PlantCtrl/rust/src/plant_hal.rs

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//mod config;
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use embedded_hal::blocking::delay::DelayMs;
use embedded_svc::wifi::{
AccessPointConfiguration, AuthMethod, ClientConfiguration, Configuration, Wifi, AccessPointInfo,
};
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use esp_idf_svc::eventloop::EspSystemEventLoop;
use esp_idf_svc::nvs::EspDefaultNvsPartition;
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use esp_idf_svc::wifi::config::{ScanConfig, ScanType};
use esp_idf_svc::wifi::{EspWifi, NonBlocking};
use plant_ctrl2::sipo::ShiftRegister40;
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use anyhow::anyhow;
use anyhow::{bail, Context, Ok, Result};
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use std::ffi::CString;
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use std::fs::File;
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use std::io::{BufReader, Read};
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use std::path::Path;
use std::str::from_utf8;
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use std::sync::{Mutex, Arc};
use std::time::Duration;
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use chrono::{DateTime, NaiveDateTime, Utc};
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use ds18b20::Ds18b20;
use embedded_hal::digital::v1_compat::OldOutputPin;
use embedded_hal::digital::v2::OutputPin;
use esp_idf_hal::adc::config::Config;
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use esp_idf_hal::adc::{attenuation, AdcChannelDriver, AdcDriver};
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use esp_idf_hal::delay::{Delay, FreeRtos};
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use esp_idf_hal::gpio::{AnyInputPin, Gpio39, Gpio4, Level, PinDriver};
use esp_idf_hal::pcnt::{
PcntChannel, PcntChannelConfig, PcntControlMode, PcntCountMode, PcntDriver, PinIndex,
};
use esp_idf_hal::prelude::Peripherals;
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use esp_idf_hal::reset::ResetReason;
use esp_idf_svc::sntp::{self, SyncStatus};
use esp_idf_svc::systime::EspSystemTime;
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use esp_idf_sys::{vTaskDelay, EspError};
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use one_wire_bus::OneWire;
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use serde::{Deserialize, Serialize};
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use crate::config::{self, WifiConfig};
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pub const PLANT_COUNT: usize = 8;
const PINS_PER_PLANT: usize = 5;
const PLANT_PUMP_OFFSET: usize = 0;
const PLANT_FAULT_OFFSET: usize = 1;
const PLANT_MOIST_PUMP_OFFSET: usize = 2;
const PLANT_MOIST_B_OFFSET: usize = 3;
const PLANT_MOIST_A_OFFSET: usize = 4;
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const SPIFFS_PARTITION_NAME: &str = "storage";
const WIFI_CONFIG_FILE: &str = "/spiffs/wifi.cfg";
const CONFIG_FILE: &str = "/spiffs/config.cfg";
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#[link_section = ".rtc.data"]
static mut LAST_WATERING_TIMESTAMP: [i64; PLANT_COUNT] = [0; PLANT_COUNT];
#[link_section = ".rtc.data"]
static mut CONSECUTIVE_WATERING_PLANT: [u32; PLANT_COUNT] = [0; PLANT_COUNT];
#[link_section = ".rtc.data"]
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static mut LOW_VOLTAGE_DETECTED: bool = false;
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pub struct BatteryState {
state_charge_percent: u8,
max_error_percent: u8,
remaining_milli_ampere_hour: u32,
max_milli_ampere_hour: u32,
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design_milli_ampere_hour: u32,
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voltage_milli_volt: u16,
average_current_milli_ampere: u16,
temperature_tenth_kelvin: u32,
average_time_to_empty_minute: u16,
average_time_to_full_minute: u16,
average_discharge_power_cycle_milli_watt: u16,
cycle_count: u16,
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state_health_percent: u8,
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}
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pub struct FileSystemSizeInfo {
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pub total_size: usize,
pub used_size: usize,
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pub free_size: usize,
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}
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#[derive(Debug)]
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pub enum Sensor {
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A,
B,
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PUMP,
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}
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pub trait PlantCtrlBoardInteraction {
