Merge remote-tracking branch 'upstream/dev' into as7343

This commit is contained in:
Anton Viktorov 2024-03-14 11:49:45 +01:00
commit 7545e68d75
370 changed files with 16570 additions and 1685 deletions

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@ -36,7 +36,7 @@ runs:
- name: Build and push to ghcr by digest
id: build-ghcr
uses: docker/build-push-action@v5.0.0
uses: docker/build-push-action@v5.2.0
with:
context: .
file: ./docker/Dockerfile
@ -67,7 +67,7 @@ runs:
- name: Build and push to dockerhub by digest
id: build-dockerhub
uses: docker/build-push-action@v5.0.0
uses: docker/build-push-action@v5.2.0
with:
context: .
file: ./docker/Dockerfile

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@ -22,7 +22,7 @@ runs:
python-version: ${{ inputs.python-version }}
- name: Restore Python virtual environment
id: cache-venv
uses: actions/cache/restore@v3.3.2
uses: actions/cache/restore@v4.0.1
with:
path: venv
# yamllint disable-line rule:line-length

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@ -13,3 +13,13 @@ updates:
schedule:
interval: daily
open-pull-requests-limit: 10
- package-ecosystem: github-actions
directory: "/.github/actions/build-image"
schedule:
interval: daily
open-pull-requests-limit: 10
- package-ecosystem: github-actions
directory: "/.github/actions/restore-python"
schedule:
interval: daily
open-pull-requests-limit: 10

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@ -46,7 +46,7 @@ jobs:
with:
python-version: "3.9"
- name: Set up Docker Buildx
uses: docker/setup-buildx-action@v3.0.0
uses: docker/setup-buildx-action@v3.1.0
- name: Set up QEMU
uses: docker/setup-qemu-action@v3.0.0

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@ -12,6 +12,7 @@ on:
- "!.github/workflows/*.yml"
- ".github/workflows/ci.yml"
- "!.yamllint"
- "!.github/dependabot.yml"
merge_group:
permissions:
@ -46,7 +47,7 @@ jobs:
python-version: ${{ env.DEFAULT_PYTHON }}
- name: Restore Python virtual environment
id: cache-venv
uses: actions/cache@v4.0.0
uses: actions/cache@v4.0.1
with:
path: venv
# yamllint disable-line rule:line-length
@ -366,7 +367,7 @@ jobs:
python-version: ${{ env.DEFAULT_PYTHON }}
cache-key: ${{ needs.common.outputs.cache-key }}
- name: Cache platformio
uses: actions/cache@v4.0.0
uses: actions/cache@v4.0.1
with:
path: ~/.platformio
# yamllint disable-line rule:line-length
@ -433,6 +434,9 @@ jobs:
matrix:
file: ${{ fromJson(needs.list-components.outputs.matrix) }}
steps:
- name: Install libsodium
run: sudo apt-get install libsodium-dev
- name: Check out code from GitHub
uses: actions/checkout@v4.1.1
- name: Restore Python

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@ -85,18 +85,18 @@ jobs:
python-version: "3.9"
- name: Set up Docker Buildx
uses: docker/setup-buildx-action@v3.0.0
uses: docker/setup-buildx-action@v3.1.0
- name: Set up QEMU
if: matrix.platform != 'linux/amd64'
uses: docker/setup-qemu-action@v3.0.0
- name: Log in to docker hub
uses: docker/login-action@v3.0.0
uses: docker/login-action@v3.1.0
with:
username: ${{ secrets.DOCKER_USER }}
password: ${{ secrets.DOCKER_PASSWORD }}
- name: Log in to the GitHub container registry
uses: docker/login-action@v3.0.0
uses: docker/login-action@v3.1.0
with:
registry: ghcr.io
username: ${{ github.actor }}
@ -163,17 +163,17 @@ jobs:
name: digests-${{ matrix.image.target }}-${{ matrix.registry }}
path: /tmp/digests
- name: Set up Docker Buildx
uses: docker/setup-buildx-action@v3.0.0
uses: docker/setup-buildx-action@v3.1.0
- name: Log in to docker hub
if: matrix.registry == 'dockerhub'
uses: docker/login-action@v3.0.0
uses: docker/login-action@v3.1.0
with:
username: ${{ secrets.DOCKER_USER }}
password: ${{ secrets.DOCKER_PASSWORD }}
- name: Log in to the GitHub container registry
if: matrix.registry == 'ghcr'
uses: docker/login-action@v3.0.0
uses: docker/login-action@v3.1.0
with:
registry: ghcr.io
username: ${{ github.actor }}

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@ -37,7 +37,7 @@ jobs:
python ./script/sync-device_class.py
- name: Commit changes
uses: peter-evans/create-pull-request@v6.0.0
uses: peter-evans/create-pull-request@v6.0.2
with:
commit-message: "Synchronise Device Classes from Home Assistant"
committer: esphomebot <esphome@nabucasa.com>

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@ -22,12 +22,15 @@ esphome/components/ade7880/* @kpfleming
esphome/components/ade7953/* @angelnu
esphome/components/ade7953_i2c/* @angelnu
esphome/components/ade7953_spi/* @angelnu
esphome/components/ads1118/* @solomondg1
esphome/components/ags10/* @mak-42
esphome/components/airthings_ble/* @jeromelaban
esphome/components/airthings_wave_base/* @jeromelaban @kpfleming @ncareau
esphome/components/airthings_wave_mini/* @ncareau
esphome/components/airthings_wave_plus/* @jeromelaban
esphome/components/alarm_control_panel/* @grahambrown11 @hwstar
esphome/components/alpha3/* @jan-hofmeier
esphome/components/am2315c/* @swoboda1337
esphome/components/am43/* @buxtronix
esphome/components/am43/cover/* @buxtronix
esphome/components/am43/sensor/* @buxtronix
@ -79,12 +82,15 @@ esphome/components/copy/* @OttoWinter
esphome/components/cover/* @esphome/core
esphome/components/cs5460a/* @balrog-kun
esphome/components/cse7761/* @berfenger
esphome/components/cst226/* @clydebarrow
esphome/components/cst816/* @clydebarrow
esphome/components/ct_clamp/* @jesserockz
esphome/components/current_based/* @djwmarcx
esphome/components/dac7678/* @NickB1
esphome/components/daikin_brc/* @hagak
esphome/components/daly_bms/* @s1lvi0
esphome/components/dashboard_import/* @esphome/core
esphome/components/datetime/* @rfdarter
esphome/components/debug/* @OttoWinter
esphome/components/delonghi/* @grob6000
esphome/components/dfplayer/* @glmnet
@ -98,6 +104,7 @@ esphome/components/duty_time/* @dudanov
esphome/components/ee895/* @Stock-M
esphome/components/ektf2232/touchscreen/* @jesserockz
esphome/components/emc2101/* @ellull
esphome/components/emmeti/* @E440QF
esphome/components/ens160/* @vincentscode
esphome/components/ens210/* @itn3rd77
esphome/components/esp32/* @esphome/core
@ -116,7 +123,8 @@ esphome/components/ezo_pmp/* @carlos-sarmiento
esphome/components/factory_reset/* @anatoly-savchenkov
esphome/components/fastled_base/* @OttoWinter
esphome/components/feedback/* @ianchi
esphome/components/fingerprint_grow/* @OnFreund @loongyh
esphome/components/fingerprint_grow/* @OnFreund @alexborro @loongyh
esphome/components/font/* @clydebarrow @esphome/core
esphome/components/fs3000/* @kahrendt
esphome/components/ft5x06/* @clydebarrow
esphome/components/ft63x6/* @gpambrozio
@ -146,6 +154,7 @@ esphome/components/honeywellabp2_i2c/* @jpfaff
esphome/components/host/* @esphome/core
esphome/components/hrxl_maxsonar_wr/* @netmikey
esphome/components/hte501/* @Stock-M
esphome/components/htu31d/* @betterengineering
esphome/components/hydreon_rgxx/* @functionpointer
esphome/components/hyt271/* @Philippe12
esphome/components/i2c/* @esphome/core
@ -165,6 +174,7 @@ esphome/components/integration/* @OttoWinter
esphome/components/internal_temperature/* @Mat931
esphome/components/interval/* @esphome/core
esphome/components/json/* @OttoWinter
esphome/components/kamstrup_kmp/* @cfeenstra1024
esphome/components/key_collector/* @ssieb
esphome/components/key_provider/* @ssieb
esphome/components/kuntze/* @ssieb
@ -226,6 +236,7 @@ esphome/components/mopeka_pro_check/* @spbrogan
esphome/components/mopeka_std_check/* @Fabian-Schmidt
esphome/components/mpl3115a2/* @kbickar
esphome/components/mpu6886/* @fabaff
esphome/components/ms8607/* @e28eta
esphome/components/network/* @esphome/core
esphome/components/nextion/* @senexcrenshaw
esphome/components/nextion/binary_sensor/* @senexcrenshaw
@ -262,6 +273,7 @@ esphome/components/pvvx_mithermometer/* @pasiz
esphome/components/pylontech/* @functionpointer
esphome/components/qmp6988/* @andrewpc
esphome/components/qr_code/* @wjtje
esphome/components/qspi_amoled/* @clydebarrow
esphome/components/qwiic_pir/* @kahrendt
esphome/components/radon_eye_ble/* @jeffeb3
esphome/components/radon_eye_rd200/* @jeffeb3
@ -275,6 +287,7 @@ esphome/components/rgbct/* @jesserockz
esphome/components/rp2040/* @jesserockz
esphome/components/rp2040_pio_led_strip/* @Papa-DMan
esphome/components/rp2040_pwm/* @jesserockz
esphome/components/rpi_dpi_rgb/* @clydebarrow
esphome/components/rtl87xx/* @kuba2k2
esphome/components/rtttl/* @glmnet
esphome/components/safe_mode/* @jsuanet @paulmonigatti
@ -282,6 +295,7 @@ esphome/components/scd4x/* @martgras @sjtrny
esphome/components/script/* @esphome/core
esphome/components/sdm_meter/* @jesserockz @polyfaces
esphome/components/sdp3x/* @Azimath
esphome/components/seeed_mr24hpc1/* @limengdu
esphome/components/selec_meter/* @sourabhjaiswal
esphome/components/select/* @esphome/core
esphome/components/sen0321/* @notjj
@ -326,6 +340,7 @@ esphome/components/ssd1351_spi/* @kbx81
esphome/components/st7567_base/* @latonita
esphome/components/st7567_i2c/* @latonita
esphome/components/st7567_spi/* @latonita
esphome/components/st7701s/* @clydebarrow
esphome/components/st7735/* @SenexCrenshaw
esphome/components/st7789v/* @kbx81
esphome/components/st7920/* @marsjan155
@ -338,6 +353,8 @@ esphome/components/tcl112/* @glmnet
esphome/components/tee501/* @Stock-M
esphome/components/teleinfo/* @0hax
esphome/components/template/alarm_control_panel/* @grahambrown11 @hwstar
esphome/components/template/datetime/* @rfdarter
esphome/components/template/fan/* @ssieb
esphome/components/text/* @mauritskorse
esphome/components/thermostat/* @kbx81
esphome/components/time/* @OttoWinter
@ -369,6 +386,7 @@ esphome/components/ultrasonic/* @OttoWinter
esphome/components/uponor_smatrix/* @kroimon
esphome/components/vbus/* @ssieb
esphome/components/veml3235/* @kbx81
esphome/components/veml7700/* @latonita
esphome/components/version/* @esphome/core
esphome/components/voice_assistant/* @jesserockz
esphome/components/wake_on_lan/* @willwill2will54

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@ -21,4 +21,10 @@ export PLATFORMIO_PLATFORMS_DIR="${pio_cache_base}/platforms"
export PLATFORMIO_PACKAGES_DIR="${pio_cache_base}/packages"
export PLATFORMIO_CACHE_DIR="${pio_cache_base}/cache"
# If /build is mounted, use that as the build path
# otherwise use path in /config (so that builds aren't lost on container restart)
if [[ -d /build ]]; then
export ESPHOME_BUILD_PATH=/build
fi
exec esphome "$@"

