xref: /linux/Documentation/devicetree/bindings/thermal/thermal-zones.yaml (revision 55d0969c451159cff86949b38c39171cab962069)
1# SPDX-License-Identifier: (GPL-2.0)
2# Copyright 2020 Linaro Ltd.
3%YAML 1.2
4---
5$id: http://devicetree.org/schemas/thermal/thermal-zones.yaml#
6$schema: http://devicetree.org/meta-schemas/base.yaml#
7
8title: Thermal zone
9
10maintainers:
11  - Daniel Lezcano <daniel.lezcano@linaro.org>
12
13description: |
14  Thermal management is achieved in devicetree by describing the sensor hardware
15  and the software abstraction of cooling devices and thermal zones required to
16  take appropriate action to mitigate thermal overloads.
17
18  The following node types are used to completely describe a thermal management
19  system in devicetree:
20   - thermal-sensor: device that measures temperature, has SoC-specific bindings
21   - cooling-device: device used to dissipate heat either passively or actively
22   - thermal-zones: a container of the following node types used to describe all
23     thermal data for the platform
24
25  This binding describes the thermal-zones.
26
27  The polling-delay properties of a thermal-zone are bound to the maximum dT/dt
28  (temperature derivative over time) in two situations for a thermal zone:
29    1. when passive cooling is activated (polling-delay-passive)
30    2. when the zone just needs to be monitored (polling-delay) or when
31       active cooling is activated.
32
33  The maximum dT/dt is highly bound to hardware power consumption and
34  dissipation capability. The delays should be chosen to account for said
35  max dT/dt, such that a device does not cross several trip boundaries
36  unexpectedly between polls. Choosing the right polling delays shall avoid
37  having the device in temperature ranges that may damage the silicon structures
38  and reduce silicon lifetime.
39
40properties:
41  $nodename:
42    const: thermal-zones
43    description:
44      A /thermal-zones node is required in order to use the thermal framework to
45      manage input from the various thermal zones in the system in order to
46      mitigate thermal overload conditions. It does not represent a real device
47      in the system, but acts as a container to link a thermal sensor device,
48      platform-data regarding temperature thresholds and the mitigation actions
49      to take when the temperature crosses those thresholds.
50
51patternProperties:
52  # Node name is limited in size due to Linux kernel requirements - 19
53  # characters in total (see THERMAL_NAME_LENGTH, including terminating NUL
54  # byte):
55  "^[a-zA-Z][a-zA-Z0-9\\-]{1,10}-thermal$":
56    type: object
57    description:
58      Each thermal zone node contains information about how frequently it
59      must be checked, the sensor responsible for reporting temperature for
60      this zone, one sub-node containing the various trip points for this
61      zone and one sub-node containing all the zone cooling-maps.
62
63    properties:
64      polling-delay:
65        $ref: /schemas/types.yaml#/definitions/uint32
66        description:
67          The maximum number of milliseconds to wait between polls when
68          checking this thermal zone. Setting this to 0 disables the polling
69          timers setup by the thermal framework and assumes that the thermal
70          sensors in this zone support interrupts.
71
72      polling-delay-passive:
73        $ref: /schemas/types.yaml#/definitions/uint32
74        description:
75          The maximum number of milliseconds to wait between polls when
76          checking this thermal zone while doing passive cooling. Setting
77          this to 0 disables the polling timers setup by the thermal
78          framework and assumes that the thermal sensors in this zone
79          support interrupts.
80
81      critical-action:
82        $ref: /schemas/types.yaml#/definitions/string
83        description: |
84          The action the OS should perform after the critical temperature is reached.
85          By default the system will shutdown as a safe action to prevent damage
86          to the hardware, if the property is not set.
87          The shutdown action should be always the default and preferred one.
88          Choose 'reboot' with care, as the hardware may be in thermal stress,
89          thus leading to infinite reboots that may cause damage to the hardware.
90          Make sure the firmware/bootloader will act as the last resort and take
91          over the thermal control.
92
93        enum:
94          - shutdown
95          - reboot
96
97      thermal-sensors:
98        $ref: /schemas/types.yaml#/definitions/phandle-array
99        maxItems: 1
100        description:
101          The thermal sensor phandle and sensor specifier used to monitor this
102          thermal zone.
