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Anton Viktorov 2024-02-26 00:14:10 +01:00
parent 83a1fc5fdb
commit fdd4536405
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CODEOWNERS
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@ -38,6 +38,7 @@ esphome/components/api/* @OttoWinter
esphome/components/as5600/* @ammmze
esphome/components/as5600/sensor/* @ammmze
esphome/components/as7341/* @mrgnr
esphome/components/as7343/* @latonita @mrgnr
esphome/components/async_tcp/* @OttoWinter
esphome/components/atc_mithermometer/* @ahpohl
esphome/components/atm90e26/* @danieltwagner

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esphome/components/as7343/__init__.py Normal file
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CODEOWNERS = ["@latonita"]

308
esphome/components/as7343/as7343.cpp Normal file
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#include "as7343.h"
#include "esphome/core/log.h"
#include "esphome/core/hal.h"
namespace esphome {
namespace as7343 {
static const char *const TAG = "as7343";
void AS7343Component::setup() {
ESP_LOGCONFIG(TAG, "Setting up AS7343...");
LOG_I2C_DEVICE(this);
// Verify device ID
this->set_bank_for_reg_(AS7343Registers::ID);
uint8_t id = this->reg((uint8_t) AS7343Registers::ID).get();
ESP_LOGCONFIG(TAG, " Read ID: 0x%X", id);
if (id != AS7343_CHIP_ID) {
this->mark_failed();
ESP_LOGE(TAG, " Invalid chip ID: 0x%X", id);
return;
}
this->set_bank_for_reg_(AS7343Registers::ENABLE);
// Power on (enter IDLE state)
if (!this->enable_power(true)) {
ESP_LOGE(TAG, " Power on failed!");
this->mark_failed();
return;
}
// Set configuration
AS7343RegCfg20 cfg20;
cfg20.raw = this->reg((uint8_t) AS7343Registers::CFG20).get();
cfg20.auto_smux = 0b11;
this->reg((uint8_t) AS7343Registers::CFG20) = cfg20.raw;
this->setup_atime(this->atime_);
this->setup_astep(this->astep_);
this->setup_gain(this->gain_);
// enable led false ?
}
void AS7343Component::dump_config() {
ESP_LOGCONFIG(TAG, "AS7343:");
LOG_I2C_DEVICE(this);
if (this->is_failed()) {
ESP_LOGE(TAG, "Communication with AS7343 failed!");
}
LOG_UPDATE_INTERVAL(this);
ESP_LOGCONFIG(TAG, " Gain: %u", get_gain());
ESP_LOGCONFIG(TAG, " ATIME: %u", get_atime());
ESP_LOGCONFIG(TAG, " ASTEP: %u", get_astep());
LOG_SENSOR(" ", "F1", this->f1_);
LOG_SENSOR(" ", "F2", this->f2_);
LOG_SENSOR(" ", "FZ", this->fz_);
LOG_SENSOR(" ", "F3", this->f3_);
LOG_SENSOR(" ", "F4", this->f4_);
LOG_SENSOR(" ", "F5", this->f5_);
LOG_SENSOR(" ", "FY", this->fy_);
LOG_SENSOR(" ", "FXL", this->fxl_);
LOG_SENSOR(" ", "F6", this->f6_);
LOG_SENSOR(" ", "F7", this->f7_);
LOG_SENSOR(" ", "F8", this->f8_);
LOG_SENSOR(" ", "NIR", this->nir_);
LOG_SENSOR(" ", "Clear", this->clear_);
}
float AS7343Component::get_setup_priority() const { return setup_priority::DATA; }
void AS7343Component::update() {
this->read_channels(this->channel_readings_);
if (this->f1_ != nullptr) {
this->f1_->publish_state(this->channel_readings_[AS7343_CHANNEL_405_F1]);
}
if (this->f2_ != nullptr) {
this->f2_->publish_state(this->channel_readings_[AS7343_CHANNEL_425_F2]);
