Provided by: thermald_2.5.8-1_amd64 bug

NAME

       thermal-conf.xml - Configuration file for thermal daemon

SYNOPSIS

       $(TDCONFDIR)/etc/thermald/thermal-conf.xml

DESCRIPTION

       thermal-conf.xml  is  a configuration file for the thermal daemon. It is used to configure
       thermal sensors, zone and cooling devices. The  location  of  this  file  depends  on  the
       configuration option used during build time.

       The  terminology used in this file conforms to "Advanced Configuration and Power Interface
       Specification". The ACPI thermal model is based around conceptual platform regions  called
       thermal  zones that physically contain devices, thermal sensors, and cooling controls. For
       example of a thermal zone can be a CPU or a laptop cover.  A  zone  can  contain  multiple
       sensors  for  monitoring  temperature.  A  cooling device provides interface to reduce the
       temperature of a source device, which causes increase in the temperature. An example of  a
       cooling device is a FAN or some Linux driver which can throttle the source device.

       A  thermal  zone  configuration  includes  one  or  more  trip  points.  A trip point is a
       temperature at which a cooling device needs to be activated.

       A cooling device can be either active or passive. An example of an active device is a FAN,
       which will not reduce performance at the cost of consuming more power and noise. A passive
       device uses performance throttling to control temperature. In addition to cooling  devices
       present  in  the thermal sysfs, the following cooling devices are built into the thermald,
       which can be used as valid cooling device type:

       • rapl_controller

       • intel_pstate

       • cpufreq

       • LCD

       The thermal sysfs under  Linux  (/sys/class/thermal)  provides  a  way  to  represent  per
       platform  ACPI  configuration.  The  kernel  thermal  governor  uses this data to keep the
       platform thermals under control. But there are some limitations, which thermald  tries  to
       resolve. For example:

       • If the ACPI data is not optimized or buggy. In this case thermal-conf.xml can be used to
         correct the behavior without change in BIOS.

       • There may be thermal zones exposed by  the  thermal  sysfs  without  associated  cooling
         actions.  In  this case thermal conf.xml can be used to tie the cooling devices to those
         zones.

       • The best cooling method may not be in the thermal sysfs. In this  case  thermal-conf.xml
         can be used to bind a zone to an external cooling device.

       • Specify  thermal relationships. A zone can be influenced by multiple source devices with
         varying degrees. In this case thermal-conf.xml  can  be  used  to  define  the  relative
         influence for apply compensation.

FILE FORMAT

       The  configuration  file  format  conforms to XML specifications. A set of tags defined to
       define platform, sensors, zones, cooling devices and trip points.

