Remove all tacho/status related logic

Signed-off-by: Egor Savkin <es@m-labs.hk>
2023-01-05 13:05:22 +08:00 · 2023-01-05 13:05:22 +08:00 · a645bfb6e8
parent 33070abd81
commit a645bfb6e8
5 changed files with 22 additions and 174 deletions
--- a/README.md
+++ b/README.md
@ -125,9 +125,10 @@ formatted as line-delimited JSON.
 | `dfu`                            | Reset device and enters USB device firmware update (DFU) mode                 |
 | `ipv4 <X.X.X.X/L> [Y.Y.Y.Y]`     | Configure IPv4 address, netmask length, and optional default gateway          |
 | `fan`                            | Show current fan settings and sensors' measurements                           |
-| `fan <value>`                    | Set fan power with values from 0 to 100, where 0 is auto mode                 |
+| `fan <value>`                    | Set fan power with values from 1 to 100                                       |
 | `fan auto`                       | Enable automatic fan speed control                                            |
 | `fcurve <a> <b> <c>`             | Set fan controller curve coefficients (see *Fan control* section)             |
-| `fcurve-restore`                 | Set fan controller curve coefficients to defaults (see *Fan control* section) |
+| `fcurve default`                 | Set fan controller curve coefficients to defaults (see *Fan control* section) |
 ## USB
@ -277,13 +278,11 @@ The thermostat implements a PID control loop for each of the TEC channels, more
 ## Fan control
 Fan control is available for the thermostat revisions with integrated fan system. For this purpose four commands are available:
-1. `fan` - show fan stats: `fan_pwm`, `tacho`, `abs_max_tec_i`, `auto_mode`. Please note that `tacho` shows *approximate* value, which
+1. `fan` - show fan stats: `fan_pwm`, `abs_max_tec_i`, `auto_mode`, `k_a`, `k_b`, `k_c`.
-linearly correlates with the actual fan speed.
+2. `fan auto` - enable auto speed controller mode, which correlates with the square of the TEC's current.
-2. `fan <value>` - set the fan power with the value from `0` to `100`. Since there is no hardware way to disable the fan,
+3. `fan <value>` - set the fan power with the value from `1` to `100` and disable auto mode. There is no way to disable the fan.
 `0` value is used for enabling automatic fan control mode, which correlates with the square of the TEC's current. 
 Values from `1` to `100` are used for setting the power from minimum to maximum respectively.
 Please note that power doesn't correlate with the actual speed linearly.
-3. `fcurve <a> <b> <c>` - set coefficients of the controlling curve `a*x^2 + b*x + c`, where `x` is `abs_max_tec_i/MAX_TEC_I`, 
+4. `fcurve <a> <b> <c>` - set coefficients of the controlling curve `a*x^2 + b*x + c`, where `x` is `abs_max_tec_i/MAX_TEC_I`, 
 i.e. receives values from 0 to 1 linearly tied to the maximum current. The controlling curve should produce values from 0 to 1,
 as below and beyond values would be substituted by 0 and 1 respectively.
-4. `fcurve-restore` - restore fan settings to defaults: `auto = true, a = 1.0, b = 0.0, c = 0.00`.
+5. `fcurve default` - restore fan curve settings to defaults: `a = 1.0, b = 0.0, c = 0.0`.
--- a/src/command_handler.rs
+++ b/src/command_handler.rs
@ -342,7 +342,7 @@ impl Handler {
        Ok(Handler::Reset)
    }
-    fn fan(socket: &mut TcpSocket, fan_pwm: u32, fan_ctrl: &mut FanCtrl) -> Result<Handler, Error> {
+    fn set_fan(socket: &mut TcpSocket, fan_pwm: u32, fan_ctrl: &mut FanCtrl) -> Result<Handler, Error> {
        fan_ctrl.set_auto_mode(false);
        fan_ctrl.set_pwm(fan_pwm);
        send_line(socket, b"{}");
@ -404,7 +404,7 @@ impl Handler {
            Command::Ipv4(config) => Handler::set_ipv4(socket, store, config),
            Command::Reset => Handler::reset(&mut fan_ctrl.channels),
            Command::Dfu => Handler::dfu(&mut fan_ctrl.channels),
-            Command::FanSet {fan_pwm} => Handler::fan(socket, fan_pwm, fan_ctrl),