}
if (this->fz_ != nullptr) {
this->fz_->publish_state(this->channel_readings_[AS7343_CHANNEL_450_FZ]);
}
if (this->f3_ != nullptr) {
this->f3_->publish_state(this->channel_readings_[AS7343_CHANNEL_475_F3]);
}
if (this->f4_ != nullptr) {
this->f4_->publish_state(this->channel_readings_[AS7343_CHANNEL_515_F4]);
}
if (this->fy_ != nullptr) {
this->fy_->publish_state(this->channel_readings_[AS7343_CHANNEL_555_FY]);
}
if (this->f5_ != nullptr) {
this->f5_->publish_state(this->channel_readings_[AS7343_CHANNEL_550_F5]);
}
if (this->fxl_ != nullptr) {
this->fxl_->publish_state(this->channel_readings_[AS7343_CHANNEL_600_FXL]);
}
if (this->f6_ != nullptr) {
this->f6_->publish_state(this->channel_readings_[AS7343_CHANNEL_640_F6]);
}
if (this->f7_ != nullptr) {
this->f7_->publish_state(this->channel_readings_[AS7343_CHANNEL_690_F7]);
}
if (this->f8_ != nullptr) {
this->f8_->publish_state(this->channel_readings_[AS7343_CHANNEL_745_F8]);
}
if (this->nir_ != nullptr) {
this->nir_->publish_state(this->channel_readings_[AS7343_CHANNEL_855_NIR]);
}
if (this->clear_ != nullptr) {
this->clear_->publish_state(this->channel_readings_[AS7343_CHANNEL_CLEAR]);
}
}
AS7343Gain AS7343Component::get_gain() {
uint8_t data;
this->read_byte((uint8_t) AS7343Registers::CFG1, &data);
return (AS7343Gain) data;
}
uint8_t AS7343Component::get_atime() {
uint8_t data;
this->read_byte((uint8_t) AS7343Registers::ATIME, &data);
return data;
}
uint16_t AS7343Component::get_astep() {
uint16_t data;
this->read_byte_16((uint8_t) AS7343Registers::ASTEP_LSB, &data);
return this->swap_bytes(data);
}
bool AS7343Component::setup_gain(AS7343Gain gain) { return this->write_byte((uint8_t) AS7343Registers::CFG1, gain); }
bool AS7343Component::setup_atime(uint8_t atime) { return this->write_byte((uint8_t) AS7343Registers::ATIME, atime); }
bool AS7343Component::setup_astep(uint16_t astep) {
return this->write_byte_16((uint8_t) AS7343Registers::ASTEP_LSB, swap_bytes(astep));
}
bool AS7343Component::read_channels(uint16_t *data) {
this->enable_spectral_measurement(true);
this->wait_for_data();
return this->read_bytes_16((uint8_t) AS7343Registers::DATA_O, this->channel_readings_, AS7343_NUM_CHANNELS);
// this->set_smux_low_channels(true);
// this->enable_spectral_measurement(true);
// this->wait_for_data();
// bool low_success = this->read_bytes_16(AS7343_CH0_DATA_L, data, 6);
// this->set_smux_low_channels(false);
// this->enable_spectral_measurement(true);
// this->wait_for_data();
// bool high_sucess = this->read_bytes_16(AS7343_CH0_DATA_L, &data[6], 6);
// return low_success && high_sucess;
}
// void AS7343Component::set_smux_low_channels(bool enable) {
// // this->enable_spectral_measurement(false);
// // this->set_smux_command(AS7343_SMUX_CMD_WRITE);
// // if (enable) {
// // this->configure_smux_low_channels();
// // } else {
// // this->configure_smux_high_channels();
// // }
// // this->enable_smux();
// }
// bool AS7343Component::set_smux_command(AS7343SmuxCommand command) {
// // uint8_t data = command << 3; // Write to bits 4:3 of the register
