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

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Differences between /Documentation/admin-guide/pm/cpuidle.rst (Version linux-6.12-rc7) and /Documentation/admin-guide/pm/cpuidle.rst (Version linux-4.11.12)


  1 .. SPDX-License-Identifier: GPL-2.0               
  2 .. include:: <isonum.txt>                         
  3                                                   
  4 .. |struct cpuidle_state| replace:: :c:type:`s    
  5 .. |cpufreq| replace:: :doc:`CPU Performance S    
  6                                                   
  7 ========================                          
  8 CPU Idle Time Management                          
  9 ========================                          
 10                                                   
 11 :Copyright: |copy| 2018 Intel Corporation         
 12                                                   
 13 :Author: Rafael J. Wysocki <rafael.j.wysocki@in    
 14                                                   
 15                                                   
 16 Concepts                                          
 17 ========                                          
 18                                                   
 19 Modern processors are generally able to enter     
 20 a program is suspended and instructions belong    
 21 memory or executed.  Those states are the *idl    
 22                                                   
 23 Since part of the processor hardware is not us    
 24 generally allows power drawn by the processor     
 25 it is an opportunity to save energy.              
 26                                                   
 27 CPU idle time management is an energy-efficien    
 28 the idle states of processors for this purpose    
 29                                                   
 30 Logical CPUs                                      
 31 ------------                                      
 32                                                   
 33 CPU idle time management operates on CPUs as s    
 34 is the part of the kernel responsible for the     
 35 work in the system).  In its view, CPUs are *l    
 36 not be separate physical entities and may just    
 37 software as individual single-core processors.    
 38 entity which appears to be fetching instructio    
 39 (program) from memory and executing them, but     
 40 physically.  Generally, three different cases     
 41                                                   
 42 First, if the whole processor can only follow     
 43 program) at a time, it is a CPU.  In that case    
 44 enter an idle state, that applies to the proce    
 45                                                   
 46 Second, if the processor is multi-core, each c    
 47 least one program at a time.  The cores need n    
 48 other (for example, they may share caches), bu    
 49 work physically in parallel with each other, s    
 50 one program, those programs run mostly indepen    
 51 time.  The entire cores are CPUs in that case     
 52 enter an idle state, that applies to the core     
 53 place, but it also may apply to a larger unit     
 54 that the core belongs to (in fact, it may appl    
 55 units containing the core).  Namely, if all of    
 56 except for one have been put into idle states     
 57 remaining core asks the processor to enter an     
 58 to put the whole larger unit into an idle stat    
 59 other cores in that unit.                         
 60                                                   
 61 Finally, each core in a multi-core processor m    
 62 program in the same time frame (that is, each     
 63 instructions from multiple locations in memory    
 64 frame, but not necessarily entirely in paralle    
 65 the cores present themselves to software as "b    
 66 multiple individual single-core "processors",     
 67 (or hyper-threads specifically on Intel hardwa    
 68 sequence of instructions.  Then, the hardware     
 69 time management perspective and if the process    
 70 by one of them, the hardware thread (or CPU) t    
 71 nothing more happens, unless all of the other     
 72 core also have asked the processor to enter an    
 73 the core may be put into an idle state individ    
 74 it may be put into an idle state as a whole (i    
 75 larger unit are in idle states already).          
 76                                                   
 77 Idle CPUs                                         
 78 ---------                                         
 79                                                   
 80 Logical CPUs, simply referred to as "CPUs" in     
 81 *idle* by the Linux kernel when there are no t    
 82 special "idle" task.                              
 83                                                   
 84 Tasks are the CPU scheduler's representation o    
 85 sequence of instructions to execute, or code,     
 86 running that code, and some context informatio    
 87 processor every time the task's code is run by    
 88 distributes work by assigning tasks to run to     
 89                                                   
 90 Tasks can be in various states.  In particular    
 91 no specific conditions preventing their code f    
 92 there is a CPU available for that (for example    
 93 events to occur or similar).  When a task beco    
 94 assigns it to one of the available CPUs to run    
 95 tasks assigned to it, the CPU will load the gi    
 96 code (from the instruction following the last     
 97 another CPU).  [If there are multiple runnable    
 98 simultaneously, they will be subject to priori    
 99 to allow them to make some progress over time.    
