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

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  1 .. SPDX-License-Identifier: GPL-2.0
  2 
  3 =======================================================
  4 Legacy Documentation of CPU Performance Scaling Drivers
  5 =======================================================
  6 
  7 Included below are historic documents describing assorted
  8 :doc:`CPU performance scaling <cpufreq>` drivers.  They are reproduced verbatim,
  9 with the original white space formatting and indentation preserved, except for
 10 the added leading space character in every line of text.
 11 
 12 
 13 AMD PowerNow! Drivers
 14 =====================
 15 
 16 ::
 17 
 18  PowerNow! and Cool'n'Quiet are AMD names for frequency
 19  management capabilities in AMD processors. As the hardware
 20  implementation changes in new generations of the processors,
 21  there is a different cpu-freq driver for each generation.
 22 
 23  Note that the driver's will not load on the "wrong" hardware,
 24  so it is safe to try each driver in turn when in doubt as to
 25  which is the correct driver.
 26 
 27  Note that the functionality to change frequency (and voltage)
 28  is not available in all processors. The drivers will refuse
 29  to load on processors without this capability. The capability
 30  is detected with the cpuid instruction.
 31 
 32  The drivers use BIOS supplied tables to obtain frequency and
 33  voltage information appropriate for a particular platform.
 34  Frequency transitions will be unavailable if the BIOS does
 35  not supply these tables.
 36 
 37  6th Generation: powernow-k6
 38 
 39  7th Generation: powernow-k7: Athlon, Duron, Geode.
 40 
 41  8th Generation: powernow-k8: Athlon, Athlon 64, Opteron, Sempron.
 42  Documentation on this functionality in 8th generation processors
 43  is available in the "BIOS and Kernel Developer's Guide", publication
 44  26094, in chapter 9, available for download from www.amd.com.
 45 
 46  BIOS supplied data, for powernow-k7 and for powernow-k8, may be
 47  from either the PSB table or from ACPI objects. The ACPI support
 48  is only available if the kernel config sets CONFIG_ACPI_PROCESSOR.
 49  The powernow-k8 driver will attempt to use ACPI if so configured,
 50  and fall back to PST if that fails.
 51  The powernow-k7 driver will try to use the PSB support first, and
 52  fall back to ACPI if the PSB support fails. A module parameter,
 53  acpi_force, is provided to force ACPI support to be used instead
 54  of PSB support.
 55 
 56 
 57 ``cpufreq-nforce2``
 58 ===================
 59 
 60 ::
 61 
 62  The cpufreq-nforce2 driver changes the FSB on nVidia nForce2 platforms.
 63 
 64  This works better than on other platforms, because the FSB of the CPU
 65  can be controlled independently from the PCI/AGP clock.
 66 
 67  The module has two options:
 68 
 69         fid:     multiplier * 10 (for example 8.5 = 85)
 70         min_fsb: minimum FSB
 71 
 72  If not set, fid is calculated from the current CPU speed and the FSB.
 73  min_fsb defaults to FSB at boot time - 50 MHz.
 74 
 75  IMPORTANT: The available range is limited downwards!
 76             Also the minimum available FSB can differ, for systems
 77             booting with 200 MHz, 150 should always work.
 78 
 79 
 80 ``pcc-cpufreq``
 81 ===============
 82 
 83 ::
 84 
 85  /*
 86   *  pcc-cpufreq.txt - PCC interface documentation
 87   *
 88   *  Copyright (C) 2009 Red Hat, Matthew Garrett <mjg@redhat.com>
 89   *  Copyright (C) 2009 Hewlett-Packard Development Company, L.P.
 90   *      Nagananda Chumbalkar <nagananda.chumbalkar@hp.com>
 91   */
 92 
 93 
 94                         Processor Clocking Control Driver
 95                         ---------------------------------
 96 
 97  Contents:
 98  ---------
 99  1.     Introduction
100  1.1    PCC interface
101  1.1.1  Get Average Frequency
102  1.1.2  Set Desired Frequency
103  1.2    Platforms affected
104  2.     Driver and /sys details
105  2.1    scaling_available_frequencies
106  2.2    cpuinfo_transition_latency
107  2.3    cpuinfo_cur_freq
108  2.4    related_cpus
109  3.     Caveats
110 
111  1. Introduction:
112  ----------------
113  Processor Clocking Control (PCC) is an interface between the platform
114  firmware and OSPM. It is a mechanism for coordinating processor
115  performance (ie: frequency) between the platform firmware and the OS.
116 
117  The PCC driver (pcc-cpufreq) allows OSPM to take advantage of the PCC
118  interface.
119 
120  OS utilizes the PCC interface to inform platform firmware what frequency the
121  OS wants for a logical processor. The platform firmware attempts to achieve
122  the requested frequency. If the request for the target frequency could not be
123  satisfied by platform firmware, then it usually means that power budget
124  conditions are in place, and "power capping" is taking place.
125 
126  1.1 PCC interface:
127  ------------------
128  The complete PCC specification is available here:
129  https://acpica.org/sites/acpica/files/Processor-Clocking-Control-v1p0.pdf
130 
131  PCC relies on a shared memory region that provides a channel for communication
132  between the OS and platform firmware. PCC also implements a "doorbell" that
133  is used by the OS to inform the platform firmware that a command has been
134  sent.
135 
136  The ACPI PCCH() method is used to discover the location of the PCC shared
137  memory region. The shared memory region header contains the "command" and
138  "status" interface. PCCH() also contains details on how to access the platform
139  doorbell.
140 
141  The following commands are supported by the PCC interface:
142  * Get Average Frequency
143  * Set Desired Frequency
144 
145  The ACPI PCCP() method is implemented for each logical processor and is
146  used to discover the offsets for the input and output buffers in the shared
147  memory region.