103
104      coefficients:
105        $ref: /schemas/types.yaml#/definitions/uint32-array
106        description:
107          An array of integers containing the coefficients of a linear equation
108          that binds all the sensors listed in this thermal zone.
109
110          The linear equation used is as follows,
111            z = c0 * x0 + c1 * x1 + ... + c(n-1) * x(n-1) + cn
112          where c0, c1, .., cn are the coefficients.
113
114          Coefficients default to 1 in case this property is not specified. The
115          coefficients are ordered and are matched with sensors by means of the
116          sensor ID. Additional coefficients are interpreted as constant offset.
117
118      sustainable-power:
119        $ref: /schemas/types.yaml#/definitions/uint32
120        description:
121          An estimate of the sustainable power (in mW) that this thermal zone
122          can dissipate at the desired control temperature. For reference, the
123          sustainable power of a 4-inch phone is typically 2000mW, while on a
124          10-inch tablet is around 4500mW.
125
126      trips:
127        type: object
128        description:
129          This node describes a set of points in the temperature domain at
130          which the thermal framework needs to take action. The actions to
131          be taken are defined in another node called cooling-maps.
132
133        patternProperties:
134          "^[a-zA-Z][a-zA-Z0-9\\-_]{0,63}$":
135            type: object
136
137            properties:
138              temperature:
139                $ref: /schemas/types.yaml#/definitions/int32
140                minimum: -273000
141                maximum: 200000
142                description:
143                  An integer expressing the trip temperature in millicelsius.
144
145              hysteresis:
146                $ref: /schemas/types.yaml#/definitions/uint32
147                description:
148                  An unsigned integer expressing the hysteresis delta with
149                  respect to the trip temperature property above, also in
150                  millicelsius. Any cooling action initiated by the framework is
151                  maintained until the temperature falls below
152                  (trip temperature - hysteresis). This potentially prevents a
153                  situation where the trip gets constantly triggered soon after
154                  cooling action is removed.
155
156              type:
157                $ref: /schemas/types.yaml#/definitions/string
158                enum:
159                  - active   # enable active cooling e.g. fans
160                  - passive  # enable passive cooling e.g. throttling cpu
161                  - hot      # send notification to driver
162                  - critical # send notification to driver, trigger shutdown
163                description: |
164                  There are four valid trip types: active, passive, hot,
165                  critical.
166
167                  The critical trip type is used to set the maximum
168                  temperature threshold above which the HW becomes
169                  unstable and underlying firmware might even trigger a
170                  reboot. Hitting the critical threshold triggers a system
171                  shutdown.
172
173                  The hot trip type can be used to send a notification to
174                  the thermal driver (if a .notify callback is registered).
175                  The action to be taken is left to the driver.
176
177                  The passive trip type can be used to slow down HW e.g. run
178                  the CPU, GPU, bus at a lower frequency.
179
180                  The active trip type can be used to control other HW to
181                  help in cooling e.g. fans can be sped up or slowed down
182
183            required:
184              - temperature
185              - hysteresis
186              - type
187            additionalProperties: false
188
189        additionalProperties: false
190
191      cooling-maps:
192        type: object
193        additionalProperties: false
194        description:
195          This node describes the action to be taken when a thermal zone
196          crosses one of the temperature thresholds described in the trips
197          node. The action takes the form of a mapping relation between a
198          trip and the target cooling device state.
199
200        patternProperties:
201          "^map[-a-zA-Z0-9]*$":
202            type: object
203
204            properties:
205              trip:
206                $ref: /schemas/types.yaml#/definitions/phandle
207                description:
208                  A phandle of a trip point node within this thermal zone.
209
210              cooling-device:
211                $ref: /schemas/types.yaml#/definitions/phandle-array
212                description:
213                  A list of cooling device phandles along with the minimum
214                  and maximum cooling state specifiers for each cooling
215                  device. Using the THERMAL_NO_LIMIT (-1UL) constant in the
216                  cooling-device phandle limit specifier lets the framework
217                  use the minimum and maximum cooling state for that cooling
218                  device automatically.
219
220              contribution:
221                $ref: /schemas/types.yaml#/definitions/uint32
222                description:
223                  The cooling contribution to the thermal zone of the referred
224                  cooling device at the referred trip point. The contribution is
225                  a ratio of the sum of all cooling contributions within a
226                  thermal zone.