100                                                   
101 The special "idle" task becomes runnable if th    
102 assigned to the given CPU and the CPU is then     
103 in Linux idle CPUs run the code of the "idle"     
104 code may cause the processor to be put into on    
105 supported, in order to save energy, but if the    
106 idle states, or there is not enough time to sp    
107 next wakeup event, or there are strict latency    
108 available idle states from being used, the CPU    
109 useless instructions in a loop until it is ass    
110                                                   
111                                                   
112 .. _idle-loop:                                    
113                                                   
114 The Idle Loop                                     
115 =============                                     
116                                                   
117 The idle loop code takes two major steps in ev    
118 calls into a code module referred to as the *g    
119 idle time management subsystem called ``CPUIdl    
120 the CPU to ask the hardware to enter.  Second,    
121 from the ``CPUIdle`` subsystem, called the *dr    
122 processor hardware to enter the idle state sel    
123                                                   
124 The role of the governor is to find an idle st    
125 conditions at hand.  For this purpose, idle st    
126 asked to enter by logical CPUs are represented    
127 the platform or the processor architecture and    
128 (linear) array.  That array has to be prepared    
129 driver matching the platform the kernel is run    
130 time.  This allows ``CPUIdle`` governors to be    
131 hardware and to work with any platforms that t    
132                                                   
133 Each idle state present in that array is chara    
134 taken into account by the governor, the *targe    
135 *exit latency*.  The target residency is the m    
136 spend in the given state, including the time n    
137 substantial), in order to save more energy tha    
138 the shallower idle states instead.  [The "dept    
139 corresponds to the power drawn by the processo    
140 latency, in turn, is the maximum time it will     
141 hardware to enter an idle state to start execu    
142 wakeup from that state.  Note that in general     
143 the time needed to enter the given state in ca    
144 hardware is entering it and it must be entered    
145 ordered manner.                                   
146                                                   
147 There are two types of information that can in    
148 First of all, the governor knows the time unti    
149 time is known exactly, because the kernel prog    
150 when they will trigger, and it is the maximum     
151 CPU depends on can spend in an idle state, inc    
152 and exit it.  However, the CPU may be woken up    
153 (in particular, before the closest timer trigg    
154 when that may happen.  The governor can only s    
155 was idle after it has been woken up (that time    
156 duration* from now on) and it can use that inf    
157 time until the closest timer to estimate the i    
158 governor uses that information depends on what    
159 and that is the primary reason for having more    
160 ``CPUIdle`` subsystem.                            
161                                                   
162 There are four ``CPUIdle`` governors available    
163 ``ladder`` and ``haltpoll``.  Which of them is    
164 configuration of the kernel and in particular     
165 tick can be `stopped by the idle loop <idle-cp    
166 governors can be read from the :file:`availabl    
167 can be changed at runtime.  The name of the ``    
168 used by the kernel can be read from the :file:    
169 :file:`current_governor` file under :file:`/sy    
170 in ``sysfs``.                                     
171                                                   
172 Which ``CPUIdle`` driver is used, on the other    
173 platform the kernel is running on, but there a    
174 matching driver.  For example, there are two d    
175 majority of Intel platforms, ``intel_idle`` an    
176 hardcoded idle states information and the othe    
177 from the system's ACPI tables, respectively.      