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@ -297,8 +297,27 @@ def upload_using_platformio(config, port):
return platformio_api.run_platformio_cli_run(config, CORE.verbose, *upload_args)
def check_permissions(port):
if os.name == "posix" and get_port_type(port) == "SERIAL":
# Check if we can open selected serial port
if not os.access(port, os.F_OK):
raise EsphomeError(
"The selected serial port does not exist. To resolve this issue, "
"check that the device is connected to this computer with a USB cable and that "
"the USB cable can be used for data and is not a power-only cable."
)
if not (os.access(port, os.R_OK | os.W_OK)):
raise EsphomeError(
"You do not have read or write permission on the selected serial port. "
"To resolve this issue, you can add your user to the dialout group "
f"by running the following command: sudo usermod -a -G dialout {os.getlogin()}. "
"You will need to log out & back in or reboot to activate the new group access."
)
def upload_program(config, args, host):
if get_port_type(host) == "SERIAL":
check_permissions(host)
if CORE.target_platform in (PLATFORM_ESP32, PLATFORM_ESP8266):
file = getattr(args, "file", None)
return upload_using_esptool(config, host, file)
@ -344,6 +363,7 @@ def show_logs(config, args, port):
if "logger" not in config:
raise EsphomeError("Logger is not configured!")
if get_port_type(port) == "SERIAL":
check_permissions(port)
return run_miniterm(config, port)
if get_port_type(port) == "NETWORK" and "api" in config:
if config[CONF_MDNS][CONF_DISABLED] and CONF_MQTT in config:

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@ -87,4 +87,5 @@ from esphome.cpp_types import ( # noqa
gpio_Flags,
EntityCategory,
Parented,
ESPTime,
)

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@ -41,6 +41,7 @@ CONF_CURRENT_GAIN_A = "current_gain_a"
CONF_CURRENT_GAIN_B = "current_gain_b"
CONF_ACTIVE_POWER_GAIN_A = "active_power_gain_a"
CONF_ACTIVE_POWER_GAIN_B = "active_power_gain_b"
CONF_USE_ACCUMULATED_ENERGY_REGISTERS = "use_accumulated_energy_registers"
PGA_GAINS = {
"1x": 0b000,
"2x": 0b001,
@ -155,6 +156,7 @@ ADE7953_CONFIG_SCHEMA = cv.Schema(
cv.Optional(CONF_ACTIVE_POWER_GAIN_B, default=0x400000): cv.hex_int_range(
min=0x100000, max=0x800000
),
cv.Optional(CONF_USE_ACCUMULATED_ENERGY_REGISTERS, default=False): cv.boolean,
}
).extend(cv.polling_component_schema("60s"))
@ -174,6 +176,9 @@ async def register_ade7953(var, config):
cg.add(var.set_bigain(config.get(CONF_CURRENT_GAIN_B)))
cg.add(var.set_awgain(config.get(CONF_ACTIVE_POWER_GAIN_A)))
cg.add(var.set_bwgain(config.get(CONF_ACTIVE_POWER_GAIN_B)))
cg.add(
var.set_use_acc_energy_regs(config.get(CONF_USE_ACCUMULATED_ENERGY_REGISTERS))
)
for key in [
CONF_VOLTAGE,

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@ -6,6 +6,9 @@ namespace ade7953_base {
static const char *const TAG = "ade7953";
static const float ADE_POWER_FACTOR = 154.0f;
static const float ADE_WATTSEC_POWER_FACTOR = ADE_POWER_FACTOR * ADE_POWER_FACTOR / 3600;
void ADE7953::setup() {
if (this->irq_pin_ != nullptr) {
this->irq_pin_->setup();
@ -34,6 +37,7 @@ void ADE7953::setup() {
this->ade_read_32(BIGAIN_32, &bigain_);
this->ade_read_32(AWGAIN_32, &awgain_);
this->ade_read_32(BWGAIN_32, &bwgain_);
this->last_update_ = millis();
this->is_setup_ = true;
});
}
@ -52,6 +56,7 @@ void ADE7953::dump_config() {
LOG_SENSOR(" ", "Active Power B Sensor", this->active_power_b_sensor_);
LOG_SENSOR(" ", "Rective Power A Sensor", this->reactive_power_a_sensor_);
LOG_SENSOR(" ", "Reactive Power B Sensor", this->reactive_power_b_sensor_);
ESP_LOGCONFIG(TAG, " USE_ACC_ENERGY_REGS: %d", this->use_acc_energy_regs_);
ESP_LOGCONFIG(TAG, " PGA_V_8: 0x%X", pga_v_);
ESP_LOGCONFIG(TAG, " PGA_IA_8: 0x%X", pga_ia_);
ESP_LOGCONFIG(TAG, " PGA_IB_8: 0x%X", pga_ib_);
@ -85,6 +90,7 @@ void ADE7953::update() {
uint32_t val;
uint16_t val_16;
uint16_t reg;
// Power factor
err = this->ade_read_16(0x010A, &val_16);
@ -92,23 +98,36 @@ void ADE7953::update() {
err = this->ade_read_16(0x010B, &val_16);
ADE_PUBLISH(power_factor_b, (int16_t) val_16, (0x7FFF / 100.0f));
float pf = ADE_POWER_FACTOR;
if (this->use_acc_energy_regs_) {
const uint32_t now = millis();
const auto diff = now - this->last_update_;
this->last_update_ = now;
// prevent DIV/0
pf = ADE_WATTSEC_POWER_FACTOR * (diff < 10 ? 10 : diff) / 1000;
ESP_LOGVV(TAG, "ADE7953::update() diff=%d pf=%f", diff, pf);
}
// Apparent power
err = this->ade_read_32(0x0310, &val);
ADE_PUBLISH(apparent_power_a, (int32_t) val, 154.0f);
err = this->ade_read_32(0x0311, &val);
ADE_PUBLISH(apparent_power_b, (int32_t) val, 154.0f);
reg = this->use_acc_energy_regs_ ? 0x0322 : 0x0310;
err = this->ade_read_32(reg, &val);
ADE_PUBLISH(apparent_power_a, (int32_t) val, pf);
err = this->ade_read_32(reg + 1, &val);
ADE_PUBLISH(apparent_power_b, (int32_t) val, pf);
// Active power
err = this->ade_read_32(0x0312, &val);
ADE_PUBLISH(active_power_a, (int32_t) val, 154.0f);
err = this->ade_read_32(0x0313, &val);
ADE_PUBLISH(active_power_b, (int32_t) val, 154.0f);
reg = this->use_acc_energy_regs_ ? 0x031E : 0x0312;
err = this->ade_read_32(reg, &val);
ADE_PUBLISH(active_power_a, (int32_t) val, pf);
err = this->ade_read_32(reg + 1, &val);
ADE_PUBLISH(active_power_b, (int32_t) val, pf);
// Reactive power
err = this->ade_read_32(0x0314, &val);
ADE_PUBLISH(reactive_power_a, (int32_t) val, 154.0f);
err = this->ade_read_32(0x0315, &val);
ADE_PUBLISH(reactive_power_b, (int32_t) val, 154.0f);
reg = this->use_acc_energy_regs_ ? 0x0320 : 0x0314;
err = this->ade_read_32(reg, &val);
ADE_PUBLISH(reactive_power_a, (int32_t) val, pf);
err = this->ade_read_32(reg + 1, &val);
ADE_PUBLISH(reactive_power_b, (int32_t) val, pf);
// Current
err = this->ade_read_32(0x031A, &val);

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@ -52,6 +52,8 @@ class ADE7953 : public PollingComponent, public sensor::Sensor {
void set_awgain(uint32_t awgain) { awgain_ = awgain; }
void set_bwgain(uint32_t bwgain) { bwgain_ = bwgain; }
void set_use_acc_energy_regs(bool use_acc_energy_regs) { use_acc_energy_regs_ = use_acc_energy_regs; }
void set_voltage_sensor(sensor::Sensor *voltage_sensor) { voltage_sensor_ = voltage_sensor; }
void set_frequency_sensor(sensor::Sensor *frequency_sensor) { frequency_sensor_ = frequency_sensor; }
@ -103,6 +105,8 @@ class ADE7953 : public PollingComponent, public sensor::Sensor {
uint32_t bigain_;
uint32_t awgain_;
uint32_t bwgain_;
bool use_acc_energy_regs_{false};
uint32_t last_update_;
virtual bool ade_write_8(uint16_t reg, uint8_t value) = 0;

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@ -0,0 +1,25 @@
import esphome.codegen as cg
import esphome.config_validation as cv
from esphome.components import spi
from esphome.const import CONF_ID
CODEOWNERS = ["@solomondg1"]
DEPENDENCIES = ["spi"]
MULTI_CONF = True
CONF_ADS1118_ID = "ads1118_id"
ads1118_ns = cg.esphome_ns.namespace("ads1118")
ADS1118 = ads1118_ns.class_("ADS1118", cg.Component, spi.SPIDevice)
CONFIG_SCHEMA = cv.Schema(
{
cv.GenerateID(): cv.declare_id(ADS1118),
}
).extend(spi.spi_device_schema(cs_pin_required=True))
async def to_code(config):
var = cg.new_Pvariable(config[CONF_ID])
await cg.register_component(var, config)
await spi.register_spi_device(var, config)

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@ -0,0 +1,126 @@
#include "ads1118.h"
#include "esphome/core/log.h"
namespace esphome {
namespace ads1118 {
static const char *const TAG = "ads1118";
static const uint8_t ADS1118_DATA_RATE_860_SPS = 0b111;
void ADS1118::setup() {
ESP_LOGCONFIG(TAG, "Setting up ads1118");
this->spi_setup();
this->config_ = 0;
// Setup multiplexer
// 0bx000xxxxxxxxxxxx
this->config_ |= ADS1118_MULTIPLEXER_P0_NG << 12;
// Setup Gain
// 0bxxxx000xxxxxxxxx
this->config_ |= ADS1118_GAIN_6P144 << 9;
// Set singleshot mode
// 0bxxxxxxx1xxxxxxxx
this->config_ |= 0b0000000100000000;
// Set data rate - 860 samples per second (we're in singleshot mode)
// 0bxxxxxxxx100xxxxx
this->config_ |= ADS1118_DATA_RATE_860_SPS << 5;
// Set temperature sensor mode - ADC
// 0bxxxxxxxxxxx0xxxx
this->config_ |= 0b0000000000000000;
// Set DOUT pull up - enable
// 0bxxxxxxxxxxxx0xxx
this->config_ |= 0b0000000000001000;
// NOP - must be 01
// 0bxxxxxxxxxxxxx01x
this->config_ |= 0b0000000000000010;
// Not used - can be 0 or 1, lets be positive
// 0bxxxxxxxxxxxxxxx1
this->config_ |= 0b0000000000000001;
}
void ADS1118::dump_config() {
ESP_LOGCONFIG(TAG, "ADS1118:");
LOG_PIN(" CS Pin:", this->cs_);
}
float ADS1118::request_measurement(ADS1118Multiplexer multiplexer, ADS1118Gain gain, bool temperature_mode) {
uint16_t temp_config = this->config_;
// Multiplexer
// 0bxBBBxxxxxxxxxxxx
temp_config &= 0b1000111111111111;
temp_config |= (multiplexer & 0b111) << 12;
// Gain
// 0bxxxxBBBxxxxxxxxx
temp_config &= 0b1111000111111111;
temp_config |= (gain & 0b111) << 9;
if (temperature_mode) {
// Set temperature sensor mode
// 0bxxxxxxxxxxx1xxxx
temp_config |= 0b0000000000010000;
} else {
// Set ADC mode
// 0bxxxxxxxxxxx0xxxx
temp_config &= 0b1111111111101111;
}
// Start conversion
temp_config |= 0b1000000000000000;
this->enable();
this->write_byte16(temp_config);
this->disable();
// about 1.2 ms with 860 samples per second
delay(2);
this->enable();
uint8_t adc_first_byte = this->read_byte();
uint8_t adc_second_byte = this->read_byte();
this->disable();
uint16_t raw_conversion = encode_uint16(adc_first_byte, adc_second_byte);
auto signed_conversion = static_cast<int16_t>(raw_conversion);
if (temperature_mode) {
return (signed_conversion >> 2) * 0.03125f;
} else {
float millivolts;
float divider = 32768.0f;
switch (gain) {
case ADS1118_GAIN_6P144:
millivolts = (signed_conversion * 6144) / divider;
break;
case ADS1118_GAIN_4P096:
millivolts = (signed_conversion * 4096) / divider;
break;
case ADS1118_GAIN_2P048:
millivolts = (signed_conversion * 2048) / divider;
break;
case ADS1118_GAIN_1P024:
millivolts = (signed_conversion * 1024) / divider;
break;
case ADS1118_GAIN_0P512:
millivolts = (signed_conversion * 512) / divider;
break;
case ADS1118_GAIN_0P256:
millivolts = (signed_conversion * 256) / divider;
break;
default:
millivolts = NAN;
}
return millivolts / 1e3f;
}
}
} // namespace ads1118
} // namespace esphome

