New component: ADE7880 voltage/current/power/energy sensor (esphome#5242

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CODEOWNERS

@@ -18,6 +18,7 @@ esphome/components/ac_dimmer/* @glmnet
 esphome/components/adc/* @esphome/core
 esphome/components/adc128s102/* @DeerMaximum
 esphome/components/addressable_light/* @justfalter
+esphome/components/ade7880/* @kpfleming
 esphome/components/ade7953/* @angelnu
 esphome/components/ade7953_i2c/* @angelnu
 esphome/components/ade7953_spi/* @angelnu

esphome/components/ade7880/__init__.py

@@ -0,0 +1 @@
+CODEOWNERS = ["@kpfleming"]

esphome/components/ade7880/ade7880.cpp

@@ -0,0 +1,302 @@
+// This component was developed using knowledge gathered by a number
+// of people who reverse-engineered the Shelly 3EM:
+//
+// @AndreKR on GitHub
+// Axel (@Axel830 on GitHub)
+// Marko (@goodkiller on GitHub)
+// Michaël Piron (@michaelpiron on GitHub)
+// Theo Arends (@arendst on GitHub)
+
+#include "ade7880.h"
+#include "ade7880_registers.h"
+#include "esphome/core/log.h"
+
+namespace esphome {
+namespace ade7880 {
+
+static const char *const TAG = "ade7880";
+
+void IRAM_ATTR ADE7880Store::gpio_intr(ADE7880Store *arg) { arg->reset_done = true; }
+
+void ADE7880::setup() {
+  if (this->irq0_pin_ != nullptr) {
+    this->irq0_pin_->setup();
+  }
+  this->irq1_pin_->setup();
+  if (this->reset_pin_ != nullptr) {
+    this->reset_pin_->setup();
+  }
+  this->store_.irq1_pin = this->irq1_pin_->to_isr();
+  this->irq1_pin_->attach_interrupt(ADE7880Store::gpio_intr, &this->store_, gpio::INTERRUPT_FALLING_EDGE);
+
+  // if IRQ1 is already asserted, the cause must be determined
+  if (this->irq1_pin_->digital_read() == 0) {
+    ESP_LOGD(TAG, "IRQ1 found asserted during setup()");
+    auto status1 = read_u32_register16_(STATUS1);
+    if ((status1 & ~STATUS1_RSTDONE) != 0) {
+      // not safe to proceed, must initiate reset
+      ESP_LOGD(TAG, "IRQ1 asserted for !RSTDONE, resetting device");
+      this->reset_device_();
+      return;
+    }
+    if ((status1 & STATUS1_RSTDONE) == STATUS1_RSTDONE) {
+      // safe to proceed, device has just completed reset cycle
+      ESP_LOGD(TAG, "Acknowledging RSTDONE");
+      this->write_u32_register16_(STATUS0, 0xFFFF);
+      this->write_u32_register16_(STATUS1, 0xFFFF);
+      this->init_device_();
+      return;
+    }
+  }
+
+  this->reset_device_();
+}
+
+void ADE7880::loop() {
+  // check for completion of a reset cycle
+  if (!this->store_.reset_done) {
+    return;
+  }
+
+  ESP_LOGD(TAG, "Acknowledging RSTDONE");
+  this->write_u32_register16_(STATUS0, 0xFFFF);
+  this->write_u32_register16_(STATUS1, 0xFFFF);
+  this->init_device_();
+  this->store_.reset_done = false;
+  this->store_.reset_pending = false;
+}
+
+template<typename F>
+void ADE7880::update_sensor_from_s24zp_register16_(sensor::Sensor *sensor, uint16_t a_register, F &&f) {
+  if (sensor == nullptr) {
+    return;
+  }
+
+  float val = this->read_s24zp_register16_(a_register);
+  sensor->publish_state(f(val));
+}
+
+template<typename F>
+void ADE7880::update_sensor_from_s16_register16_(sensor::Sensor *sensor, uint16_t a_register, F &&f) {
+  if (sensor == nullptr) {
+    return;
+  }
+
+  float val = this->read_s16_register16_(a_register);
+  sensor->publish_state(f(val));
+}
+
+template<typename F>
+void ADE7880::update_sensor_from_s32_register16_(sensor::Sensor *sensor, uint16_t a_register, F &&f) {