178 driver chosen at the system initialization tim    
179 decision on which one of them to use has to be    
180 the ``acpi_idle`` driver will be used if ``int    
181 reason or if it does not recognize the process    
182 driver currently used by the kernel can be rea    
183 file under :file:`/sys/devices/system/cpu/cpui    
184                                                   
185                                                   
186 .. _idle-cpus-and-tick:                           
187                                                   
188 Idle CPUs and The Scheduler Tick                  
189 ================================                  
190                                                   
191 The scheduler tick is a timer that triggers pe    
192 the time sharing strategy of the CPU scheduler    
193 multiple runnable tasks assigned to one CPU at    
194 allow them to make reasonable progress in a gi    
195 share the available CPU time.  Namely, in roug    
196 given a slice of the CPU time to run its code,    
197 prioritization and so on and when that time sl    
198 switched over to running (the code of) another    
199 may not want to give the CPU away voluntarily,    
200 is there to make the switch happen regardless.    
201 tick, but it is the primary reason for using i    
202                                                   
203 The scheduler tick is problematic from the CPU    
204 because it triggers periodically and relativel    
205 configuration, the length of the tick period i    
206 Thus, if the tick is allowed to trigger on idl    
207 for them to ask the hardware to enter idle sta    
208 the tick period length.  Moreover, in that cas    
209 will never exceed the tick period length and t    
210 exiting idle states due to the tick wakeups on    
211                                                   
212 Fortunately, it is not really necessary to all    
213 CPUs, because (by definition) they have no tas    
214 "idle" one.  In other words, from the CPU sche    
215 of the CPU time on them is the idle loop.  Sin    
216 not be shared between multiple runnable tasks,    
217 tick goes away if the given CPU is idle.  Cons    
218 the scheduler tick entirely on idle CPUs in pr    
219 always be worth the effort.                       
220                                                   
221 Whether or not it makes sense to stop the sche    
222 depends on what is expected by the governor.      
223 (non-tick) timer due to trigger within the tic    
224 would be a waste of time, even though the time    
225 reprogrammed in that case.  Second, if the gov    
226 wakeup within the tick range, stopping the tic    
227 be harmful.  Namely, in that case the governor    
228 the target residency within the time until the    
229 going to be relatively shallow.  The governor     
230 state then, as that would contradict its own e    
231 order.  Now, if the wakeup really occurs short    
232 waste of time and in this case the timer hardw    
233 which is expensive.  On the other hand, if the    
234 does not occur any time soon, the hardware may    
235 in the shallow idle state selected by the gove    
236 energy.  Hence, if the governor is expecting a    
237 tick range, it is better to allow the tick tri    
238 governor will select a relatively deep idle st    
239 so that it does not wake up the CPU too early.    
240                                                   
241 In any case, the governor knows what it is exp    
242 or not to stop the scheduler tick belongs to i    
243 stopped already (in one of the previous iterat    
244 to leave it as is and the governor needs to ta    
245                                                   
246 The kernel can be configured to disable stoppi    
247 loop altogether.  That can be done through the    
248 (by unsetting the ``CONFIG_NO_HZ_IDLE`` config    
249 ``nohz=off`` to it in the command line.  In bo    
250 scheduler tick is disabled, the governor's dec    
251 ignored by the idle loop code and the tick is     
252                                                   
253 The systems that run kernels configured to all    
254 stopped on idle CPUs are referred to as *tickl    
255 generally regarded as more energy-efficient th    
256 which the tick cannot be stopped.  If the give    
257 the ``menu`` governor by default and if it is     
258 ``CPUIdle`` governor on it will be ``ladder``.    
259                                                   
260                                                   
261 .. _menu-gov:                                     
262                                                   
263 The ``menu`` Governor                             
264 =====================                             
265                                                   
266 The ``menu`` governor is the default ``CPUIdle    
267 It is quite complex, but the basic principle o    
268 Namely, when invoked to select an idle state f    
269 the CPU will ask the processor hardware to ent    
270 idle duration and uses the predicted value for    
271                                                   
272 It first obtains the time until the closest ti    
273 that the scheduler tick will be stopped.  That    
274 length* in what follows, is the upper bound on    
275 wakeup.  It is used to determine the sleep len    
276 to get the sleep length correction factor.        