// // return this->write_byte(AS7343_CFG6, data);
// }
// void AS7343Component::configure_smux_low_channels() {
// // SMUX Config for F1,F2,F3,F4,NIR,Clear
// // this->write_byte(0x00, 0x30); // F3 left set to ADC2
// // this->write_byte(0x01, 0x01); // F1 left set to ADC0
// // this->write_byte(0x02, 0x00); // Reserved or disabled
// // this->write_byte(0x03, 0x00); // F8 left disabled
// // this->write_byte(0x04, 0x00); // F6 left disabled
// // this->write_byte(0x05, 0x42); // F4 left connected to ADC3/f2 left connected to ADC1
// // this->write_byte(0x06, 0x00); // F5 left disbled
// // this->write_byte(0x07, 0x00); // F7 left disbled
// // this->write_byte(0x08, 0x50); // CLEAR connected to ADC4
// // this->write_byte(0x09, 0x00); // F5 right disabled
// // this->write_byte(0x0A, 0x00); // F7 right disabled
// // this->write_byte(0x0B, 0x00); // Reserved or disabled
// // this->write_byte(0x0C, 0x20); // F2 right connected to ADC1
// // this->write_byte(0x0D, 0x04); // F4 right connected to ADC3
// // this->write_byte(0x0E, 0x00); // F6/F8 right disabled
// // this->write_byte(0x0F, 0x30); // F3 right connected to AD2
// // this->write_byte(0x10, 0x01); // F1 right connected to AD0
// // this->write_byte(0x11, 0x50); // CLEAR right connected to AD4
// // this->write_byte(0x12, 0x00); // Reserved or disabled
// // this->write_byte(0x13, 0x06); // NIR connected to ADC5
// }
// void AS7343Component::configure_smux_high_channels() {
// // SMUX Config for F5,F6,F7,F8,NIR,Clear
// // this->write_byte(0x00, 0x00); // F3 left disable
// // this->write_byte(0x01, 0x00); // F1 left disable
// // this->write_byte(0x02, 0x00); // reserved/disable
// // this->write_byte(0x03, 0x40); // F8 left connected to ADC3
// // this->write_byte(0x04, 0x02); // F6 left connected to ADC1
// // this->write_byte(0x05, 0x00); // F4/ F2 disabled
// // this->write_byte(0x06, 0x10); // F5 left connected to ADC0
// // this->write_byte(0x07, 0x03); // F7 left connected to ADC2
// // this->write_byte(0x08, 0x50); // CLEAR Connected to ADC4
// // this->write_byte(0x09, 0x10); // F5 right connected to ADC0
// // this->write_byte(0x0A, 0x03); // F7 right connected to ADC2
// // this->write_byte(0x0B, 0x00); // Reserved or disabled
// // this->write_byte(0x0C, 0x00); // F2 right disabled
// // this->write_byte(0x0D, 0x00); // F4 right disabled
// // this->write_byte(0x0E, 0x24); // F8 right connected to ADC2/ F6 right connected to ADC1
// // this->write_byte(0x0F, 0x00); // F3 right disabled
// // this->write_byte(0x10, 0x00); // F1 right disabled
// // this->write_byte(0x11, 0x50); // CLEAR right connected to AD4
// // this->write_byte(0x12, 0x00); // Reserved or disabled
// // this->write_byte(0x13, 0x06); // NIR connected to ADC5
// }
// bool AS7343Component::enable_smux() {
// // this->set_register_bit(AS7343_ENABLE, 4);
// // uint16_t timeout = 1000;
// // for (uint16_t time = 0; time < timeout; time++) {
// // // The SMUXEN bit is cleared once the SMUX operation is finished
// // bool smuxen = this->read_register_bit(AS7343_ENABLE, 4);