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#pragma once
#include "esphome/components/spi/spi.h"
#include "esphome/core/component.h"
#include "esphome/core/hal.h"
namespace esphome {
namespace ads1118 {
enum ADS1118Multiplexer {
ADS1118_MULTIPLEXER_P0_N1 = 0b000,
ADS1118_MULTIPLEXER_P0_N3 = 0b001,
ADS1118_MULTIPLEXER_P1_N3 = 0b010,
ADS1118_MULTIPLEXER_P2_N3 = 0b011,
ADS1118_MULTIPLEXER_P0_NG = 0b100,
ADS1118_MULTIPLEXER_P1_NG = 0b101,
ADS1118_MULTIPLEXER_P2_NG = 0b110,
ADS1118_MULTIPLEXER_P3_NG = 0b111,
};
enum ADS1118Gain {
ADS1118_GAIN_6P144 = 0b000,
ADS1118_GAIN_4P096 = 0b001,
ADS1118_GAIN_2P048 = 0b010,
ADS1118_GAIN_1P024 = 0b011,
ADS1118_GAIN_0P512 = 0b100,
ADS1118_GAIN_0P256 = 0b101,
};
class ADS1118 : public Component,
public spi::SPIDevice<spi::BIT_ORDER_MSB_FIRST, spi::CLOCK_POLARITY_LOW, spi::CLOCK_PHASE_TRAILING,
spi::DATA_RATE_1MHZ> {
public:
ADS1118() = default;
void setup() override;
void dump_config() override;
float get_setup_priority() const override { return setup_priority::DATA; }
/// Helper method to request a measurement from a sensor.
float request_measurement(ADS1118Multiplexer multiplexer, ADS1118Gain gain, bool temperature_mode);
protected:
uint16_t config_{0};
};
} // namespace ads1118
} // namespace esphome

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import esphome.codegen as cg
import esphome.config_validation as cv
from esphome.components import sensor, voltage_sampler
from esphome.const import (
CONF_GAIN,
CONF_MULTIPLEXER,
DEVICE_CLASS_VOLTAGE,
DEVICE_CLASS_TEMPERATURE,
STATE_CLASS_MEASUREMENT,
UNIT_CELSIUS,
UNIT_VOLT,
CONF_TYPE,
)
from .. import ads1118_ns, ADS1118, CONF_ADS1118_ID
AUTO_LOAD = ["voltage_sampler"]
DEPENDENCIES = ["ads1118"]
ADS1118Multiplexer = ads1118_ns.enum("ADS1118Multiplexer")
MUX = {
"A0_A1": ADS1118Multiplexer.ADS1118_MULTIPLEXER_P0_N1,
"A0_A3": ADS1118Multiplexer.ADS1118_MULTIPLEXER_P0_N3,
"A1_A3": ADS1118Multiplexer.ADS1118_MULTIPLEXER_P1_N3,
"A2_A3": ADS1118Multiplexer.ADS1118_MULTIPLEXER_P2_N3,
"A0_GND": ADS1118Multiplexer.ADS1118_MULTIPLEXER_P0_NG,
"A1_GND": ADS1118Multiplexer.ADS1118_MULTIPLEXER_P1_NG,
"A2_GND": ADS1118Multiplexer.ADS1118_MULTIPLEXER_P2_NG,
"A3_GND": ADS1118Multiplexer.ADS1118_MULTIPLEXER_P3_NG,
}
ADS1118Gain = ads1118_ns.enum("ADS1118Gain")
GAIN = {
"6.144": ADS1118Gain.ADS1118_GAIN_6P144,
"4.096": ADS1118Gain.ADS1118_GAIN_4P096,
"2.048": ADS1118Gain.ADS1118_GAIN_2P048,
"1.024": ADS1118Gain.ADS1118_GAIN_1P024,
"0.512": ADS1118Gain.ADS1118_GAIN_0P512,
"0.256": ADS1118Gain.ADS1118_GAIN_0P256,
}
ADS1118Sensor = ads1118_ns.class_(
"ADS1118Sensor",
cg.PollingComponent,
sensor.Sensor,
voltage_sampler.VoltageSampler,
cg.Parented.template(ADS1118),
)
TYPE_ADC = "adc"
TYPE_TEMPERATURE = "temperature"
CONFIG_SCHEMA = cv.typed_schema(
{
TYPE_ADC: sensor.sensor_schema(
ADS1118Sensor,
unit_of_measurement=UNIT_VOLT,
accuracy_decimals=3,
device_class=DEVICE_CLASS_VOLTAGE,
state_class=STATE_CLASS_MEASUREMENT,
)
.extend(
{
cv.GenerateID(CONF_ADS1118_ID): cv.use_id(ADS1118),
cv.Required(CONF_MULTIPLEXER): cv.enum(MUX, upper=True, space="_"),
cv.Required(CONF_GAIN): cv.enum(GAIN, string=True),
}
)
.extend(cv.polling_component_schema("60s")),
TYPE_TEMPERATURE: sensor.sensor_schema(
ADS1118Sensor,
unit_of_measurement=UNIT_CELSIUS,
accuracy_decimals=2,
device_class=DEVICE_CLASS_TEMPERATURE,
state_class=STATE_CLASS_MEASUREMENT,
)
.extend(
{
cv.GenerateID(CONF_ADS1118_ID): cv.use_id(ADS1118),
}
)
.extend(cv.polling_component_schema("60s")),
},
default_type=TYPE_ADC,
)
async def to_code(config):
var = await sensor.new_sensor(config)
await cg.register_component(var, config)
await cg.register_parented(var, config[CONF_ADS1118_ID])
if config[CONF_TYPE] == TYPE_ADC:
cg.add(var.set_multiplexer(config[CONF_MULTIPLEXER]))
cg.add(var.set_gain(config[CONF_GAIN]))
if config[CONF_TYPE] == TYPE_TEMPERATURE:
cg.add(var.set_temperature_mode(True))

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#include "ads1118_sensor.h"
#include "esphome/core/log.h"
namespace esphome {
namespace ads1118 {
static const char *const TAG = "ads1118.sensor";
void ADS1118Sensor::dump_config() {
LOG_SENSOR(" ", "ADS1118 Sensor", this);
ESP_LOGCONFIG(TAG, " Multiplexer: %u", this->multiplexer_);
ESP_LOGCONFIG(TAG, " Gain: %u", this->gain_);
}
float ADS1118Sensor::sample() {
return this->parent_->request_measurement(this->multiplexer_, this->gain_, this->temperature_mode_);
}
void ADS1118Sensor::update() {
float v = this->sample();
if (!std::isnan(v)) {
ESP_LOGD(TAG, "'%s': Got Voltage=%fV", this->get_name().c_str(), v);
this->publish_state(v);
}
}
} // namespace ads1118
} // namespace esphome

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#pragma once
#include "esphome/core/component.h"
#include "esphome/core/helpers.h"
#include "esphome/components/sensor/sensor.h"
#include "esphome/components/voltage_sampler/voltage_sampler.h"
#include "../ads1118.h"
namespace esphome {
namespace ads1118 {
class ADS1118Sensor : public PollingComponent,
public sensor::Sensor,
public voltage_sampler::VoltageSampler,
public Parented<ADS1118> {
public:
void update() override;
void set_multiplexer(ADS1118Multiplexer multiplexer) { this->multiplexer_ = multiplexer; }
void set_gain(ADS1118Gain gain) { this->gain_ = gain; }
void set_temperature_mode(bool temp) { this->temperature_mode_ = temp; }
float sample() override;
void dump_config() override;
protected:
ADS1118Multiplexer multiplexer_{ADS1118_MULTIPLEXER_P0_NG};
ADS1118Gain gain_{ADS1118_GAIN_6P144};
bool temperature_mode_;
};
} // namespace ads1118
} // namespace esphome

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CODEOWNERS = ["@mak-42"]

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#include "ags10.h"
namespace esphome {
namespace ags10 {
static const char *const TAG = "ags10";
// Data acquisition.
static const uint8_t REG_TVOC = 0x00;
// Zero-point calibration.
static const uint8_t REG_CALIBRATION = 0x01;
// Read version.
static const uint8_t REG_VERSION = 0x11;
// Read current resistance.
static const uint8_t REG_RESISTANCE = 0x20;
// Modify target address.
static const uint8_t REG_ADDRESS = 0x21;
// Zero-point calibration with current resistance.
static const uint16_t ZP_CURRENT = 0x0000;
// Zero-point reset.
static const uint16_t ZP_DEFAULT = 0xFFFF;
void AGS10Component::setup() {
ESP_LOGCONFIG(TAG, "Setting up ags10...");
auto version = this->read_version_();
if (version) {
ESP_LOGD(TAG, "AGS10 Sensor Version: 0x%02X", *version);
if (this->version_ != nullptr) {
this->version_->publish_state(*version);
}
} else {
ESP_LOGE(TAG, "AGS10 Sensor Version: unknown");
}
auto resistance = this->read_resistance_();
if (resistance) {
ESP_LOGD(TAG, "AGS10 Sensor Resistance: 0x%08X", *resistance);
if (this->resistance_ != nullptr) {
this->resistance_->publish_state(*resistance);
}
} else {
ESP_LOGE(TAG, "AGS10 Sensor Resistance: unknown");
}
ESP_LOGD(TAG, "Sensor initialized");
}
void AGS10Component::update() {
auto tvoc = this->read_tvoc_();
if (tvoc) {
this->tvoc_->publish_state(*tvoc);
this->status_clear_warning();
} else {
this->status_set_warning();
}
}
void AGS10Component::dump_config() {
ESP_LOGCONFIG(TAG, "AGS10:");
LOG_I2C_DEVICE(this);
switch (this->error_code_) {
case NONE:
break;
case COMMUNICATION_FAILED:
ESP_LOGE(TAG, "Communication with AGS10 failed!");
break;
case CRC_CHECK_FAILED:
ESP_LOGE(TAG, "The crc check failed");
break;
case ILLEGAL_STATUS:
ESP_LOGE(TAG, "AGS10 is not ready to return TVOC data or sensor in pre-heat stage.");
break;
case UNSUPPORTED_UNITS:
ESP_LOGE(TAG, "AGS10 returns TVOC data in unsupported units.");
break;
default:
ESP_LOGE(TAG, "Unknown error: %d", this->error_code_);
break;
}
LOG_UPDATE_INTERVAL(this);
LOG_SENSOR(" ", "TVOC Sensor", this->tvoc_);
LOG_SENSOR(" ", "Firmware Version Sensor", this->version_);
LOG_SENSOR(" ", "Resistance Sensor", this->resistance_);
}
/**
* Sets new I2C address of AGS10.
*/
bool AGS10Component::new_i2c_address(uint8_t newaddress) {
uint8_t rev_newaddress = ~newaddress;
std::array<uint8_t, 5> data{newaddress, rev_newaddress, newaddress, rev_newaddress, 0};
data[4] = calc_crc8_(data, 4);
if (!this->write_bytes(REG_ADDRESS, data)) {
this->error_code_ = COMMUNICATION_FAILED;
this->status_set_warning();
ESP_LOGE(TAG, "couldn't write the new I2C address 0x%02X", newaddress);
return false;
}
this->set_i2c_address(newaddress);
ESP_LOGW(TAG, "changed I2C address to 0x%02X", newaddress);
this->error_code_ = NONE;
this->status_clear_warning();
return true;
}
bool AGS10Component::set_zero_point_with_factory_defaults() { return this->set_zero_point_with(ZP_DEFAULT); }
bool AGS10Component::set_zero_point_with_current_resistance() { return this->set_zero_point_with(ZP_CURRENT); }
bool AGS10Component::set_zero_point_with(uint16_t value) {
std::array<uint8_t, 5> data{0x00, 0x0C, (uint8_t) ((value >> 8) & 0xFF), (uint8_t) (value & 0xFF), 0};
data[4] = calc_crc8_(data, 4);
if (!this->write_bytes(REG_CALIBRATION, data)) {
this->error_code_ = COMMUNICATION_FAILED;
this->status_set_warning();
ESP_LOGE(TAG, "unable to set zero-point calibration with 0x%02X", value);
return false;
}
if (value == ZP_CURRENT) {
ESP_LOGI(TAG, "zero-point calibration has been set with current resistance");
} else if (value == ZP_DEFAULT) {
ESP_LOGI(TAG, "zero-point calibration has been reset to the factory defaults");
} else {
ESP_LOGI(TAG, "zero-point calibration has been set with 0x%02X", value);
}
this->error_code_ = NONE;
this->status_clear_warning();
return true;
}
optional<uint32_t> AGS10Component::read_tvoc_() {
auto data = this->read_and_check_<5>(REG_TVOC);
if (!data) {
return nullopt;
}
auto res = *data;
auto status_byte = res[0];
int units = status_byte & 0x0e;
int status_bit = status_byte & 0x01;
if (status_bit != 0) {
this->error_code_ = ILLEGAL_STATUS;
ESP_LOGW(TAG, "Reading AGS10 data failed: illegal status (not ready or sensor in pre-heat stage)!");
return nullopt;
}
if (units != 0) {
this->error_code_ = UNSUPPORTED_UNITS;
ESP_LOGE(TAG, "Reading AGS10 data failed: unsupported units (%d)!", units);
return nullopt;
}
return encode_uint24(res[1], res[2], res[3]);
}
optional<uint8_t> AGS10Component::read_version_() {
auto data = this->read_and_check_<5>(REG_VERSION);
if (data) {
auto res = *data;
return res[3];
}
return nullopt;
}
optional<uint32_t> AGS10Component::read_resistance_() {
auto data = this->read_and_check_<5>(REG_RESISTANCE);
if (data) {
auto res = *data;
return encode_uint32(res[0], res[1], res[2], res[3]);
}
return nullopt;
}
template<size_t N> optional<std::array<uint8_t, N>> AGS10Component::read_and_check_(uint8_t a_register) {
auto data = this->read_bytes<N>(a_register);
if (!data.has_value()) {
this->error_code_ = COMMUNICATION_FAILED;
ESP_LOGE(TAG, "Reading AGS10 version failed!");
return optional<std::array<uint8_t, N>>();
}
auto len = N - 1;
auto res = *data;
auto crc_byte = res[len];
if (crc_byte != calc_crc8_(res, len)) {
this->error_code_ = CRC_CHECK_FAILED;
ESP_LOGE(TAG, "Reading AGS10 version failed: crc error!");
return optional<std::array<uint8_t, N>>();
}
return data;
}
template<size_t N> uint8_t AGS10Component::calc_crc8_(std::array<uint8_t, N> dat, uint8_t num) {
uint8_t i, byte1, crc = 0xFF;
for (byte1 = 0; byte1 < num; byte1++) {
crc ^= (dat[byte1]);
for (i = 0; i < 8; i++) {
if (crc & 0x80) {
crc = (crc << 1) ^ 0x31;
} else {
crc = (crc << 1);
}
}
}
return crc;
}
} // namespace ags10
} // namespace esphome

