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//! Module containing the fan sensors and their related functionality.
use super::*;
use crate::hwmon::async_hwmon::Hwmon;
use crate::units::{AngularVelocity, FanDivisor, Raw};
use std::path::{Path, PathBuf};
#[async_trait]
/// Helper trait that sums up all functionality of a read-only fan sensor.
pub trait AsyncFanSensor: AsyncSensor + std::fmt::Debug {
/// Reads the target_revs subfunction of this fan sensor.
///
/// Only makes sense if the chip supports closed-loop fan speed control based on the measured fan speed.
/// Returns an error, if this sensor doesn't support the subfunction.
async fn read_target(&self) -> Result<AngularVelocity> {
let raw = self.read_raw(SensorSubFunctionType::Target).await?;
AngularVelocity::from_raw(&raw).map_err(Error::from)
}
/// Reads the div subfunction of this fan sensor.
/// Returns an error, if this sensor doesn't support the subfunction.
async fn read_div(&self) -> Result<FanDivisor> {
let raw = self.read_raw(SensorSubFunctionType::Div).await?;
FanDivisor::from_raw(&raw).map_err(Error::from)
}
/// Reads whether or not this sensor is enabled.
/// Returns an error, if the sensor doesn't support the feature.
async fn read_enable(&self) -> Result<bool> {
let raw = self.read_raw(SensorSubFunctionType::Enable).await?;
bool::from_raw(&raw).map_err(Error::from)
}
/// Reads the input subfunction of this temp sensor.
/// Returns an error, if this sensor doesn't support the subtype.
async fn read_input(&self) -> Result<AngularVelocity> {
if self.read_faulty().await.unwrap_or(false) {
return Err(Error::FaultySensor);
}
let raw = self.read_raw(SensorSubFunctionType::Input).await?;
AngularVelocity::from_raw(&raw).map_err(Error::from)
}
/// Reads this sensor's min value.
/// Returns an error, if this sensor doesn't support the feature.
async fn read_min(&self) -> Result<AngularVelocity> {
let raw = self.read_raw(SensorSubFunctionType::Min).await?;
AngularVelocity::from_raw(&raw).map_err(Error::from)
}
/// Reads this sensor's max value.
/// Returns an error, if this sensor doesn't support the feature.
async fn read_max(&self) -> Result<AngularVelocity> {
let raw = self.read_raw(SensorSubFunctionType::Max).await?;
AngularVelocity::from_raw(&raw).map_err(Error::from)
}
/// Reads whether this sensor is faulty or not.
/// Returns an error, if this sensor doesn't support the feature.
async fn read_faulty(&self) -> Result<bool> {
let raw = self.read_raw(SensorSubFunctionType::Fault).await?;
bool::from_raw(&raw).map_err(Error::from)
}
/// Reads whether or not an alarm condition exists for the sensor.
/// Returns an error, if the sensor doesn't support the feature.
async fn read_alarm(&self) -> Result<bool> {
let raw = self.read_raw(SensorSubFunctionType::Alarm).await?;
bool::from_raw(&raw).map_err(Error::from)
}
/// Reads whether or not an alarm condition exists for the min subfunction of the sensor.
/// Returns an error, if the sensor doesn't support the feature.
async fn read_min_alarm(&self) -> Result<bool> {
let raw = self.read_raw(SensorSubFunctionType::MinAlarm).await?;
bool::from_raw(&raw).map_err(Error::from)
}
/// Reads whether or not an alarm condition exists for the max subfunction of the sensor.
/// Returns an error, if the sensor doesn't support the feature.
async fn read_max_alarm(&self) -> Result<bool> {
let raw = self.read_raw(SensorSubFunctionType::MaxAlarm).await?;
bool::from_raw(&raw).map_err(Error::from)
}
/// Reads whether or not an alarm condition for the sensor also triggers beeping.
/// Returns an error, if the sensor doesn't support the feature.
async fn read_beep(&self) -> Result<bool> {
let raw = self.read_raw(SensorSubFunctionType::Beep).await?;
bool::from_raw(&raw).map_err(Error::from)
}
}
/// Struct that represents a read only fan sensor.
#[derive(Debug, Clone)]
pub(crate) struct FanSensorStruct {
hwmon_path: PathBuf,
index: u16,
}
impl Sensor for FanSensorStruct {
fn static_base() -> &'static str where Self: Sized {
"fan"
}
fn base(&self) -> &'static str {
"fan"
}
fn index(&self) -> u16 {
self.index
}
fn hwmon_path(&self) -> &Path {
self.hwmon_path.as_path()
}
}
impl AsyncSensor for FanSensorStruct {}
#[async_trait]
impl AsyncSensorExt for FanSensorStruct {
async fn parse(hwmon: &Hwmon, index: u16) -> Result<Self> {
let sensor = Self {
hwmon_path: hwmon.path().to_path_buf(),
index,
};
inspect_sensor(sensor, SensorSubFunctionType::Input).await
}
}
impl AsyncFanSensor for FanSensorStruct {}
#[cfg(feature = "writeable")]
impl AsyncWriteableSensor for FanSensorStruct {}
#[cfg(feature = "writeable")]
#[async_trait]
/// Helper trait that sums up all functionality of a read-write fan sensor.
pub trait AsyncWriteableFanSensor: AsyncFanSensor + AsyncWriteableSensor {
/// Converts target and writes it to this fan's target subfunction.
///
/// Only makes sense if the chip supports closed-loop fan speed control based on the measured fan speed.
/// Returns an error, if this sensor doesn't support the subfunction.
async fn write_target(&self, target: AngularVelocity) -> Result<()> {
self.write_raw(SensorSubFunctionType::Target, &target.to_raw())
.await
}
/// Converts div and writes it to this fan's divisor subfunction.
/// Returns an error, if this sensor doesn't support the subfunction.
async fn write_div(&self, div: FanDivisor) -> Result<()> {
self.write_raw(SensorSubFunctionType::Div, &div.to_raw())
.await
}
/// Sets this sensor's enabled state.
/// Returns an error, if the sensor doesn't support the feature.
async fn write_enable(&self, enable: bool) -> Result<()> {
self.write_raw(SensorSubFunctionType::Enable, &enable.to_raw())
.await
}
/// Writes this sensor's min value.
/// Returns an error, if the sensor doesn't support the feature.
async fn write_min(&self, min: AngularVelocity) -> Result<()> {
self.write_raw(SensorSubFunctionType::Min, &min.to_raw())
.await
}
/// Writes this sensor's max value.
/// Returns an error, if the sensor doesn't support the feature.
async fn write_max(&self, max: AngularVelocity) -> Result<()> {
self.write_raw(SensorSubFunctionType::Max, &max.to_raw())
.await
}
/// Sets whether or not an alarm condition for the sensor also triggers beeping.
/// Returns an error, if the sensor doesn't support the feature.
async fn write_beep(&self, beep: bool) -> Result<()> {
self.write_raw(SensorSubFunctionType::Beep, &beep.to_raw())
.await
}
}
#[cfg(feature = "writeable")]
impl AsyncWriteableFanSensor for FanSensorStruct {}