mh
/
mhsw-espurna

/*

LED MODULE
Copyright (C) 2016-2019 by Xose Pérez <xose dot perez at gmail dot com>
*/
#include "led.h"

#if LED_SUPPORT

#include <algorithm>

#include "broker.h"
#include "mqtt.h"
#include "relay.h"
#include "rpc.h"
#include "ws.h"

#include "led_pattern.h"
#include "led_config.h"

// LED helper class

led_t::led_t(unsigned char pin, bool inverse, unsigned char mode, unsigned char relayID) :    pin(pin),    inverse(inverse),    mode(mode),    relayID(relayID){    if (pin != GPIO_NONE) {        pinMode(pin, OUTPUT);        status(false);    }}
bool led_t::status() {    bool result = digitalRead(pin);    return inverse ? !result : result;}
bool led_t::status(bool new_status) {    digitalWrite(pin, inverse ? !new_status : new_status);    return new_status;}
bool led_t::toggle() {    return status(!status());}
led_delay_t::led_delay_t(unsigned long on_ms, unsigned long off_ms, unsigned char repeats) :    type(repeats ? led_delay_mode_t::Finite : led_delay_mode_t::Infinite),    on(microsecondsToClockCycles(on_ms * 1000)),    off(microsecondsToClockCycles(off_ms * 1000)),    repeats(repeats ? repeats : 0){}
led_delay_t::led_delay_t(unsigned long on_ms, unsigned long off_ms) :    led_delay_t(on_ms, off_ms, 0){}
led_pattern_t::led_pattern_t(const std::vector<led_delay_t>& delays) :    delays(delays),    queue(),    clock_last(ESP.getCycleCount()),    clock_delay(delays.size() ? delays.back().on : 0){}
bool led_pattern_t::started() {    return queue.size() > 0;}
bool led_pattern_t::ready() {    return delays.size() > 0;}
void led_pattern_t::start() {    clock_last = ESP.getCycleCount();    clock_delay = 0;    queue = {        delays.rbegin(), delays.rend()    };}
void led_pattern_t::stop() {    queue.clear();}
// For relay-based modes
bool _led_update = false;
// For network-based modes, cycle ON & OFF (time in milliseconds)
// XXX: internals convert these to clock cycles, delay cannot be longer than 25000 / 50000 ms
const led_delay_t _ledDelays[] {    {100, 100},   // Autoconfig
    {100, 4900},  // Connected
    {4900, 100},  // Connected (inverse)
    {100, 900},   // Config / AP
    {900, 100},   // Config / AP (inverse)
    {500, 500}    // Idle
};
std::vector<led_t> _leds;
// -----------------------------------------------------------------------------

unsigned char ledCount() {    return _leds.size();}
bool _ledStatus(led_t& led) {    return led.pattern.started() || led.status();}
bool _ledStatus(led_t& led, bool status) {    bool result = false;
    // when led has pattern, status depends on whether it's running
    if (led.pattern.ready()) {        if (status) {            if (!led.pattern.started()) {                led.pattern.start();            }            result = true;        } else {            led.pattern.stop();            led.status(false);            result = false;        }    // if not, simply proxy status directly to the led pin
    } else {        result = led.status(status);    }
    return result;}
bool _ledToggle(led_t& led) {    return _ledStatus(led, !_ledStatus(led));}
bool ledStatus(unsigned char id, bool status) {    if (id >= ledCount()) return false;    return _ledStatus(_leds[id], status);}
bool ledStatus(unsigned char id) {    if (id >= ledCount()) return false;    return _ledStatus(_leds[id]);}
const led_delay_t& _ledModeToDelay(LedMode mode) {    static_assert(        (sizeof(_ledDelays) / sizeof(_ledDelays[0])) <= static_cast<int>(LedMode::None),        "LedMode mapping out-of-bounds"    );    return _ledDelays[static_cast<int>(mode)];}
void _ledPattern(led_t& led) {    const auto clock_current = ESP.getCycleCount();    if (clock_current - led.pattern.clock_last >= led.pattern.clock_delay) {        const bool status = led.toggle();        auto& current = led.pattern.queue.back();        switch (current.type) {            case led_delay_mode_t::Finite:                if (status && !--current.repeats) {                    led.pattern.queue.pop_back();                    if (!led.pattern.queue.size()) {                        led.status(false);                        return;                    }                }                break;            case led_delay_mode_t::Infinite:            case led_delay_mode_t::None:            default:                break;        }
        led.pattern.clock_delay = status ? current.on : current.off;        led.pattern.clock_last = ESP.getCycleCount();    }}
void _ledBlink(led_t& led, const led_delay_t& delays) {    static auto clock_last = ESP.getCycleCount();    static auto delay_for = delays.on;
    const auto clock_current = ESP.getCycleCount();    if (clock_current - clock_last >= delay_for) {        delay_for = led.toggle() ? delays.on : delays.off;        clock_last = clock_current;    }}
inline void _ledBlink(led_t& led, const LedMode mode) {    _ledBlink(led, _ledModeToDelay(mode));}
#if WEB_SUPPORT