277                                                   
278 The ``menu`` governor maintains two arrays of     
279 One of them is used when tasks previously runn    
280 for some I/O operations to complete and the ot    
281 the case.  Each array contains several correct    
282 to different sleep length ranges organized so     
283 array is approximately 10 times wider than the    
284                                                   
285 The correction factor for the given sleep leng    
286 selecting the idle state for the CPU) is updat    
287 up and the closer the sleep length is to the o    
288 to 1 the correction factor becomes (it must fa    
289 The sleep length is multiplied by the correcti    
290 falls into to obtain the first approximation o    
291                                                   
292 Next, the governor uses a simple pattern recog    
293 idle duration prediction.  Namely, it saves th    
294 values and, when predicting the idle duration     
295 and variance of them.  If the variance is smal    
296 milliseconds) or it is small relative to the a    
297 that 6 times the standard deviation), the aver    
298 interval" value.  Otherwise, the longest of th    
299 values is discarded and the computation is rep    
300 Again, if the variance of them is small (in th    
301 taken as the "typical interval" value and so o    
302 interval" is determined or too many data point    
303 the "typical interval" is assumed to equal "in    
304 integer value).  The "typical interval" comput    
305 sleep length multiplied by the correction fact    
306 taken as the predicted idle duration.             
307                                                   
308 Then, the governor computes an extra latency l    
309 workloads.  It uses the observation that if th    
310 idle state is comparable with the predicted id    
311 in that state probably will be very short and     
312 entering it will be relatively small, so likel    
313 overhead related to entering that state and ex    
314 shallower state is likely to be a better optio    
315 of the extra latency limit is the predicted id    
316 additionally is divided by a value depending o    
317 previously ran on the given CPU and now they a    
318 complete.  The result of that division is comp    
319 from the power management quality of service,     
320 framework and the minimum of the two is taken     
321 exit latency.                                     
322                                                   
323 Now, the governor is ready to walk the list of    
324 them.  For this purpose, it compares the targe    
325 the predicted idle duration and the exit laten    
326 limit.  It selects the state with the target r    
327 idle duration, but still below it, and exit la    
328 limit.                                            
329                                                   
330 In the final step the governor may still need     
331 if it has not decided to `stop the scheduler t    
332 happens if the idle duration predicted by it i    
333 the tick has not been stopped already (in a pr    
334 loop).  Then, the sleep length used in the pre    
335 the real time until the closest timer event an    
336 that time, the governor may need to select a s    
337 target residency.                                 
338                                                   
339                                                   
340 .. _teo-gov:                                      
341                                                   
342 The Timer Events Oriented (TEO) Governor          
343 ========================================          
344                                                   
345 The timer events oriented (TEO) governor is an    
346 for tickless systems.  It follows the same bas    
347 <menu-gov_>`_: it always tries to find the dee    
348 given conditions.  However, it applies a diffe    
349                                                   
350 .. kernel-doc:: drivers/cpuidle/governors/teo.    
351    :doc: teo-description                          
352                                                   
353 .. _idle-states-representation:                   
354                                                   
355 Representation of Idle States                     
356 =============================                     
357                                                   
358 For the CPU idle time management purposes all     
359 supported by the processor have to be represen    
360 |struct cpuidle_state| objects each allowing a    
361 the processor hardware to enter an idle state     
362 is a hierarchy of units in the processor, one     
363 cover a combination of idle states supported b    
364 the hierarchy.  In that case, the `target resi    
365 of it <idle-loop_>`_, must reflect the propert    
366 deepest level (i.e. the idle state of the unit    
367 units).                                           
368                                                   
369 For example, take a processor with two cores i    
370 a "module" and suppose that asking the hardwar    
371 (say "X") at the "core" level by one core will    
372 enter a specific idle state of its own (say "M    
373 state "X" already.  In other words, asking for    
374 level gives the hardware a license to go as de    
375 "module" level, but there is no guarantee that    
376 asking for idle state "X" may just end up in t    
377 Then, the target residency of the |struct cpui    
378 idle state "X" must reflect the minimum time t    
379 the module (including the time needed to enter    
380 time the CPU needs to be idle to save any ener    
381 that state.  Analogously, the exit latency par    
382 the exit time of idle state "MX" of the module    
383 because that is the maximum delay between a wa    
384 will start to execute the first new instructio    
385 module will always be ready to execute instruc    
386 becomes operational as a whole).                  