// // if (!smuxen) {
// // return true;
// // }
// // delay(1);
// // }
// // return false;
// }
bool AS7343Component::wait_for_data(uint16_t timeout) {
for (uint16_t time = 0; time < timeout; time++) {
if (this->is_data_ready()) {
return true;
}
delay(1);
}
return false;
}
bool AS7343Component::is_data_ready() { return this->read_register_bit((uint8_t) AS7343Registers::STATUS2, 6); }
void AS7343Component::set_bank_for_reg_(AS7343Registers reg) {
bool bank = (uint8_t) reg < 0x80;
if (bank == this->bank_) {
return;
}
this->write_register_bit((uint8_t) AS7343Registers::CFG0, bank, AS7343_CFG0_REG_BANK_BIT);
this->bank_ = bank;
}
bool AS7343Component::enable_power(bool enable) {
return this->write_register_bit((uint8_t) AS7343Registers::ENABLE, enable, AS7343_ENABLE_PON_BIT);
}
bool AS7343Component::enable_spectral_measurement(bool enable) {
return this->write_register_bit((uint8_t) AS7343Registers::ENABLE, enable, AS7343_ENABLE_SP_EN_BIT);
}
bool AS7343Component::read_register_bit(uint8_t address, uint8_t bit_position) {
uint8_t data;
this->read_byte(address, &data);
bool bit = (data & (1 << bit_position)) > 0;
return bit;
}
bool AS7343Component::write_register_bit(uint8_t address, bool value, uint8_t bit_position) {
if (value) {
return this->set_register_bit(address, bit_position);
}
return this->clear_register_bit(address, bit_position);
}
bool AS7343Component::set_register_bit(uint8_t address, uint8_t bit_position) {
uint8_t data;
this->read_byte(address, &data);
data |= (1 << bit_position);
return this->write_byte(address, data);
}
bool AS7343Component::clear_register_bit(uint8_t address, uint8_t bit_position) {
uint8_t data;
this->read_byte(address, &data);
data &= ~(1 << bit_position);
return this->write_byte(address, data);
}
uint16_t AS7343Component::swap_bytes(uint16_t data) { return (data >> 8) | (data << 8); }
} // namespace as7343
} // namespace esphome

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esphome/components/as7343/as7343.h Normal file
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#pragma once
#include "esphome/core/component.h"
#include "esphome/components/sensor/sensor.h"
#include "esphome/components/i2c/i2c.h"
#include "as7343_registers.h"
namespace esphome {
namespace as7343 {
static const uint8_t AS7341_CONFIG = 0x70;
static const uint8_t AS7341_LED = 0x74;
static const uint8_t AS7341_ENABLE = 0x80;
static const uint8_t AS7341_ATIME = 0x81;
static const uint8_t AS7341_WTIME = 0x83;
static const uint8_t AS7341_AUXID = 0x90;
static const uint8_t AS7341_REVID = 0x91;
static const uint8_t AS7341_ID = 0x92;
static const uint8_t AS7341_STATUS = 0x93;
// static const uint8_t AS7341_CH0_DATA_L = 0x95;
// static const uint8_t AS7341_CH0_DATA_H = 0x96;
// static const uint8_t AS7341_CH1_DATA_L = 0x97;
// static const uint8_t AS7341_CH1_DATA_H = 0x98;
// static const uint8_t AS7341_CH2_DATA_L = 0x99;
// static const uint8_t AS7341_CH2_DATA_H = 0x9A;
// static const uint8_t AS7341_CH3_DATA_L = 0x9B;
// static const uint8_t AS7341_CH3_DATA_H = 0x9C;