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#pragma once
#include "esphome/core/automation.h"
#include "esphome/core/component.h"
#include "esphome/components/sensor/sensor.h"
#include "esphome/components/i2c/i2c.h"
namespace esphome {
namespace ags10 {
class AGS10Component : public PollingComponent, public i2c::I2CDevice {
public:
/**
* Sets TVOC sensor.
*/
void set_tvoc(sensor::Sensor *tvoc) { this->tvoc_ = tvoc; }
/**
* Sets version info sensor.
*/
void set_version(sensor::Sensor *version) { this->version_ = version; }
/**
* Sets resistance info sensor.
*/
void set_resistance(sensor::Sensor *resistance) { this->resistance_ = resistance; }
void setup() override;
void update() override;
void dump_config() override;
float get_setup_priority() const override { return setup_priority::DATA; }
/**
* Modifies target address of AGS10.
*
* New address is saved and takes effect immediately even after power-off.
*/
bool new_i2c_address(uint8_t newaddress);
/**
* Sets zero-point with factory defaults.
*/
bool set_zero_point_with_factory_defaults();
/**
* Sets zero-point with current sensor resistance.
*/
bool set_zero_point_with_current_resistance();
/**
* Sets zero-point with the value.
*/
bool set_zero_point_with(uint16_t value);
protected:
/**
* TVOC.
*/
sensor::Sensor *tvoc_{nullptr};
/**
* Firmvare version.
*/
sensor::Sensor *version_{nullptr};
/**
* Resistance.
*/
sensor::Sensor *resistance_{nullptr};
/**
* Last operation error code.
*/
enum ErrorCode {
NONE = 0,
COMMUNICATION_FAILED,
CRC_CHECK_FAILED,
ILLEGAL_STATUS,
UNSUPPORTED_UNITS,
} error_code_{NONE};
/**
* Reads and returns value of TVOC.
*/
optional<uint32_t> read_tvoc_();
/**
* Reads and returns a firmware version of AGS10.
*/
optional<uint8_t> read_version_();
/**
* Reads and returns the resistance of AGS10.
*/
optional<uint32_t> read_resistance_();
/**
* Read, checks and returns data from the sensor.
*/
template<size_t N> optional<std::array<uint8_t, N>> read_and_check_(uint8_t a_register);
/**
* Calculates CRC8 value.
*
* CRC8 calculation, initial value: 0xFF, polynomial: 0x31 (x8+ x5+ x4+1)
*
* @param[in] dat the data buffer
* @param num number of bytes in the buffer
*/
template<size_t N> uint8_t calc_crc8_(std::array<uint8_t, N> dat, uint8_t num);
};
template<typename... Ts> class AGS10NewI2cAddressAction : public Action<Ts...>, public Parented<AGS10Component> {
public:
TEMPLATABLE_VALUE(uint8_t, new_address)
void play(Ts... x) override { this->parent_->new_i2c_address(this->new_address_.value(x...)); }
};
enum AGS10SetZeroPointActionMode {
// Zero-point reset.
FACTORY_DEFAULT,
// Zero-point calibration with current resistance.
CURRENT_VALUE,
// Zero-point calibration with custom resistance.
CUSTOM_VALUE,
};
template<typename... Ts> class AGS10SetZeroPointAction : public Action<Ts...>, public Parented<AGS10Component> {
public:
TEMPLATABLE_VALUE(uint16_t, value)
TEMPLATABLE_VALUE(AGS10SetZeroPointActionMode, mode)
void play(Ts... x) override {
switch (this->mode_.value(x...)) {
case FACTORY_DEFAULT:
this->parent_->set_zero_point_with_factory_defaults();
break;
case CURRENT_VALUE:
this->parent_->set_zero_point_with_current_resistance();
break;
case CUSTOM_VALUE:
this->parent_->set_zero_point_with(this->value_.value(x...));
break;
}
}
};
} // namespace ags10
} // namespace esphome

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import esphome.codegen as cg
from esphome import automation
import esphome.config_validation as cv
from esphome.components import i2c, sensor
from esphome.const import (
CONF_ID,
ICON_RADIATOR,
ICON_RESTART,
DEVICE_CLASS_VOLATILE_ORGANIC_COMPOUNDS_PARTS,
ENTITY_CATEGORY_DIAGNOSTIC,
STATE_CLASS_MEASUREMENT,
UNIT_OHM,
UNIT_PARTS_PER_BILLION,
CONF_ADDRESS,
CONF_TVOC,
CONF_VERSION,
CONF_MODE,
CONF_VALUE,
)
CONF_RESISTANCE = "resistance"
DEPENDENCIES = ["i2c"]
ags10_ns = cg.esphome_ns.namespace("ags10")
AGS10Component = ags10_ns.class_("AGS10Component", cg.PollingComponent, i2c.I2CDevice)
# Actions
AGS10NewI2cAddressAction = ags10_ns.class_(
"AGS10NewI2cAddressAction", automation.Action
)
AGS10SetZeroPointAction = ags10_ns.class_("AGS10SetZeroPointAction", automation.Action)
CONFIG_SCHEMA = (
cv.Schema(
{
cv.GenerateID(): cv.declare_id(AGS10Component),
cv.Optional(CONF_TVOC): sensor.sensor_schema(
unit_of_measurement=UNIT_PARTS_PER_BILLION,
icon=ICON_RADIATOR,
accuracy_decimals=0,
device_class=DEVICE_CLASS_VOLATILE_ORGANIC_COMPOUNDS_PARTS,
state_class=STATE_CLASS_MEASUREMENT,
),
cv.Optional(CONF_VERSION): sensor.sensor_schema(
icon=ICON_RESTART,
entity_category=ENTITY_CATEGORY_DIAGNOSTIC,
),
cv.Optional(CONF_RESISTANCE): sensor.sensor_schema(
unit_of_measurement=UNIT_OHM,
icon=ICON_RESTART,
accuracy_decimals=0,
state_class=STATE_CLASS_MEASUREMENT,
entity_category=ENTITY_CATEGORY_DIAGNOSTIC,
),
}
)
.extend(cv.polling_component_schema("60s"))
.extend(i2c.i2c_device_schema(0x1A))
)
FINAL_VALIDATE_SCHEMA = i2c.final_validate_device_schema("ags10", max_frequency="15khz")
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)
sens = await sensor.new_sensor(config[CONF_TVOC])
cg.add(var.set_tvoc(sens))
if version_config := config.get(CONF_VERSION):
sens = await sensor.new_sensor(version_config)
cg.add(var.set_version(sens))
if resistance_config := config.get(CONF_RESISTANCE):
sens = await sensor.new_sensor(resistance_config)
cg.add(var.set_resistance(sens))
AGS10_NEW_I2C_ADDRESS_SCHEMA = cv.maybe_simple_value(
{
cv.GenerateID(): cv.use_id(AGS10Component),
cv.Required(CONF_ADDRESS): cv.templatable(cv.i2c_address),
},
key=CONF_ADDRESS,
)
@automation.register_action(
"ags10.new_i2c_address",
AGS10NewI2cAddressAction,
AGS10_NEW_I2C_ADDRESS_SCHEMA,
)
async def ags10newi2caddress_to_code(config, action_id, template_arg, args):
var = cg.new_Pvariable(action_id, template_arg)
await cg.register_parented(var, config[CONF_ID])
address = await cg.templatable(config[CONF_ADDRESS], args, int)
cg.add(var.set_new_address(address))
return var
AGS10SetZeroPointActionMode = ags10_ns.enum("AGS10SetZeroPointActionMode")
AGS10_SET_ZERO_POINT_ACTION_MODE = {
"FACTORY_DEFAULT": AGS10SetZeroPointActionMode.FACTORY_DEFAULT,
"CURRENT_VALUE": AGS10SetZeroPointActionMode.CURRENT_VALUE,
"CUSTOM_VALUE": AGS10SetZeroPointActionMode.CUSTOM_VALUE,
}
AGS10_SET_ZERO_POINT_SCHEMA = cv.Schema(
{
cv.GenerateID(): cv.use_id(AGS10Component),
cv.Required(CONF_MODE): cv.enum(AGS10_SET_ZERO_POINT_ACTION_MODE, upper=True),
cv.Optional(CONF_VALUE, default=0xFFFF): cv.templatable(cv.uint16_t),
},
)
@automation.register_action(
"ags10.set_zero_point",
AGS10SetZeroPointAction,
AGS10_SET_ZERO_POINT_SCHEMA,
)
async def ags10setzeropoint_to_code(config, action_id, template_arg, args):
var = cg.new_Pvariable(action_id, template_arg)
await cg.register_parented(var, config[CONF_ID])
mode = await cg.templatable(config.get(CONF_MODE), args, enumerate)
cg.add(var.set_mode(mode))
value = await cg.templatable(config[CONF_VALUE], args, int)
cg.add(var.set_value(value))
return var

