Message ID | 1551602966-2334-2-git-send-email-talel@amazon.com (mailing list archive) |
---|---|
State | Superseded, archived |
Delegated to: | Eduardo Valentin |
Headers | show |
Series | Thermal MMIO Driver | expand |
On Sun, Mar 03, 2019 at 10:49:25AM +0200, Talel Shenhar wrote: > Add thermal binding documentation for thermal MMIO driver. > > Signed-off-by: Talel Shenhar <talel@amazon.com> > --- > .../devicetree/bindings/thermal/thermal_mmio.txt | 173 +++++++++++++++++++++ > 1 file changed, 173 insertions(+) > create mode 100644 Documentation/devicetree/bindings/thermal/thermal_mmio.txt > > diff --git a/Documentation/devicetree/bindings/thermal/thermal_mmio.txt b/Documentation/devicetree/bindings/thermal/thermal_mmio.txt > new file mode 100644 > index 0000000..1f4d738 > --- /dev/null > +++ b/Documentation/devicetree/bindings/thermal/thermal_mmio.txt > @@ -0,0 +1,173 @@ > +Generic Thermal MMIO Driver Bindings aren't for drivers. Do h/w specific bindings and map those to a generic driver if you like. We simply don't do single register level bindings because that doesn't scale and things never turn out to be so generic. > + > +The generic thermal driver enables easy connectivity between "simple" > +thermal HW devices to the thermal subsystem. "simple" - thermal HW that > +doesn't need any configuration (such as power reset or clock enable) by a > +driver and only exports the temperature via simple MMIO access, or, > +alternatively, all the configuration is done by other entity (e.g. > +bootloader). > + > +Any system that allows temperature reading via a single memory map read, be > +it register or shared memory, is a potential candidate to work with this > +driver. > +This driver allows manipulations on the read value in order to allow some > +flexibility for the various thermal HW, e.g. sensor-factor which will be > +multiplied by the read value. > + > +This driver is most suitable for cases such as the following: > +- The entire thermal HW setup (e.g. configure the thermal HW to work in > + continuous mode) is done by another SW entity (e.g. bootloader) and all > + that is left is to read the current temperature from a register > +- The thermal reading is done by an external CPU (e.g. micro-controller) > + and that CPU is exporting the reading via a shared memory > +- The thermal HW setup and reading is done via CPLD, which exports the > + current temperature to the system via a register > +- The thermal HW is working out-of-the-box and only reports temperature via > + a single register access > + > +Some examples for cases that this driver is not suitable for: > +- Your HW need clock enabling to be done by thermal driver ...or avoiding disabling of a clock, regulator, etc. > +- Your HW need some registers configurations in order to start reporting > + temperatures and it is not doable by other entities (e.g. bootloader) > +- Your HW allows reading of temperatures only between ADCs (or any other > + timing constrains) > +- In case your HW was configured by a bootloader and it lose the > + configuration as part of low-power-state and need to be reconfigured. > + (bootloader configuration typically is not sustained across low power > + states) > +- In case the reading from the MMIO require any type of locking Or filtering/averaging of values. > + > +So the only operation this driver will do is MMIO read for the temperature. > +In case you are using HW that require some configurations this driver is > +not suitable (you can decide to move all the configuration logic into your > +bootloader and only leave the temperature reading to this driver but this > +is up to you). > + > +An example of a system that uses this driver is the Amazon Nitro SoC in > +which there is the main CPU and micro-controller: > +(1) The micro-controller accesses an SBUS controller to read the thermal > + sensor from an SBUS slave called Avago Technologies digital > + Temperature/Voltage Sensor (ip16_SENS_thermvolt25_0) > +(2) Once the micro-controller gathers the temperature it relays it to the > + main CPU via a Shared Integrated RAM which is MMIO accessible by the CPU > +(3) The thermal_mmio driver that runs on the main CPU will read the > + temperature via an MMIO access to the Shared RAM > + > ++------------------+ +----------------+ > +| | (3) | | > +| Main CPU +----->+ Integrated RAM | > +| | | | > ++------------------+ +---------^------+ > + |(2) > ++-----------------+ +------------------+ > +| | (1) | | > +| SBUS controller <-------+ micro-controller | > +| | | | > ++--------+--------+ +------------------+ > + | > ++--------v---------------------+ > +| | > +| Avago Technologies digital | > +| Temperature/Voltage Sensor | > +| (ip16_SENS_thermvolt25_0) | > +| | > ++------------------------------+ Very specific information for a 'generic' binding. > + > +Required properties: > +- compatible: "thermal-mmio". > +- reg: The physical base address and length of the sensor's registers. > +- #thermal-sensor-cells: Must be 1. See ./thermal.txt for a description. > + > +Optional properties:> +- sensor-width: Width (in bytes) of each consecutive sensor. > + Supported: 1, 2, 4. > + (Default = 4) > +- sensor-mask: Mask to be applied on the raw read value before any > + calculation. > + (Default = 0xFFFFFFFF) > +- sensor-factor: Scale value by which to multiple the masked read value > + This is a signed 32 bit value. > + (Default = 1) > +- sensor-bias: Bias value to be added to the scaled value. > + This is a signed 32 bit value. > + (Default = 0) > +- sensor-divider: Dividing value by which to divide the calculated value. > + Diving will be Integer Division. > + This is a unsigned 32 bit value. > + (Default = 1) If you are going to abstract all the h/w access, then get rid of all of this and just put Celsius values into the "register". > + > +Conversion formula from HW MMIO read value to millidegrees (Celsius): > +T_millidegrees = (bias + (T_raw & mask)*factor)/divider > + > +Example 1, two thermal devices with one thermal sensor each, that uses only > +the required properties (uses default): > + > + thermal_d1: thermal_d1 { > + compatible = "thermal-mmio"; > + reg = <0x0 0x05002860 0x0 0x4>; > + #thermal-sensor-cells = <0x1>; > + }; > + > + thermal_d2: thermal_d2 { > + compatible = "thermal-mmio"; > + reg = <0x0 0x05000730 0x0 0x4>; > + #thermal-sensor-cells = <0x1>; > + }; > + > + thermal-zones { > + thermal_d1_z0 { > + polling-delay-passive = <250>; > + polling-delay = <1000>; > + thermal-sensors = <&thermal_d1 0>; > + trips { > + thermal_d1_z0_crit { > + temperature = <105000>; > + hysteresis = <2000>; > + type = "critical"; > + }; > + }; > + > + }; > + > + thermal_d2_z0 { > + polling-delay-passive = <250>; > + polling-delay = <1000>; > + thermal-sensors = <&thermal_d2 0>; > + trips { > + thermal_d2_z0_crit { > + temperature = <105000>; > + hysteresis = <2000>; > + type = "critical"; > + }; > + }; > + }; > + }; > + > +Example 2, one thermal device with two sensors of 6 bits each each, that > +has a factor of -5, bias of 23 and dividing of 2: > + > + thermal_d3: thermal_d3 { > + compatible = "thermal-mmio"; > + reg = <0x0 0x05005700 0x0 0x2>; > + #thermal-sensor-cells = <0x1>; > + sensor-width = <1>; > + sensor-mask = <0x3F>; > + sensor-factor = <(-5)>; > + sensor-bias = <23>; > + sensor-divider = <2>; > + }; > + > + thermal-zones { > + thermal_d3 { > + polling-delay-passive = <250>; > + polling-delay = <1000>; > + thermal-sensors = <&thermal_d3 0>; > + trips { > + thermal_d3_z0_crit { > + temperature = <105000>; > + hysteresis = <2000>; > + type = "critical"; > + }; > + }; > + }; > + }; > -- > 2.7.4 >
diff --git a/Documentation/devicetree/bindings/thermal/thermal_mmio.txt b/Documentation/devicetree/bindings/thermal/thermal_mmio.txt new file mode 100644 index 0000000..1f4d738 --- /dev/null +++ b/Documentation/devicetree/bindings/thermal/thermal_mmio.txt @@ -0,0 +1,173 @@ +Generic Thermal MMIO Driver + +The generic thermal driver enables easy connectivity between "simple" +thermal HW devices to the thermal subsystem. "simple" - thermal HW that +doesn't need any configuration (such as power reset or clock enable) by a +driver and only exports the temperature via simple MMIO access, or, +alternatively, all the configuration is done by other entity (e.g. +bootloader). + +Any system that allows temperature reading via a single memory map read, be +it register or shared memory, is a potential candidate to work with this +driver. +This driver allows manipulations on the read value in order to allow some +flexibility for the various thermal HW, e.g. sensor-factor which will be +multiplied by the read value. + +This driver is most suitable for cases such as the following: +- The entire thermal HW setup (e.g. configure the thermal HW to work in + continuous mode) is done by another SW entity (e.g. bootloader) and all + that is left is to read the current temperature from a register +- The thermal reading is done by an external CPU (e.g. micro-controller) + and that CPU is exporting the reading via a shared memory +- The thermal HW setup and reading is done via CPLD, which exports the + current temperature to the system via a register +- The thermal HW is working out-of-the-box and only reports temperature via + a single register access + +Some examples for cases that this driver is not suitable for: +- Your HW need clock enabling to be done by