bool _ledWebSocketOnKeyCheck(const char * key, JsonVariant& value) {    return (strncmp(key, "led", 3) == 0);}
void _ledWebSocketOnVisible(JsonObject& root) {    if (ledCount() > 0) {        root["ledVisible"] = 1;    }}
void _ledWebSocketOnConnected(JsonObject& root) {    if (!ledCount()) return;    JsonObject& module = root.createNestedObject("led");
    JsonArray& schema = module.createNestedArray("schema");    schema.add("GPIO");    schema.add("Inv");    schema.add("Mode");    schema.add("Relay");
    JsonArray& leds = module.createNestedArray("list");
    for (unsigned char index = 0; index < ledCount(); ++index) {        JsonArray& led = leds.createNestedArray();        led.add(getSetting({"ledGPIO", index}, _ledPin(index)));        led.add(static_cast<int>(getSetting({"ledInv", index}, _ledInverse(index))));        led.add(getSetting({"ledMode", index}, _ledMode(index)));        led.add(getSetting({"ledRelay", index}, _ledRelay(index)));    }}
#endif

void _ledBrokerCallback(const String& topic, unsigned char, unsigned int) {
    // Only process status messages for switches
    if (topic.equals(MQTT_TOPIC_RELAY)) {        ledUpdate(true);    }
}
#if MQTT_SUPPORT
void _ledMQTTCallback(unsigned int type, const char * topic, const char * payload) {
    if (type == MQTT_CONNECT_EVENT) {        char buffer[strlen(MQTT_TOPIC_LED) + 3];        snprintf_P(buffer, sizeof(buffer), PSTR("%s/+"), MQTT_TOPIC_LED);        mqttSubscribe(buffer);    }
    if (type == MQTT_MESSAGE_EVENT) {
        // Only want `led/+/<MQTT_SETTER>`
        const String magnitude = mqttMagnitude((char *) topic);        if (!magnitude.startsWith(MQTT_TOPIC_LED)) return;
        // Get led ID from after the slash when t is `led/<LED_ID>`
        unsigned int ledID = magnitude.substring(strlen(MQTT_TOPIC_LED) + 1).toInt();        if (ledID >= ledCount()) {            DEBUG_MSG_P(PSTR("[LED] Wrong ledID (%d)\n"), ledID);            return;        }
        // Check if LED is managed
        if (_leds[ledID].mode != LED_MODE_MANUAL) return;
        // Get value based on rpc payload logic (see rpc.ino)
        const auto value = rpcParsePayload(payload);        switch (value) {            case PayloadStatus::On:            case PayloadStatus::Off:                _ledStatus(_leds[ledID], (value == PayloadStatus::On));                break;            case PayloadStatus::Toggle:                _ledToggle(_leds[ledID]);                break;            case PayloadStatus::Unknown:            default:                _ledLoadPattern(_leds[ledID], payload);                _ledStatus(_leds[ledID], true);                break;        }
    }
}#endif

void _ledConfigure() {    for (unsigned char id = 0; id < _leds.size(); ++id) {        _leds[id].mode = getSetting({"ledMode", id}, _ledMode(id));        _leds[id].relayID = getSetting({"ledRelay", id}, _ledRelay(id));        _leds[id].pattern.stop();        _ledLoadPattern(_leds[id], getSetting({"ledPattern", id}).c_str());    }    _led_update = true;}
// -----------------------------------------------------------------------------

void ledUpdate(bool do_update) {    _led_update = do_update;}
void ledLoop() {
    const auto wifi_state = wifiState();
    for (auto& led : _leds) {
        switch (led.mode) {            case LED_MODE_WIFI:                if ((wifi_state & WIFI_STATE_WPS) || (wifi_state & WIFI_STATE_SMARTCONFIG)) {                    _ledBlink(led, LedMode::NetworkAutoconfig);                } else if (wifi_state & WIFI_STATE_STA) {                    _ledBlink(led, LedMode::NetworkConnected);                } else if (wifi_state & WIFI_STATE_AP) {                    _ledBlink(led, LedMode::NetworkConfig);                } else {                    _ledBlink(led, LedMode::NetworkIdle);                }                break;
        #if RELAY_SUPPORT