       <ThermalConfiguration>
         <Platform>
           <Name>Example Platform Name</Name>
           <!-- UUID is optional, if present this will be matched. Both product
                name and UUID can contain wild card "*", which matches any
                platform. -->
           <UUID>Example UUID</UUID>
           <!-- configuration file format conforms to XML specifications. A
                set of tags defined to define platform, sensors, zones, cooling
                devices and trip points. -->
           <ProductName>Example Product Name</ProductName>
           <Preference>QUIET|PERFORMANCE</Preference>
           <!-- Quiet mode will only use passive cooling device. "PERFORMANCE"
                will only select active devices. -->
           <ThermalSensors>
             <ThermalSensor>
               <!-- New Sensor with a type and path -->
               <Type>example_sensor_1</Type>
               <Path>/some_path</Path>
               <AsyncCapable>0</AsyncCapable>
             </ThermalSensor>
             <ThermalSensor>
               <!-- Already present in thermal sysfs, enable this or
                    add/change config For example, here we are indicating
                    that sensor can do async events to avoid polling. -->
               <Type>example_thermal_sysfs_sensor</Type>
               <!-- If async capable, then we don't need to poll. -->
               <AsyncCapable>1</AsyncCapable>
             </ThermalSensor>
           </ThermalSensors>
           <ThermalZones>
             <ThermalZone>
               <Type>Example Zone type</Type>
               <TripPoints>
                 <TripPoint>
                   <SensorType>example_sensor_1</SensorType>
                   <!-- Temperature at which to take action. -->
                   <Temperature> 75000 </Temperature>
                   <!-- max/passive/active If a MAX type is specified, then
                        daemon will use PID control to aggressively throttle
                        to avoid reaching this temp. -->
                   <type>max</type>
                   <!-- SEQUENTIAL | PARALLEL. When a trip point temp is
                        violated, then number of cooling devices can be
                        activated. If control type is SEQUENTIAL then, it
                        will exhaust first cooling device
                        before trying next. -->
                   <ControlType>SEQUENTIAL</ControlType>
                   <CoolingDevice>
                     <index>1</index>
                     <type>example_cooling_device</type>
                     <!-- Influence will be used order cooling devices. First
                          cooling device will be used, which has highest
                          influence. -->
                     <influence> 100 </influence>
                     <!-- Delay in using this cdev, this takes some time too
                          actually cool a zone. -->
                     <SamplingPeriod> 12 </SamplingPeriod>
                     <!-- Set a specific state of this cooling device when this
                          trip is violated. -->
                     <TargetState> 6 </TargetState>
                   </CoolingDevice>
                 </TripPoint>
               </TripPoints>
             </ThermalZone>
           </ThermalZones>
           <CoolingDevices>
             <CoolingDevice>
               <!-- Cooling device can be specified by a type and optionally
                    a sysfs path. If the type is already present in thermal
                    sysfs, there is no need of a path. Compensation can use
                    min/max and step size to increasing cool the system.
                    Debounce period can be used to force a waiting period
                    for action. -->
               <Type>example_cooling_device</Type>
               <MinState>0</MinState>
               <IncDecStep>10</IncDecStep>
               <ReadBack> 0 </ReadBack>
               <MaxState>50</MaxState>
               <DebouncePeriod>5000</DebouncePeriod>
               <!-- If there are no PID parameters, compensation increase step
                    wise and exponentially (if single step is not able to
                    change trend).
                    Alternatively a PID parameters can be specified then next
                    step will use PID calculation using provided PID
                    constants. -->
               <PidControl>
                 <kp>0.001</kp>
                 <kd>0.0001</kd>
                 <ki>0.0001</ki>
               </PidControl>
               <!-- Write some prefix attached to state value, like below the
                    prefix is "level ". It will preserve spaces as entered
                    when writing to sysfs. -->
               <WritePrefix>level </WritePrefix>
             </CoolingDevice>
           </CoolingDevices>
         </Platform>
       </ThermalConfiguration>

EXAMPLE CONFIGURATIONS

       Example 1: This is a very simple configuration, to change the passive limit  on  the  CPU.
       Instead of default, this new temperature 86C in the configuration is used. This will start
       cooling, once the temperature reaches 86C.

       <?xml version="1.0"?>
       <ThermalConfiguration>
         <Platform>
           <Name>Override CPU default passive</Name>
           <ProductName>*</ProductName>
           <Preference>QUIET</Preference>
           <ThermalZones>
             <ThermalZone>
               <Type>cpu</Type>
               <TripPoints>
                 <TripPoint>
                   <Temperature>86000</Temperature>
                   <type>passive</type>
                 </TripPoint>
               </TripPoints>
             </ThermalZone>
           </ThermalZones>
         </Platform>
       </ThermalConfiguration>

       Example 2: In this configuration, we are controlling backlight  when  some  sensor  "SEN2"
       reaches  60C.  Here  "LCD"  is a standard cooling device, which uses Linux backlight sysfs
       interface. "LCD_Zone" is a valid thermal zone in Linux thermal sysfs on the test platform,
       hence  we  don't need to provide path for sysfs for "LCD_Zone". The Linux thermal sysfs is
       already parsed and loaded by the thermald program.

       <?xml version="1.0"?>
       <ThermalConfiguration>
         <Platform>
           <Name>Change Backlight</Name>
           <ProductName>*</ProductName>
           <Preference>QUIET</Preference>
           <ThermalZones>
             <ThermalZone>
               <Type>LCD_Zone</Type>
               <TripPoints>
                 <TripPoint>
                   <SensorType>SEN2</SensorType>
                   <Temperature>60000</Temperature>
                   <type>passive</type>
                   <CoolingDevice>
                     <Type>LCD</Type>
                   </CoolingDevice>
                 </TripPoint>
               </TripPoints>
             </ThermalZone>
           </ThermalZones>
         </Platform>
       </ThermalConfiguration>

       Example 3: In this example Lenovo Thinkpad X220  and  fan  speed  is  controlled.  Here  a
       cooling       device       "_Fan",       can       be       controlled      via      sysfs
       /sys/devices/platform/thinkpad_hwmon/pwm1. When  the  x86_pkg_temp  reaches  45C,  Fan  is
       started with increasing speeds, if the temperature can't be controlled at 45C.