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fn time(&mut self) -> Result<chrono::DateTime<Utc>>;
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fn wifi(&mut self, ssid: &str, password: Option<&str>, max_wait: u32) -> Result<()>;
fn sntp(&mut self, max_wait: u32) -> Result<chrono::DateTime<Utc>>;
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fn mountFileSystem(&mut self) -> Result<()>;
fn fileSystemSize(&mut self) -> Result<FileSystemSizeInfo>;
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fn battery_state(&mut self) -> Result<BatteryState>;
fn general_fault(&mut self, enable: bool);
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fn is_day(&self) -> bool;
fn water_temperature_c(&mut self) -> Result<f32>;
fn tank_sensor_mv(&mut self) -> Result<u16>;
fn set_low_voltage_in_cycle(&mut self);
fn clear_low_voltage_in_cycle(&mut self);
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fn low_voltage_in_cycle(&mut self) -> bool;
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fn any_pump(&mut self, enabled: bool) -> Result<()>;
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//keep state during deepsleep
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fn light(&mut self, enable: bool) -> Result<()>;
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fn measure_moisture_hz(&self, plant: usize, sensor: Sensor) -> Result<i32>;
fn pump(&self, plant: usize, enable: bool) -> Result<()>;
fn last_pump_time(&self, plant: usize) -> Result<chrono::DateTime<Utc>>;
fn store_last_pump_time(&mut self, plant: usize, time: chrono::DateTime<Utc>);
fn store_consecutive_pump_count(&mut self, plant: usize, count: u32);
fn consecutive_pump_count(&mut self, plant: usize) -> u32;
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//keep state during deepsleep
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fn fault(&self, plant: usize, enable: bool);
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//config
fn is_config_reset(&mut self) -> bool;
fn remove_configs(&mut self) -> Result<()>;
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fn get_config(&mut self) -> Result<config::Config>;
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fn get_wifi(&mut self) -> Result<config::WifiConfig>;
fn set_wifi(&mut self, wifi: &WifiConfig) -> Result<()>;
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fn wifi_ap(&mut self) -> Result<()>;
fn wifi_scan(&mut self) -> Result<Vec<AccessPointInfo>>;
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}
pub trait CreatePlantHal<'a> {
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fn create() -> Result<Arc<Mutex<PlantCtrlBoard<'static>>>>;
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}
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pub struct PlantHal {}
impl CreatePlantHal<'_> for PlantHal {
fn create() -> Result<Arc<Mutex<PlantCtrlBoard<'static>>>> {
let peripherals = Peripherals::take()?;
let mut clock = PinDriver::output(peripherals.pins.gpio21)?;
let mut latch = PinDriver::output(peripherals.pins.gpio22)?;
let mut data = PinDriver::output(peripherals.pins.gpio19)?;
// loop {
// unsafe {
// let delay = Delay::new_default();
// latch.set_low().unwrap();
// delay.delay_ms(1);
// for i in 1..2 {
// data.set_high().unwrap();
// delay.delay_ms(1);
// clock.set_high().unwrap();
// delay.delay_ms(1);
// clock.set_low().unwrap();
// delay.delay_ms(1);
// }
// latch.set_high().unwrap();
// latch.set_low().unwrap();
// delay.delay_ms(1);
// for i in 1..2 {
// data.set_low().unwrap();
// delay.delay_ms(1);
// clock.set_high().unwrap();
// delay.delay_ms(1);
// clock.set_low().unwrap();
// delay.delay_ms(1);
// }
// latch.set_high().unwrap();
// vTaskDelay(5);
// }
// }
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let one_wire_pin = PinDriver::input_output_od(peripherals.pins.gpio4)?;
//TODO make to none if not possible to init
//init,reset rtc memory depending on cause
let reasons = ResetReason::get();
let reset_store = match reasons {
ResetReason::Software => false,
ResetReason::ExternalPin => false,
ResetReason::Watchdog => true,
ResetReason::Sdio => true,
ResetReason::Panic => true,
ResetReason::InterruptWatchdog => true,
ResetReason::PowerOn => true,
ResetReason::Unknown => true,
ResetReason::Brownout => true,
ResetReason::TaskWatchdog => true,
ResetReason::DeepSleep => false,
};
if reset_store {
println!("Clear and reinit RTC store");
unsafe {
LAST_WATERING_TIMESTAMP = [0; PLANT_COUNT];
CONSECUTIVE_WATERING_PLANT = [0; PLANT_COUNT];
LOW_VOLTAGE_DETECTED = false;
};
} else {
println!("Keeping RTC store");
}
let mut counter_unit1 = PcntDriver::new(
peripherals.pcnt0,
Some(peripherals.pins.gpio18),
Option::<AnyInputPin>::None,
Option::<AnyInputPin>::None,
Option::<AnyInputPin>::None,
)?;
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println!("Channel config start");