            case LED_MODE_FINDME_WIFI:                if ((wifi_state & WIFI_STATE_WPS) || (wifi_state & WIFI_STATE_SMARTCONFIG)) {                    _ledBlink(led, LedMode::NetworkAutoconfig);                } else if (wifi_state & WIFI_STATE_STA) {                    if (relayStatus(led.relayID)) {                        _ledBlink(led, LedMode::NetworkConnected);                    } else {                        _ledBlink(led, LedMode::NetworkConnectedInverse);                    }                } else if (wifi_state & WIFI_STATE_AP) {                    if (relayStatus(led.relayID)) {                        _ledBlink(led, LedMode::NetworkConfig);                    } else {                        _ledBlink(led, LedMode::NetworkConfigInverse);                    }                } else {                    _ledBlink(led, LedMode::NetworkIdle);                }                break;
            case LED_MODE_RELAY_WIFI:                if ((wifi_state & WIFI_STATE_WPS) || (wifi_state & WIFI_STATE_SMARTCONFIG)) {                    _ledBlink(led, LedMode::NetworkAutoconfig);                } else if (wifi_state & WIFI_STATE_STA) {                    if (relayStatus(led.relayID)) {                        _ledBlink(led, LedMode::NetworkConnected);                    } else {                        _ledBlink(led, LedMode::NetworkConnectedInverse);                    }                } else if (wifi_state & WIFI_STATE_AP) {                    if (relayStatus(led.relayID)) {                        _ledBlink(led, LedMode::NetworkConfig);                    } else {                        _ledBlink(led, LedMode::NetworkConfigInverse);                    }                } else {                    _ledBlink(led, LedMode::NetworkIdle);                }                break;
            case LED_MODE_FOLLOW:                if (!_led_update) break;                _ledStatus(led, relayStatus(led.relayID));                break;
            case LED_MODE_FOLLOW_INVERSE:                if (!_led_update) break;                led.status(!relayStatus(led.relayID));                _ledStatus(led, !relayStatus(led.relayID));                break;
            case LED_MODE_FINDME: {                if (!_led_update) break;                bool status = true;                for (unsigned char relayID = 0; relayID < relayCount(); ++relayID) {                    if (relayStatus(relayID)) {                        status = false;                        break;                    }                }                _ledStatus(led, status);                break;            }
            case LED_MODE_RELAY: {                if (!_led_update) break;                bool status = false;                for (unsigned char relayID = 0; relayID < relayCount(); ++relayID) {                    if (relayStatus(relayID)) {                        status = true;                        break;                    }                }                _ledStatus(led, status);                break;            }
        #endif // RELAY_SUPPORT == 1

            case LED_MODE_ON:                if (!_led_update) break;                _ledStatus(led, true);                break;
            case LED_MODE_OFF:                if (!_led_update) break;                _ledStatus(led, false);                break;
        }
        if (led.pattern.started()) {            _ledPattern(led);            continue;        }
    }
    _led_update = false;
}
void ledSetup() {
    size_t leds = 0;
    #if LED1_PIN != GPIO_NONE
        ++leds;    #endif
    #if LED2_PIN != GPIO_NONE
        ++leds;    #endif
    #if LED3_PIN != GPIO_NONE
        ++leds;    #endif
    #if LED4_PIN != GPIO_NONE
        ++leds;    #endif
    #if LED5_PIN != GPIO_NONE
        ++leds;    #endif
    #if LED6_PIN != GPIO_NONE
        ++leds;    #endif
    #if LED7_PIN != GPIO_NONE
        ++leds;    #endif
    #if LED8_PIN != GPIO_NONE
        ++leds;    #endif

    _leds.reserve(leds);
    for (unsigned char index=0; index < LedsMax; ++index) {        const auto pin = getSetting({"ledGPIO", index}, _ledPin(index));        if (!gpioValid(pin)) {            break;        }        _leds.emplace_back(            pin,            getSetting({"ledInv", index}, _ledInverse(index)),            getSetting({"ledMode", index}, _ledMode(index)),            getSetting({"ledRelay", index}, _ledRelay(index))        );    }
    _led_update = true;
    #if MQTT_SUPPORT
        mqttRegister(_ledMQTTCallback);    #endif

    #if WEB_SUPPORT
        wsRegister()            .onVisible(_ledWebSocketOnVisible)            .onConnected(_ledWebSocketOnConnected)            .onKeyCheck(_ledWebSocketOnKeyCheck);    #endif

    StatusBroker::Register(_ledBrokerCallback);
    DEBUG_MSG_P(PSTR("[LED] Number of leds: %d\n"), _leds.size());
    // Main callbacks
    espurnaRegisterLoop(ledLoop);    espurnaRegisterReload(_ledConfigure);
}

#endif // LED_SUPPORT