       <?xml version="1.0"?>
       <ThermalConfiguration>
         <Platform>
           <Name>Lenovo ThinkPad X220</Name>
           <ProductName>*</ProductName>
           <Preference>QUIET</Preference>
           <ThermalZones>
             <ThermalZone>
               <Type>x86_pkg_temp</Type>
               <TripPoints>
                 <TripPoint>
                   <SensorType>x86_pkg_temp</SensorType>
                   <Temperature>45000</Temperature>
                   <type>passive</type>
                   <ControlType>SEQUENTIAL</ControlType>
                   <CoolingDevice>
                     <index>1</index>
                     <type>_Fan</type>
                     <influence> 100 </influence>
                     <SamplingPeriod> 12 </SamplingPeriod>
                   </CoolingDevice>
                 </TripPoint>
               </TripPoints>
             </ThermalZone>
           </ThermalZones>
           <CoolingDevices>
             <CoolingDevice>
               <Type>_Fan</Type>
               <Path>/sys/devices/platform/thinkpad_hwmon/pwm1</Path>
               <MinState>0</MinState>
               <IncDecStep>30</IncDecStep>
               <ReadBack> 0 </ReadBack>
               <MaxState>255</MaxState>
               <DebouncePeriod>5</DebouncePeriod>
             </CoolingDevice>
           </CoolingDevices>
         </Platform>
       </ThermalConfiguration>

       Example  4: The following example shows how PID can be used. Here once temperature exceeds
       80C, compensation is calculated using PID using 80C as set point of PID. The  compensation
       depends on error from the set point. Here the default built in processor cooling device is
       used with min state as 0 and max state as 10.

       <?xml version="1.0"?>
       <ThermalConfiguration>
         <Platform>
           <Name>Use PID param </Name>
           <ProductName>*</ProductName>
           <Preference>QUIET</Preference>
           <ThermalZones>
             <ThermalZone>
               <Type>x86_pkg_temp</Type>
               <TripPoints>
                 <TripPoint>
                   <SensorType>x86_pkg_temp</SensorType>
                   <Temperature>80000</Temperature>
                   <type>passive</type>
                   <ControlType>SEQUENTIAL</ControlType>
                   <CoolingDevice>
                     <type>Processor</type>
                   </CoolingDevice>
                 </TripPoint>
               </TripPoints>
             </ThermalZone>
           </ThermalZones>
           <CoolingDevices>
             <CoolingDevice>
               <Type>Processor</Type>
               <PidControl>
                 <kp>0.0002</kp>
                 <kd>0</kd>
                 <ki>0</ki>
               </PidControl>
             </CoolingDevice>
           </CoolingDevices>
         </Platform>
       </ThermalConfiguration>

       Example 5: The following example shows how to control Fan  when  the  sysfs  expects  some
       string  prefix.  For  example  instead  of  just  write a number to fan control sysfs, the
       interface requires "level " in front of the speed index value.

       <?xml version="1.0"?>
       <ThermalConfiguration>
         <Platform>
           <Name>Use Fan control first then CPU throttle </Name>
           <ProductName>*</ProductName>
           <Preference>QUIET</Preference>
           <ThermalZones>
             <ThermalZone>
               <Type>x86_pkg_temp</Type>
               <TripPoints>
                 <TripPoint>
                   <SensorType>x86_pkg_temp</SensorType>
                   <Temperature>80000</Temperature>
                   <type>passive</type>
                   <ControlType>SEQUENTIAL</ControlType>
                   <CoolingDevice>
                     <type>_fan_</type>
                   </CoolingDevice>
                 </TripPoint>
               </TripPoints>
             </ThermalZone>
           </ThermalZones>
           <CoolingDevices>
             <CoolingDevice>
               <Type>_fan_</Type>
               <Path>/proc/acpi/ibm/fan</Path>
               <WritePrefix>level </WritePrefix>
               <MinState>0</MinState>
               <MaxState>5</MaxState>
               <DebouncePeriod>10</DebouncePeriod>
             </CoolingDevice>
           </CoolingDevices>
         </Platform>
       </ThermalConfiguration>

       Example 6: Similar to example 5, but write different speeds at different temperatures.