thermal driver +- Your HW need some registers configurations in order to start reporting + temperatures and it is not doable by other entities (e.g. bootloader) +- Your HW allows reading of temperatures only between ADCs (or any other + timing constrains) +- In case your HW was configured by a bootloader and it lose the + configuration as part of low-power-state and need to be reconfigured. + (bootloader configuration typically is not sustained across low power + states) +- In case the reading from the MMIO require any type of locking + +So the only operation this driver will do is MMIO read for the temperature. +In case you are using HW that require some configurations this driver is +not suitable (you can decide to move all the configuration logic into your +bootloader and only leave the temperature reading to this driver but this +is up to you). + +An example of a system that uses this driver is the Amazon Nitro SoC in +which there is the main CPU and micro-controller: +(1) The micro-controller accesses an SBUS controller to read the thermal + sensor from an SBUS slave called Avago Technologies digital + Temperature/Voltage Sensor (ip16_SENS_thermvolt25_0) +(2) Once the micro-controller gathers the temperature it relays it to the + main CPU via a Shared Integrated RAM which is MMIO accessible by the CPU +(3) The thermal_mmio driver that runs on the main CPU will read the + temperature via an MMIO access to the Shared RAM + ++------------------+ +----------------+ +| | (3) | | +| Main CPU +----->+ Integrated RAM | +| | | | ++------------------+ +---------^------+ + |(2) ++-----------------+ +------------------+ +| | (1) | | +| SBUS controller <-------+ micro-controller | +| | | | ++--------+--------+ +------------------+ + | ++--------v---------------------+ +| | +| Avago Technologies digital | +| Temperature/Voltage Sensor | +| (ip16_SENS_thermvolt25_0) | +| | ++------------------------------+ + +Required properties: +- compatible: "thermal-mmio". +- reg: The physical base address and length of the sensor's registers. +- #thermal-sensor-cells: Must be 1. See ./thermal.txt for a description. + +Optional properties: +- sensor-width: Width (in bytes) of each consecutive sensor. + Supported: 1, 2, 4. + (Default = 4) +- sensor-mask: Mask to be applied on the raw read value before any + calculation. + (Default = 0xFFFFFFFF) +- sensor-factor: Scale value by which to multiple the masked read value + This is a signed 32 bit value. + (Default = 1) +- sensor-bias: Bias value to be added to the scaled value. + This is a signed 32 bit value. + (Default = 0) +- sensor-divider: Dividing value by which to divide the calculated value. + Diving will be Integer Division. + This is a unsigned 32 bit value. + (Default = 1) + +Conversion formula from HW MMIO read value to millidegrees (Celsius): +T_millidegrees = (bias + (T_raw & mask)*factor)/divider + +Example 1, two thermal devices with one thermal sensor each, that uses only +the required properties (uses default): + + thermal_d1: thermal_d1 { + compatible = "thermal-mmio"; + reg = <0x0 0x05002860 0x0 0x4>; + #thermal-sensor-cells = <0x1>; + }; + + thermal_d2: thermal_d2 { + compatible = "thermal-mmio"; + reg = <0x0 0x05000730 0x0 0x4>; + #thermal-sensor-cells = <0x1>; + }; + + thermal-zones { + thermal_d1_z0 { + polling-delay-passive = <250>; + polling-delay = <1000>; + thermal-sensors = <&thermal_d1 0>; + trips { + thermal_d1_z0_crit { + temperature = <105000>; + hysteresis = <2000>; + type = "critical"; + }; + }; + + }; + + thermal_d2_z0 { + polling-delay-passive = <250>; + polling-delay = <1000>; + thermal-sensors = <&thermal_d2 0>; + trips { + thermal_d2_z0_crit { + temperature = <105000>; + hysteresis = <2000>; + type = "critical"; + }; + }; + }; + }; + +Example 2, one thermal device with two sensors of 6 bits each each, that +has a factor of -5, bias of 23 and dividing of 2: + + thermal_d3: thermal_d3 { + compatible = "thermal-mmio"; + reg = <0x0 0x05005700 0x0 0x2>; + #thermal-sensor-cells = <0x1>; + sensor-width = <1>; + sensor-mask = <0x3F>; + sensor-factor = <(-5)>; + sensor-bias = <23>; + sensor-divider = <2>; + }; + + thermal-zones { + thermal_d3 { + polling-delay-passive = <250>; + polling-delay = <1000>; + thermal-sensors = <&thermal_d3 0>; + trips { + thermal_d3_z0_crit { + temperature = <105000>; + hysteresis = <2000>; + type = "critical"; + }; + }; + }; + };
Add thermal binding documentation for thermal MMIO driver. Signed-off-by: Talel Shenhar <talel@amazon.com> --- .../devicetree/bindings/thermal/thermal_mmio.txt | 173 +++++++++++++++++++++ 1 file changed, 173 insertions(+) create mode 100644 Documentation/devicetree/bindings/thermal/thermal_mmio.txt