| * Thermal Framework Device Tree descriptor |
| |
| This file describes a generic binding to provide a way of |
| defining hardware thermal structure using device tree. |
| A thermal structure includes thermal zones and their components, |
| such as trip points, polling intervals, sensors and cooling devices |
| binding descriptors. |
| |
| The target of device tree thermal descriptors is to describe only |
| the hardware thermal aspects. The thermal device tree bindings are |
| not about how the system must control or which algorithm or policy |
| must be taken in place. |
| |
| There are five types of nodes involved to describe thermal bindings: |
| - thermal sensors: devices which may be used to take temperature |
| measurements. |
| - cooling devices: devices which may be used to dissipate heat. |
| - trip points: describe key temperatures at which cooling is recommended. The |
| set of points should be chosen based on hardware limits. |
| - cooling maps: used to describe links between trip points and cooling devices; |
| - thermal zones: used to describe thermal data within the hardware; |
| |
| The following is a description of each of these node types. |
| |
| * Thermal sensor devices |
| |
| Thermal sensor devices are nodes providing temperature sensing capabilities on |
| thermal zones. Typical devices are I2C ADC converters and bandgaps. These are |
| nodes providing temperature data to thermal zones. Thermal sensor devices may |
| control one or more internal sensors. |
| |
| Required property: |
| - #thermal-sensor-cells: Used to provide sensor device specific information |
| Type: unsigned while referring to it. Typically 0 on thermal sensor |
| Size: one cell nodes with only one sensor, and at least 1 on nodes |
| with several internal sensors, in order |
| to identify uniquely the sensor instances within |
| the IC. See thermal zone binding for more details |
| on how consumers refer to sensor devices. |
| |
| * Cooling device nodes |
| |
| Cooling devices are nodes providing control on power dissipation. There |
| are essentially two ways to provide control on power dissipation. First |
| is by means of regulating device performance, which is known as passive |
| cooling. A typical passive cooling is a CPU that has dynamic voltage and |
| frequency scaling (DVFS), and uses lower frequencies as cooling states. |
| Second is by means of activating devices in order to remove |
| the dissipated heat, which is known as active cooling, e.g. regulating |
| fan speeds. In both cases, cooling devices shall have a way to determine |
| the state of cooling in which the device is. |
| |
| Any cooling device has a range of cooling states (i.e. different levels |
| of heat dissipation). For example a fan's cooling states correspond to |
| the different fan speeds possible. Cooling states are referred to by |
| single unsigned integers, where larger numbers mean greater heat |
| dissipation. The precise set of cooling states associated with a device |
| (as referred to be the cooling-min-state and cooling-max-state |
| properties) should be defined in a particular device's binding. |
| For more examples of cooling devices, refer to the example sections below. |
| |
| Required properties: |
| - cooling-min-state: An integer indicating the smallest |
| Type: unsigned cooling state accepted. Typically 0. |
| Size: one cell |
| |
| - cooling-max-state: An integer indicating the largest |
| Type: unsigned cooling state accepted. |
| Size: one cell |
| |
| - #cooling-cells: Used to provide cooling device specific information |
| Type: unsigned while referring to it. Must be at least 2, in order |
| Size: one cell to specify minimum and maximum cooling state used |
| in the reference. The first cell is the minimum |
| cooling state requested and the second cell is |
| the maximum cooling state requested in the reference. |
| See Cooling device maps section below for more details |
| on how consumers refer to cooling devices. |
| |
| * Trip points |
| |
| The trip node is a node to describe a point in the temperature domain |
