esphome-dev/esphome/components/output/float_output.cpp

#include "float_output.h"
#include "esphome/core/log.h"
#include "esphome/core/helpers.h"

namespace esphome {
namespace output {

static const char *TAG = "output.float";

void FloatOutput::set_max_power(float max_power) {
  this->max_power_ = clamp(max_power, this->min_power_, 1.0f);  // Clamp to MIN>=MAX>=1.0
}

float FloatOutput::get_max_power() const { return this->max_power_; }

void FloatOutput::set_min_power(float min_power) {
  this->min_power_ = clamp(min_power, 0.0f, this->max_power_);  // Clamp to 0.0>=MIN>=MAX
}

float FloatOutput::get_min_power() const { return this->min_power_; }

void FloatOutput::set_level(float state) {
  state = clamp(state, 0.0f, 1.0f);

#ifdef USE_POWER_SUPPLY
  if (state > 0.0f) {  // ON
    if (this->power_supply_ != nullptr && !this->has_requested_high_power_) {
      this->power_supply_->request_high_power();
      this->has_requested_high_power_ = true;
    }
  } else {  // OFF
    if (this->power_supply_ != nullptr && this->has_requested_high_power_) {
      this->power_supply_->unrequest_high_power();
      this->has_requested_high_power_ = false;
    }
  }
#endif

  float adjusted_value = (state * (this->max_power_ - this->min_power_)) + this->min_power_;
  if (this->is_inverted())
    adjusted_value = 1.0f - adjusted_value;
  this->write_state(adjusted_value);
}

void FloatOutput::write_state(bool state) { this->set_level(state != this->inverted_ ? 1.0f : 0.0f); }

}  // namespace output
}  // namespace esphome