// static const uint8_t AS7341_CH4_DATA_L = 0x9D;
// static const uint8_t AS7341_CH4_DATA_H = 0x9E;
// static const uint8_t AS7341_CH5_DATA_L = 0x9F;
// static const uint8_t AS7341_CH5_DATA_H = 0xA0;
// static const uint8_t AS7341_STATUS2 = 0xA3;
// static const uint8_t AS7341_CFG1 = 0xAA; ///< Controls ADC Gain
// static const uint8_t AS7341_CFG6 = 0xAF; // Stores SMUX command
// static const uint8_t AS7341_CFG9 = 0xB2; // Config for system interrupts (SMUX, Flicker detection)
// static const uint8_t AS7341_ASTEP = 0xCA; // LSB
// static const uint8_t AS7341_ASTEP_MSB = 0xCB; // MSB
// enum AS7343AdcChannel {
// AS7343_ADC_CHANNEL_0,
// AS7343_ADC_CHANNEL_1,
// AS7343_ADC_CHANNEL_2,
// AS7343_ADC_CHANNEL_3,
// AS7343_ADC_CHANNEL_4,
// AS7343_ADC_CHANNEL_5,
// };
// enum AS7343SmuxCommand {
// AS7343_SMUX_CMD_ROM_RESET, ///< ROM code initialization of SMUX
// AS7343_SMUX_CMD_READ, ///< Read SMUX configuration to RAM from SMUX chain
// AS7343_SMUX_CMD_WRITE, ///< Write SMUX configuration from RAM to SMUX chain
// };
class AS7343Component : public PollingComponent, public i2c::I2CDevice {
public:
void setup() override;
void dump_config() override;
float get_setup_priority() const override;
void update() override;
void set_f1_sensor(sensor::Sensor *f1_sensor) { f1_ = f1_sensor; }
void set_f2_sensor(sensor::Sensor *f2_sensor) { f2_ = f2_sensor; }
void set_fz_sensor(sensor::Sensor *fz_sensor) { fz_ = fz_sensor; }
void set_f3_sensor(sensor::Sensor *f3_sensor) { f3_ = f3_sensor; }
void set_f4_sensor(sensor::Sensor *f4_sensor) { f4_ = f4_sensor; }
void set_fy_sensor(sensor::Sensor *fy_sensor) { fy_ = fy_sensor; }
void set_f5_sensor(sensor::Sensor *f5_sensor) { f5_ = f5_sensor; }
void set_fxl_sensor(sensor::Sensor *fxl_sensor) { fxl_ = fxl_sensor; }
void set_f6_sensor(sensor::Sensor *f6_sensor) { f6_ = f6_sensor; }
void set_f7_sensor(sensor::Sensor *f7_sensor) { f7_ = f7_sensor; }
void set_f8_sensor(sensor::Sensor *f8_sensor) { f8_ = f8_sensor; }
void set_nir_sensor(sensor::Sensor *nir_sensor) { nir_ = nir_sensor; }
void set_clear_sensor(sensor::Sensor *clear_sensor) { clear_ = clear_sensor; }
void set_gain(AS7343Gain gain) { gain_ = gain; }
void set_atime(uint8_t atime) { atime_ = atime; }
void set_astep(uint16_t astep) { astep_ = astep; }
AS7343Gain get_gain();
uint8_t get_atime();
uint16_t get_astep();
bool setup_gain(AS7343Gain gain);
bool setup_atime(uint8_t atime);
bool setup_astep(uint16_t astep);
// uint16_t read_channel(AS7343AdcChannel channel);
bool read_channels(uint16_t *data);
// void set_smux_low_channels(bool enable);
// bool set_smux_command(AS7343SmuxCommand command);
// void configure_smux_low_channels();
// void configure_smux_high_channels();
// bool enable_smux();
bool wait_for_data(uint16_t timeout = 1000);
bool is_data_ready();
bool enable_power(bool enable);
bool enable_spectral_measurement(bool enable);
bool read_register_bit(uint8_t address, uint8_t bit_position);
bool write_register_bit(uint8_t address, bool value, uint8_t bit_position);
bool set_register_bit(uint8_t address, uint8_t bit_position);