| in which the system takes an action. This node describes just the point, |
| not the action. |
| |
| Required properties: |
| - temperature: An integer indicating the trip temperature level, |
| Type: signed in millicelsius. |
| Size: one cell |
| |
| - hysteresis: A low hysteresis value on temperature property (above). |
| Type: unsigned This is a relative value, in millicelsius. |
| Size: one cell |
| |
| - type: a string containing the trip type. Expected values are: |
| "active": A trip point to enable active cooling |
| "passive": A trip point to enable passive cooling |
| "hot": A trip point to notify emergency |
| "critical": Hardware not reliable. |
| Type: string |
| |
| * Cooling device maps |
| |
| The cooling device maps node is a node to describe how cooling devices |
| get assigned to trip points of the zone. The cooling devices are expected |
| to be loaded in the target system. |
| |
| Required properties: |
| - cooling-device: A phandle of a cooling device with its specifier, |
| Type: phandle + referring to which cooling device is used in this |
| cooling specifier binding. In the cooling specifier, the first cell |
| is the minimum cooling state and the second cell |
| is the maximum cooling state used in this map. |
| - trip: A phandle of a trip point node within the same thermal |
| Type: phandle of zone. |
| trip point node |
| |
| Optional property: |
| - contribution: The cooling contribution to the thermal zone of the |
| Type: unsigned referred cooling device at the referred trip point. |
| Size: one cell The contribution is a ratio of the sum |
| of all cooling contributions within a thermal zone. |
| |
| Note: Using the THERMAL_NO_LIMIT (-1UL) constant in the cooling-device phandle |
| limit specifier means: |
| (i) - minimum state allowed for minimum cooling state used in the reference. |
| (ii) - maximum state allowed for maximum cooling state used in the reference. |
| Refer to include/dt-bindings/thermal/thermal.h for definition of this constant. |
| |
| * Thermal zone nodes |
| |
| The thermal zone node is the node containing all the required info |
| for describing a thermal zone, including its cooling device bindings. The |
| thermal zone node must contain, apart from its own properties, one sub-node |
| containing trip nodes and one sub-node containing all the zone cooling maps. |
| |
| Required properties: |
| - polling-delay: The maximum number of milliseconds to wait between polls |
| Type: unsigned when checking this thermal zone. |
| Size: one cell |
| |
| - polling-delay-passive: The maximum number of milliseconds to wait |
| Type: unsigned between polls when performing passive cooling. |
| Size: one cell |
| |
| - thermal-sensors: A list of thermal sensor phandles and sensor specifier |
| Type: list of used while monitoring the thermal zone. |
| phandles + sensor |
| specifier |
| |
| - trips: A sub-node which is a container of only trip point nodes |
| Type: sub-node required to describe the thermal zone. |
| |
| - cooling-maps: A sub-node which is a container of only cooling device |
| Type: sub-node map nodes, used to describe the relation between trips |
| and cooling devices. |
| |
| Optional property: |
| - coefficients: An array of integers (one signed cell) containing |
| Type: array coefficients to compose a linear relation between |
| Elem size: one cell the sensors listed in the thermal-sensors property. |
| Elem type: signed Coefficients defaults to 1, in case this property |
| is not specified. A simple linear polynomial is used: |
| Z = c0 * x0 + c1 + x1 + ... + c(n-1) * x(n-1) + cn. |
| |
| The coefficients are ordered and they match with sensors |
| by means of sensor ID. Additional coefficients are |
| interpreted as constant offset. |
| |
| - sustainable-power: An estimate of the sustainable power (in mW) that the |
| Type: unsigned thermal zone can dissipate at the desired |
| Size: one cell control temperature. For reference, the |
| sustainable power of a 4'' phone is typically |
| 2000mW, while on a 10'' tablet is around |
| 4500mW. |
| |
| Note: The delay properties are bound to the maximum dT/dt (temperature |