227
228            required:
229              - trip
230              - cooling-device
231            additionalProperties: false
232
233    required:
234      - thermal-sensors
235
236    additionalProperties: false
237
238additionalProperties: false
239
240examples:
241  - |
242    #include <dt-bindings/interrupt-controller/arm-gic.h>
243    #include <dt-bindings/thermal/thermal.h>
244
245    // Example 1: SDM845 TSENS
246    soc {
247            #address-cells = <2>;
248            #size-cells = <2>;
249
250            /* ... */
251
252            tsens0: thermal-sensor@c263000 {
253                    compatible = "qcom,sdm845-tsens", "qcom,tsens-v2";
254                    reg = <0 0x0c263000 0 0x1ff>, /* TM */
255                          <0 0x0c222000 0 0x1ff>; /* SROT */
256                    #qcom,sensors = <13>;
257                    interrupts = <GIC_SPI 506 IRQ_TYPE_LEVEL_HIGH>,
258                                 <GIC_SPI 508 IRQ_TYPE_LEVEL_HIGH>;
259                    interrupt-names = "uplow", "critical";
260                    #thermal-sensor-cells = <1>;
261            };
262
263            tsens1: thermal-sensor@c265000 {
264                    compatible = "qcom,sdm845-tsens", "qcom,tsens-v2";
265                    reg = <0 0x0c265000 0 0x1ff>, /* TM */
266                          <0 0x0c223000 0 0x1ff>; /* SROT */
267                    #qcom,sensors = <8>;
268                    interrupts = <GIC_SPI 507 IRQ_TYPE_LEVEL_HIGH>,
269                                 <GIC_SPI 509 IRQ_TYPE_LEVEL_HIGH>;
270                    interrupt-names = "uplow", "critical";
271                    #thermal-sensor-cells = <1>;
272            };
273    };
274
275    /* ... */
276
277    thermal-zones {
278            cpu0-thermal {
279                    polling-delay-passive = <250>;
280                    polling-delay = <1000>;
281
282                    thermal-sensors = <&tsens0 1>;
283
284                    trips {
285                            cpu0_alert0: trip-point0 {
286                                    temperature = <90000>;
287                                    hysteresis = <2000>;
288                                    type = "passive";
289                            };
290
291                            cpu0_alert1: trip-point1 {
292                                    temperature = <95000>;
293                                    hysteresis = <2000>;
294                                    type = "passive";
295                            };
296
297                            cpu0_crit: cpu_crit {
298                                    temperature = <110000>;
299                                    hysteresis = <1000>;
300                                    type = "critical";
301                            };
302                    };
303
304                    cooling-maps {
305                            map0 {
306                                    trip = <&cpu0_alert0>;
307                                    /* Corresponds to 1400MHz in OPP table */
308                                    cooling-device = <&CPU0 3 3>, <&CPU1 3 3>,
309                                                     <&CPU2 3 3>, <&CPU3 3 3>;
310                            };
311
312                            map1 {
313                                    trip = <&cpu0_alert1>;
314                                    /* Corresponds to 1000MHz in OPP table */
315                                    cooling-device = <&CPU0 5 5>, <&CPU1 5 5>,
316                                                     <&CPU2 5 5>, <&CPU3 5 5>;
317                            };
318                    };
319            };
320
321            /* ... */
322
323            cluster0-thermal {
324                    polling-delay-passive = <250>;
325                    polling-delay = <1000>;
326
327                    thermal-sensors = <&tsens0 5>;
328
329                    trips {
330                            cluster0_alert0: trip-point0 {
331                                    temperature = <90000>;
332                                    hysteresis = <2000>;
333                                    type = "hot";
334                            };
335                            cluster0_crit: cluster0_crit {
336                                    temperature = <110000>;
337                                    hysteresis = <2000>;
338                                    type = "critical";
339                            };
340                    };
341            };
342
343            /* ... */
344
345            gpu-top-thermal {
346                    polling-delay-passive = <250>;
347                    polling-delay = <1000>;
348
349                    thermal-sensors = <&tsens0 11>;
350
351                    trips {
352                            gpu1_alert0: trip-point0 {
353                                    temperature = <90000>;
354                                    hysteresis = <2000>;
355                                    type = "hot";
356                            };
357                    };
358            };
359    };
360...
361