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counter_unit1.channel_config(
PcntChannel::Channel0,
PinIndex::Pin0,
PinIndex::Pin1,
&PcntChannelConfig {
lctrl_mode: PcntControlMode::Reverse,
hctrl_mode: PcntControlMode::Keep,
pos_mode: PcntCountMode::Decrement,
neg_mode: PcntCountMode::Increment,
counter_h_lim: i16::MAX,
counter_l_lim: 0,
},
)?;
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println!("Setup filter");
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//TODO validate filter value! currently max allowed value
counter_unit1.set_filter_value(1023)?;
counter_unit1.filter_enable()?;
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println!("Wifi start");
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let sys_loop = EspSystemEventLoop::take()?;
let nvs = EspDefaultNvsPartition::take()?;
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let wifi_driver = EspWifi::new(peripherals.modem, sys_loop, Some(nvs))?;
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let shift_register = ShiftRegister40::new(clock, latch, data);
let last_watering_timestamp = Mutex::new(unsafe { LAST_WATERING_TIMESTAMP });
let consecutive_watering_plant = Mutex::new(unsafe { CONSECUTIVE_WATERING_PLANT });
let low_voltage_detected = Mutex::new(unsafe { LOW_VOLTAGE_DETECTED });
let tank_driver = AdcDriver::new(peripherals.adc1, &Config::new())?;
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let tank_channel: AdcChannelDriver<'_, { attenuation::DB_11 }, Gpio39> =
AdcChannelDriver::new(peripherals.pins.gpio39)?;
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let solar_is_day = PinDriver::input(peripherals.pins.gpio25)?;
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let boot_button = PinDriver::input(peripherals.pins.gpio0)?;
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let light = PinDriver::output(peripherals.pins.gpio26)?;
let main_pump = PinDriver::output(peripherals.pins.gpio23)?;
let tank_power = PinDriver::output(peripherals.pins.gpio27)?;
let general_fault = PinDriver::output(peripherals.pins.gpio13)?;
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let one_wire_bus = OneWire::new(one_wire_pin)
.map_err(|err| -> anyhow::Error { anyhow!("Missing attribute: {:?}", err) })?;
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println!("After stuff");
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let rv = Arc::new(Mutex::new(PlantCtrlBoard {
//shift_register : shift_register,
last_watering_timestamp: last_watering_timestamp,
consecutive_watering_plant: consecutive_watering_plant,
low_voltage_detected: low_voltage_detected,
tank_driver: tank_driver,
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tank_channel: tank_channel,
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solar_is_day: solar_is_day,
boot_button: boot_button,
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light: light,
main_pump: main_pump,
tank_power: tank_power,
general_fault: general_fault,
one_wire_bus: one_wire_bus,
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signal_counter: counter_unit1,
wifi_driver: wifi_driver,
}));
return Ok(rv);
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}
}
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pub struct PlantCtrlBoard<'a> {
//shift_register: ShiftRegister40<OldOutputPin<PinDriver<'a, esp_idf_hal::gpio::Gpio21, esp_idf_hal::gpio::Output>>, OldOutputPin<PinDriver<'a, esp_idf_hal::gpio::Gpio22, esp_idf_hal::gpio::Output>>, OldOutputPin<PinDriver<'a, esp_idf_hal::gpio::Gpio19, esp_idf_hal::gpio::Output>>>,
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consecutive_watering_plant: Mutex<[u32; PLANT_COUNT]>,
last_watering_timestamp: Mutex<[i64; PLANT_COUNT]>,
low_voltage_detected: Mutex<bool>,
tank_driver: AdcDriver<'a, esp_idf_hal::adc::ADC1>,
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tank_channel: esp_idf_hal::adc::AdcChannelDriver<'a, { attenuation::DB_11 }, Gpio39>,
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solar_is_day: PinDriver<'a, esp_idf_hal::gpio::Gpio25, esp_idf_hal::gpio::Input>,
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boot_button: PinDriver<'a, esp_idf_hal::gpio::Gpio0, esp_idf_hal::gpio::Input>,
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signal_counter: PcntDriver<'a>,
light: PinDriver<'a, esp_idf_hal::gpio::Gpio26, esp_idf_hal::gpio::Output>,
main_pump: PinDriver<'a, esp_idf_hal::gpio::Gpio23, esp_idf_hal::gpio::Output>,
tank_power: PinDriver<'a, esp_idf_hal::gpio::Gpio27, esp_idf_hal::gpio::Output>,
general_fault: PinDriver<'a, esp_idf_hal::gpio::Gpio13, esp_idf_hal::gpio::Output>,
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pub wifi_driver: EspWifi<'a>,
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one_wire_bus: OneWire<PinDriver<'a, Gpio4, esp_idf_hal::gpio::InputOutput>>,
}
impl PlantCtrlBoardInteraction for PlantCtrlBoard<'_> {