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@ -21,30 +21,39 @@ namespace esphome {
namespace aht10 {
static const char *const TAG = "aht10";
static const size_t SIZE_CALIBRATE_CMD = 3;
static const uint8_t AHT10_CALIBRATE_CMD[] = {0xE1, 0x08, 0x00};
static const uint8_t AHT20_CALIBRATE_CMD[] = {0xBE, 0x08, 0x00};
static const uint8_t AHT10_INITIALIZE_CMD[] = {0xE1, 0x08, 0x00};
static const uint8_t AHT20_INITIALIZE_CMD[] = {0xBE, 0x08, 0x00};
static const uint8_t AHT10_MEASURE_CMD[] = {0xAC, 0x33, 0x00};
static const uint8_t AHT10_DEFAULT_DELAY = 5; // ms, for calibration and temperature measurement
static const uint8_t AHT10_SOFTRESET_CMD[] = {0xBA};
static const uint8_t AHT10_DEFAULT_DELAY = 5; // ms, for initialization and temperature measurement
static const uint8_t AHT10_HUMIDITY_DELAY = 30; // ms
static const uint8_t AHT10_SOFTRESET_DELAY = 30; // ms
static const uint8_t AHT10_ATTEMPTS = 3; // safety margin, normally 3 attempts are enough: 3*30=90ms
static const uint8_t AHT10_CAL_ATTEMPTS = 10;
static const uint8_t AHT10_INIT_ATTEMPTS = 10;
static const uint8_t AHT10_STATUS_BUSY = 0x80;
void AHT10Component::setup() {
const uint8_t *calibrate_cmd;
if (this->write(AHT10_SOFTRESET_CMD, sizeof(AHT10_SOFTRESET_CMD)) != i2c::ERROR_OK) {
ESP_LOGE(TAG, "Reset AHT10 failed!");
}
delay(AHT10_SOFTRESET_DELAY);
const uint8_t *init_cmd;
switch (this->variant_) {
case AHT10Variant::AHT20:
calibrate_cmd = AHT20_CALIBRATE_CMD;
init_cmd = AHT20_INITIALIZE_CMD;
ESP_LOGCONFIG(TAG, "Setting up AHT20");
break;
case AHT10Variant::AHT10:
default:
calibrate_cmd = AHT10_CALIBRATE_CMD;
init_cmd = AHT10_INITIALIZE_CMD;
ESP_LOGCONFIG(TAG, "Setting up AHT10");
}
if (this->write(calibrate_cmd, SIZE_CALIBRATE_CMD) != i2c::ERROR_OK) {
if (this->write(init_cmd, sizeof(init_cmd)) != i2c::ERROR_OK) {
ESP_LOGE(TAG, "Communication with AHT10 failed!");
this->mark_failed();
return;
@ -59,19 +68,19 @@ void AHT10Component::setup() {
return;
}
++cal_attempts;
if (cal_attempts > AHT10_CAL_ATTEMPTS) {
ESP_LOGE(TAG, "AHT10 calibration timed out!");
if (cal_attempts > AHT10_INIT_ATTEMPTS) {
ESP_LOGE(TAG, "AHT10 initialization timed out!");
this->mark_failed();
return;
}
}
if ((data & 0x68) != 0x08) { // Bit[6:5] = 0b00, NORMAL mode and Bit[3] = 0b1, CALIBRATED
ESP_LOGE(TAG, "AHT10 calibration failed!");
ESP_LOGE(TAG, "AHT10 initialization failed!");
this->mark_failed();
return;
}
ESP_LOGV(TAG, "AHT10 calibrated");
ESP_LOGV(TAG, "AHT10 initialization");
}
void AHT10Component::update() {

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@ -0,0 +1 @@
CODEOWNERS = ["@swoboda1337"]

View File

@ -0,0 +1,200 @@
// MIT License
//
// Copyright (c) 2023-2024 Rob Tillaart
//
// Permission is hereby granted, free of charge, to any person obtaining a copy
// of this software and associated documentation files (the "Software"), to deal
// in the Software without restriction, including without limitation the rights
// to use, copy, modify, merge, publish, distribute, sublicense, and/or sell
// copies of the Software, and to permit persons to whom the Software is
// furnished to do so, subject to the following conditions:
//
// The above copyright notice and this permission notice shall be included in all
// copies or substantial portions of the Software.
//
// THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
// IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
// FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE
// AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER
// LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM,
// OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE
// SOFTWARE.
#include "am2315c.h"
#include "esphome/core/hal.h"
#include "esphome/core/helpers.h"
#include "esphome/core/log.h"
namespace esphome {
namespace am2315c {
static const char *const TAG = "am2315c";
uint8_t AM2315C::crc8_(uint8_t *data, uint8_t len) {
uint8_t crc = 0xFF;
while (len--) {
crc ^= *data++;
for (uint8_t i = 0; i < 8; i++) {
if (crc & 0x80) {
crc <<= 1;
crc ^= 0x31;
} else {
crc <<= 1;
}
}
}
return crc;
}
bool AM2315C::reset_register_(uint8_t reg) {
// code based on demo code sent by www.aosong.com
// no further documentation.
// 0x1B returned 18, 0, 4
// 0x1C returned 18, 65, 0
// 0x1E returned 18, 8, 0
// 18 seems to be status register
// other values unknown.
uint8_t data[3];
data[0] = reg;
data[1] = 0;
data[2] = 0;
ESP_LOGD(TAG, "Reset register: 0x%02x", reg);
if (this->write(data, 3) != i2c::ERROR_OK) {
ESP_LOGE(TAG, "Write failed!");
this->mark_failed();
return false;
}
delay(5);
if (this->read(data, 3) != i2c::ERROR_OK) {
ESP_LOGE(TAG, "Read failed!");
this->mark_failed();
return false;
}
delay(10);
data[0] = 0xB0 | reg;
if (this->write(data, 3) != i2c::ERROR_OK) {
ESP_LOGE(TAG, "Write failed!");
this->mark_failed();
return false;
}
delay(5);
return true;
}
bool AM2315C::convert_(uint8_t *data, float &humidity, float &temperature) {
uint32_t raw;
raw = (data[1] << 12) | (data[2] << 4) | (data[3] >> 4);
humidity = raw * 9.5367431640625e-5;
raw = ((data[3] & 0x0F) << 16) | (data[4] << 8) | data[5];
temperature = raw * 1.9073486328125e-4 - 50;
return this->crc8_(data, 6) == data[6];
}
void AM2315C::setup() {
ESP_LOGCONFIG(TAG, "Setting up AM2315C...");
// get status
uint8_t status = 0;
if (this->read(&status, 1) != i2c::ERROR_OK) {
ESP_LOGE(TAG, "Read failed!");
this->mark_failed();
return;
}
// reset registers if required, according to the datasheet
// this can be required after power on, although this was
// never required during testing
if ((status & 0x18) != 0x18) {
ESP_LOGD(TAG, "Resetting AM2315C registers");
if (!this->reset_register_(0x1B)) {
this->mark_failed();
return;
}
if (!this->reset_register_(0x1C)) {
this->mark_failed();
return;
}
if (!this->reset_register_(0x1E)) {
this->mark_failed();
return;
}
}
}
void AM2315C::update() {
// request measurement
uint8_t data[3];
data[0] = 0xAC;
data[1] = 0x33;
data[2] = 0x00;
if (this->write(data, 3) != i2c::ERROR_OK) {
ESP_LOGE(TAG, "Write failed!");
this->mark_failed();
return;
}
// wait for hw to complete measurement
set_timeout(160, [this]() {
// check status
uint8_t status = 0;
if (this->read(&status, 1) != i2c::ERROR_OK) {
ESP_LOGE(TAG, "Read failed!");
this->mark_failed();
return;
}
if ((status & 0x80) == 0x80) {
ESP_LOGE(TAG, "HW still busy!");
this->mark_failed();
return;
}
// read
uint8_t data[7];
if (this->read(data, 7) != i2c::ERROR_OK) {
ESP_LOGE(TAG, "Read failed!");
this->mark_failed();
return;
}
// check for all zeros
bool zeros = true;
for (uint8_t i : data) {
zeros = zeros && (i == 0);
}
if (zeros) {
ESP_LOGW(TAG, "Data all zeros!");
this->status_set_warning();
return;
}
// convert
float temperature = 0.0;
float humidity = 0.0;
if (this->convert_(data, humidity, temperature)) {
if (this->temperature_sensor_ != nullptr) {
this->temperature_sensor_->publish_state(temperature);
}
if (this->humidity_sensor_ != nullptr) {
this->humidity_sensor_->publish_state(humidity);
}
this->status_clear_warning();
} else {
ESP_LOGW(TAG, "CRC failed!");
this->status_set_warning();
}
});
}
void AM2315C::dump_config() {
ESP_LOGCONFIG(TAG, "AM2315C:");
LOG_I2C_DEVICE(this);
if (this->is_failed()) {
ESP_LOGE(TAG, "Communication with AM2315C failed!");
}
LOG_SENSOR(" ", "Temperature", this->temperature_sensor_);
LOG_SENSOR(" ", "Humidity", this->humidity_sensor_);
}
float AM2315C::get_setup_priority() const { return setup_priority::DATA; }
} // namespace am2315c
} // namespace esphome

View File

@ -0,0 +1,51 @@
// MIT License
//
// Copyright (c) 2023-2024 Rob Tillaart
//
// Permission is hereby granted, free of charge, to any person obtaining a copy
// of this software and associated documentation files (the "Software"), to deal
// in the Software without restriction, including without limitation the rights
// to use, copy, modify, merge, publish, distribute, sublicense, and/or sell
// copies of the Software, and to permit persons to whom the Software is
// furnished to do so, subject to the following conditions:
//
// The above copyright notice and this permission notice shall be included in all
// copies or substantial portions of the Software.
//
// THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
// IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
// FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE
// AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER
// LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM,
// OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE
// SOFTWARE.
#pragma once
#include "esphome/core/component.h"
#include "esphome/components/sensor/sensor.h"
#include "esphome/components/i2c/i2c.h"
namespace esphome {
namespace am2315c {
class AM2315C : public PollingComponent, public i2c::I2CDevice {
public:
void dump_config() override;
void update() override;
void setup() override;
float get_setup_priority() const override;
void set_temperature_sensor(sensor::Sensor *temperature_sensor) { this->temperature_sensor_ = temperature_sensor; }
void set_humidity_sensor(sensor::Sensor *humidity_sensor) { this->humidity_sensor_ = humidity_sensor; }
protected:
uint8_t crc8_(uint8_t *data, uint8_t len);
bool convert_(uint8_t *data, float &humidity, float &temperature);
bool reset_register_(uint8_t reg);
sensor::Sensor *temperature_sensor_{nullptr};
sensor::Sensor *humidity_sensor_{nullptr};
};
} // namespace am2315c
} // namespace esphome

View File

@ -0,0 +1,54 @@
import esphome.codegen as cg
import esphome.config_validation as cv
from esphome.components import i2c, sensor
from esphome.const import (
CONF_HUMIDITY,
CONF_ID,
CONF_TEMPERATURE,
DEVICE_CLASS_HUMIDITY,
DEVICE_CLASS_TEMPERATURE,
STATE_CLASS_MEASUREMENT,
UNIT_CELSIUS,
UNIT_PERCENT,
)
DEPENDENCIES = ["i2c"]
am2315c_ns = cg.esphome_ns.namespace("am2315c")
AM2315C = am2315c_ns.class_("AM2315C", cg.PollingComponent, i2c.I2CDevice)
CONFIG_SCHEMA = (
cv.Schema(
{
cv.GenerateID(): cv.declare_id(AM2315C),
cv.Optional(CONF_TEMPERATURE): sensor.sensor_schema(
unit_of_measurement=UNIT_CELSIUS,
accuracy_decimals=1,
device_class=DEVICE_CLASS_TEMPERATURE,
state_class=STATE_CLASS_MEASUREMENT,
),
cv.Optional(CONF_HUMIDITY): sensor.sensor_schema(
unit_of_measurement=UNIT_PERCENT,
accuracy_decimals=1,
device_class=DEVICE_CLASS_HUMIDITY,
state_class=STATE_CLASS_MEASUREMENT,
),
}
)
.extend(cv.polling_component_schema("60s"))
.extend(i2c.i2c_device_schema(0x38))
)
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)
if temperature_config := config.get(CONF_TEMPERATURE):
sens = await sensor.new_sensor(temperature_config)
cg.add(var.set_temperature_sensor(sens))
if humidity_config := config.get(CONF_HUMIDITY):
sens = await sensor.new_sensor(humidity_config)
cg.add(var.set_humidity_sensor(sens))

View File

@ -44,6 +44,7 @@ service APIConnection {
rpc button_command (ButtonCommandRequest) returns (void) {}
rpc lock_command (LockCommandRequest) returns (void) {}
rpc media_player_command (MediaPlayerCommandRequest) returns (void) {}
rpc date_command (DateCommandRequest) returns (void) {}
rpc subscribe_bluetooth_le_advertisements(SubscribeBluetoothLEAdvertisementsRequest) returns (void) {}
rpc bluetooth_device_request(BluetoothDeviceRequest) returns (void) {}
@ -600,6 +601,7 @@ message ListEntitiesTextSensorResponse {
string icon = 5;
bool disabled_by_default = 6;
EntityCategory entity_category = 7;
string device_class = 8;
}
message TextSensorStateResponse {
option (id) = 27;
@ -1449,6 +1451,7 @@ message VoiceAssistantRequest {
string conversation_id = 2;
uint32 flags = 3;
VoiceAssistantAudioSettings audio_settings = 4;
string wake_word_phrase = 5;
}
message VoiceAssistantResponse {
@ -1596,3 +1599,45 @@ message TextCommandRequest {
fixed32 key = 1;
string state = 2;
}
// ==================== DATETIME DATE ====================
message ListEntitiesDateResponse {
option (id) = 100;
option (source) = SOURCE_SERVER;
option (ifdef) = "USE_DATETIME_DATE";
string object_id = 1;
fixed32 key = 2;
string name = 3;
string unique_id = 4;
string icon = 5;
bool disabled_by_default = 6;
EntityCategory entity_category = 7;
}
message DateStateResponse {
option (id) = 101;
option (source) = SOURCE_SERVER;
option (ifdef) = "USE_DATETIME_DATE";
option (no_delay) = true;
fixed32 key = 1;
// If the date does not have a valid state yet.
// Equivalent to `!obj->has_state()` - inverse logic to make state packets smaller
bool missing_state = 2;
uint32 year = 3;
uint32 month = 4;
uint32 day = 5;
}
message DateCommandRequest {
option (id) = 102;
option (source) = SOURCE_CLIENT;
option (ifdef) = "USE_DATETIME_DATE";
option (no_delay) = true;
fixed32 key = 1;
uint32 year = 2;
uint32 month = 3;
uint32 day = 4;
}