+  if (sensor == nullptr) {
+    return;
+  }
+
+  float val = this->read_s32_register16_(a_register);
+  sensor->publish_state(f(val));
+}
+
+void ADE7880::update() {
+  if (this->store_.reset_pending) {
+    return;
+  }
+
+  auto start = millis();
+
+  if (this->channel_n_ != nullptr) {
+    auto *chan = this->channel_n_;
+    this->update_sensor_from_s24zp_register16_(chan->current, NIRMS, [](float val) { return val / 100000.0f; });
+  }
+
+  if (this->channel_a_ != nullptr) {
+    auto *chan = this->channel_a_;
+    this->update_sensor_from_s24zp_register16_(chan->current, AIRMS, [](float val) { return val / 100000.0f; });
+    this->update_sensor_from_s24zp_register16_(chan->voltage, BVRMS, [](float val) { return val / 10000.0f; });
+    this->update_sensor_from_s24zp_register16_(chan->active_power, AWATT, [](float val) { return val / 100.0f; });
+    this->update_sensor_from_s24zp_register16_(chan->apparent_power, AVA, [](float val) { return val / 100.0f; });
+    this->update_sensor_from_s16_register16_(chan->power_factor, APF,
+                                             [](float val) { return std::abs(val / -327.68f); });
+    this->update_sensor_from_s32_register16_(chan->forward_active_energy, AFWATTHR, [&chan](float val) {
+      return chan->forward_active_energy_total += val / 14400.0f;
+    });
+    this->update_sensor_from_s32_register16_(chan->reverse_active_energy, AFWATTHR, [&chan](float val) {
+      return chan->reverse_active_energy_total += val / 14400.0f;
+    });
+  }
+
+  if (this->channel_b_ != nullptr) {
+    auto *chan = this->channel_b_;
+    this->update_sensor_from_s24zp_register16_(chan->current, BIRMS, [](float val) { return val / 100000.0f; });
+    this->update_sensor_from_s24zp_register16_(chan->voltage, BVRMS, [](float val) { return val / 10000.0f; });
+    this->update_sensor_from_s24zp_register16_(chan->active_power, BWATT, [](float val) { return val / 100.0f; });
+    this->update_sensor_from_s24zp_register16_(chan->apparent_power, BVA, [](float val) { return val / 100.0f; });
+    this->update_sensor_from_s16_register16_(chan->power_factor, BPF,
+                                             [](float val) { return std::abs(val / -327.68f); });
+    this->update_sensor_from_s32_register16_(chan->forward_active_energy, BFWATTHR, [&chan](float val) {
+      return chan->forward_active_energy_total += val / 14400.0f;
+    });
+    this->update_sensor_from_s32_register16_(chan->reverse_active_energy, BFWATTHR, [&chan](float val) {
+      return chan->reverse_active_energy_total += val / 14400.0f;
+    });
+  }
+
+  if (this->channel_c_ != nullptr) {
+    auto *chan = this->channel_c_;
+    this->update_sensor_from_s24zp_register16_(chan->current, CIRMS, [](float val) { return val / 100000.0f; });
+    this->update_sensor_from_s24zp_register16_(chan->voltage, CVRMS, [](float val) { return val / 10000.0f; });
+    this->update_sensor_from_s24zp_register16_(chan->active_power, CWATT, [](float val) { return val / 100.0f; });
+    this->update_sensor_from_s24zp_register16_(chan->apparent_power, CVA, [](float val) { return val / 100.0f; });
+    this->update_sensor_from_s16_register16_(chan->power_factor, CPF,
+                                             [](float val) { return std::abs(val / -327.68f); });
+    this->update_sensor_from_s32_register16_(chan->forward_active_energy, CFWATTHR, [&chan](float val) {