+            Command::FanSet {fan_pwm} => Handler::set_fan(socket, fan_pwm, fan_ctrl),
            Command::ShowFan => Handler::show_fan(socket, fan_ctrl),
            Command::FanAuto => Handler::fan_auto(socket, fan_ctrl),
            Command::FanCurve { k_a, k_b, k_c } => Handler::fan_curve(socket, fan_ctrl, k_a, k_b, k_c),
--- a/src/fan_ctrl.rs
+++ b/src/fan_ctrl.rs
@ -2,23 +2,14 @@ use serde::Serialize;
 use stm32f4xx_hal::{
    pwm::{self, PwmChannels},
    pac::TIM8,
    gpio::{
        Floating, Input, ExtiPin,
        gpioc::PC8, Edge,
    },
    stm32::EXTI,
    syscfg::{SysCfg},
 };
 use smoltcp::time::Instant;
 use crate::{
    pins::HWRevPins,
    channels::{Channels, JsonBuffer},
    timer
 };
 pub type FanPin = PwmChannels<TIM8, pwm::C4>;
 pub type TachoPin = PC8<Input<Floating>>;
 // as stated in the schematics
 const MAX_TEC_I: f64 = 3.0;
@ -26,27 +17,13 @@ const MAX_TEC_I: f64 = 3.0;
 const MAX_USER_FAN_PWM: f64 = 100.0;
 const MIN_USER_FAN_PWM: f64 = 1.0;
 const MAX_FAN_PWM: f64 = 1.0;
-// below this value, motor pulse signal is too weak to be registered by tachometer
+// below this value, motor pulse signal is too weak
 const MIN_FAN_PWM: f64 = 0.05;
 const TACHO_MEASURE_MS: i64 = 2500;
 // by default up to 2 cycles are skipped on changes in PWM output,
 // and the halt threshold will help detect the failure during these skipped cycles
 const TACHO_HALT_THRESHOLD: u32 = 250;
 const TACHO_SKIP_CYCLES: u8 = 2;
 const DEFAULT_K_A: f64 = 1.0;
 const DEFAULT_K_B: f64 = 0.0;
 const DEFAULT_K_C: f64 = 0.0;
 // This regression is from 6% to 25% lower than values registered in the experiments.
 // Actual values would be better estimated by logarithmic regression, but that would require more
 // runtime computation, and wouldn't give significant correlation difference
 // (0.996 for log and 0.966 for quadratic regression).
 const TACHO_REGRESSION_A: f64 = -0.04135128436;
 const TACHO_REGRESSION_B: f64 = 6.23015531;
 const TACHO_REGRESSION_C: f64 = 403.6833577;
 #[derive(Serialize, Copy, Clone)]
 pub struct HWRev {
@ -54,83 +31,46 @@ pub struct HWRev {
    pub minor: u8,
 }
 #[derive(Serialize, Clone, Copy, PartialEq)]
 pub enum FanStatus {
    OK,
    NotAvailable,
    TooSlow,
    Halted
 }
 struct TachoCtrl {
    tacho: TachoPin,
    tacho_cnt: u32,
    tacho_value: Option<u32>,
    prev_epoch: i64,
 }
 pub struct FanCtrl {
    fan: FanPin,
    tacho: TachoCtrl,
    fan_auto: bool,
    available: bool,
    k_a: f64,
    k_b: f64,
    k_c: f64,
    pub channels: Channels,
    last_status: FanStatus,
    skip_cycles: u8,
 }
 impl FanCtrl {
-    pub fn new(mut fan: FanPin, tacho: TachoPin, channels: Channels, exti: &mut EXTI, syscfg: &mut SysCfg) -> Self {
+    pub fn new(mut fan: FanPin, channels: Channels) -> Self {
        let available = channels.hwrev.fan_available();
        let mut tacho_ctrl = TachoCtrl::new(tacho);
        if available {
            fan.set_duty(0);
            fan.enable();
            tacho_ctrl.init(exti, syscfg);
        }
        FanCtrl {
            fan,
            tacho: tacho_ctrl,
            available,
            fan_auto: true,
            k_a: DEFAULT_K_A,
            k_b: DEFAULT_K_B,
            k_c: DEFAULT_K_C,
            channels,
            last_status: if available { FanStatus::OK } else { FanStatus::NotAvailable },
            skip_cycles: 0
        }
    }
-    pub fn cycle(&mut self) -> Result<(), FanStatus> {
+    pub fn cycle(&mut self) {
        if self.available {
            if self.tacho.cycle() {
                self.skip_cycles >>= 1;
            }
        }
        self.adjust_speed();
        let diagnose = self.diagnose();
        if (self.skip_cycles == 0 || diagnose == FanStatus::Halted) && diagnose != self.last_status {
            self.last_status = diagnose;
            Err(diagnose)
        } else {
            Ok(())
        }
    }