387                                                   
388 There are processors without direct coordinati    
389 hierarchy of units inside them, however.  In t    
390 state at the "core" level does not automatical    
391 example, in any way and the ``CPUIdle`` driver    
392 handling of the hierarchy.  Then, the definiti    
393 entirely up to the driver, but still the physi    
394 that the processor hardware finally goes into     
395 used by the governor for idle state selection     
396 latency of that idle state must not exceed the    
397 idle state object selected by the governor).      
398                                                   
399 In addition to the target residency and exit l    
400 discussed above, the objects representing idle    
401 parameters describing the idle state and a poi    
402 order to ask the hardware to enter that state.    
403 |struct cpuidle_state| object, there is a corr    
404 :c:type:`struct cpuidle_state_usage <cpuidle_s    
405 statistics of the given idle state.  That info    
406 via ``sysfs``.                                    
407                                                   
408 For each CPU in the system, there is a :file:`    
409 directory in ``sysfs``, where the number ``<N>    
410 CPU at the initialization time.  That director    
411 called :file:`state0`, :file:`state1` and so o    
412 objects defined for the given CPU minus one.      
413 corresponds to one idle state object and the l    
414 deeper the (effective) idle state represented     
415 a number of files (attributes) representing th    
416 object corresponding to it, as follows:           
417                                                   
418 ``above``                                         
419         Total number of times this idle state     
420         observed idle duration was certainly t    
421         residency.                                
422                                                   
423 ``below``                                         
424         Total number of times this idle state     
425         a deeper idle state would have been a     
426         duration.                                 
427                                                   
428 ``desc``                                          
429         Description of the idle state.            
430                                                   
431 ``disable``                                       
432         Whether or not this idle state is disa    
433                                                   
434 ``default_status``                                
435         The default status of this state, "ena    
436                                                   
437 ``latency``                                       
438         Exit latency of the idle state in micr    
439                                                   
440 ``name``                                          
441         Name of the idle state.                   
442                                                   
443 ``power``                                         
444         Power drawn by hardware in this idle s    
445         0 otherwise).                             
446                                                   
447 ``residency``                                     
448         Target residency of the idle state in     
449                                                   
450 ``time``                                          
451         Total time spent in this idle state by    
452         kernel) in microseconds.                  
453                                                   
454 ``usage``                                         
455         Total number of times the hardware has    
456         enter this idle state.                    
457                                                   
458 ``rejected``                                      
459         Total number of times a request to ent    
460         CPU was rejected.                         
461                                                   
462 The :file:`desc` and :file:`name` files both c    
463 between them is that the name is expected to b    
464 description may be longer and it may contain w    
465 The other files listed above contain integer n    
466                                                   
467 The :file:`disable` attribute is the only writ    
468 given idle state is disabled for this particul    
469 governor will never select it for this particu    
470 driver will never ask the hardware to enter it    
471 However, disabling an idle state for one CPU d    
472 asked for by the other CPUs, so it must be dis    
473 never be asked for by any of them.  [Note that    
474 governor is implemented, disabling an idle sta    
475 selecting any idle states deeper than the disa    
476                                                   
477 If the :file:`disable` attribute contains 0, t    
478 this particular CPU, but it still may be disab    
479 CPUs in the system at the same time.  Writing     
480 be disabled for this particular CPU and writin    
481 take it into consideration for the given CPU a    
482 unless that state was disabled globally in the    
483 be used at all).                                  
