abhas
/
esphome-xiaomi_bslamp2


								#pragma once


								namespace esphome {

								namespace yeelight {

								namespace bs2 {


								    /// This is an interface definition that is used to extend the

								    /// YeelightBS2LightOutput class with methods to access properties

								    /// of an active LightTranformer from the TransitionHandler class.

								    ///

								    /// The transformer is protected in the light output class, making

								    /// it impossible to access these properties directly from the

								    /// light output class.

								    class LightStateTransformerInspector {

								    public:

								        virtual bool is_active() = 0;

								        virtual bool is_transition() = 0;

								        virtual light::LightColorValues get_end_values() = 0;

								        virtual float get_progress() = 0;

								    };


								    /// This class is used to handle color transition requirements.

								    ///

								    /// When using the default ESPHome logic, transitioning is done by

								    /// transitioning all light properties linearly from the original

								    /// values to the new values, and letting the light output object

								    /// translate these properties into light outputs on every step of the

								    /// way. While this does work, it does not work nicely.

								    ///

								    /// For example, when transitioning from warm to cold white light,

								    /// the color temperature would be transitioned from the old value to

								    /// the new value. While doing so, the transition hits the middle

								    /// white light setting, which shows up as a bright flash in the

								    /// middle of the transition. The original firmware however, shows a

								    /// smooth transition from warm to cold white light, without any flash.

								    ///

								    /// This class handles transitions by not varying the light properties

								    /// over time, but by transitioning the LEDC duty cycle output levels

								    /// over time. This matches the behavior of the original firmware.

								    class TransitionHandler : public GPIOOutputs {

								    public:

								        TransitionHandler(LightStateTransformerInspector *inspector) : transformer_(inspector) {}


								        bool set_light_color_values(light::LightColorValues values) {

								            if (!light_state_has_active_transition_()) {

								                // Remember the last active light color values. When a transition

								                // is detected, use these as the starting point. It is not possible

								                // to use the current values at that point, because the transition

								                // is already in progress by the time the transition is detected.

								                start_values = values;


								                active_ = false;

								                return false;

								            }


								            // When a fresh transition is started, then compute the GPIO outputs

								            // to use for both the start and end point. This transition handler

								            // will then transition linearly between these two.

								            if (is_fresh_transition_()) {

								                start_->set_light_color_values(start_values);

								                end_->set_light_color_values(transformer_->get_end_values());

								                active_ = true;

								            }

								            // When a transition is modified, then use the current GPIO outputs

								            // as the new starting point.

								            else if (is_modified_transition_()) {

								                this->copy_to(start_);

								                end_->set_light_color_values(transformer_->get_end_values());

								            }


								            // Determine the required GPIO outputs for the current transition progress.

								            progress_ = transformer_->get_progress();

								            auto smoothed = light::LightTransitionTransformer::smoothed_progress(progress_);

								            red = esphome::lerp(smoothed, start_->red, end_->red);

								            green = esphome::lerp(smoothed, start_->green, end_->green);

								            blue = esphome::lerp(smoothed, start_->blue, end_->blue);

								            white = esphome::lerp(smoothed, start_->white, end_->white);


								            return true;

								        }


								    protected:

								        bool active_ = false;

								        float progress_ = 0.0f;

								        LightStateTransformerInspector *transformer_;

								        light::LightColorValues start_values;

								        GPIOOutputs *start_ = new ColorTranslator();

								        GPIOOutputs *end_ = new ColorTranslator();


								        /// Checks if the LightState object currently has an active LightTransformer.

								        bool light_state_has_active_transition_() {

								            if (!transformer_->is_active())

								                return false;

								            if (!transformer_->is_transition())

								                return false;

								            return true;

								        }


								        /// Checks if a fresh transitioning is started.

								        /// A transitioning is fresh when no existing transition is active.

								        bool is_fresh_transition_() {

								            return active_ == false;

								        }


								        /// Checks if a new end state is set, while an existing transition

								        /// is active. This might be detected in two ways:

								        /// - the end color has been updated

								        /// - the progress has been reverted

								        bool is_modified_transition_() {

								            auto new_end_values = transformer_->get_end_values();

								            auto new_progress = transformer_->get_progress();

								            return new_end_values != end_->values || new_progress < progress_;

								        }

								    };


								    /// An implementation of the LightOutput interface for the Yeelight

								    /// Bedside Lamp 2. The function of this class is to translate a

								    /// required light state into actual physicial GPIO output signals

								    /// to drive the device's LED circuitry.

