6b775e870c
The power allocator governor is a thermal governor that controls system and device power allocation to control temperature. Conceptually, the implementation divides the sustainable power of a thermal zone among all the heat sources in that zone. This governor relies on "power actors", entities that represent heat sources. They can report current and maximum power consumption and can set a given maximum power consumption, usually via a cooling device. The governor uses a Proportional Integral Derivative (PID) controller driven by the temperature of the thermal zone. The output of the controller is a power budget that is then allocated to each power actor that can have bearing on the temperature we are trying to control. It decides how much power to give each cooling device based on the performance they are requesting. The PID controller ensures that the total power budget does not exceed the control temperature. Cc: Zhang Rui <rui.zhang@intel.com> Cc: Eduardo Valentin <edubezval@gmail.com> Signed-off-by: Punit Agrawal <punit.agrawal@arm.com> Signed-off-by: Javi Merino <javi.merino@arm.com> Signed-off-by: Eduardo Valentin <edubezval@gmail.com>
247 lines
10 KiB
Text
247 lines
10 KiB
Text
Power allocator governor tunables
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=================================
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Trip points
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-----------
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The governor requires the following two passive trip points:
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1. "switch on" trip point: temperature above which the governor
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control loop starts operating. This is the first passive trip
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point of the thermal zone.
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2. "desired temperature" trip point: it should be higher than the
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"switch on" trip point. This the target temperature the governor
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is controlling for. This is the last passive trip point of the
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thermal zone.
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PID Controller
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--------------
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The power allocator governor implements a
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Proportional-Integral-Derivative controller (PID controller) with
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temperature as the control input and power as the controlled output:
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P_max = k_p * e + k_i * err_integral + k_d * diff_err + sustainable_power
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where
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e = desired_temperature - current_temperature
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err_integral is the sum of previous errors
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diff_err = e - previous_error
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It is similar to the one depicted below:
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k_d
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current_temp |
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| v
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| +----------+ +---+
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| +----->| diff_err |-->| X |------+
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| | +----------+ +---+ |
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| | | tdp actor
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| | k_i | | get_requested_power()
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| | | | | | |
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| | | | | | | ...
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v | v v v v v
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+---+ | +-------+ +---+ +---+ +---+ +----------+
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| S |-------+----->| sum e |----->| X |--->| S |-->| S |-->|power |
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+---+ | +-------+ +---+ +---+ +---+ |allocation|
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^ | ^ +----------+
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| | | | |
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| | +---+ | | |
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| +------->| X |-------------------+ v v
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| +---+ granted performance
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desired_temperature ^
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k_po/k_pu
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Sustainable power
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-----------------
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An estimate of the sustainable dissipatable power (in mW) should be
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provided while registering the thermal zone. This estimates the
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sustained power that can be dissipated at the desired control
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temperature. This is the maximum sustained power for allocation at
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the desired maximum temperature. The actual sustained power can vary
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for a number of reasons. The closed loop controller will take care of
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variations such as environmental conditions, and some factors related
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to the speed-grade of the silicon. `sustainable_power` is therefore
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simply an estimate, and may be tuned to affect the aggressiveness of
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the thermal ramp. For reference, the sustainable power of a 4" phone
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is typically 2000mW, while on a 10" tablet is around 4500mW (may vary
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depending on screen size).
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If you are using device tree, do add it as a property of the
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thermal-zone. For example:
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thermal-zones {
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soc_thermal {
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polling-delay = <1000>;
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polling-delay-passive = <100>;
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sustainable-power = <2500>;
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...
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Instead, if the thermal zone is registered from the platform code, pass a
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`thermal_zone_params` that has a `sustainable_power`. If no
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`thermal_zone_params` were being passed, then something like below
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will suffice:
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static const struct thermal_zone_params tz_params = {
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.sustainable_power = 3500,
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};
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and then pass `tz_params` as the 5th parameter to
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`thermal_zone_device_register()`
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k_po and k_pu
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-------------
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The implementation of the PID controller in the power allocator
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thermal governor allows the configuration of two proportional term
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constants: `k_po` and `k_pu`. `k_po` is the proportional term
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constant during temperature overshoot periods (current temperature is
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above "desired temperature" trip point). Conversely, `k_pu` is the
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proportional term constant during temperature undershoot periods
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(current temperature below "desired temperature" trip point).
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These controls are intended as the primary mechanism for configuring
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the permitted thermal "ramp" of the system. For instance, a lower
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`k_pu` value will provide a slower ramp, at the cost of capping
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available capacity at a low temperature. On the other hand, a high
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value of `k_pu` will result in the governor granting very high power
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whilst temperature is low, and may lead to temperature overshooting.