+      return chan->forward_active_energy_total += val / 14400.0f;
+    });
+    this->update_sensor_from_s32_register16_(chan->reverse_active_energy, CFWATTHR, [&chan](float val) {
+      return chan->reverse_active_energy_total += val / 14400.0f;
+    });
+  }
+
+  ESP_LOGD(TAG, "update took %u ms", millis() - start);
+}
+
+void ADE7880::dump_config() {
+  ESP_LOGCONFIG(TAG, "ADE7880:");
+  LOG_PIN("  IRQ0  Pin: ", this->irq0_pin_);
+  LOG_PIN("  IRQ1  Pin: ", this->irq1_pin_);
+  LOG_PIN("  RESET Pin: ", this->reset_pin_);
+  ESP_LOGCONFIG(TAG, "  Frequency: %.0f Hz", this->frequency_);
+
+  if (this->channel_a_ != nullptr) {
+    ESP_LOGCONFIG(TAG, "  Phase A:");
+    LOG_SENSOR("    ", "Current", this->channel_a_->current);
+    LOG_SENSOR("    ", "Voltage", this->channel_a_->voltage);
+    LOG_SENSOR("    ", "Active Power", this->channel_a_->active_power);
+    LOG_SENSOR("    ", "Apparent Power", this->channel_a_->apparent_power);
+    LOG_SENSOR("    ", "Power Factor", this->channel_a_->power_factor);
+    LOG_SENSOR("    ", "Forward Active Energy", this->channel_a_->forward_active_energy);
+    LOG_SENSOR("    ", "Reverse Active Energy", this->channel_a_->reverse_active_energy);
+    ESP_LOGCONFIG(TAG, "    Calibration:");
+    ESP_LOGCONFIG(TAG, "     Current: %u", this->channel_a_->current_gain_calibration);
+    ESP_LOGCONFIG(TAG, "     Voltage: %d", this->channel_a_->voltage_gain_calibration);
+    ESP_LOGCONFIG(TAG, "     Power: %d", this->channel_a_->power_gain_calibration);
+    ESP_LOGCONFIG(TAG, "     Phase Angle: %u", this->channel_a_->phase_angle_calibration);
+  }
+
+  if (this->channel_b_ != nullptr) {
+    ESP_LOGCONFIG(TAG, "  Phase B:");
+    LOG_SENSOR("    ", "Current", this->channel_b_->current);
+    LOG_SENSOR("    ", "Voltage", this->channel_b_->voltage);
+    LOG_SENSOR("    ", "Active Power", this->channel_b_->active_power);
+    LOG_SENSOR("    ", "Apparent Power", this->channel_b_->apparent_power);
+    LOG_SENSOR("    ", "Power Factor", this->channel_b_->power_factor);
+    LOG_SENSOR("    ", "Forward Active Energy", this->channel_b_->forward_active_energy);
+    LOG_SENSOR("    ", "Reverse Active Energy", this->channel_b_->reverse_active_energy);
+    ESP_LOGCONFIG(TAG, "    Calibration:");
+    ESP_LOGCONFIG(TAG, "     Current: %u", this->channel_b_->current_gain_calibration);
+    ESP_LOGCONFIG(TAG, "     Voltage: %d", this->channel_b_->voltage_gain_calibration);
+    ESP_LOGCONFIG(TAG, "     Power: %d", this->channel_b_->power_gain_calibration);
+    ESP_LOGCONFIG(TAG, "     Phase Angle: %u", this->channel_b_->phase_angle_calibration);
+  }
+
+  if (this->channel_c_ != nullptr) {
+    ESP_LOGCONFIG(TAG, "  Phase C:");
+    LOG_SENSOR("    ", "Current", this->channel_c_->current);
+    LOG_SENSOR("    ", "Voltage", this->channel_c_->voltage);
+    LOG_SENSOR("    ", "Active Power", this->channel_c_->active_power);
+    LOG_SENSOR("    ", "Apparent Power", this->channel_c_->apparent_power);
+    LOG_SENSOR("    ", "Power Factor", this->channel_c_->power_factor);
+    LOG_SENSOR("    ", "Forward Active Energy", this->channel_c_->forward_active_energy);
+    LOG_SENSOR("    ", "Reverse Active Energy", this->channel_c_->reverse_active_energy);
+    ESP_LOGCONFIG(TAG, "    Calibration:");
+    ESP_LOGCONFIG(TAG, "     Current: %u", this->channel_c_->current_gain_calibration);