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fn battery_state(&mut self) -> Result<BatteryState> {
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todo!()
}
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fn is_day(&self) -> bool {
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return self.solar_is_day.get_level().into();
}
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fn water_temperature_c(&mut self) -> Result<f32> {
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let mut delay = Delay::new_default();
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self.one_wire_bus
.reset(&mut delay)
.map_err(|err| -> anyhow::Error { anyhow!("Missing attribute: {:?}", err) })?;
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let first = self.one_wire_bus.devices(false, &mut delay).next();
if first.is_none() {
bail!("Not found any one wire Ds18b20");
}
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let device_address = first
.unwrap()
.map_err(|err| -> anyhow::Error { anyhow!("Missing attribute: {:?}", err) })?;
let water_temp_sensor = Ds18b20::new::<EspError>(device_address)
.map_err(|err| -> anyhow::Error { anyhow!("Missing attribute: {:?}", err) })?;
water_temp_sensor
.start_temp_measurement(&mut self.one_wire_bus, &mut delay)
.map_err(|err| -> anyhow::Error { anyhow!("Missing attribute: {:?}", err) })?;
ds18b20::Resolution::Bits12.delay_for_measurement_time(&mut delay);
let sensor_data = water_temp_sensor
.read_data(&mut self.one_wire_bus, &mut delay)
.map_err(|err| -> anyhow::Error { anyhow!("Missing attribute: {:?}", err) })?;
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if sensor_data.temperature == 85_f32 {
bail!("Ds18b20 dummy temperature returned");
}
return Ok(sensor_data.temperature);
}
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fn tank_sensor_mv(&mut self) -> Result<u16> {
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let delay = Delay::new_default();
self.tank_power.set_high()?;
//let stabilize
delay.delay_ms(100);
let value = self.tank_driver.read(&mut self.tank_channel)?;
self.tank_power.set_low()?;
return Ok(value);
}
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fn set_low_voltage_in_cycle(&mut self) {
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*self.low_voltage_detected.get_mut().unwrap() = true;
}
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fn clear_low_voltage_in_cycle(&mut self) {
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*self.low_voltage_detected.get_mut().unwrap() = false;
}
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fn light(&mut self, enable: bool) -> Result<()> {
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self.light.set_state(enable.into())?;
Ok(())
}
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fn pump(&self, plant: usize, enable: bool) -> Result<()> {
let index = plant * PINS_PER_PLANT + PLANT_PUMP_OFFSET;
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//currently infailable error, keep for future as result anyway
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//self.shift_register.decompose()[index].set_state(enable.into()).unwrap();
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Ok(())
}
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fn last_pump_time(&self, plant: usize) -> Result<chrono::DateTime<Utc>> {
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let ts = unsafe { LAST_WATERING_TIMESTAMP }[plant];
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let timestamp = NaiveDateTime::from_timestamp_millis(ts)
.ok_or(anyhow!("could not convert timestamp"))?;
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return Ok(DateTime::<Utc>::from_naive_utc_and_offset(timestamp, Utc));
}
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fn store_last_pump_time(&mut self, plant: usize, time: chrono::DateTime<Utc>) {
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self.last_watering_timestamp.get_mut().unwrap()[plant] = time.timestamp_millis();
}
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fn store_consecutive_pump_count(&mut self, plant: usize, count: u32) {
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self.consecutive_watering_plant.get_mut().unwrap()[plant] = count;
}
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fn consecutive_pump_count(&mut self, plant: usize) -> u32 {
return self.consecutive_watering_plant.get_mut().unwrap()[plant];
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}
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fn fault(&self, plant: usize, enable: bool) {
let index = plant * PINS_PER_PLANT + PLANT_FAULT_OFFSET;
//self.shift_register.decompose()[index].set_state(enable.into()).unwrap()
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}
fn low_voltage_in_cycle(&mut self) -> bool {
