save compiling state during refactor

2025-04-18 14:01:51 +02:00 · 2025-04-18 14:01:51 +02:00 · d2b55fdafb
commit d2b55fdafb
parent 4b1d87b66f
4 changed files with 98 additions and 92 deletions
--- a/rust/src/main.rs
+++ b/rust/src/main.rs
@ -7,7 +7,6 @@ use anyhow::{bail, Result};
 use chrono::{DateTime, Datelike, TimeDelta, Timelike, Utc};
 use chrono_tz::{Europe::Berlin, Tz};

-use config::PlantWateringMode;
 use esp_idf_hal::delay::Delay;
 use esp_idf_sys::{
    esp_ota_get_app_partition_count, esp_ota_get_running_partition, esp_ota_get_state_partition,
@ -410,50 +409,55 @@ fn safe_main() -> anyhow::Result<()> {
    let mut plantstate: [PlantState; PLANT_COUNT] =
        core::array::from_fn(|i| PlantState::read_hardware_state(i, &mut board, &config.plants[i]));

-    let pump_required = plantstate.iter().any(|it| it.needs_to_be_watered(&config.plants[i], &timezone_time)) && !water_frozen;
+    let pump_required = plantstate
+        .iter()
+        .zip(&config.plants)
+        .any(|(it, conf)| it.needs_to_be_watered(&conf, &timezone_time))
+        && !water_frozen;
    if pump_required {
        log(log::LogMessage::EnableMain, dry_run as u32, 0, "", "");
        if !dry_run {
-            board.any_pump(true)?;
+            board.any_pump(true)?; // what does this do? Does it need to be reset?
        }
-        for plant in 0..PLANT_COUNT {
-            let state = &mut plantstate[plant];
-            if state.do_water {
-                let plant_config = &config.plants[plant];
-                state.consecutive_pump_count = board.consecutive_pump_count(plant) + 1;
-                board.store_consecutive_pump_count(plant, state.consecutive_pump_count);
-                if state.consecutive_pump_count > plant_config.max_consecutive_pump_count as u32 {
-                    log(
-                        log::LogMessage::ConsecutivePumpCountLimit,
-                        state.consecutive_pump_count as u32,
-                        plant_config.max_consecutive_pump_count as u32,
-                        &plant.to_string(),
-                        "",
-                    );
-                    state.not_effective = true;
-                    board.fault(plant, true);
-                }
+        for (plant_id, (state, plant_config)) in plantstate.iter().zip(&config.plants).enumerate() {
+            if state.needs_to_be_watered(&plant_config, &timezone_time) {
+                let pump_count = board.consecutive_pump_count(plant_id) + 1;
+                board.store_consecutive_pump_count(plant_id, pump_count);
+                //TODO(judge) where to put this?
+                //if state.consecutive_pump_count > plant_config.max_consecutive_pump_count as u32 {
+                //    log(
+                //        log::LogMessage::ConsecutivePumpCountLimit,
+                //        state.consecutive_pump_count as u32,
+                //        plant_config.max_consecutive_pump_count as u32,
+                //        &plant.to_string(),
+                //        "",
+                //    );
+                //    state.not_effective = true;
+                //    board.fault(plant, true);
+                //}
                log(
                    log::LogMessage::PumpPlant,
-                    (plant + 1) as u32,
+                    (plant_id + 1) as u32,
                    plant_config.pump_time_s as u32,
                    &dry_run.to_string(),
                    "",
                );
-                board.store_last_pump_time(plant, cur);
-                board.last_pump_time(plant);
-                state.active = true;
+                board.store_last_pump_time(plant_id, cur);
+                board.last_pump_time(plant_id);
+                //state.active = true;
                if !dry_run {
-                    board.pump(plant, true)?;
-                    for _ in 0..plant_config.pump_time_s {
-                        Delay::new_default().delay_ms(1000);
-                    }
-                    board.pump(plant, false)?;
+                    board.pump(plant_id, true)?;
+                    Delay::new_default().delay_ms(1000*plant_config.pump_time_s as u32);
+                    board.pump(plant_id, false)?;
                }
+            } else if !state.pump_in_timeout(&plant_config, &timezone_time){
+                // plant does not need to be watered and is not in timeout
+                // -> reset consecutive pump count
+                board.store_consecutive_pump_count(plant_id, 0);
            }
        }
    }
-    update_plant_state(&mut plantstate, &mut board, &config);
+    //update_plant_state(&mut plantstate, &mut board, &config);

    let is_day = board.is_day();
    let state_of_charge = board.state_charge_percent().unwrap_or(0);
--- a/rust/src/plant_hal.rs
+++ b/rust/src/plant_hal.rs
@ -603,7 +603,7 @@ impl PlantCtrlBoard<'_> {
        self.time()
    }

