 Coordination of P-State Limits
509 ------------------------------
510 
511 ``intel_pstate`` allows P-state limits to be set in two ways: with the help of
512 the ``max_perf_pct`` and ``min_perf_pct`` `global attributes
513 <Global Attributes_>`_ or via the ``scaling_max_freq`` and ``scaling_min_freq``
514 ``CPUFreq`` policy attributes.  The coordination between those limits is based
515 on the following rules, regardless of the current operation mode of the driver:
516 
517  1. All CPUs are affected by the global limits (that is, none of them can be
518     requested to run faster than the global maximum and none of them can be
519     requested to run slower than the global minimum).
520 
521  2. Each individual CPU is affected by its own per-policy limits (that is, it
522     cannot be requested to run faster than its own per-policy maximum and it
523     cannot be requested to run slower than its own per-policy minimum). The
524     effective performance depends on whether the platform supports per core
525     P-states, hyper-threading is enabled and on current performance requests
526     from other CPUs. When platform doesn't support per core P-states, the
527     effective performance can be more than the policy limits set on a CPU, if
528     other CPUs are requesting higher performance at that moment. Even with per
529     core P-states support, when hyper-threading is enabled, if the sibling CPU
530     is requesting higher performance, the other siblings will get higher
531     performance than their policy limits.
532 
533  3. The global and per-policy limits can be set independently.
534 
535 In the `active mode with the HWP feature enabled <Active Mode With HWP_>`_, the
536 resulting effective values are written into hardware registers whenever the
537 limits change in order to request its internal P-state selection logic to always
538 set P-states within these limits.  Otherwise, the limits are taken into account
539 by scaling governors (in the `passive mode <Passive Mode_>`_) and by the driver
540 every time before setting a new P-state for a CPU.
541 
542 Additionally, if the ``intel_pstate=per_cpu_perf_limits`` command line argument
543 is passed to the kernel, ``max_perf_pct`` and ``min_perf_pct`` are not exposed
544 at all and the only way to set the limits is by using the policy attributes.
545 
546 
547 Energy vs Performance Hints
548 ---------------------------
549 
550 If the hardware-managed P-states (HWP) is enabled in the processor, additional
551 attributes, intended to allow user space to help ``intel_pstate`` to adjust the
552 processor's internal P-state selection logic by focusing it on performance or on
553 energy-efficiency, or somewhere between the two extremes, are present in every
554 ``CPUFreq`` policy directory in ``sysfs``.  They are :
555 
556 ``energy_performance_preference``
557         Current value of the energy vs performance hint for the given policy
558         (or the CPU represented by it).
559 
560         The hint can be changed by writing to this attribute.
561 
562 ``energy_performance_available_preferences``
563         List of strings that can be written to the
564         ``energy_performance_preference`` attribute.
565 
566         They represent different energy vs performance hints and should be
567         self-explanatory, except that ``default`` represents whatever hint
568         value was set by the platform firmware.
569 
570 Strings written to the ``energy_performance_preference`` attribute are
571 internally translated to integer values written to the processor's
572 Energy-Performance Preference (EPP) knob (if supported) or its
573 Energy-Performance Bias (EPB) knob. It is also possible to write a positive
574 integer value between 0 to 255, if the EPP feature is present. If the EPP
575 feature is not present, writing integer value to this attribute is not
576 supported. In this case, user can use the
577 "/sys/devices/system/cpu/cpu*/power/energy_perf_bias" interface.
578 
579 [Note that tasks may by migrated from one CPU to another by the scheduler's
580 load-balancing algorithm and if different energy vs performance hints are
581 set for those CPUs, that may lead to undesirable outcomes.  To avoid such
582 issues it is better to set the same energy vs performance hint for all CPUs
583 or to pin every task potentially sensitive to them to a specific CPU.]
584 
585 .. _acpi-cpufreq:
586 
587 ``intel_pstate`` vs ``acpi-cpufreq``
588 ====================================
589 
590 On the majority of systems supported by ``intel_pstate``, the ACPI tables
591 provided by the platform firmware contain ``_PSS`` objects returning information
592 that can be used for CPU performance scaling (refer to the ACPI specification
593 [3]_ for details on the ``_PSS`` objects and the format of the information
594 returned by them).