148 
149  When PCC mode is enabled, the platform will not expose processor performance
150  or throttle states (_PSS, _TSS and related ACPI objects) to OSPM. Therefore,
151  the native P-state driver (such as acpi-cpufreq for Intel, powernow-k8 for
152  AMD) will not load.
153 
154  However, OSPM remains in control of policy. The governor (eg: "ondemand")
155  computes the required performance for each processor based on server workload.
156  The PCC driver fills in the command interface, and the input buffer and
157  communicates the request to the platform firmware. The platform firmware is
158  responsible for delivering the requested performance.
159 
160  Each PCC command is "global" in scope and can affect all the logical CPUs in
161  the system. Therefore, PCC is capable of performing "group" updates. With PCC
162  the OS is capable of getting/setting the frequency of all the logical CPUs in
163  the system with a single call to the BIOS.
164 
165  1.1.1 Get Average Frequency:
166  ----------------------------
167  This command is used by the OSPM to query the running frequency of the
168  processor since the last time this command was completed. The output buffer
169  indicates the average unhalted frequency of the logical processor expressed as
170  a percentage of the nominal (ie: maximum) CPU frequency. The output buffer
171  also signifies if the CPU frequency is limited by a power budget condition.
172 
173  1.1.2 Set Desired Frequency:
174  ----------------------------
175  This command is used by the OSPM to communicate to the platform firmware the
176  desired frequency for a logical processor. The output buffer is currently
177  ignored by OSPM. The next invocation of "Get Average Frequency" will inform
178  OSPM if the desired frequency was achieved or not.
179 
180  1.2 Platforms affected:
181  -----------------------
182  The PCC driver will load on any system where the platform firmware:
183  * supports the PCC interface, and the associated PCCH() and PCCP() methods
184  * assumes responsibility for managing the hardware clocking controls in order
185  to deliver the requested processor performance
186 
187  Currently, certain HP ProLiant platforms implement the PCC interface. On those
188  platforms PCC is the "default" choice.
189 
190  However, it is possible to disable this interface via a BIOS setting. In
191  such an instance, as is also the case on platforms where the PCC interface
192  is not implemented, the PCC driver will fail to load silently.
193 
194  2. Driver and /sys details:
195  ---------------------------
196  When the driver loads, it merely prints the lowest and the highest CPU
197  frequencies supported by the platform firmware.
198 
199  The PCC driver loads with a message such as:
200  pcc-cpufreq: (v1.00.00) driver loaded with frequency limits: 1600 MHz, 2933
201  MHz
202 
203  This means that the OPSM can request the CPU to run at any frequency in
204  between the limits (1600 MHz, and 2933 MHz) specified in the message.
205 
206  Internally, there is no need for the driver to convert the "target" frequency
207  to a corresponding P-state.
208 
209  The VERSION number for the driver will be of the format v.xy.ab.
210  eg: 1.00.02
211     ----- --
212      |    |
213      |    -- this will increase with bug fixes/enhancements to the driver
214      |-- this is the version of the PCC specification the driver adheres to
215 
216 
217  The following is a brief discussion on some of the fields exported via the
218  /sys filesystem and how their values are affected by the PCC driver:
219 
220  2.1 scaling_available_frequencies:
221  ----------------------------------
222  scaling_available_frequencies is not created in /sys. No intermediate
223  frequencies need to be listed because the BIOS will try to achieve any
224  frequency, within limits, requested by the governor. A frequency does not have
225  to be strictly associated with a P-state.
226 
227  2.2 cpuinfo_transition_latency:
228  -------------------------------
229  The cpuinfo_transition_latency field is 0. The PCC specification does
230  not include a field to expose this value currently.
231 
232  2.3 cpuinfo_cur_freq:
233  ---------------------
234  A) Often cpuinfo_cur_freq will show a value different than what is declared
235  in the scaling_available_frequencies or scaling_cur_freq, or scaling_max_freq.
236  This is due to "turbo boost" available on recent Intel processors. If certain
237  conditions are met the BIOS can achieve a slightly higher speed than requested
238  by OSPM. An example:
239 
240  scaling_cur_freq       : 2933000
241  cpuinfo_cur_freq       : 3196000
242 
243  B) There is a round-off error associated with the cpuinfo_cur_freq value.
244  Since the driver obtains the current frequency as a "percentage" (%) of the
245  nominal frequency from the BIOS, sometimes, the values displayed by
246  scaling_cur_freq and cpuinfo_cur_freq may not match. An example:
247 
248  scaling_cur_freq       : 1600000
249  cpuinfo_cur_freq       : 1583000
250 
251  In this example, the nominal frequency is 2933 MHz. The driver obtains the
252  current frequency, cpuinfo_cur_freq, as 54% of the nominal frequency:
253 
254         54% of 2933 MHz = 1583 MHz
255 
256  Nominal frequency is the maximum frequency of the processor, and it usually
257  corresponds to the frequency of the P0 P-state.
258 
259  2.4 related_cpus:
260  -----------------
261  The related_cpus field is identical to affected_cpus.
262 
263  affected_cpus  : 4
264  related_cpus   : 4
265 
266  Currently, the PCC driver does not evaluate _PSD. The platforms that support
267  PCC do not implement SW_ALL. So OSPM doesn't need to perform any coordination
268  to ensure that the same frequency is requested of all dependent CPUs.
269 
270  3. Caveats:
271  -----------
272  The "cpufreq_stats" module in its present form cannot be loaded and
273  expected to work with the PCC driver. Since the "cpufreq_stats" module
274  provides information wrt each P-state, it is not applicable to the PCC driver.

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