    pub fn summary(&mut self) -> Result<JsonBuffer, serde_json_core::ser::Error> {
        if self.available {
            let summary = FanSummary {
                fan_pwm: self.get_pwm(),
                tacho: self.tacho.get(),
                abs_max_tec_i: self.channels.current_abs_max_tec_i(),
                auto_mode: self.fan_auto,
                status: self.diagnose(),
                k_a: self.k_a,
                k_b: self.k_b,
                k_c: self.k_c,
@ -165,15 +105,11 @@ impl FanCtrl {
    #[inline]
    pub fn restore_defaults(&mut self) {
        self.set_auto_mode(true);
        self.set_curve(DEFAULT_K_A, DEFAULT_K_B, DEFAULT_K_C);
    }
    pub fn set_pwm(&mut self, fan_pwm: u32) -> f64 {
        let fan_pwm = fan_pwm.min(MAX_USER_FAN_PWM as u32).max(MIN_USER_FAN_PWM as u32);
        self.skip_cycles = if (self.tacho.get() as f64) <= Self::threshold_for_pwm(fan_pwm as f64) {
            TACHO_SKIP_CYCLES
        } else { self.skip_cycles };
        let duty = Self::scale_number(fan_pwm as f64, MIN_FAN_PWM, MAX_FAN_PWM, MIN_USER_FAN_PWM, MAX_USER_FAN_PWM);
        let max = self.fan.get_max_duty();
        let value = ((duty * (max as f64)) as u16).min(max);
@ -181,31 +117,11 @@ impl FanCtrl {
        value as f64 / (max as f64)
    }
    #[inline]
    fn threshold_for_pwm(fan_pwm: f64) -> f64 {
        (TACHO_REGRESSION_A * fan_pwm + TACHO_REGRESSION_B) * fan_pwm + TACHO_REGRESSION_C
    }
    #[inline]
    fn scale_number(unscaled: f64, to_min: f64, to_max: f64, from_min: f64, from_max: f64) -> f64 {
        (to_max - to_min) * (unscaled - from_min) / (from_max - from_min) + to_min
    }
    fn diagnose(&mut self) -> FanStatus {
        if !self.available {
            return FanStatus::NotAvailable;
        }
        let threshold = Self::threshold_for_pwm(self.get_pwm() as f64) as u32;
        let tacho = self.tacho.get();
        if tacho >= threshold {
            FanStatus::OK
        } else if tacho >= TACHO_HALT_THRESHOLD {
            FanStatus::TooSlow
        } else {
            FanStatus::Halted
        }
    }
    fn get_pwm(&self) -> u32 {
        let duty = self.fan.get_duty();
        let max = self.fan.get_max_duty();
@ -213,53 +129,6 @@ impl FanCtrl {
    }
 }
 impl TachoCtrl {
    fn new(tacho: TachoPin) -> Self {
        TachoCtrl {
            tacho,
            tacho_cnt: 0,
            tacho_value: None,
            prev_epoch: 0,
        }
    }
    fn init(&mut self, exti: &mut EXTI, syscfg: &mut SysCfg) {
        // These lines do not cause NVIC to run the ISR,
        // since the interrupt is masked in the cortex_m::peripheral::NVIC.
        // Also using interrupt-related workaround is the best
        // option for the current version of stm32f4xx-hal,
        // since tying the IC's PC8 with the PWM's PC9 to the same TIM8 is not supported.
        // The possible solution would be to update the library to >=v0.14.*,
        // and use its Timer's counter functionality.
        self.tacho.make_interrupt_source(syscfg);
        self.tacho.trigger_on_edge(exti, Edge::Rising);
        self.tacho.enable_interrupt(exti);
    }
    // returns whether the epoch elapsed
    fn cycle(&mut self) -> bool {
        let tacho_input = self.tacho.check_interrupt();
        if tacho_input {
            self.tacho.clear_interrupt_pending_bit();
            self.tacho_cnt += 1;
        }
        let instant = Instant::from_millis(i64::from(timer::now()));
        if instant.millis - self.prev_epoch >= TACHO_MEASURE_MS {
            self.tacho_value = Some(self.tacho_cnt);
            self.tacho_cnt = 0;
            self.prev_epoch = instant.millis;
            true
        } else {
            false
        }
    }
    fn get(&self) -> u32 {
        self.tacho_value.unwrap_or(u32::MAX)
    }
 }
 impl HWRev {
    pub fn detect_hw_rev(hwrev_pins: &HWRevPins) -> Self {
        let (h0, h1, h2, h3) = (hwrev_pins.hwrev0.is_high(), hwrev_pins.hwrev1.is_high(),
@ -280,26 +149,13 @@ impl HWRev {