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return *self.low_voltage_detected.get_mut().unwrap();
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}
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fn any_pump(&mut self, enable: bool) -> Result<()> {
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return Ok(self.main_pump.set_state(enable.into()).unwrap());
}
fn time(&mut self) -> Result<chrono::DateTime<Utc>> {
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let time = EspSystemTime {}.now().as_millis();
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let smaller_time = time as i64;
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let local_time = NaiveDateTime::from_timestamp_millis(smaller_time)
.ok_or(anyhow!("could not convert timestamp"))?;
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return Ok(local_time.and_utc());
}
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fn sntp(&mut self, max_wait_ms: u32) -> Result<chrono::DateTime<Utc>> {
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let sntp = sntp::EspSntp::new_default()?;
let mut counter = 0;
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while sntp.get_sync_status() != SyncStatus::Completed {
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let delay = Delay::new_default();
delay.delay_ms(100);
counter += 100;
if counter > max_wait_ms {
bail!("Reached sntp timeout, aborting")
}
}
return self.time();
}
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fn measure_moisture_hz(&self, plant: usize, sensor: Sensor) -> Result<i32> {
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self.signal_counter.counter_pause()?;
self.signal_counter.counter_clear()?;
//
let offset = match sensor {
Sensor::A => PLANT_MOIST_A_OFFSET,
Sensor::B => PLANT_MOIST_B_OFFSET,
Sensor::PUMP => PLANT_MOIST_PUMP_OFFSET,
};
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let index = plant * PINS_PER_PLANT + offset;
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let delay = Delay::new_default();
let measurement = 100;
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let factor = 1000 / 100;
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//self.shift_register.decompose()[index].set_high().unwrap();
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//give some time to stabilize
delay.delay_ms(10);
self.signal_counter.counter_resume()?;
delay.delay_ms(measurement);
self.signal_counter.counter_pause()?;
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//self.shift_register.decompose()[index].set_low().unwrap();
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let unscaled = self.signal_counter.get_counter_value()? as i32;
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let hz = unscaled * factor;
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println!("Measuring {:?} @ {} with {}", sensor, plant, hz);
return Ok(hz);
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}
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fn general_fault(&mut self, enable: bool) {
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self.general_fault.set_state(enable.into()).unwrap();
}
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fn wifi_ap(&mut self) -> Result<()> {
let apconfig = AccessPointConfiguration {
ssid: "PlantCtrl".into(),
auth_method: AuthMethod::None,
ssid_hidden: false,
..Default::default()
};
let clientconfig = ClientConfiguration::default();
self.wifi_driver.set_configuration(&Configuration::Mixed(clientconfig, apconfig))?;
self.wifi_driver.start()?;
Ok(())
}
fn wifi(&mut self, ssid: &str, password: Option<&str>, max_wait: u32) -> Result<()> {
match password {
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Some(pw) => {
//TODO expect error due to invalid pw or similar! //call this during configuration and check if works, revert to config mode if not
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self.wifi_driver.set_configuration(&Configuration::Client(
ClientConfiguration {
ssid: ssid.into(),
password: pw.into(),
..Default::default()
},
))?;
}
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None => {
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self.wifi_driver
.set_configuration(&Configuration::Client(ClientConfiguration {
ssid: ssid.into(),
auth_method: AuthMethod::None,
..Default::default()
}))
.unwrap();
}
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}
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self.wifi_driver.start()?;
self.wifi_driver.connect()?;
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let delay = Delay::new_default();
let mut counter = 0_u32;
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while !self.wifi_driver.is_connected()? {
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println!("Waiting for station connection");
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//TODO blink status?
