Documentation/devicetree/bindings/thermal/thermal.txt - pub/scm/linux/kernel/git/paulg/linux-4.8.y - Git at Google

 * 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 by the cooling-min-level and cooling-max-level
 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-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.

 Optional properties:
 - cooling-min-level:	An integer indicating the smallest
   Type: unsigned	cooling state accepted. Typically 0.
   Size: one cell

 - cooling-max-level:	An integer indicating the largest
   Type: unsigned	cooling state accepted.
   Size: one cell

 * 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-level = <0>;
 		cooling-max-level = <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-level = <0>;
 		cooling-max-level = <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.
	* 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 by the cooling-min-level and cooling-max-level
	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-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.

	Optional properties:
	- cooling-min-level: An integer indicating the smallest
	Type: unsigned cooling state accepted. Typically 0.
	Size: one cell

	- cooling-max-level: An integer indicating the largest
	Type: unsigned cooling state accepted.
	Size: one cell

	* 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-level = <0>;
	cooling-max-level = <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-level = <0>;
	cooling-max-level = <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 = c1x1 + c2x2 + 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.