bool clear_register_bit(uint8_t address, uint8_t bit_position);
uint16_t swap_bytes(uint16_t data);
protected:
void set_bank_for_reg_(AS7343Registers reg = AS7343Registers::ENABLE);
bool bank_{false};
sensor::Sensor *f1_{nullptr};
sensor::Sensor *f2_{nullptr};
sensor::Sensor *fz_{nullptr};
sensor::Sensor *f3_{nullptr};
sensor::Sensor *f4_{nullptr};
sensor::Sensor *fy_{nullptr};
sensor::Sensor *f5_{nullptr};
sensor::Sensor *fxl_{nullptr};
sensor::Sensor *f6_{nullptr};
sensor::Sensor *f7_{nullptr};
sensor::Sensor *f8_{nullptr};
sensor::Sensor *nir_{nullptr};
sensor::Sensor *clear_{nullptr};
uint16_t astep_;
AS7343Gain gain_;
uint8_t atime_;
uint16_t channel_readings_[AS7343_NUM_CHANNELS];
};
} // namespace as7343
} // namespace esphome

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esphome/components/as7343/as7343_registers.h Normal file
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#pragma once
#include <cstdint>
namespace esphome {
namespace as7343 {
enum class AS7343Registers : uint8_t {
AUXID = 0x58,
REVID = 0x59,
ID = 0x5A,
CFG12 = 0x66,
ENABLE = 0x80,
ATIME = 0x81,
WTIME = 0x83,
SP_TH_L_LSB = 0x84,
SP_TH_L_MSB = 0x85,
SP_TH_H_LSB = 0x86,
SP_TH_H_MSB = 0x87,
STATUS = 0x93,
ASTATUS = 0x94,
DATA_O = 0x95,
STATUS2 = 0x90,
STATUS3 = 0x91,
STATUS5 = 0xBB,
STATUS4 = 0xBC,
CFG0 = 0xBF,
CFG1 = 0xC6,
CFG3 = 0xC7,
CFG6 = 0xF5,
CFG8 = 0xC9,
CFG9 = 0xCA,
CFG10 = 0x65,
PERS = 0xCF,
GPIO = 0x6B,
ASTEP_LSB = 0xD4,
ASTEP_MSB = 0xD5,
CFG20 = 0xD6,
LED = 0xCD,
AGC_GAIN_MAX = 0xD7,
AZ_CONFIG = 0xDE,
FD_TIME_1 = 0xE0,
FD_TIME_2 = 0xE2,
FD_CFG0 = 0xDF,
FD_STATUS = 0xE3,
INTENAB = 0xF9,
CONTROL = 0xFA,
FIFO_MAP = 0xFC,
FIFO_LVL = 0xFD,
FDATA_L = 0xFE,
FDATA_H = 0xFF,
};
static constexpr uint8_t AS7343_CHIP_ID = 0b10000001;
static constexpr uint8_t AS7343_ENABLE_PON_BIT = 0;
static constexpr uint8_t AS7343_ENABLE_SP_EN_BIT = 1;
static constexpr uint8_t AS7343_CFG0_REG_BANK_BIT = 4;
union AS7343RegCfg20 {
uint8_t raw;
struct {
uint8_t reserved : 5;
uint8_t auto_smux : 2;
uint8_t fd_fifo_8b : 1;
};
};
enum AS7343Gain : uint8_t {
AS7343_GAIN_0_5X,
AS7343_GAIN_1X,
AS7343_GAIN_2X,
AS7343_GAIN_4X,
AS7343_GAIN_8X,
AS7343_GAIN_16X,
AS7343_GAIN_32X,
AS7343_GAIN_64X,
AS7343_GAIN_128X,
AS7343_GAIN_256X,
AS7343_GAIN_512X,
AS7343_GAIN_1024X,
AS7343_GAIN_2048X,
};
enum AS7343Channel : uint8_t {
AS7343_CHANNEL_450_FZ,
AS7343_CHANNEL_555_FY,
AS7343_CHANNEL_600_FXL,
AS7343_CHANNEL_855_NIR,
AS7343_CHANNEL_CLEAR_1,
AS7343_CHANNEL_FD_1,
AS7343_CHANNEL_425_F2,
AS7343_CHANNEL_475_F3,
AS7343_CHANNEL_515_F4,
AS7343_CHANNEL_640_F6,
AS7343_CHANNEL_CLEAR_0,
AS7343_CHANNEL_FD_0,
AS7343_CHANNEL_405_F1,
AS7343_CHANNEL_550_F5,
AS7343_CHANNEL_690_F7,
AS7343_CHANNEL_745_F8,
AS7343_CHANNEL_CLEAR,
AS7343_CHANNEL_FD,
};
static constexpr uint8_t AS7343_NUM_CHANNELS = 18;
} // namespace as7343
} // namespace esphome

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esphome/components/as7343/sensor.py Normal file
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import esphome.codegen as cg
import esphome.config_validation as cv