-    pub fn measure_moisture_hz(&mut self, plant: usize, sensor: Sensor) -> Result<u32> {
+    pub fn measure_moisture_hz(&mut self, plant: usize, sensor: Sensor) -> Result<f32> {
        let sensor_channel = match sensor {
            Sensor::A => match plant {
                0 => SENSOR_A_1,
@ -629,7 +629,7 @@ impl PlantCtrlBoard<'_> {
            },
        };

-        let mut results = [0_u32; REPEAT_MOIST_MEASURE];
+        let mut results = [0_f32; REPEAT_MOIST_MEASURE];
        for repeat in 0..REPEAT_MOIST_MEASURE {
            self.signal_counter.counter_pause()?;
            self.signal_counter.counter_clear()?;
@ -644,7 +644,7 @@ impl PlantCtrlBoard<'_> {
                .unwrap();

            let delay = Delay::new_default();
-            let measurement = 100;
+            let measurement = 100; // TODO what is this scaling factor? what is its purpose?
            let factor = 1000 as f32 / measurement as f32;

            //give some time to stabilize
@ -658,7 +658,7 @@ impl PlantCtrlBoard<'_> {
                .unwrap();
            delay.delay_ms(10);
            let unscaled = self.signal_counter.get_counter_value()? as i32;
-            let hz = (unscaled as f32 * factor) as u32;
+            let hz = unscaled as f32 * factor;
            log(
                LogMessage::RawMeasure,
                unscaled as u32,
@ -668,7 +668,7 @@ impl PlantCtrlBoard<'_> {
            );
            results[repeat] = hz;
        }
-        results.sort();
+        results.sort_by(|a,b| a.partial_cmp(b).unwrap()); // floats don't seem to implement total_ord

        let mid = results.len() / 2;

--- a/rust/src/plant_state.rs
+++ b/rust/src/plant_state.rs
@ -8,18 +8,19 @@ use crate::{
    plant_hal::{self, PLANT_COUNT},
 };

-const MOIST_SENSOR_MAX_FREQUENCY: u32 = 5500; // 60kHz (500Hz margin)
-const MOIST_SENSOR_MIN_FREQUENCY: u32 = 150; // this is really really dry, think like cactus levels
+const MOIST_SENSOR_MAX_FREQUENCY: f32 = 5500.; // 60kHz (500Hz margin)
+const MOIST_SENSOR_MIN_FREQUENCY: f32 = 150.; // this is really really dry, think like cactus levels

+#[derive(Debug, PartialEq, Serialize)]
 pub enum HumiditySensorError {
    ShortCircuit { hz: f32, max: f32 },
    OpenLoop { hz: f32, min: f32 },
 }

-#[derive(Debug, PartialEq)]
+#[derive(Debug, PartialEq, Serialize)]
 pub enum HumiditySensorState {
    Disabled,
-    HumidityValue { raw_hz: u32, moisture_percent: f32 },
+    HumidityValue { raw_hz: f32, moisture_percent: f32 },
    SensorError(HumiditySensorError),
    BoardError(String),
 }
@ -35,7 +36,7 @@ impl HumiditySensorState {
            moisture_percent,
        } = self
        {
-            Some(moisture_percent)
+            Some(*moisture_percent)
        } else {
            None
        }
@ -44,7 +45,7 @@ impl HumiditySensorState {

 impl HumiditySensorState {}

-#[derive(Debug, PartialEq)]
+#[derive(Debug, PartialEq, Serialize)]
 pub enum PumpError {
    PumpNotWorking {
        failed_attempts: usize,
@ -52,6 +53,7 @@ pub enum PumpError {
    },
 }

+#[derive(Debug, Serialize)]
 pub struct PumpState {
    consecutive_pump_count: u32,
    previous_pump: Option<DateTime<Utc>>,
@ -74,7 +76,7 @@ pub struct PlantState {

 fn map_range_moisture(s: f32) -> Result<f32, HumiditySensorError> {
    if s < MOIST_SENSOR_MIN_FREQUENCY {
-        return Err(HumiditySensorError::OpenCircuit {
+        return Err(HumiditySensorError::OpenLoop {
            hz: s,
            min: MOIST_SENSOR_MIN_FREQUENCY,
        });
@ -85,7 +87,7 @@ fn map_range_moisture(s: f32) -> Result<f32, HumiditySensorError> {
            max: MOIST_SENSOR_MAX_FREQUENCY,
        });
    }
-    let moisture_percent = (s - MOIST_SENSOR_MIN_FREQUENCY) * 100
+    let moisture_percent = (s - MOIST_SENSOR_MIN_FREQUENCY) * 100.0
        / (MOIST_SENSOR_MAX_FREQUENCY - MOIST_SENSOR_MIN_FREQUENCY);

    return Ok(moisture_percent);
@ -165,7 +167,7 @@ impl PlantState {
            PlantWateringMode::TargetMoisture => {
                let moisture_percent = match (
                    self.sensor_a.moisture_percent(),
-                    &self.sensor_b.moisture_percent(),
+                    self.sensor_b.moisture_percent(),
                ) {
                    (Some(moisture_a), Some(moisture_b)) => (moisture_a + moisture_b) / 2.,
                    (Some(moisture_percent), _) => moisture_percent,
@ -196,51 +198,51 @@ impl PlantState {
    }
 }