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The default value for `k_pu` is:
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2 * sustainable_power / (desired_temperature - switch_on_temp)
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This means that at `switch_on_temp` the output of the controller's
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proportional term will be 2 * `sustainable_power`. The default value
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for `k_po` is:
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sustainable_power / (desired_temperature - switch_on_temp)
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Focusing on the proportional and feed forward values of the PID
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controller equation we have:
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P_max = k_p * e + sustainable_power
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The proportional term is proportional to the difference between the
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desired temperature and the current one. When the current temperature
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is the desired one, then the proportional component is zero and
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`P_max` = `sustainable_power`. That is, the system should operate in
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thermal equilibrium under constant load. `sustainable_power` is only
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an estimate, which is the reason for closed-loop control such as this.
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Expanding `k_pu` we get:
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P_max = 2 * sustainable_power * (T_set - T) / (T_set - T_on) +
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sustainable_power
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where
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T_set is the desired temperature
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T is the current temperature
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T_on is the switch on temperature
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When the current temperature is the switch_on temperature, the above
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formula becomes:
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P_max = 2 * sustainable_power * (T_set - T_on) / (T_set - T_on) +
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sustainable_power = 2 * sustainable_power + sustainable_power =
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3 * sustainable_power
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Therefore, the proportional term alone linearly decreases power from
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3 * `sustainable_power` to `sustainable_power` as the temperature
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rises from the switch on temperature to the desired temperature.
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k_i and integral_cutoff
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-----------------------
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`k_i` configures the PID loop's integral term constant. This term
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allows the PID controller to compensate for long term drift and for
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the quantized nature of the output control: cooling devices can't set
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the exact power that the governor requests. When the temperature
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error is below `integral_cutoff`, errors are accumulated in the
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integral term. This term is then multiplied by `k_i` and the result
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added to the output of the controller. Typically `k_i` is set low (1
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or 2) and `integral_cutoff` is 0.
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k_d
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---
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`k_d` configures the PID loop's derivative term constant. It's
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recommended to leave it as the default: 0.
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Cooling device power API
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========================
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Cooling devices controlled by this governor must supply the additional
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"power" API in their `cooling_device_ops`. It consists on three ops:
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1. int get_requested_power(struct thermal_cooling_device *cdev,
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struct thermal_zone_device *tz, u32 *power);
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@cdev: The `struct thermal_cooling_device` pointer
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@tz: thermal zone in which we are currently operating
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@power: pointer in which to store the calculated power
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`get_requested_power()` calculates the power requested by the device
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in milliwatts and stores it in @power . It should return 0 on
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success, -E* on failure. This is currently used by the power
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allocator governor to calculate how much power to give to each cooling
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device.
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2. int state2power(struct thermal_cooling_device *cdev, struct
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thermal_zone_device *tz, unsigned long state, u32 *power);
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@cdev: The `struct thermal_cooling_device` pointer
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@tz: thermal zone in which we are currently operating
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@state: A cooling device state
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@power: pointer in which to store the equivalent power
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Convert cooling device state @state into power consumption in
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milliwatts and store it in @power. It should return 0 on success, -E*
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on failure. This is currently used by thermal core to calculate the
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maximum power that an actor can consume.
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3. int power2state(struct thermal_cooling_device *cdev, u32 power,
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unsigned long *state);
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@cdev: The `struct thermal_cooling_device` pointer
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@power: power in milliwatts
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@state: pointer in which to store the resulting state
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Calculate a cooling device state that would make the device consume at
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most @power mW and store it in @state. It should return 0 on success,
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-E* on failure. This is currently used by the thermal core to convert
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a given power set by the power allocator governor to a state that the
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cooling device can set. It is a function because this conversion may
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depend on external factors that may change so this function should the
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best conversion given "current circumstances".
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Cooling device weights
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----------------------
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Weights are a mechanism to bias the allocation among cooling
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devices. They express the relative power efficiency of different
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cooling devices. Higher weight can be used to express higher power
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efficiency. Weighting is relative such that if each cooling device
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has a weight of one they are considered equal. This is particularly
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useful in heterogeneous systems where two cooling devices may perform
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the same kind of compute, but with different efficiency. For example,
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a system with two different types of processors.
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If the thermal zone is registered using
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`thermal_zone_device_register()` (i.e., platform code), then weights
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are passed as part of the thermal zone's `thermal_bind_parameters`.
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If the platform is registered using device tree, then they are passed
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as the `contribution` property of each map in the `cooling-maps` node.
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Limitations of the power allocator governor
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===========================================
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The power allocator governor's PID controller works best if there is a
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periodic tick. If you have a driver that calls
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`thermal_zone_device_update()` (or anything that ends up calling the
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governor's `throttle()` function) repetitively, the governor response
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won't be very good. Note that this is not particular to this
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governor, step-wise will also misbehave if you call its throttle()
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faster than the normal thermal framework tick (due to interrupts for
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example) as it will overreact.
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