View File

@ -543,6 +543,7 @@ bool APIConnection::send_text_sensor_info(text_sensor::TextSensor *text_sensor)
msg.icon = text_sensor->get_icon();
msg.disabled_by_default = text_sensor->is_disabled_by_default();
msg.entity_category = static_cast<enums::EntityCategory>(text_sensor->get_entity_category());
msg.device_class = text_sensor->get_device_class();
return this->send_list_entities_text_sensor_response(msg);
}
#endif
@ -697,6 +698,43 @@ void APIConnection::number_command(const NumberCommandRequest &msg) {
}
#endif
#ifdef USE_DATETIME_DATE
bool APIConnection::send_date_state(datetime::DateEntity *date) {
if (!this->state_subscription_)
return false;
DateStateResponse resp{};
resp.key = date->get_object_id_hash();
resp.missing_state = !date->has_state();
resp.year = date->year;
resp.month = date->month;
resp.day = date->day;
return this->send_date_state_response(resp);
}
bool APIConnection::send_date_info(datetime::DateEntity *date) {
ListEntitiesDateResponse msg;
msg.key = date->get_object_id_hash();
msg.object_id = date->get_object_id();
if (date->has_own_name())
msg.name = date->get_name();
msg.unique_id = get_default_unique_id("date", date);
msg.icon = date->get_icon();
msg.disabled_by_default = date->is_disabled_by_default();
msg.entity_category = static_cast<enums::EntityCategory>(date->get_entity_category());
return this->send_list_entities_date_response(msg);
}
void APIConnection::date_command(const DateCommandRequest &msg) {
datetime::DateEntity *date = App.get_date_by_key(msg.key);
if (date == nullptr)
return;
auto call = date->make_call();
call.set_date(msg.year, msg.month, msg.day);
call.perform();
}
#endif
#ifdef USE_TEXT
bool APIConnection::send_text_state(text::Text *text, std::string state) {
if (!this->state_subscription_)

View File

@ -72,6 +72,11 @@ class APIConnection : public APIServerConnection {
bool send_number_info(number::Number *number);
void number_command(const NumberCommandRequest &msg) override;
#endif
#ifdef USE_DATETIME_DATE
bool send_date_state(datetime::DateEntity *date);
bool send_date_info(datetime::DateEntity *date);
void date_command(const DateCommandRequest &msg) override;
#endif
#ifdef USE_TEXT
bool send_text_state(text::Text *text, std::string state);
bool send_text_info(text::Text *text);

View File

@ -2721,6 +2721,10 @@ bool ListEntitiesTextSensorResponse::decode_length(uint32_t field_id, ProtoLengt
this->icon = value.as_string();
return true;
}
case 8: {
this->device_class = value.as_string();
return true;
}
default:
return false;
}
@ -2743,6 +2747,7 @@ void ListEntitiesTextSensorResponse::encode(ProtoWriteBuffer buffer) const {
buffer.encode_string(5, this->icon);
buffer.encode_bool(6, this->disabled_by_default);
buffer.encode_enum<enums::EntityCategory>(7, this->entity_category);
buffer.encode_string(8, this->device_class);
}
#ifdef HAS_PROTO_MESSAGE_DUMP
void ListEntitiesTextSensorResponse::dump_to(std::string &out) const {
@ -2776,6 +2781,10 @@ void ListEntitiesTextSensorResponse::dump_to(std::string &out) const {
out.append(" entity_category: ");
out.append(proto_enum_to_string<enums::EntityCategory>(this->entity_category));
out.append("\n");
out.append(" device_class: ");
out.append("'").append(this->device_class).append("'");
out.append("\n");
out.append("}");
}
#endif
@ -6594,6 +6603,10 @@ bool VoiceAssistantRequest::decode_length(uint32_t field_id, ProtoLengthDelimite
this->audio_settings = value.as_message<VoiceAssistantAudioSettings>();
return true;
}
case 5: {
this->wake_word_phrase = value.as_string();
return true;
}
default:
return false;
}
@ -6603,6 +6616,7 @@ void VoiceAssistantRequest::encode(ProtoWriteBuffer buffer) const {
buffer.encode_string(2, this->conversation_id);
buffer.encode_uint32(3, this->flags);
buffer.encode_message<VoiceAssistantAudioSettings>(4, this->audio_settings);
buffer.encode_string(5, this->wake_word_phrase);
}
#ifdef HAS_PROTO_MESSAGE_DUMP
void VoiceAssistantRequest::dump_to(std::string &out) const {
@ -6624,6 +6638,10 @@ void VoiceAssistantRequest::dump_to(std::string &out) const {
out.append(" audio_settings: ");
this->audio_settings.dump_to(out);
out.append("\n");
out.append(" wake_word_phrase: ");
out.append("'").append(this->wake_word_phrase).append("'");
out.append("\n");
out.append("}");
}
#endif
@ -7166,6 +7184,225 @@ void TextCommandRequest::dump_to(std::string &out) const {
out.append("}");
}
#endif
bool ListEntitiesDateResponse::decode_varint(uint32_t field_id, ProtoVarInt value) {
switch (field_id) {
case 6: {
this->disabled_by_default = value.as_bool();
return true;
}
case 7: {
this->entity_category = value.as_enum<enums::EntityCategory>();
return true;
}
default:
return false;
}
}
bool ListEntitiesDateResponse::decode_length(uint32_t field_id, ProtoLengthDelimited value) {
switch (field_id) {
case 1: {
this->object_id = value.as_string();
return true;
}
case 3: {
this->name = value.as_string();
return true;
}
case 4: {
this->unique_id = value.as_string();
return true;
}
case 5: {
this->icon = value.as_string();
return true;
}
default:
return false;
}
}
bool ListEntitiesDateResponse::decode_32bit(uint32_t field_id, Proto32Bit value) {
switch (field_id) {
case 2: {
this->key = value.as_fixed32();
return true;
}
default:
return false;
}
}
void ListEntitiesDateResponse::encode(ProtoWriteBuffer buffer) const {
buffer.encode_string(1, this->object_id);
buffer.encode_fixed32(2, this->key);
buffer.encode_string(3, this->name);
buffer.encode_string(4, this->unique_id);
buffer.encode_string(5, this->icon);
buffer.encode_bool(6, this->disabled_by_default);
buffer.encode_enum<enums::EntityCategory>(7, this->entity_category);
}
#ifdef HAS_PROTO_MESSAGE_DUMP
void ListEntitiesDateResponse::dump_to(std::string &out) const {
__attribute__((unused)) char buffer[64];
out.append("ListEntitiesDateResponse {\n");
out.append(" object_id: ");
out.append("'").append(this->object_id).append("'");
out.append("\n");
out.append(" key: ");
sprintf(buffer, "%" PRIu32, this->key);
out.append(buffer);
out.append("\n");
out.append(" name: ");
out.append("'").append(this->name).append("'");
out.append("\n");
out.append(" unique_id: ");
out.append("'").append(this->unique_id).append("'");
out.append("\n");
out.append(" icon: ");
out.append("'").append(this->icon).append("'");
out.append("\n");
out.append(" disabled_by_default: ");
out.append(YESNO(this->disabled_by_default));
out.append("\n");
out.append(" entity_category: ");
out.append(proto_enum_to_string<enums::EntityCategory>(this->entity_category));
out.append("\n");
out.append("}");
}
#endif
bool DateStateResponse::decode_varint(uint32_t field_id, ProtoVarInt value) {
switch (field_id) {
case 2: {
this->missing_state = value.as_bool();
return true;
}
case 3: {
this->year = value.as_uint32();
return true;
}
case 4: {
this->month = value.as_uint32();
return true;
}
case 5: {
this->day = value.as_uint32();
return true;
}
default:
return false;
}
}
bool DateStateResponse::decode_32bit(uint32_t field_id, Proto32Bit value) {
switch (field_id) {
case 1: {
this->key = value.as_fixed32();
return true;
}
default:
return false;
}
}
void DateStateResponse::encode(ProtoWriteBuffer buffer) const {
buffer.encode_fixed32(1, this->key);
buffer.encode_bool(2, this->missing_state);
buffer.encode_uint32(3, this->year);
buffer.encode_uint32(4, this->month);
buffer.encode_uint32(5, this->day);
}
#ifdef HAS_PROTO_MESSAGE_DUMP
void DateStateResponse::dump_to(std::string &out) const {
__attribute__((unused)) char buffer[64];
out.append("DateStateResponse {\n");
out.append(" key: ");
sprintf(buffer, "%" PRIu32, this->key);
out.append(buffer);
out.append("\n");
out.append(" missing_state: ");
out.append(YESNO(this->missing_state));
out.append("\n");
out.append(" year: ");
sprintf(buffer, "%" PRIu32, this->year);
out.append(buffer);
out.append("\n");
out.append(" month: ");
sprintf(buffer, "%" PRIu32, this->month);
out.append(buffer);
out.append("\n");
out.append(" day: ");
sprintf(buffer, "%" PRIu32, this->day);
out.append(buffer);
out.append("\n");
out.append("}");
}
#endif
bool DateCommandRequest::decode_varint(uint32_t field_id, ProtoVarInt value) {
switch (field_id) {
case 2: {
this->year = value.as_uint32();
return true;
}
case 3: {
this->month = value.as_uint32();
return true;
}
case 4: {
this->day = value.as_uint32();
return true;
}
default:
return false;
}
}
bool DateCommandRequest::decode_32bit(uint32_t field_id, Proto32Bit value) {
switch (field_id) {
case 1: {
this->key = value.as_fixed32();
return true;
}
default:
return false;
}
}
void DateCommandRequest::encode(ProtoWriteBuffer buffer) const {
buffer.encode_fixed32(1, this->key);
buffer.encode_uint32(2, this->year);
buffer.encode_uint32(3, this->month);
buffer.encode_uint32(4, this->day);
}
#ifdef HAS_PROTO_MESSAGE_DUMP
void DateCommandRequest::dump_to(std::string &out) const {
__attribute__((unused)) char buffer[64];
out.append("DateCommandRequest {\n");
out.append(" key: ");
sprintf(buffer, "%" PRIu32, this->key);
out.append(buffer);
out.append("\n");
out.append(" year: ");
sprintf(buffer, "%" PRIu32, this->year);
out.append(buffer);
out.append("\n");
out.append(" month: ");
sprintf(buffer, "%" PRIu32, this->month);
out.append(buffer);
out.append("\n");
out.append(" day: ");
sprintf(buffer, "%" PRIu32, this->day);
out.append(buffer);
out.append("\n");
out.append("}");
}
#endif
} // namespace api
} // namespace esphome