								    class YeelightBS2LightOutput : public Component, public light::LightOutput {

								    public:

								        /// Set the LEDC output for the red LED circuitry channel.

								        void set_red_output(ledc::LEDCOutput *red) {

								            red_ = red;

								        }


								        /// Set the LEDC output for the green LED circuitry channel.

								        void set_green_output(ledc::LEDCOutput *green) {

								            green_ = green;

								        }


								        /// Set the LEDC output for the blue LED circuitry channel.

								        void set_blue_output(ledc::LEDCOutput *blue) {

								            blue_ = blue;

								        }


								        /// Set the LEDC output for the white LED circuitry channel.

								        void set_white_output(ledc::LEDCOutput *white) {

								            white_ = white;

								        }


								        /// Set the first GPIO binary output, used as internal master

								        /// switch for the LED light circuitry.

								        void set_master1_output(gpio::GPIOBinaryOutput *master1) {

								            master1_ = master1;

								        }


								        /// Set the second GPIO binary output, used as internal master

								        /// switch for the LED light circuitry.

								        void set_master2_output(gpio::GPIOBinaryOutput *master2) {

								            master2_ = master2;

								        }


								        /// Returns a LightTraits object, which is used to explain to the

								        /// outside world (e.g. Home Assistant) what features are supported

								        /// by this device.

								        light::LightTraits get_traits() override

								        {

								            auto traits = light::LightTraits();

								            traits.set_supports_rgb(true);

								            traits.set_supports_color_temperature(true);

								            traits.set_supports_brightness(true);

								            traits.set_supports_rgb_white_value(false);

								            traits.set_supports_color_interlock(true);

								            traits.set_min_mireds(MIRED_MIN);

								            traits.set_max_mireds(MIRED_MAX);

								            return traits;

								        }


								        /// Applies a requested light state to the physicial GPIO outputs.

								        void write_state(light::LightState *state)

								        {

								            auto values = state->current_values;


								            // Turn off the light when its state is 'off'.

								            if (values.get_state() == 0)

								            {

								                ESP_LOGD(TAG, "Turn off the light");

								                red_->set_level(1.0f);

								                green_->set_level(1.0f);

								                blue_->set_level(1.0f);

								                white_->set_level(0.0f);

								                master2_->turn_off();

								                master1_->turn_off();

								                return;

								            }


								            GPIOOutputs *delegate;

								            if (transition_handler_->set_light_color_values(values)) {

								                transition_handler_->log("TRANSITION");

								                delegate = transition_handler_;

								            } else {

								                instant_handler_->set_light_color_values(values);

								                instant_handler_->log("INSTANT");

								                delegate = instant_handler_;

								            }


								            delegate->set_light_color_values(values);

								            master2_->turn_on();

								            master1_->turn_on();

								            red_->set_level(delegate->red);

								            green_->set_level(delegate->green);

								            blue_->set_level(delegate->blue);

								            white_->set_level(delegate->white);

								        }


								    protected:

								        ledc::LEDCOutput *red_;

								        ledc::LEDCOutput *green_;

								        ledc::LEDCOutput *blue_;

								        ledc::LEDCOutput *white_;

								        esphome::gpio::GPIOBinaryOutput *master1_;

								        esphome::gpio::GPIOBinaryOutput *master2_;

								        GPIOOutputs *transition_handler_;

								        GPIOOutputs *instant_handler_ = new ColorTranslator();


								        friend class YeelightBS2LightState;


								        /// Called by the YeelightBS2LightState class, to set the object that

								        /// can be used to access protected data from the light state object.

								        void set_transformer_inspector(LightStateTransformerInspector *exposer) {

								            transition_handler_ = new TransitionHandler(exposer);

								        }

								    };


								    class YeelightBS2LightState : public light::LightState, public LightStateTransformerInspector

								    {

								    public:

								        YeelightBS2LightState(const std::string &name, YeelightBS2LightOutput *output) : light::LightState(name, output) {

								            output->set_transformer_inspector(this);

								        }


								        bool is_active() {

								            return this->transformer_ != nullptr;

								        }


								        bool is_transition() {

								            return this->transformer_->is_transition();

								        }


								        light::LightColorValues get_end_values() {

								            return this->transformer_->get_end_values();

								        }


								        float get_progress() {

								            return this->transformer_->get_progress();

								        }

								    };


								} // namespace bs2

								} // namespace yeelight

								} // namespace esphome