595 
596 The information returned by the ACPI ``_PSS`` objects is used by the
597 ``acpi-cpufreq`` scaling driver.  On systems supported by ``intel_pstate``
598 the ``acpi-cpufreq`` driver uses the same hardware CPU performance scaling
599 interface, but the set of P-states it can use is limited by the ``_PSS``
600 output.
601 
602 On those systems each ``_PSS`` object returns a list of P-states supported by
603 the corresponding CPU which basically is a subset of the P-states range that can
604 be used by ``intel_pstate`` on the same system, with one exception: the whole
605 `turbo range <turbo_>`_ is represented by one item in it (the topmost one).  By
606 convention, the frequency returned by ``_PSS`` for that item is greater by 1 MHz
607 than the frequency of the highest non-turbo P-state listed by it, but the
608 corresponding P-state representation (following the hardware specification)
609 returned for it matches the maximum supported turbo P-state (or is the
610 special value 255 meaning essentially "go as high as you can get").
611 
612 The list of P-states returned by ``_PSS`` is reflected by the table of
613 available frequencies supplied by ``acpi-cpufreq`` to the ``CPUFreq`` core and
614 scaling governors and the minimum and maximum supported frequencies reported by
615 it come from that list as well.  In particular, given the special representation
616 of the turbo range described above, this means that the maximum supported
617 frequency reported by ``acpi-cpufreq`` is higher by 1 MHz than the frequency
618 of the highest supported non-turbo P-state listed by ``_PSS`` which, of course,
619 affects decisions made by the scaling governors, except for ``powersave`` and
620 ``performance``.
621 
622 For example, if a given governor attempts to select a frequency proportional to
623 estimated CPU load and maps the load of 100% to the maximum supported frequency
624 (possibly multiplied by a constant), then it will tend to choose P-states below
625 the turbo threshold if ``acpi-cpufreq`` is used as the scaling driver, because
626 in that case the turbo range corresponds to a small fraction of the frequency
627 band it can use (1 MHz vs 1 GHz or more).  In consequence, it will only go to
628 the turbo range for the highest loads and the other loads above 50% that might
629 benefit from running at turbo frequencies will be given non-turbo P-states
630 instead.
631 
632 One more issue related to that may appear on systems supporting the
633 `Configurable TDP feature <turbo_>`_ allowing the platform firmware to set the
634 turbo threshold.  Namely, if that is not coordinated with the lists of P-states
635 returned by ``_PSS`` properly, there may be more than one item corresponding to
636 a turbo P-state in those lists and there may be a problem with avoiding the
637 turbo range (if desirable or necessary).  Usually, to avoid using turbo
638 P-states overall, ``acpi-cpufreq`` simply avoids using the topmost state listed
639 by ``_PSS``, but that is not sufficient when there are other turbo P-states in
640 the list returned by it.
641 
642 Apart from the above, ``acpi-cpufreq`` works like ``intel_pstate`` in the
643 `passive mode <Passive Mode_>`_, except that the number of P-states it can set
644 is limited to the ones listed by the ACPI ``_PSS`` objects.
645 
646 
647 Kernel Command Line Options for ``intel_pstate``
648 ================================================
649 
650 Several kernel command line options can be used to pass early-configuration-time
651 parameters to ``intel_pstate`` in order to enforce specific behavior of it.  All
652 of them have to be prepended with the ``intel_pstate=`` prefix.
653 
654 ``disable``
655         Do not register ``intel_pstate`` as the scaling driver even if the
656         processor is supported by it.
657 
658 ``active``
659         Register ``intel_pstate`` in the `active mode <Active Mode_>`_ to start
660         with.
661 
662 ``passive``
663         Register ``intel_pstate`` in the `passive mode <Passive Mode_>`_ to
664         start with.
665 
666 ``force``
667         Register ``intel_pstate`` as the scaling driver instead of
668         ``acpi-cpufreq`` even if the latter is preferred on the given system.
669 
670         This may prevent some platform features (such as thermal controls and
671         power capping) that rely on the availability of ACPI P-states
672         information from functioning as expected, so it should be used with
673         caution.
674 
675         This option does not work with processors that are not supported by
676         ``intel_pstate`` and on platforms where the ``pcc-cpufreq`` scaling
677         driver is used instead of ``acpi-cpufreq``.