View File

@ -713,6 +713,7 @@ class ListEntitiesTextSensorResponse : public ProtoMessage {
std::string icon{};
bool disabled_by_default{false};
enums::EntityCategory entity_category{};
std::string device_class{};
void encode(ProtoWriteBuffer buffer) const override;
#ifdef HAS_PROTO_MESSAGE_DUMP
void dump_to(std::string &out) const override;
@ -1701,6 +1702,7 @@ class VoiceAssistantRequest : public ProtoMessage {
std::string conversation_id{};
uint32_t flags{0};
VoiceAssistantAudioSettings audio_settings{};
std::string wake_word_phrase{};
void encode(ProtoWriteBuffer buffer) const override;
#ifdef HAS_PROTO_MESSAGE_DUMP
void dump_to(std::string &out) const override;
@ -1848,6 +1850,56 @@ class TextCommandRequest : public ProtoMessage {
bool decode_32bit(uint32_t field_id, Proto32Bit value) override;
bool decode_length(uint32_t field_id, ProtoLengthDelimited value) override;
};
class ListEntitiesDateResponse : public ProtoMessage {
public:
std::string object_id{};
uint32_t key{0};
std::string name{};
std::string unique_id{};
std::string icon{};
bool disabled_by_default{false};
enums::EntityCategory entity_category{};
void encode(ProtoWriteBuffer buffer) const override;
#ifdef HAS_PROTO_MESSAGE_DUMP
void dump_to(std::string &out) const override;
#endif
protected:
bool decode_32bit(uint32_t field_id, Proto32Bit value) override;
bool decode_length(uint32_t field_id, ProtoLengthDelimited value) override;
bool decode_varint(uint32_t field_id, ProtoVarInt value) override;
};
class DateStateResponse : public ProtoMessage {
public:
uint32_t key{0};
bool missing_state{false};
uint32_t year{0};
uint32_t month{0};
uint32_t day{0};
void encode(ProtoWriteBuffer buffer) const override;
#ifdef HAS_PROTO_MESSAGE_DUMP
void dump_to(std::string &out) const override;
#endif
protected:
bool decode_32bit(uint32_t field_id, Proto32Bit value) override;
bool decode_varint(uint32_t field_id, ProtoVarInt value) override;
};
class DateCommandRequest : public ProtoMessage {
public:
uint32_t key{0};
uint32_t year{0};
uint32_t month{0};
uint32_t day{0};
void encode(ProtoWriteBuffer buffer) const override;
#ifdef HAS_PROTO_MESSAGE_DUMP
void dump_to(std::string &out) const override;
#endif
protected:
bool decode_32bit(uint32_t field_id, Proto32Bit value) override;
bool decode_varint(uint32_t field_id, ProtoVarInt value) override;
};
} // namespace api
} // namespace esphome

View File

@ -513,6 +513,24 @@ bool APIServerConnectionBase::send_text_state_response(const TextStateResponse &
#endif
#ifdef USE_TEXT
#endif
#ifdef USE_DATETIME_DATE
bool APIServerConnectionBase::send_list_entities_date_response(const ListEntitiesDateResponse &msg) {
#ifdef HAS_PROTO_MESSAGE_DUMP
ESP_LOGVV(TAG, "send_list_entities_date_response: %s", msg.dump().c_str());
#endif
return this->send_message_<ListEntitiesDateResponse>(msg, 100);
}
#endif
#ifdef USE_DATETIME_DATE
bool APIServerConnectionBase::send_date_state_response(const DateStateResponse &msg) {
#ifdef HAS_PROTO_MESSAGE_DUMP
ESP_LOGVV(TAG, "send_date_state_response: %s", msg.dump().c_str());
#endif
return this->send_message_<DateStateResponse>(msg, 101);
}
#endif
#ifdef USE_DATETIME_DATE
#endif
bool APIServerConnectionBase::read_message(uint32_t msg_size, uint32_t msg_type, uint8_t *msg_data) {
switch (msg_type) {
case 1: {
@ -942,6 +960,17 @@ bool APIServerConnectionBase::read_message(uint32_t msg_size, uint32_t msg_type,
ESP_LOGVV(TAG, "on_text_command_request: %s", msg.dump().c_str());
#endif
this->on_text_command_request(msg);
#endif
break;
}
case 102: {
#ifdef USE_DATETIME_DATE
DateCommandRequest msg;
msg.decode(msg_data, msg_size);
#ifdef HAS_PROTO_MESSAGE_DUMP
ESP_LOGVV(TAG, "on_date_command_request: %s", msg.dump().c_str());
#endif
this->on_date_command_request(msg);
#endif
break;
}
@ -1218,6 +1247,19 @@ void APIServerConnection::on_media_player_command_request(const MediaPlayerComma
this->media_player_command(msg);
}
#endif
#ifdef USE_DATETIME_DATE
void APIServerConnection::on_date_command_request(const DateCommandRequest &msg) {
if (!this->is_connection_setup()) {
this->on_no_setup_connection();
return;
}
if (!this->is_authenticated()) {
this->on_unauthenticated_access();
return;
}
this->date_command(msg);
}
#endif
#ifdef USE_BLUETOOTH_PROXY
void APIServerConnection::on_subscribe_bluetooth_le_advertisements_request(
const SubscribeBluetoothLEAdvertisementsRequest &msg) {

View File

@ -257,6 +257,15 @@ class APIServerConnectionBase : public ProtoService {
#endif
#ifdef USE_TEXT
virtual void on_text_command_request(const TextCommandRequest &value){};
#endif
#ifdef USE_DATETIME_DATE
bool send_list_entities_date_response(const ListEntitiesDateResponse &msg);
#endif
#ifdef USE_DATETIME_DATE
bool send_date_state_response(const DateStateResponse &msg);
#endif
#ifdef USE_DATETIME_DATE
virtual void on_date_command_request(const DateCommandRequest &value){};
#endif
protected:
bool read_message(uint32_t msg_size, uint32_t msg_type, uint8_t *msg_data) override;
@ -312,6 +321,9 @@ class APIServerConnection : public APIServerConnectionBase {
#ifdef USE_MEDIA_PLAYER
virtual void media_player_command(const MediaPlayerCommandRequest &msg) = 0;
#endif
#ifdef USE_DATETIME_DATE
virtual void date_command(const DateCommandRequest &msg) = 0;
#endif
#ifdef USE_BLUETOOTH_PROXY
virtual void subscribe_bluetooth_le_advertisements(const SubscribeBluetoothLEAdvertisementsRequest &msg) = 0;
#endif
@ -398,6 +410,9 @@ class APIServerConnection : public APIServerConnectionBase {
#ifdef USE_MEDIA_PLAYER
void on_media_player_command_request(const MediaPlayerCommandRequest &msg) override;
#endif
#ifdef USE_DATETIME_DATE
void on_date_command_request(const DateCommandRequest &msg) override;
#endif
#ifdef USE_BLUETOOTH_PROXY
void on_subscribe_bluetooth_le_advertisements_request(const SubscribeBluetoothLEAdvertisementsRequest &msg) override;
#endif

View File

@ -255,6 +255,15 @@ void APIServer::on_number_update(number::Number *obj, float state) {
}
#endif
#ifdef USE_DATETIME_DATE
void APIServer::on_date_update(datetime::DateEntity *obj) {
if (obj->is_internal())
return;
for (auto &c : this->clients_)
c->send_date_state(obj);
}
#endif
#ifdef USE_TEXT
void APIServer::on_text_update(text::Text *obj, const std::string &state) {
if (obj->is_internal())

View File

@ -66,6 +66,9 @@ class APIServer : public Component, public Controller {
#ifdef USE_NUMBER
void on_number_update(number::Number *obj, float state) override;
#endif
#ifdef USE_DATETIME_DATE
void on_date_update(datetime::DateEntity *obj) override;
#endif
#ifdef USE_TEXT
void on_text_update(text::Text *obj, const std::string &state) override;
#endif

View File

@ -1,8 +1,8 @@
#include "list_entities.h"
#include "esphome/core/util.h"
#include "esphome/core/log.h"
#include "esphome/core/application.h"
#include "api_connection.h"
#include "esphome/core/application.h"
#include "esphome/core/log.h"
#include "esphome/core/util.h"
namespace esphome {
namespace api {
@ -60,6 +60,10 @@ bool ListEntitiesIterator::on_climate(climate::Climate *climate) { return this->
bool ListEntitiesIterator::on_number(number::Number *number) { return this->client_->send_number_info(number); }
#endif
#ifdef USE_DATETIME_DATE
bool ListEntitiesIterator::on_date(datetime::DateEntity *date) { return this->client_->send_date_info(date); }
#endif
#ifdef USE_TEXT
bool ListEntitiesIterator::on_text(text::Text *text) { return this->client_->send_text_info(text); }
#endif

View File

@ -46,6 +46,9 @@ class ListEntitiesIterator : public ComponentIterator {
#ifdef USE_NUMBER
bool on_number(number::Number *number) override;
#endif
#ifdef USE_DATETIME_DATE
bool on_date(datetime::DateEntity *date) override;
#endif
#ifdef USE_TEXT
bool on_text(text::Text *text) override;
#endif

View File

@ -42,6 +42,9 @@ bool InitialStateIterator::on_number(number::Number *number) {
return this->client_->send_number_state(number, number->state);
}
#endif
#ifdef USE_DATETIME_DATE
bool InitialStateIterator::on_date(datetime::DateEntity *date) { return this->client_->send_date_state(date); }
#endif
#ifdef USE_TEXT
bool InitialStateIterator::on_text(text::Text *text) { return this->client_->send_text_state(text, text->state); }
#endif

View File

@ -43,6 +43,9 @@ class InitialStateIterator : public ComponentIterator {
#ifdef USE_NUMBER
bool on_number(number::Number *number) override;
#endif
#ifdef USE_DATETIME_DATE
bool on_date(datetime::DateEntity *date) override;
#endif
#ifdef USE_TEXT
bool on_text(text::Text *text) override;
#endif

View File

@ -22,7 +22,7 @@ CONFIG_SCHEMA = cv.All(
async def to_code(config):
if CORE.is_esp32 or CORE.is_libretiny:
# https://github.com/esphome/AsyncTCP/blob/master/library.json
cg.add_library("esphome/AsyncTCP-esphome", "2.0.1")
cg.add_library("esphome/AsyncTCP-esphome", "2.1.3")
elif CORE.is_esp8266:
# https://github.com/esphome/ESPAsyncTCP
cg.add_library("esphome/ESPAsyncTCP-esphome", "2.0.0")

View File

@ -117,7 +117,7 @@ void ATM90E26Component::setup() {
this->write16_(ATM90E26_REGISTER_ADJSTART,
0x8765); // Checks correctness of 31-3A registers and starts normal measurement if ok
uint16_t sys_status = this->read16_(ATM90E26_REGISTER_SYSSTATUS);
const uint16_t sys_status = this->read16_(ATM90E26_REGISTER_SYSSTATUS);
if (sys_status & 0xC000) { // Checksum 1 Error
ESP_LOGW(TAG, "Could not initialize ATM90E26 IC: CS1 was incorrect, expected: 0x%04X",
@ -177,27 +177,27 @@ void ATM90E26Component::write16_(uint8_t a_register, uint16_t val) {
}
float ATM90E26Component::get_line_current_() {
uint16_t current = this->read16_(ATM90E26_REGISTER_IRMS);
const uint16_t current = this->read16_(ATM90E26_REGISTER_IRMS);
return current / 1000.0f;
}
float ATM90E26Component::get_line_voltage_() {
uint16_t voltage = this->read16_(ATM90E26_REGISTER_URMS);
const uint16_t voltage = this->read16_(ATM90E26_REGISTER_URMS);
return voltage / 100.0f;
}
float ATM90E26Component::get_active_power_() {
int16_t val = this->read16_(ATM90E26_REGISTER_PMEAN); // two's complement
const int16_t val = this->read16_(ATM90E26_REGISTER_PMEAN); // two's complement
return (float) val;
}
float ATM90E26Component::get_reactive_power_() {
int16_t val = this->read16_(ATM90E26_REGISTER_QMEAN); // two's complement
const int16_t val = this->read16_(ATM90E26_REGISTER_QMEAN); // two's complement
return (float) val;
}
float ATM90E26Component::get_power_factor_() {
uint16_t val = this->read16_(ATM90E26_REGISTER_POWERF); // signed
const uint16_t val = this->read16_(ATM90E26_REGISTER_POWERF); // signed
if (val & 0x8000) {
return -(val & 0x7FF) / 1000.0f;
} else {
@ -206,7 +206,7 @@ float ATM90E26Component::get_power_factor_() {
}
float ATM90E26Component::get_forward_active_energy_() {
uint16_t val = this->read16_(ATM90E26_REGISTER_APENERGY);
const uint16_t val = this->read16_(ATM90E26_REGISTER_APENERGY);
if ((UINT32_MAX - this->cumulative_forward_active_energy_) > val) {
this->cumulative_forward_active_energy_ += val;
} else {
@ -217,7 +217,7 @@ float ATM90E26Component::get_forward_active_energy_() {
}
float ATM90E26Component::get_reverse_active_energy_() {
uint16_t val = this->read16_(ATM90E26_REGISTER_ANENERGY);
const uint16_t val = this->read16_(ATM90E26_REGISTER_ANENERGY);
if (UINT32_MAX - this->cumulative_reverse_active_energy_ > val) {
this->cumulative_reverse_active_energy_ += val;
} else {
@ -227,7 +227,7 @@ float ATM90E26Component::get_reverse_active_energy_() {
}
float ATM90E26Component::get_frequency_() {
uint16_t freq = this->read16_(ATM90E26_REGISTER_FREQ);
const uint16_t freq = this->read16_(ATM90E26_REGISTER_FREQ);
return freq / 100.0f;
}