-fn update_plant_state(
-    plantstate: &mut [PlantInfo; PLANT_COUNT],
-    board: &mut std::sync::MutexGuard<'_, PlantCtrlBoard<'_>>,
-    config: &PlantControllerConfig,
-) {
-    for plant in 0..PLANT_COUNT {
-        let state = &plantstate[plant];
-        let plant_config = &config.plants[plant];
-
-        let mode = format!("{:?}", plant_config.mode);
-
-        let plant_dto = PlantStateMQTT {
-            a: &sensor_to_string(
-                &state.a,
-                &state.sensor_error_a,
-                plant_config.mode != PlantWateringMode::OFF,
-            ),
-            a_raw: &state.a_raw.unwrap_or(0).to_string(),
-            b: &sensor_to_string(&state.b, &state.sensor_error_b, plant_config.sensor_b),
-            b_raw: &state.b_raw.unwrap_or(0).to_string(),
-            active: state.active,
-            mode: &mode,
-            last_pump: &time_to_string_utc(board.last_pump_time(plant)),
-            next_pump: &time_to_string(state.next_pump),
-            consecutive_pump_count: state.consecutive_pump_count,
-            cooldown: state.cooldown,
-            dry: state.dry,
-            not_effective: state.not_effective,
-            out_of_work_hour: state.out_of_work_hour,
-            pump_error: state.pump_error,
-        };
-
-        match serde_json::to_string(&plant_dto) {
-            Ok(state) => {
-                let plant_topic = format!("/plant{}", plant + 1);
-                let _ = board.mqtt_publish(&config, &plant_topic, state.as_bytes());
-                //reduce speed as else messages will be dropped
-                Delay::new_default().delay_ms(200);
-            }
-            Err(err) => {
-                println!("Error publishing lightstate {}", err);
-            }
-        };
-    }
-}
+//fn update_plant_state(
+//    plantstate: &mut [PlantInfo; PLANT_COUNT],
+//    board: &mut std::sync::MutexGuard<'_, PlantCtrlBoard<'_>>,
+//    config: &PlantControllerConfig,
+//) {
+//    for plant in 0..PLANT_COUNT {
+//        let state = &plantstate[plant];
+//        let plant_config = &config.plants[plant];
+//
+//        let mode = format!("{:?}", plant_config.mode);
+//
+//        let plant_dto = PlantStateMQTT {
+//            a: &sensor_to_string(
+//                &state.a,
+//                &state.sensor_error_a,
+//                plant_config.mode != PlantWateringMode::OFF,
+//            ),
+//            a_raw: &state.a_raw.unwrap_or(0).to_string(),
+//            b: &sensor_to_string(&state.b, &state.sensor_error_b, plant_config.sensor_b),
+//            b_raw: &state.b_raw.unwrap_or(0).to_string(),
+//            active: state.active,
+//            mode: &mode,
+//            last_pump: &time_to_string_utc(board.last_pump_time(plant)),
+//            next_pump: &time_to_string(state.next_pump),
+//            consecutive_pump_count: state.consecutive_pump_count,
+//            cooldown: state.cooldown,
+//            dry: state.dry,
+//            not_effective: state.not_effective,
+//            out_of_work_hour: state.out_of_work_hour,
+//            pump_error: state.pump_error,
+//        };
+//
+//        match serde_json::to_string(&plant_dto) {
+//            Ok(state) => {
+//                let plant_topic = format!("/plant{}", plant + 1);
+//                let _ = board.mqtt_publish(&config, &plant_topic, state.as_bytes());
+//                //reduce speed as else messages will be dropped
+//                Delay::new_default().delay_ms(200);
+//            }
+//            Err(err) => {
+//                println!("Error publishing lightstate {}", err);
+//            }
+//        };
+//    }
+//}

 #[derive(Debug, PartialEq, Serialize)]
 /// State of a single plant to be tracked
@ -250,7 +252,7 @@ pub struct PlantInfo {
    /// state of humidity sensor on bank b
    sensor_b: HumiditySensorState,
    /// configured plant watering mode
-    mode: config::PlantWateringMode,
+    mode: PlantWateringMode,
    /// plant needs to be watered
    do_water: bool,
    /// is plant considerd to be dry according to settings
--- a/rust/src/util.rs
+++ b/rust/src/util.rs
@ -1,10 +1,10 @@

 pub trait LimitPrecision {
-    fn to_precision(self, presision: i32) -> self;
+    fn to_precision(self, presision: i32) -> Self;
 }

 impl LimitPrecision for f32 {
-    fn to_precision(self, precision: i32) -> self {
+    fn to_precision(self, precision: i32) -> Self {
        (self * (10_f32).powi(precision)).round() / (10_f32).powi(precision)
    }
 }