2026-02-18 15:12:29 +01:00
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#include "HalPowerManager.h"
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#include <Logging.h>
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#include <WiFi.h>
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#include <esp_sleep.h>
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#include <cassert>
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#include "HalGPIO.h"
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HalPowerManager powerManager; // Singleton instance
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void HalPowerManager::begin() {
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2026-04-04 09:25:43 -06:00
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if (gpio.deviceIsX3()) {
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// X3 uses an I2C fuel gauge for battery monitoring.
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// I2C init must come AFTER gpio.begin() so early hardware detection/probes are finished.
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Wire.begin(X3_I2C_SDA, X3_I2C_SCL, X3_I2C_FREQ);
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Wire.setTimeOut(4);
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_batteryUseI2C = true;
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} else {
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pinMode(BAT_GPIO0, INPUT);
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}
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2026-02-18 15:12:29 +01:00
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normalFreq = getCpuFrequencyMhz();
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modeMutex = xSemaphoreCreateMutex();
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assert(modeMutex != nullptr);
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}
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void HalPowerManager::setPowerSaving(bool enabled) {
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if (normalFreq <= 0) {
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return; // invalid state
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}
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auto wifiMode = WiFi.getMode();
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if (wifiMode != WIFI_MODE_NULL) {
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// Wifi is active, force disabling power saving
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enabled = false;
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}
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// Note: We don't use mutex here to avoid too much overhead,
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// it's not very important if we read a slightly stale value for currentLockMode
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const LockMode mode = currentLockMode;
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if (mode == None && enabled && !isLowPower) {
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LOG_DBG("PWR", "Going to low-power mode");
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if (!setCpuFrequencyMhz(LOW_POWER_FREQ)) {
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LOG_DBG("PWR", "Failed to set CPU frequency = %d MHz", LOW_POWER_FREQ);
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return;
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}
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isLowPower = true;
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} else if ((!enabled || mode != None) && isLowPower) {
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LOG_DBG("PWR", "Restoring normal CPU frequency");
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if (!setCpuFrequencyMhz(normalFreq)) {
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LOG_DBG("PWR", "Failed to set CPU frequency = %d MHz", normalFreq);
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return;
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}
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isLowPower = false;
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}
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// Otherwise, no change needed
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}
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void HalPowerManager::startDeepSleep(HalGPIO& gpio) const {
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// Ensure that the power button has been released to avoid immediately turning back on if you're holding it
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while (gpio.isPressed(HalGPIO::BTN_POWER)) {
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delay(50);
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gpio.update();
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}
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2026-03-21 19:35:38 +01:00
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// Pre-sleep routines from the original firmware
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// GPIO13 is connected to battery latch MOSFET, we need to make sure it's low during sleep
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// Note that this means the MCU will be completely powered off during sleep, including RTC
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constexpr gpio_num_t GPIO_SPIWP = GPIO_NUM_13;
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gpio_set_direction(GPIO_SPIWP, GPIO_MODE_OUTPUT);
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gpio_set_level(GPIO_SPIWP, 0);
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esp_sleep_config_gpio_isolate();
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gpio_deep_sleep_hold_en();
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gpio_hold_en(GPIO_SPIWP);
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pinMode(InputManager::POWER_BUTTON_PIN, INPUT_PULLUP);
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2026-02-18 15:12:29 +01:00
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// Arm the wakeup trigger *after* the button is released
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2026-03-21 19:35:38 +01:00
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// Note: this is only useful for waking up on USB power. On battery, the MCU will be completely powered off, so the
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// power button is hard-wired to briefly provide power to the MCU, waking it up regardless of the wakeup source
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// configuration
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2026-02-18 15:12:29 +01:00
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esp_deep_sleep_enable_gpio_wakeup(1ULL << InputManager::POWER_BUTTON_PIN, ESP_GPIO_WAKEUP_GPIO_LOW);
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// Enter Deep Sleep
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esp_deep_sleep_start();
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}
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2026-02-19 15:05:35 -08:00
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uint16_t HalPowerManager::getBatteryPercentage() const {
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2026-04-04 09:25:43 -06:00
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if (_batteryUseI2C) {
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const unsigned long now = millis();
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if (_batteryLastPollMs != 0 && (now - _batteryLastPollMs) < BATTERY_POLL_MS) {
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return _batteryCachedPercent;
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}
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// Read SOC directly from I2C fuel gauge (16-bit LE register).
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// On I2C error, keep last known value to avoid UI jitter/slowdowns.
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Wire.beginTransmission(I2C_ADDR_BQ27220);
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Wire.write(BQ27220_SOC_REG);
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if (Wire.endTransmission(false) != 0) {
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_batteryLastPollMs = now;
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return _batteryCachedPercent;
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}
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Wire.requestFrom(I2C_ADDR_BQ27220, (uint8_t)2);
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if (Wire.available() < 2) {
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_batteryLastPollMs = now;
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return _batteryCachedPercent;
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}
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const uint8_t lo = Wire.read();
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const uint8_t hi = Wire.read();
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const uint16_t soc = (hi << 8) | lo;
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_batteryCachedPercent = soc > 100 ? 100 : soc;
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_batteryLastPollMs = now;
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return _batteryCachedPercent;
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}
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2026-02-18 15:12:29 +01:00
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static const BatteryMonitor battery = BatteryMonitor(BAT_GPIO0);
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2026-04-16 01:28:43 -04:00
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// smooth the battery %.
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if (_batteryCachedPercent == 0) {
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_batteryCachedPercent = 10 * battery.readPercentage();
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} else {
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_batteryCachedPercent = (_batteryCachedPercent * 9 + battery.readPercentage() * 10) / 10;
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}
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return _batteryCachedPercent / 10;
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2026-02-18 15:12:29 +01:00
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}
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HalPowerManager::Lock::Lock() {
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xSemaphoreTake(powerManager.modeMutex, portMAX_DELAY);
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// Current limitation: only one lock at a time
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if (powerManager.currentLockMode != None) {
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LOG_ERR("PWR", "Lock already held, ignore");
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valid = false;
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} else {
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powerManager.currentLockMode = NormalSpeed;
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valid = true;
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}
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xSemaphoreGive(powerManager.modeMutex);
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if (valid) {
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// Immediately restore normal CPU frequency if currently in low-power mode
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powerManager.setPowerSaving(false);
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}
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}
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HalPowerManager::Lock::~Lock() {
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xSemaphoreTake(powerManager.modeMutex, portMAX_DELAY);
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if (valid) {
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powerManager.currentLockMode = None;
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}
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xSemaphoreGive(powerManager.modeMutex);
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}
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