       <?xml version="1.0"?>
       <ThermalConfiguration>
         <Platform>
           <Name>Use Fan control first then CPU throttle </Name>
           <ProductName>*</ProductName>
           <Preference>QUIET</Preference>
           <ThermalZones>
             <ThermalZone>
               <Type>x86_pkg_temp</Type>
               <TripPoints>
                 <TripPoint>
                   <SensorType>x86_pkg_temp</SensorType>
                   <Temperature>80000</Temperature>
                   <type>passive</type>
                   <CoolingDevice>
                     <type>_fan_</type>
                     <TargetState>1</TargetState>
                   </CoolingDevice>
                 </TripPoint>
                 <TripPoint>
                   <SensorType>x86_pkg_temp</SensorType>
                   <Temperature>85000</Temperature>
                   <type>passive</type>
                   <CoolingDevice>
                     <type>_fan_</type>
                     <TargetState>2</TargetState>
                   </CoolingDevice>
                 </TripPoint>
               </TripPoints>
             </ThermalZone>
           </ThermalZones>
           <CoolingDevices>
             <CoolingDevice>
               <Type>_fan_</Type>
               <Path>/proc/acpi/ibm/fan</Path>
               <WritePrefix>level </WritePrefix>
               <MinState>0</MinState>
               <MaxState>5</MaxState>
               <DebouncePeriod>10</DebouncePeriod>
             </CoolingDevice>
           </CoolingDevices>
         </Platform>
       </ThermalConfiguration>

       Example 7: Use RAPL power limits to control.

       <?xml version="1.0"?>
       <!-- BEGIN -->
       <ThermalConfiguration>
       <Platform>
            <Name> TEST </Name>
            <ProductName>Example_RAPL_Power </ProductName>
            <Preference>QUIET</Preference>
            <PPCC>
                 <!--
                 Specify the Maximum/Minimum RAPL power limit for the
                 platform. The limits are in milli watts.
                 The step size to reduce/increase for each sampling interval
                 Time window in miili seconds.
                 -->
                 <PowerLimitIndex>0</PowerLimitIndex>
                 <PowerLimitMaximum>15000</PowerLimitMaximum>
                 <PowerLimitMinimum>2000</PowerLimitMinimum>
                 <TimeWindowMinimum>20</TimeWindowMinimum>
                 <TimeWindowMaximum>30</TimeWindowMaximum>
                 <StepSize>1000</StepSize>
            </PPCC>
            <ThermalZones>
                 <ThermalZone>
                      <Type>TestZone</Type>
                      <TripPoints>
                           <TripPoint>
                                <SensorType>SEN3</SensorType>
                                <Temperature>50000</Temperature>
                                <Type>Passive</Type>
                                <CoolingDevice>
                                     <Type>B0D4</Type>
                                     <SamplingPeriod>3</SamplingPeriod>
                                     <TargetState>2147483647</TargetState>
                                          <!--
                                          This setting means that when SEN3 reaches 50C, set the RAPL
                                          max power limit to whatever the maximum power limit of the
                                          platform.
                                          -->
                                </CoolingDevice>
                           </TripPoint>
                           <TripPoint>
                                <SensorType>SEN3</SensorType>
                                <Temperature>52000</Temperature>
                                <Type>Passive</Type>
                                <CoolingDevice>
                                     <Type>B0D4</Type>
                                     <SamplingPeriod>3</SamplingPeriod>
                                     <TargetState>8500000</TargetState>
                                          <!--
                                          This setting means that when SEN3 reaches 52C, set the RAPL
                                          max power limit to 8.5W.
                                          -->
                                </CoolingDevice>
                           </TripPoint>
                           <TripPoint>
                                <SensorType>SEN3</SensorType>
                                <Temperature>60000</Temperature>
                                <Type>Passive</Type>
                                <CoolingDevice>
                                     <Type>B0D4</Type>
                                     <SamplingPeriod>3</SamplingPeriod>
                                     <TargetState>4500000</TargetState>
                                          <!--
                                          This setting means that when SEN3 reaches 60C, set the RAPL
                                          max power limit to 4.5W.
                                          -->
                                </CoolingDevice>
                           </TripPoint>
                           <TripPoint>
                                <SensorType>SEN3</SensorType>
                                <Temperature>65000</Temperature>
                                <Type>Passive</Type>
                                <CoolingDevice>
                                     <Type>B0D4</Type>
                                     <SamplingPeriod>3</SamplingPeriod>
                                          <!--
                                          This setting means that when SEN3 reaches 65C, set the RAPL
                                          max power limit to minimum power limit for the platform.
                                          -->
                                </CoolingDevice>
                           </TripPoint>
                      </TripPoints>
                 </ThermalZone>
            </ThermalZones>
       </Platform>
       </ThermalConfiguration>

                                           Dec 18, 2018                       thermal-conf.xml(5)