484                                                   
485 The :file:`power` attribute is not defined ver    
486 objects representing combinations of idle stat    
487 hierarchy of units in the processor, and it ge    
488 state power numbers for complex hardware, so :    
489 available) and if it contains a nonzero number    
490 accurate and it should not be relied on for an    
491                                                   
492 The number in the :file:`time` file generally     
493 really spent by the given CPU in the given idl    
494 the kernel and it may not cover the cases in w    
495 this idle state and entered a shallower one in    
496 enter any idle state at all).  The kernel can     
497 asking the hardware to enter an idle state and    
498 and it cannot say what really happened in the     
499 Moreover, if the idle state object in question    
500 states at different levels of the hierarchy of    
501 the kernel can never say how deep the hardware    
502 particular case.  For these reasons, the only     
503 much time has been spent by the hardware in di    
504 it is to use idle state residency counters in     
505                                                   
506 Generally, an interrupt received when trying t    
507 idle state entry request to be rejected, in wh    
508 may return an error code to indicate that this    
509 and :file:`rejected` files report the number o    
510 was entered successfully or rejected, respecti    
511                                                   
512 .. _cpu-pm-qos:                                   
513                                                   
514 Power Management Quality of Service for CPUs      
515 ============================================      
516                                                   
517 The power management quality of service (PM Qo    
518 allows kernel code and user space processes to    
519 energy-efficiency features of the kernel to pr    
520 below a required level.                           
521                                                   
522 CPU idle time management can be affected by PM    
523 global CPU latency limit and through the resum    
524 individual CPUs.  Kernel code (e.g. device dri    
525 the help of special internal interfaces provid    
526 space can modify the former by opening the :fi    
527 device file under :file:`/dev/` and writing a     
528 signed 32-bit integer) to it.  In turn, the re    
529 can be modified from user space by writing a s    
530 32-bit integer) to the :file:`power/pm_qos_res    
531 :file:`/sys/devices/system/cpu/cpu<N>/` in ``s    
532 ``<N>`` is allocated at the system initializat    
533 will be rejected in both cases and, also in bo    
534 number will be interpreted as a requested PM Q    
535                                                   
536 The requested value is not automatically appli    
537 as it may be less restrictive (greater in this    
538 constraint previously requested by someone els    
539 framework maintains a list of requests that ha    
540 global CPU latency limit and for each individu    
541 applies the effective (minimum in this particu    
542 constraint.                                       
543                                                   
544 In fact, opening the :file:`cpu_dma_latency` s    
545 PM QoS request to be created and added to a gl    
546 limit requests and the file descriptor coming     
547 represents that request.  If that file descrip    
548 number written to it will be associated with t    
549 it as a new requested limit value.  Next, the     
550 used to determine the new effective value of t    
551 that effective value will be set as a new CPU     
552 new limit value will only change the real limi    
553 affected by it, which is the case if it is the    
554 in the list.                                      
555                                                   
556 The process holding a file descriptor obtained    
557 :file:`cpu_dma_latency` special device file co    
558 associated with that file descriptor, but it c    
559 request only.                                     
560                                                   
561 Closing the :file:`cpu_dma_latency` special de    
562 file descriptor obtained while opening it, cau    
563 with that file descriptor to be removed from t    
564 latency limit requests and destroyed.  If that    
565 mechanism will be used again, to determine the    
566 list and that value will become the new limit.    
567                                                   
568 In turn, for each CPU there is one resume late    
569 the :file:`power/pm_qos_resume_latency_us` fil    
570 :file:`/sys/devices/system/cpu/cpu<N>/` in ``s    
571 this single PM QoS request to be updated regar    
572 process does that.  In other words, this PM Qo    
573 user space, so access to the file associated w    
574 to avoid confusion.  [Arguably, the only legit    
575 practice is to pin a process to the CPU in que    
576 ``sysfs`` interface to control the resume late    
577 still only a request, however.  It is an entry    
578 determine the effective value to be set as the    
579 CPU in question every time the list of request    
580 (there may be other requests coming from kerne    
581                                                   
582 CPU idle time governors are expected to regard    
583 (effective) CPU latency limit and the effectiv    
584 the given CPU as the upper limit for the exit     
585 they are allowed to select for that CPU.  They    
586 states with exit latency beyond that limit.       