 #[derive(Serialize)]
 pub struct FanSummary {
    fan_pwm: u32,
    tacho: u32,
    abs_max_tec_i: f64,
    auto_mode: bool,
    status: FanStatus,
    k_a: f64,
    k_b: f64,
    k_c: f64,
 }
 impl FanStatus {
    pub fn fmt_u8(&self) -> &'static [u8] {
        match *self {
            FanStatus::OK => "Fan is OK".as_bytes(),
            FanStatus::NotAvailable => "Fan is not available".as_bytes(),
            FanStatus::TooSlow => "Fan is too slow".as_bytes(),
            FanStatus::Halted => "Fan is halted".as_bytes(),
        }
    }
 }
 #[cfg(test)]
 mod test {
    use super::*;
--- a/src/main.rs
+++ b/src/main.rs
@ -18,7 +18,6 @@ use stm32f4xx_hal::{
    stm32::{CorePeripherals, Peripherals, SCB},
    time::{U32Ext, MegaHertz},
    watchdog::IndependentWatchdog,
    syscfg::SysCfgExt
 };
 use smoltcp::{
    time::Instant,
@ -104,7 +103,7 @@ fn main() -> ! {
    cp.SCB.enable_icache();
    cp.SCB.enable_dcache(&mut cp.CPUID);
-    let mut dp = Peripherals::take().unwrap();
+    let dp = Peripherals::take().unwrap();
    let clocks = dp.RCC.constrain()
        .cfgr
        .use_hse(HSE)
@ -120,7 +119,7 @@ fn main() -> ! {
    timer::setup(cp.SYST, clocks);
-    let (pins, mut leds, mut eeprom, eth_pins, usb, fan, tacho) = Pins::setup(
+    let (pins, mut leds, mut eeprom, eth_pins, usb, fan) = Pins::setup(
        clocks, dp.TIM1, dp.TIM3, dp.TIM8,
        dp.GPIOA, dp.GPIOB, dp.GPIOC, dp.GPIOD, dp.GPIOE, dp.GPIOF, dp.GPIOG,
        dp.I2C1,
@ -151,7 +150,7 @@ fn main() -> ! {
        }
    }
-    let mut fan_ctrl = FanCtrl::new(fan, tacho, channels, &mut dp.EXTI, &mut dp.SYSCFG.constrain());
+    let mut fan_ctrl = FanCtrl::new(fan, channels);
    // default net config:
    let mut ipv4_config = Ipv4Config {
@ -186,7 +185,7 @@ fn main() -> ! {
                    server.for_each(|_, session| session.set_report_pending(channel.into()));
                }
-                let fan_status = fan_ctrl.cycle();
+                fan_ctrl.cycle();
                let instant = Instant::from_millis(i64::from(timer::now()));
                cortex_m::interrupt::free(net::clear_pending);
@ -239,12 +238,6 @@ fn main() -> ! {
                                    }
                                }
                            }
                            match fan_status {
                                Ok(_) => {}
                                Err(status) => {
                                    send_line(&mut socket, status.fmt_u8());
                                }
                            };
                        }
                    });
                } else {
--- a/src/pins.rs
+++ b/src/pins.rs
@ -33,7 +33,7 @@ use stm32_eth::EthPins;
 use crate::{
    channel::{Channel0, Channel1},
    leds::Leds,
-    fan_ctrl::{TachoPin, FanPin}
+    fan_ctrl::FanPin
 };
 const PWM_FREQ: KiloHertz = KiloHertz(20u32);
@ -131,7 +131,7 @@ impl Pins {
        spi2: SPI2, spi4: SPI4, spi5: SPI5,
        adc1: ADC1,
        otg_fs_global: OTG_FS_GLOBAL, otg_fs_device: OTG_FS_DEVICE, otg_fs_pwrclk: OTG_FS_PWRCLK,
-    ) -> (Self, Leds, Eeprom, EthernetPins, USB, FanPin, TachoPin) {
+    ) -> (Self, Leds, Eeprom, EthernetPins, USB, FanPin) {
        let gpioa = gpioa.split();
        let gpiob = gpiob.split();
        let gpioc = gpioc.split();
@ -228,9 +228,9 @@ impl Pins {
            hclk: clocks.hclk(),
        };
-        let fan = Timer::new(tim8, &clocks).pwm(gpioc.pc9.into_alternate(), 20u32.khz());
+        let fan = Timer::new(tim8, &clocks).pwm(gpioc.pc9.into_alternate(), PWM_FREQ);
-        (pins, leds, eeprom, eth_pins, usb, fan, gpioc.pc8)
+        (pins, leds, eeprom, eth_pins, usb, fan)
    }
    /// Configure the GPIO pins for SPI operation, and initialize SPI
@ -342,7 +342,7 @@ impl PwmPins {
        PwmPins {
            max_v0, max_v1,
            max_i_pos0, max_i_pos1,
-            max_i_neg0, max_i_neg1
+            max_i_neg0, max_i_neg1,
        }
    }
 }