+    ESP_LOGCONFIG(TAG, "     Voltage: %d", this->channel_c_->voltage_gain_calibration);
+    ESP_LOGCONFIG(TAG, "     Power: %d", this->channel_c_->power_gain_calibration);
+    ESP_LOGCONFIG(TAG, "     Phase Angle: %u", this->channel_c_->phase_angle_calibration);
+  }
+
+  if (this->channel_n_ != nullptr) {
+    ESP_LOGCONFIG(TAG, "  Neutral:");
+    LOG_SENSOR("    ", "Current", this->channel_n_->current);
+    ESP_LOGCONFIG(TAG, "    Calibration:");
+    ESP_LOGCONFIG(TAG, "     Current: %u", this->channel_n_->current_gain_calibration);
+  }
+
+  LOG_I2C_DEVICE(this);
+  LOG_UPDATE_INTERVAL(this);
+}
+
+void ADE7880::calibrate_s10zp_reading_(uint16_t a_register, int16_t calibration) {
+  if (calibration == 0) {
+    return;
+  }
+
+  this->write_s10zp_register16_(a_register, calibration);
+}
+
+void ADE7880::calibrate_s24zpse_reading_(uint16_t a_register, int32_t calibration) {
+  if (calibration == 0) {
+    return;
+  }
+
+  this->write_s24zpse_register16_(a_register, calibration);
+}
+
+void ADE7880::init_device_() {
+  this->write_u8_register16_(CONFIG2, CONFIG2_I2C_LOCK);
+
+  this->write_u16_register16_(GAIN, 0);
+
+  if (this->frequency_ > 55) {
+    this->write_u16_register16_(COMPMODE, COMPMODE_DEFAULT | COMPMODE_SELFREQ);
+  }
+
+  if (this->channel_n_ != nullptr) {
+    this->calibrate_s24zpse_reading_(NIGAIN, this->channel_n_->current_gain_calibration);
+  }
+
+  if (this->channel_a_ != nullptr) {
+    this->calibrate_s24zpse_reading_(AIGAIN, this->channel_a_->current_gain_calibration);
+    this->calibrate_s24zpse_reading_(AVGAIN, this->channel_a_->voltage_gain_calibration);
+    this->calibrate_s24zpse_reading_(APGAIN, this->channel_a_->power_gain_calibration);
+    this->calibrate_s10zp_reading_(APHCAL, this->channel_a_->phase_angle_calibration);
+  }
+
+  if (this->channel_b_ != nullptr) {
+    this->calibrate_s24zpse_reading_(BIGAIN, this->channel_b_->current_gain_calibration);
+    this->calibrate_s24zpse_reading_(BVGAIN, this->channel_b_->voltage_gain_calibration);
+    this->calibrate_s24zpse_reading_(BPGAIN, this->channel_b_->power_gain_calibration);
+    this->calibrate_s10zp_reading_(BPHCAL, this->channel_b_->phase_angle_calibration);
+  }
+
+  if (this->channel_c_ != nullptr) {
+    this->calibrate_s24zpse_reading_(CIGAIN, this->channel_c_->current_gain_calibration);
+    this->calibrate_s24zpse_reading_(CVGAIN, this->channel_c_->voltage_gain_calibration);
+    this->calibrate_s24zpse_reading_(CPGAIN, this->channel_c_->power_gain_calibration);
+    this->calibrate_s10zp_reading_(CPHCAL, this->channel_c_->phase_angle_calibration);
+  }
+
+  // write three default values to data memory RAM to flush the I2C write queue
+  this->write_s32_register16_(VLEVEL, 0);
+  this->write_s32_register16_(VLEVEL, 0);
+  this->write_s32_register16_(VLEVEL, 0);
+
+  this->write_u8_register16_(DSPWP_SEL, DSPWP_SEL_SET);
+  this->write_u8_register16_(DSPWP_SET, DSPWP_SET_RO);
+  this->write_u16_register16_(RUN, RUN_ENABLE);
+}
+
+void ADE7880::reset_device_() {
+  if (this->reset_pin_ != nullptr) {
+    ESP_LOGD(TAG, "Reset device using RESET pin");
+    this->reset_pin_->digital_write(false);
+    delay(1);
+    this->reset_pin_->digital_write(true);
+  } else {
+    ESP_LOGD(TAG, "Reset device using SWRST command");
+    this->write_u16_register16_(CONFIG, CONFIG_SWRST);
+  }
+  this->store_.reset_pending = true;
+}
+
+}  // namespace ade7880
+}  // namespace esphome