from esphome.components import i2c, sensor
from esphome.const import (
CONF_GAIN,
CONF_ID,
CONF_NAME,
DEVICE_CLASS_ILLUMINANCE,
ICON_BRIGHTNESS_5,
STATE_CLASS_MEASUREMENT,
)
CODEOWNERS = ["@mrgnr", "@latonita"]
DEPENDENCIES = ["i2c"]
as7343_ns = cg.esphome_ns.namespace("as7343")
AS7343Component = as7343_ns.class_(
"AS7343Component", cg.PollingComponent, i2c.I2CDevice
)
CONF_ATIME = "atime"
CONF_ASTEP = "astep"
CONF_F1 = "f1"
CONF_F2 = "f2"
CONF_FZ = "fz"
CONF_F3 = "f3"
CONF_F4 = "f4"
CONF_FY = "fy"
CONF_F5 = "f5"
CONF_FXL = "fxl"
CONF_F6 = "f6"
CONF_F7 = "f7"
CONF_F8 = "f8"
CONF_NIR = "nir"
CONF_CLEAR = "clear"
UNIT_COUNTS = "#"
AS7343_GAIN = as7343_ns.enum("AS7343Gain")
GAIN_OPTIONS = {
"X0.5": AS7343_GAIN.AS7343_GAIN_0_5X,
"X1": AS7343_GAIN.AS7343_GAIN_1X,
"X2": AS7343_GAIN.AS7343_GAIN_2X,
"X4": AS7343_GAIN.AS7343_GAIN_4X,
"X8": AS7343_GAIN.AS7343_GAIN_8X,
"X16": AS7343_GAIN.AS7343_GAIN_16X,
"X32": AS7343_GAIN.AS7343_GAIN_32X,
"X64": AS7343_GAIN.AS7343_GAIN_64X,
"X128": AS7343_GAIN.AS7343_GAIN_128X,
"X256": AS7343_GAIN.AS7343_GAIN_256X,
"X512": AS7343_GAIN.AS7343_GAIN_512X,
"X1024": AS7343_GAIN.AS7343_GAIN_1024X,
"X2048": AS7343_GAIN.AS7343_GAIN_2048X,
}
SENSOR_SCHEMA = cv.maybe_simple_value(
sensor.sensor_schema(
unit_of_measurement=UNIT_COUNTS,
icon=ICON_BRIGHTNESS_5,
accuracy_decimals=0,
device_class=DEVICE_CLASS_ILLUMINANCE,
state_class=STATE_CLASS_MEASUREMENT,
),
key=CONF_NAME,
)
CONFIG_SCHEMA = (
cv.Schema(
{
cv.GenerateID(): cv.declare_id(AS7343Component),
cv.Optional(CONF_F1): SENSOR_SCHEMA,
cv.Optional(CONF_F2): SENSOR_SCHEMA,
cv.Optional(CONF_FZ): SENSOR_SCHEMA,
cv.Optional(CONF_F3): SENSOR_SCHEMA,
cv.Optional(CONF_F4): SENSOR_SCHEMA,
cv.Optional(CONF_FY): SENSOR_SCHEMA,
cv.Optional(CONF_F5): SENSOR_SCHEMA,
cv.Optional(CONF_FXL): SENSOR_SCHEMA,
cv.Optional(CONF_F6): SENSOR_SCHEMA,
cv.Optional(CONF_F7): SENSOR_SCHEMA,
cv.Optional(CONF_F8): SENSOR_SCHEMA,
cv.Optional(CONF_NIR): SENSOR_SCHEMA,
cv.Optional(CONF_GAIN, default="X8"): cv.enum(GAIN_OPTIONS),
cv.Optional(CONF_ATIME, default=29): cv.int_range(min=0, max=255),
cv.Optional(CONF_ASTEP, default=599): cv.int_range(min=0, max=65534),
}
)
.extend(cv.polling_component_schema("60s"))
.extend(i2c.i2c_device_schema(0x39))
)
SENSORS = {
CONF_F1: "set_f1_sensor",
CONF_F2: "set_f2_sensor",
CONF_FZ: "set_fz_sensor",
CONF_F3: "set_f3_sensor",
CONF_F4: "set_f4_sensor",
CONF_FY: "set_fy_sensor",
CONF_F5: "set_f5_sensor",
CONF_FXL: "set_fxl_sensor",
CONF_F6: "set_f6_sensor",
CONF_F7: "set_f7_sensor",
CONF_F8: "set_f8_sensor",
CONF_NIR: "set_nir_sensor",
CONF_CLEAR: "set_clear_sensor",
}
async def to_code(config):
var = cg.new_Pvariable(config[CONF_ID])
await cg.register_component(var, config)
await i2c.register_i2c_device(var, config)
cg.add(var.set_gain(config[CONF_GAIN]))
cg.add(var.set_atime(config[CONF_ATIME]))
cg.add(var.set_astep(config[CONF_ASTEP]))
for conf_id, set_sensor_func in SENSORS.items():
if sens_config := config.get(conf_id):
sens = await sensor.new_sensor(sens_config)
cg.add(getattr(var, set_sensor_func)(sens))