| derivative over time) in two situations for a thermal zone: |
| (i) - when passive cooling is activated (polling-delay-passive); and |
| (ii) - when the zone just needs to be monitored (polling-delay) or |
| when active cooling is activated. |
| |
| The maximum dT/dt is highly bound to hardware power consumption and dissipation |
| capability. The delays should be chosen to account for said max dT/dt, |
| such that a device does not cross several trip boundaries unexpectedly |
| between polls. Choosing the right polling delays shall avoid having the |
| device in temperature ranges that may damage the silicon structures and |
| reduce silicon lifetime. |
| |
| * The thermal-zones node |
| |
| The "thermal-zones" node is a container for all thermal zone nodes. It shall |
| contain only sub-nodes describing thermal zones as in the section |
| "Thermal zone nodes". The "thermal-zones" node appears under "/". |
| |
| * Examples |
| |
| Below are several examples on how to use thermal data descriptors |
| using device tree bindings: |
| |
| (a) - CPU thermal zone |
| |
| The CPU thermal zone example below describes how to setup one thermal zone |
| using one single sensor as temperature source and many cooling devices and |
| power dissipation control sources. |
| |
| #include <dt-bindings/thermal/thermal.h> |
| |
| cpus { |
| /* |
| * Here is an example of describing a cooling device for a DVFS |
| * capable CPU. The CPU node describes its four OPPs. |
| * The cooling states possible are 0..3, and they are |
| * used as OPP indexes. The minimum cooling state is 0, which means |
| * all four OPPs can be available to the system. The maximum |
| * cooling state is 3, which means only the lowest OPPs (198MHz@0.85V) |
| * can be available in the system. |
| */ |
| cpu0: cpu@0 { |
| ... |
| operating-points = < |
| /* kHz uV */ |
| 970000 1200000 |
| 792000 1100000 |
| 396000 950000 |
| 198000 850000 |
| >; |
| cooling-min-state = <0>; |
| cooling-max-state = <3>; |
| #cooling-cells = <2>; /* min followed by max */ |
| }; |
| ... |
| }; |
| |
| &i2c1 { |
| ... |
| /* |
| * A simple fan controller which supports 10 speeds of operation |
| * (represented as 0-9). |
| */ |
| fan0: fan@0x48 { |
| ... |
| cooling-min-state = <0>; |
| cooling-max-state = <9>; |
| #cooling-cells = <2>; /* min followed by max */ |
| }; |
| }; |
| |
| ocp { |
| ... |
| /* |
| * A simple IC with a single bandgap temperature sensor. |
| */ |
| bandgap0: bandgap@0x0000ED00 { |
| ... |
| #thermal-sensor-cells = <0>; |
| }; |
| }; |
| |
| thermal-zones { |
| cpu_thermal: cpu-thermal { |
| polling-delay-passive = <250>; /* milliseconds */ |
| polling-delay = <1000>; /* milliseconds */ |
| |
| thermal-sensors = <&bandgap0>; |
| |
| trips { |
| cpu_alert0: cpu-alert0 { |
| temperature = <90000>; /* millicelsius */ |
| hysteresis = <2000>; /* millicelsius */ |
| type = "active"; |
| }; |
| cpu_alert1: cpu-alert1 { |
| temperature = <100000>; /* millicelsius */ |
| hysteresis = <2000>; /* millicelsius */ |
| type = "passive"; |
| }; |
| cpu_crit: cpu-crit { |
| temperature = <125000>; /* millicelsius */ |
| hysteresis = <2000>; /* millicelsius */ |
| type = "critical"; |
| }; |
| }; |
| |
| cooling-maps { |
| map0 { |
| trip = <&cpu_alert0>; |
| cooling-device = <&fan0 THERMAL_NO_LIMIT 4>; |
| }; |
| map1 { |
| trip = <&cpu_alert1>; |
| cooling-device = <&fan0 5 THERMAL_NO_LIMIT>; |
| }; |
| map2 { |
| trip = <&cpu_alert1>; |
| cooling-device = |
| <&cpu0 THERMAL_NO_LIMIT THERMAL_NO_LIMIT>; |
| }; |
| }; |
| }; |
| }; |
| |
| In the example above, the ADC sensor (bandgap0) at address 0x0000ED00 is |
| used to monitor the zone 'cpu-thermal' using its sole sensor. A fan |
| device (fan0) is controlled via I2C bus 1, at address 0x48, and has ten |
| different cooling states 0-9. It is used to remove the heat out of |
| the thermal zone 'cpu-thermal' using its cooling states |
| from its minimum to 4, when it reaches trip point 'cpu_alert0' |
| at 90C, as an example of active cooling. The same cooling device is used at |
