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Despite being named with .rst extension, this file doesn't match the ReST standard. It actually causes a crash at Sphinx: Sphinx parallel build error: docutils.utils.SystemMessage: /devel/v4l/docs/Documentation/driver-api/thermal/cpu-idle-cooling.rst:69: (SEVERE/4) Unexpected section title. Add needed markups for it to be properly parsed. Signed-off-by: Mauro Carvalho Chehab <mchehab+huawei@kernel.org> Link: https://lore.kernel.org/r/7640755514809a7b5fe2756f3702613865877dcb.1592203650.git.mchehab+huawei@kernel.org Signed-off-by: Jonathan Corbet <corbet@lwn.net>
199 lines
7.1 KiB
ReStructuredText
199 lines
7.1 KiB
ReStructuredText
.. SPDX-License-Identifier: GPL-2.0
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================
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CPU Idle Cooling
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================
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Situation:
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----------
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Under certain circumstances a SoC can reach a critical temperature
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limit and is unable to stabilize the temperature around a temperature
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control. When the SoC has to stabilize the temperature, the kernel can
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act on a cooling device to mitigate the dissipated power. When the
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critical temperature is reached, a decision must be taken to reduce
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the temperature, that, in turn impacts performance.
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Another situation is when the silicon temperature continues to
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increase even after the dynamic leakage is reduced to its minimum by
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clock gating the component. This runaway phenomenon can continue due
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to the static leakage. The only solution is to power down the
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component, thus dropping the dynamic and static leakage that will
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allow the component to cool down.
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Last but not least, the system can ask for a specific power budget but
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because of the OPP density, we can only choose an OPP with a power
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budget lower than the requested one and under-utilize the CPU, thus
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losing performance. In other words, one OPP under-utilizes the CPU
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with a power less than the requested power budget and the next OPP
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exceeds the power budget. An intermediate OPP could have been used if
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it were present.
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Solutions:
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----------
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If we can remove the static and the dynamic leakage for a specific
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duration in a controlled period, the SoC temperature will
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decrease. Acting on the idle state duration or the idle cycle
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injection period, we can mitigate the temperature by modulating the
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power budget.
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The Operating Performance Point (OPP) density has a great influence on
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the control precision of cpufreq, however different vendors have a
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plethora of OPP density, and some have large power gap between OPPs,
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that will result in loss of performance during thermal control and
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loss of power in other scenarios.
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At a specific OPP, we can assume that injecting idle cycle on all CPUs
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belong to the same cluster, with a duration greater than the cluster
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idle state target residency, we lead to dropping the static and the
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dynamic leakage for this period (modulo the energy needed to enter
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this state). So the sustainable power with idle cycles has a linear
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relation with the OPP’s sustainable power and can be computed with a
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coefficient similar to::
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Power(IdleCycle) = Coef x Power(OPP)
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Idle Injection:
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---------------
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The base concept of the idle injection is to force the CPU to go to an
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idle state for a specified time each control cycle, it provides
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another way to control CPU power and heat in addition to
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cpufreq. Ideally, if all CPUs belonging to the same cluster, inject
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their idle cycles synchronously, the cluster can reach its power down
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state with a minimum power consumption and reduce the static leakage
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to almost zero. However, these idle cycles injection will add extra
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latencies as the CPUs will have to wakeup from a deep sleep state.
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We use a fixed duration of idle injection that gives an acceptable
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performance penalty and a fixed latency. Mitigation can be increased
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or decreased by modulating the duty cycle of the idle injection.
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::
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^
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|------- -------
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|_______|_______________________|_______|___________
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<------>
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idle <---------------------->
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running
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<----------------------------->
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duty cycle 25%
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The implementation of the cooling device bases the number of states on
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the duty cycle percentage. When no mitigation is happening the cooling
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device state is zero, meaning the duty cycle is 0%.
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When the mitigation begins, depending on the governor's policy, a
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starting state is selected. With a fixed idle duration and the duty
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cycle (aka the cooling device state), the running duration can be
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computed.
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The governor will change the cooling device state thus the duty cycle
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and this variation will modulate the cooling effect.
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::
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^
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|------- -------
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|_______|_______________|_______|___________
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<------>
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idle <-------------->
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running
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<--------------------->
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duty cycle 33%
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^
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|------- -------
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|_______|_______|_______|___________
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<------>
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idle <------>
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running
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<------------->
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duty cycle 50%
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The idle injection duration value must comply with the constraints:
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- It is less than or equal to the latency we tolerate when the
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mitigation begins. It is platform dependent and will depend on the
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user experience, reactivity vs performance trade off we want. This
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value should be specified.
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- It is greater than the idle state’s target residency we want to go
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for thermal mitigation, otherwise we end up consuming more energy.
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Power considerations
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--------------------
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When we reach the thermal trip point, we have to sustain a specified
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power for a specific temperature but at this time we consume::
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Power = Capacitance x Voltage^2 x Frequency x Utilisation
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... which is more than the sustainable power (or there is something
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wrong in the system setup). The ‘Capacitance’ and ‘Utilisation’ are a
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fixed value, ‘Voltage’ and the ‘Frequency’ are fixed artificially
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because we don’t want to change the OPP. We can group the
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‘Capacitance’ and the ‘Utilisation’ into a single term which is the
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‘Dynamic Power Coefficient (Cdyn)’ Simplifying the above, we have::
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Pdyn = Cdyn x Voltage^2 x Frequency
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The power allocator governor will ask us somehow to reduce our power
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in order to target the sustainable power defined in the device
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tree. So with the idle injection mechanism, we want an average power
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(Ptarget) resulting in an amount of time running at full power on a
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specific OPP and idle another amount of time. That could be put in a
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equation::
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P(opp)target = ((Trunning x (P(opp)running) + (Tidle x P(opp)idle)) /
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(Trunning + Tidle)
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...
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Tidle = Trunning x ((P(opp)running / P(opp)target) - 1)
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At this point if we know the running period for the CPU, that gives us
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the idle injection we need. Alternatively if we have the idle
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injection duration, we can compute the running duration with::
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Trunning = Tidle / ((P(opp)running / P(opp)target) - 1)
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Practically, if the running power is less than the targeted power, we
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end up with a negative time value, so obviously the equation usage is
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bound to a power reduction, hence a higher OPP is needed to have the
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running power greater than the targeted power.
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However, in this demonstration we ignore three aspects:
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* The static leakage is not defined here, we can introduce it in the
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equation but assuming it will be zero most of the time as it is
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difficult to get the values from the SoC vendors
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* The idle state wake up latency (or entry + exit latency) is not
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taken into account, it must be added in the equation in order to
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rigorously compute the idle injection
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* The injected idle duration must be greater than the idle state
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target residency, otherwise we end up consuming more energy and
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potentially invert the mitigation effect
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So the final equation is::
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Trunning = (Tidle - Twakeup ) x
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(((P(opp)dyn + P(opp)static ) - P(opp)target) / P(opp)target )
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