delay.delay_ms(250);
counter += 250;
if counter > max_wait {
//ignore these errors, wifi will not be used this
self.wifi_driver.disconnect().unwrap_or(());
self.wifi_driver.stop().unwrap_or(());
bail!("Did not manage wifi connection within timeout");
}
}
println!("Should be connected now");
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while self.wifi_driver.is_up().unwrap() == false {
println!("Waiting for network being up");
delay.delay_ms(250);
counter += 250;
if counter > max_wait {
//ignore these errors, wifi will not be used this
self.wifi_driver.disconnect().unwrap_or(());
self.wifi_driver.stop().unwrap_or(());
bail!("Did not manage wifi connection within timeout");
}
}
//update freertos registers ;)
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let address = self.wifi_driver.sta_netif().get_ip_info().unwrap();
println!("IP info: {:?}", address);
return Ok(());
}
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fn mountFileSystem(&mut self) -> Result<()> {
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let base_path = CString::new("/spiffs")?;
let storage = CString::new(SPIFFS_PARTITION_NAME)?;
let conf = esp_idf_sys::esp_vfs_spiffs_conf_t {
base_path: base_path.as_ptr(),
partition_label: storage.as_ptr(),
max_files: 2,
format_if_mount_failed: true,
};
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unsafe {
esp_idf_sys::esp!(esp_idf_sys::esp_vfs_spiffs_register(&conf))?;
Ok(())
}
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}
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fn fileSystemSize(&mut self) -> Result<FileSystemSizeInfo> {
let storage = CString::new(SPIFFS_PARTITION_NAME)?;
let mut total_size = 0;
let mut used_size = 0;
unsafe {
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esp_idf_sys::esp!(esp_idf_sys::esp_spiffs_info(
storage.as_ptr(),
&mut total_size,
&mut used_size
))?;
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}
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return Ok(FileSystemSizeInfo {
total_size,
used_size,
free_size: total_size - used_size,
});
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}
fn is_config_reset(&mut self) -> bool {
return self.boot_button.get_level() == Level::Low;
}
fn remove_configs(&mut self) -> Result<()> {
let wifi_config = Path::new(WIFI_CONFIG_FILE);
if wifi_config.exists() {
println!("Removing wifi config");
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std::fs::remove_file(wifi_config)?;
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}
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let config = Path::new(CONFIG_FILE);
if config.exists() {
println!("Removing config");
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std::fs::remove_file(config)?;
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}
Ok(())
}
fn get_wifi(&mut self) -> Result<config::WifiConfig> {
let cfg = File::open(WIFI_CONFIG_FILE)?;
let config: WifiConfig = serde_json::from_reader(cfg)?;
return Ok(config);
}
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fn set_wifi(&mut self, wifi: &WifiConfig) -> Result<()> {
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let mut cfg = File::create(WIFI_CONFIG_FILE)?;
serde_json::to_writer(&mut cfg, &wifi)?;
println!("Wrote wifi config {}", wifi);
return Ok(());
}
fn get_config(&mut self) -> Result<config::Config> {
let mut cfg = File::open(CONFIG_FILE)?;
let mut data: [u8; 512] = [0; 512];
let read = cfg.read(&mut data)?;
println!("Read file {}", from_utf8(&data[0..read])?);
bail!("todo")
}
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fn wifi_scan(&mut self) -> Result<Vec<AccessPointInfo>> {
for i in 1..11 {
println!("Scanning channel {}", i);
self.wifi_driver.start_scan(&ScanConfig{
scan_type : ScanType::Passive(Duration::from_secs(1)),
show_hidden: false,
channel: Some(i),
..Default::default()
}, true)?;
let sr = self.wifi_driver.get_scan_result()?;
for r in sr.iter(){
println!("Found wifi {}", r.ssid);
}
}
return bail!("dummy");
}
}