| 'cpu_alert1', but from 5 to its maximum state. The cpu@0 device is also |
| linked to the same thermal zone, 'cpu-thermal', as a passive cooling device, |
| using all its cooling states at trip point 'cpu_alert1', |
| which is a trip point at 100C. On the thermal zone 'cpu-thermal', at the |
| temperature of 125C, represented by the trip point 'cpu_crit', the silicon |
| is not reliable anymore. |
| |
| (b) - IC with several internal sensors |
| |
| The example below describes how to deploy several thermal zones based off a |
| single sensor IC, assuming it has several internal sensors. This is a common |
| case on SoC designs with several internal IPs that may need different thermal |
| requirements, and thus may have their own sensor to monitor or detect internal |
| hotspots in their silicon. |
| |
| #include <dt-bindings/thermal/thermal.h> |
| |
| ocp { |
| ... |
| /* |
| * A simple IC with several bandgap temperature sensors. |
| */ |
| bandgap0: bandgap@0x0000ED00 { |
| ... |
| #thermal-sensor-cells = <1>; |
| }; |
| }; |
| |
| thermal-zones { |
| cpu_thermal: cpu-thermal { |
| polling-delay-passive = <250>; /* milliseconds */ |
| polling-delay = <1000>; /* milliseconds */ |
| |
| /* sensor ID */ |
| thermal-sensors = <&bandgap0 0>; |
| |
| trips { |
| /* each zone within the SoC may have its own trips */ |
| cpu_alert: cpu-alert { |
| temperature = <100000>; /* millicelsius */ |
| hysteresis = <2000>; /* millicelsius */ |
| type = "passive"; |
| }; |
| cpu_crit: cpu-crit { |
| temperature = <125000>; /* millicelsius */ |
| hysteresis = <2000>; /* millicelsius */ |
| type = "critical"; |
| }; |
| }; |
| |
| cooling-maps { |
| /* each zone within the SoC may have its own cooling */ |
| ... |
| }; |
| }; |
| |
| gpu_thermal: gpu-thermal { |
| polling-delay-passive = <120>; /* milliseconds */ |
| polling-delay = <1000>; /* milliseconds */ |
| |
| /* sensor ID */ |
| thermal-sensors = <&bandgap0 1>; |
| |
| trips { |
| /* each zone within the SoC may have its own trips */ |
| gpu_alert: gpu-alert { |
| temperature = <90000>; /* millicelsius */ |
| hysteresis = <2000>; /* millicelsius */ |
| type = "passive"; |
| }; |
| gpu_crit: gpu-crit { |
| temperature = <105000>; /* millicelsius */ |
| hysteresis = <2000>; /* millicelsius */ |
| type = "critical"; |
| }; |
| }; |
| |
| cooling-maps { |
| /* each zone within the SoC may have its own cooling */ |
| ... |
| }; |
| }; |
| |
| dsp_thermal: dsp-thermal { |
| polling-delay-passive = <50>; /* milliseconds */ |
| polling-delay = <1000>; /* milliseconds */ |
| |
| /* sensor ID */ |
| thermal-sensors = <&bandgap0 2>; |
| |
| trips { |
| /* each zone within the SoC may have its own trips */ |
| dsp_alert: dsp-alert { |
| temperature = <90000>; /* millicelsius */ |
| hysteresis = <2000>; /* millicelsius */ |
| type = "passive"; |
| }; |
| dsp_crit: gpu-crit { |
| temperature = <135000>; /* millicelsius */ |
| hysteresis = <2000>; /* millicelsius */ |
| type = "critical"; |
| }; |
| }; |
| |
| cooling-maps { |
| /* each zone within the SoC may have its own cooling */ |
| ... |
| }; |
| }; |
| }; |
| |
| In the example above, there is one bandgap IC which has the capability to |
| monitor three sensors. The hardware has been designed so that sensors are |
| placed on different places in the DIE to monitor different temperature |
| hotspots: one for CPU thermal zone, one for GPU thermal zone and the |
| other to monitor a DSP thermal zone. |
| |
| Thus, there is a need to assign each sensor provided by the bandgap IC |
| to different thermal zones. This is achieved by means of using the |
| #thermal-sensor-cells property and using the first cell of the sensor |
| specifier as sensor ID. In the example, then, <bandgap 0> is used to |
| monitor CPU thermal zone, <bandgap 1> is used to monitor GPU thermal |
| zone and <bandgap 2> is used to monitor DSP thermal zone. Each zone |
| may be uncorrelated, having its own dT/dt requirements, trips |
| and cooling maps. |
| |
| |
| (c) - Several sensors within one single thermal zone |
| |
| The example below illustrates how to use more than one sensor within |
| one thermal zone. |