678 
679 ``no_hwp``
680         Do not enable the hardware-managed P-states (HWP) feature even if it is
681         supported by the processor.
682 
683 ``hwp_only``
684         Register ``intel_pstate`` as the scaling driver only if the
685         hardware-managed P-states (HWP) feature is supported by the processor.
686 
687 ``support_acpi_ppc``
688         Take ACPI ``_PPC`` performance limits into account.
689 
690         If the preferred power management profile in the FADT (Fixed ACPI
691         Description Table) is set to "Enterprise Server" or "Performance
692         Server", the ACPI ``_PPC`` limits are taken into account by default
693         and this option has no effect.
694 
695 ``per_cpu_perf_limits``
696         Use per-logical-CPU P-State limits (see `Coordination of P-state
697         Limits`_ for details).
698 
699 
700 Diagnostics and Tuning
701 ======================
702 
703 Trace Events
704 ------------
705 
706 There are two static trace events that can be used for ``intel_pstate``
707 diagnostics.  One of them is the ``cpu_frequency`` trace event generally used
708 by ``CPUFreq``, and the other one is the ``pstate_sample`` trace event specific
709 to ``intel_pstate``.  Both of them are triggered by ``intel_pstate`` only if
710 it works in the `active mode <Active Mode_>`_.
711 
712 The following sequence of shell commands can be used to enable them and see
713 their output (if the kernel is generally configured to support event tracing)::
714 
715  # cd /sys/kernel/tracing/
716  # echo 1 > events/power/pstate_sample/enable
717  # echo 1 > events/power/cpu_frequency/enable
718  # cat trace
719  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
720  cat-5235  [002] ..s.  1177.681723: cpu_frequency: state=2900000 cpu_id=2
721 
722 If ``intel_pstate`` works in the `passive mode <Passive Mode_>`_, the
723 ``cpu_frequency`` trace event will be triggered either by the ``schedutil``
724 scaling governor (for the policies it is attached to), or by the ``CPUFreq``
725 core (for the policies with other scaling governors).
726 
727 ``ftrace``
728 ----------
729 
730 The ``ftrace`` interface can be used for low-level diagnostics of
731 ``intel_pstate``.  For example, to check how often the function to set a
732 P-state is called, the ``ftrace`` filter can be set to
733 :c:func:`intel_pstate_set_pstate`::
734 
735  # cd /sys/kernel/tracing/
736  # cat available_filter_functions | grep -i pstate
737  intel_pstate_set_pstate
738  intel_pstate_cpu_init
739  ...
740  # echo intel_pstate_set_pstate > set_ftrace_filter
741  # echo function > current_tracer
742  # cat trace | head -15
743  # tracer: function
744  #
745  # entries-in-buffer/entries-written: 80/80   #P:4
746  #
747  #                              _-----=> irqs-off
748  #                             / _----=> need-resched
749  #                            | / _---=> hardirq/softirq
750  #                            || / _--=> preempt-depth
751  #                            ||| /     delay
752  #           TASK-PID   CPU#  ||||    TIMESTAMP  FUNCTION
753  #              | |       |   ||||       |         |
754              Xorg-3129  [000] ..s.  2537.644844: intel_pstate_set_pstate <-intel_pstate_timer_func
755   gnome-terminal--4510  [002] ..s.  2537.649844: intel_pstate_set_pstate <-intel_pstate_timer_func
756       gnome-shell-3409  [001] ..s.  2537.650850: intel_pstate_set_pstate <-intel_pstate_timer_func
757            <idle>-0     [000] ..s.  2537.654843: intel_pstate_set_pstate <-intel_pstate_timer_func
758 
759 
760 References
761 ==========
762 
763 .. [1] Kristen Accardi, *Balancing Power and Performance in the Linux Kernel*,
764        https://events.static.linuxfound.org/sites/events/files/slides/LinuxConEurope_2015.pdf
765 
766 .. [2] *Intel® 64 and IA-32 Architectures Software Developer’s Manual Volume 3: System Programming Guide*,
767        https://www.intel.com/content/www/us/en/architecture-and-technology/64-ia-32-architectures-software-developer-system-programming-manual-325384.html
768 
769 .. [3] *Advanced Configuration and Power Interface Specification*,
770        https://uefi.org/sites/default/files/resources/ACPI_6_3_final_Jan30.pdf

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