587                                                   
588                                                   
589 Idle States Control Via Kernel Command Line       
590 ===========================================       
591                                                   
592 In addition to the ``sysfs`` interface allowin    
593 `disabled for individual CPUs <idle-states-rep    
594 command line parameters affecting CPU idle tim    
595                                                   
596 The ``cpuidle.off=1`` kernel command line opti    
597 CPU idle time management entirely.  It does no    
598 running on idle CPUs, but it prevents the CPU     
599 from being invoked.  If it is added to the ker    
600 will ask the hardware to enter idle states on     
601 support code that is expected to provide a def    
602 That default mechanism usually is the least co    
603 processors implementing the architecture (i.e.    
604 however, so it is rather crude and not very en    
605 it is not recommended for production use.         
606                                                   
607 The ``cpuidle.governor=`` kernel command line     
608 governor to use to be specified.  It has to be    
609 the name of an available governor (e.g. ``cpui    
610 governor will be used instead of the default o    
611 the ``menu`` governor to be used on the system    
612 by default this way, for example.                 
613                                                   
614 The other kernel command line parameters contr    
615 described below are only relevant for the *x86    
616 to ``intel_idle`` affect Intel processors only    
617                                                   
618 The *x86* architecture support code recognizes    
619 options related to CPU idle time management: `    
620 and ``idle=nomwait``.  The first two of them d    
621 ``intel_idle`` drivers altogether, which effec    
622 ``CPUIdle`` subsystem to be disabled and makes    
623 architecture support code to deal with idle CP    
624 which of the two parameters is added to the ke    
625 ``idle=halt`` case, the architecture support c    
626 instruction of the CPUs (which, as a rule, sus    
627 and causes the hardware to attempt to enter th    
628 for this purpose, and if ``idle=poll`` is used    
629 more or less "lightweight" sequence of instruc    
630 that using ``idle=poll`` is somewhat drastic i    
631 CPUs from saving almost any energy at all may     
632 For example, on Intel hardware it effectively     
633 P-states (see |cpufreq|) that require any numb    
634 idle, so it very well may hurt single-thread c    
635 energy-efficiency.  Thus using it for performa    
636 at all.]                                          
637                                                   
638 The ``idle=nomwait`` option prevents the use o    
639 the CPU to enter idle states. When this option    
640 driver will use the ``HLT`` instruction instea    
641 running Intel processors, this option disables    
642 and forces the use of the ``acpi_idle`` driver    
643 case, ``acpi_idle`` driver will function only     
644 by it is in the system's ACPI tables.             
645                                                   
646 In addition to the architecture-level kernel c    
647 idle time management, there are parameters aff    
648 drivers that can be passed to them via the ker    
649 the ``intel_idle.max_cstate=<n>`` and ``proces    
650 where ``<n>`` is an idle state index also used    
651 state's directory in ``sysfs`` (see               
652 `Representation of Idle States <idle-states-re    
653 ``intel_idle`` and ``acpi_idle`` drivers, resp    
654 idle states deeper than idle state ``<n>``.  I    
655 for any of those idle states or expose them to    
656 the two drivers is different for ``<n>`` equal    
657 ``intel_idle.max_cstate=0`` to the kernel comm    
658 ``intel_idle`` driver and allows ``acpi_idle``    
659 ``processor.max_cstate=0`` is equivalent to ``    
660 Also, the ``acpi_idle`` driver is part of the     
661 can be loaded separately and ``max_cstate=<n>`    
662 parameter when it is loaded.]                     
                                                      

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