| |
| #include <dt-bindings/thermal/thermal.h> |
| |
| &i2c1 { |
| ... |
| /* |
| * A simple IC with a single temperature sensor. |
| */ |
| adc: sensor@0x49 { |
| ... |
| #thermal-sensor-cells = <0>; |
| }; |
| }; |
| |
| ocp { |
| ... |
| /* |
| * A simple IC with a single bandgap temperature sensor. |
| */ |
| bandgap0: bandgap@0x0000ED00 { |
| ... |
| #thermal-sensor-cells = <0>; |
| }; |
| }; |
| |
| thermal-zones { |
| cpu_thermal: cpu-thermal { |
| polling-delay-passive = <250>; /* milliseconds */ |
| polling-delay = <1000>; /* milliseconds */ |
| |
| thermal-sensors = <&bandgap0>, /* cpu */ |
| <&adc>; /* pcb north */ |
| |
| /* hotspot = 100 * bandgap - 120 * adc + 484 */ |
| coefficients = <100 -120 484>; |
| |
| trips { |
| ... |
| }; |
| |
| cooling-maps { |
| ... |
| }; |
| }; |
| }; |
| |
| In some cases, there is a need to use more than one sensor to extrapolate |
| a thermal hotspot in the silicon. The above example illustrates this situation. |
| For instance, it may be the case that a sensor external to CPU IP may be placed |
| close to CPU hotspot and together with internal CPU sensor, it is used |
| to determine the hotspot. Assuming this is the case for the above example, |
| the hypothetical extrapolation rule would be: |
| hotspot = 100 * bandgap - 120 * adc + 484 |
| |
| In other context, the same idea can be used to add fixed offset. For instance, |
| consider the hotspot extrapolation rule below: |
| hotspot = 1 * adc + 6000 |
| |
| In the above equation, the hotspot is always 6C higher than what is read |
| from the ADC sensor. The binding would be then: |
| thermal-sensors = <&adc>; |
| |
| /* hotspot = 1 * adc + 6000 */ |
| coefficients = <1 6000>; |
| |
| (d) - Board thermal |
| |
| The board thermal example below illustrates how to setup one thermal zone |
| with many sensors and many cooling devices. |
| |
| #include <dt-bindings/thermal/thermal.h> |
| |
| &i2c1 { |
| ... |
| /* |
| * An IC with several temperature sensor. |
| */ |
| adc_dummy: sensor@0x50 { |
| ... |
| #thermal-sensor-cells = <1>; /* sensor internal ID */ |
| }; |
| }; |
| |
| thermal-zones { |
| batt-thermal { |
| polling-delay-passive = <500>; /* milliseconds */ |
| polling-delay = <2500>; /* milliseconds */ |
| |
| /* sensor ID */ |
| thermal-sensors = <&adc_dummy 4>; |
| |
| trips { |
| ... |
| }; |
| |
| cooling-maps { |
| ... |
| }; |
| }; |
| |
| board_thermal: board-thermal { |
| polling-delay-passive = <1000>; /* milliseconds */ |
| polling-delay = <2500>; /* milliseconds */ |
| |
| /* sensor ID */ |
| thermal-sensors = <&adc_dummy 0>, /* pcb top edge */ |
| <&adc_dummy 1>, /* lcd */ |
| <&adc_dummy 2>; /* back cover */ |
| /* |
| * An array of coefficients describing the sensor |
| * linear relation. E.g.: |
| * z = c1*x1 + c2*x2 + c3*x3 |
| */ |
| coefficients = <1200 -345 890>; |
| |
| sustainable-power = <2500>; |
| |
| trips { |
| /* Trips are based on resulting linear equation */ |
| cpu_trip: cpu-trip { |
| temperature = <60000>; /* millicelsius */ |
| hysteresis = <2000>; /* millicelsius */ |
| type = "passive"; |
| }; |
| gpu_trip: gpu-trip { |
| temperature = <55000>; /* millicelsius */ |
| hysteresis = <2000>; /* millicelsius */ |
| type = "passive"; |
| } |
| lcd_trip: lcp-trip { |
| temperature = <53000>; /* millicelsius */ |
| hysteresis = <2000>; /* millicelsius */ |
| type = "passive"; |
| }; |
| crit_trip: crit-trip { |
| temperature = <68000>; /* millicelsius */ |
| hysteresis = <2000>; /* millicelsius */ |
| type = "critical"; |
| }; |
| }; |
| |
| cooling-maps { |
| map0 { |
| trip = <&cpu_trip>; |
| cooling-device = <&cpu0 0 2>; |
| contribution = <55>; |
| }; |
| map1 { |
| trip = <&gpu_trip>; |
| cooling-device = <&gpu0 0 2>; |
| contribution = <20>; |
| }; |
| map2 { |
| trip = <&lcd_trip>; |
| cooling-device = <&lcd0 5 10>; |
| contribution = <15>; |
| }; |
| }; |
| }; |
| }; |
| |
| The above example is a mix of previous examples, a sensor IP with several internal |
| sensors used to monitor different zones, one of them is composed by several sensors and |
| with different cooling devices. |