View File

@ -7,75 +7,112 @@ namespace esphome {
namespace atm90e32 {
static const char *const TAG = "atm90e32";
void ATM90E32Component::update() {
if (this->read16_(ATM90E32_REGISTER_METEREN) != 1) {
this->status_set_warning();
return;
void ATM90E32Component::loop() {
if (this->get_publish_interval_flag_()) {
this->set_publish_interval_flag_(false);
for (uint8_t phase = 0; phase < 3; phase++) {
if (this->phase_[phase].voltage_sensor_ != nullptr) {
this->phase_[phase].voltage_ = this->get_phase_voltage_(phase);
}
if (this->phase_[0].voltage_sensor_ != nullptr) {
this->phase_[0].voltage_sensor_->publish_state(this->get_line_voltage_a_());
}
if (this->phase_[1].voltage_sensor_ != nullptr) {
this->phase_[1].voltage_sensor_->publish_state(this->get_line_voltage_b_());
for (uint8_t phase = 0; phase < 3; phase++) {
if (this->phase_[phase].current_sensor_ != nullptr) {
this->phase_[phase].current_ = this->get_phase_current_(phase);
}
if (this->phase_[2].voltage_sensor_ != nullptr) {
this->phase_[2].voltage_sensor_->publish_state(this->get_line_voltage_c_());
}
if (this->phase_[0].current_sensor_ != nullptr) {
this->phase_[0].current_sensor_->publish_state(this->get_line_current_a_());
for (uint8_t phase = 0; phase < 3; phase++) {
if (this->phase_[phase].power_sensor_ != nullptr) {
this->phase_[phase].active_power_ = this->get_phase_active_power_(phase);
}
if (this->phase_[1].current_sensor_ != nullptr) {
this->phase_[1].current_sensor_->publish_state(this->get_line_current_b_());
}
if (this->phase_[2].current_sensor_ != nullptr) {
this->phase_[2].current_sensor_->publish_state(this->get_line_current_c_());
for (uint8_t phase = 0; phase < 3; phase++) {
if (this->phase_[phase].power_factor_sensor_ != nullptr) {
this->phase_[phase].power_factor_ = this->get_phase_power_factor_(phase);
}
if (this->phase_[0].power_sensor_ != nullptr) {
this->phase_[0].power_sensor_->publish_state(this->get_active_power_a_());
}
if (this->phase_[1].power_sensor_ != nullptr) {
this->phase_[1].power_sensor_->publish_state(this->get_active_power_b_());
for (uint8_t phase = 0; phase < 3; phase++) {
if (this->phase_[phase].reactive_power_sensor_ != nullptr) {
this->phase_[phase].reactive_power_ = this->get_phase_reactive_power_(phase);
}
if (this->phase_[2].power_sensor_ != nullptr) {
this->phase_[2].power_sensor_->publish_state(this->get_active_power_c_());
}
if (this->phase_[0].reactive_power_sensor_ != nullptr) {
this->phase_[0].reactive_power_sensor_->publish_state(this->get_reactive_power_a_());
for (uint8_t phase = 0; phase < 3; phase++) {
if (this->phase_[phase].forward_active_energy_sensor_ != nullptr) {
this->phase_[phase].forward_active_energy_ = this->get_phase_forward_active_energy_(phase);
}
if (this->phase_[1].reactive_power_sensor_ != nullptr) {
this->phase_[1].reactive_power_sensor_->publish_state(this->get_reactive_power_b_());
}
if (this->phase_[2].reactive_power_sensor_ != nullptr) {
this->phase_[2].reactive_power_sensor_->publish_state(this->get_reactive_power_c_());
for (uint8_t phase = 0; phase < 3; phase++) {
if (this->phase_[phase].reverse_active_energy_sensor_ != nullptr) {
this->phase_[phase].reverse_active_energy_ = this->get_phase_reverse_active_energy_(phase);
}
if (this->phase_[0].power_factor_sensor_ != nullptr) {
this->phase_[0].power_factor_sensor_->publish_state(this->get_power_factor_a_());
}
if (this->phase_[1].power_factor_sensor_ != nullptr) {
this->phase_[1].power_factor_sensor_->publish_state(this->get_power_factor_b_());
for (uint8_t phase = 0; phase < 3; phase++) {
if (this->phase_[phase].phase_angle_sensor_ != nullptr) {
this->phase_[phase].phase_angle_ = this->get_phase_angle_(phase);
}
if (this->phase_[2].power_factor_sensor_ != nullptr) {
this->phase_[2].power_factor_sensor_->publish_state(this->get_power_factor_c_());
}
if (this->phase_[0].forward_active_energy_sensor_ != nullptr) {
this->phase_[0].forward_active_energy_sensor_->publish_state(this->get_forward_active_energy_a_());
for (uint8_t phase = 0; phase < 3; phase++) {
if (this->phase_[phase].harmonic_active_power_sensor_ != nullptr) {
this->phase_[phase].harmonic_active_power_ = this->get_phase_harmonic_active_power_(phase);
}
if (this->phase_[1].forward_active_energy_sensor_ != nullptr) {
this->phase_[1].forward_active_energy_sensor_->publish_state(this->get_forward_active_energy_b_());
}
if (this->phase_[2].forward_active_energy_sensor_ != nullptr) {
this->phase_[2].forward_active_energy_sensor_->publish_state(this->get_forward_active_energy_c_());
for (uint8_t phase = 0; phase < 3; phase++) {
if (this->phase_[phase].peak_current_sensor_ != nullptr) {
this->phase_[phase].peak_current_ = this->get_phase_peak_current_(phase);
}
if (this->phase_[0].reverse_active_energy_sensor_ != nullptr) {
this->phase_[0].reverse_active_energy_sensor_->publish_state(this->get_reverse_active_energy_a_());
}
if (this->phase_[1].reverse_active_energy_sensor_ != nullptr) {
this->phase_[1].reverse_active_energy_sensor_->publish_state(this->get_reverse_active_energy_b_());
// After the local store in collected we can publish them trusting they are withing +-1 haardware sampling
for (uint8_t phase = 0; phase < 3; phase++) {
if (this->phase_[phase].voltage_sensor_ != nullptr) {
this->phase_[phase].voltage_sensor_->publish_state(this->get_local_phase_voltage_(phase));
}
}
for (uint8_t phase = 0; phase < 3; phase++) {
if (this->phase_[phase].current_sensor_ != nullptr) {
this->phase_[phase].current_sensor_->publish_state(this->get_local_phase_current_(phase));
}
}
for (uint8_t phase = 0; phase < 3; phase++) {
if (this->phase_[phase].power_sensor_ != nullptr) {
this->phase_[phase].power_sensor_->publish_state(this->get_local_phase_active_power_(phase));
}
}
for (uint8_t phase = 0; phase < 3; phase++) {
if (this->phase_[phase].power_factor_sensor_ != nullptr) {
this->phase_[phase].power_factor_sensor_->publish_state(this->get_local_phase_power_factor_(phase));
}
}
for (uint8_t phase = 0; phase < 3; phase++) {
if (this->phase_[phase].reactive_power_sensor_ != nullptr) {
this->phase_[phase].reactive_power_sensor_->publish_state(this->get_local_phase_reactive_power_(phase));
}
}
for (uint8_t phase = 0; phase < 3; phase++) {
if (this->phase_[phase].forward_active_energy_sensor_ != nullptr) {
this->phase_[phase].forward_active_energy_sensor_->publish_state(
this->get_local_phase_forward_active_energy_(phase));
}
}
for (uint8_t phase = 0; phase < 3; phase++) {
if (this->phase_[phase].reverse_active_energy_sensor_ != nullptr) {
this->phase_[phase].reverse_active_energy_sensor_->publish_state(
this->get_local_phase_reverse_active_energy_(phase));
}
}
for (uint8_t phase = 0; phase < 3; phase++) {
if (this->phase_[phase].phase_angle_sensor_ != nullptr) {
this->phase_[phase].phase_angle_sensor_->publish_state(this->get_local_phase_angle_(phase));
}
}
for (uint8_t phase = 0; phase < 3; phase++) {
if (this->phase_[phase].harmonic_active_power_sensor_ != nullptr) {
this->phase_[phase].harmonic_active_power_sensor_->publish_state(
this->get_local_phase_harmonic_active_power_(phase));
}
}
for (uint8_t phase = 0; phase < 3; phase++) {
if (this->phase_[phase].peak_current_sensor_ != nullptr) {
this->phase_[phase].peak_current_sensor_->publish_state(this->get_local_phase_peak_current_(phase));
}
if (this->phase_[2].reverse_active_energy_sensor_ != nullptr) {
this->phase_[2].reverse_active_energy_sensor_->publish_state(this->get_reverse_active_energy_c_());
}
if (this->freq_sensor_ != nullptr) {
this->freq_sensor_->publish_state(this->get_frequency_());
@ -83,6 +120,15 @@ void ATM90E32Component::update() {
if (this->chip_temperature_sensor_ != nullptr) {
this->chip_temperature_sensor_->publish_state(this->get_chip_temperature_());
}
}
}
void ATM90E32Component::update() {
if (this->read16_(ATM90E32_REGISTER_METEREN) != 1) {
this->status_set_warning();
return;
}
this->set_publish_interval_flag_(true);
this->status_clear_warning();
}
@ -101,13 +147,16 @@ void ATM90E32Component::setup() {
}
this->write16_(ATM90E32_REGISTER_SOFTRESET, 0x789A); // Perform soft reset
delay(6); // Wait for the minimum 5ms + 1ms
this->write16_(ATM90E32_REGISTER_CFGREGACCEN, 0x55AA); // enable register config access
this->write16_(ATM90E32_REGISTER_METEREN, 0x0001); // Enable Metering
if (this->read16_(ATM90E32_REGISTER_LASTSPIDATA) != 0x0001) {
if (this->read16_(ATM90E32_REGISTER_LASTSPIDATA) != 0x55AA) {
ESP_LOGW(TAG, "Could not initialize ATM90E32 IC, check SPI settings");
this->mark_failed();
return;
}
this->write16_(ATM90E32_REGISTER_METEREN, 0x0001); // Enable Metering
this->write16_(ATM90E32_REGISTER_SAGPEAKDETCFG, 0xFF3F); // Peak Detector time ms (15:8), Sag Period ms (7:0)
this->write16_(ATM90E32_REGISTER_PLCONSTH, 0x0861); // PL Constant MSB (default) = 140625000
this->write16_(ATM90E32_REGISTER_PLCONSTL, 0xC468); // PL Constant LSB (default)
this->write16_(ATM90E32_REGISTER_ZXCONFIG, 0xD654); // ZX2, ZX1, ZX0 pin config
@ -115,14 +164,33 @@ void ATM90E32Component::setup() {
this->write16_(ATM90E32_REGISTER_MMODE1, pga_gain_); // PGA Gain Configuration for Current Channels
this->write16_(ATM90E32_REGISTER_PSTARTTH, 0x1D4C); // All Active Startup Power Threshold - 0.02A/0.00032 = 7500
this->write16_(ATM90E32_REGISTER_QSTARTTH, 0x1D4C); // All Reactive Startup Power Threshold - 50%
this->write16_(ATM90E32_REGISTER_SSTARTTH, 0x1D4C); // All Reactive Startup Power Threshold - 50%
this->write16_(ATM90E32_REGISTER_PPHASETH, 0x02EE); // Each Phase Active Phase Threshold - 0.002A/0.00032 = 750
this->write16_(ATM90E32_REGISTER_QPHASETH, 0x02EE); // Each phase Reactive Phase Threshold - 10%
this->write16_(ATM90E32_REGISTER_UGAINA, this->phase_[0].volt_gain_); // A Voltage rms gain
this->write16_(ATM90E32_REGISTER_IGAINA, this->phase_[0].ct_gain_); // A line current gain
this->write16_(ATM90E32_REGISTER_UGAINB, this->phase_[1].volt_gain_); // B Voltage rms gain
this->write16_(ATM90E32_REGISTER_IGAINB, this->phase_[1].ct_gain_); // B line current gain
this->write16_(ATM90E32_REGISTER_UGAINC, this->phase_[2].volt_gain_); // C Voltage rms gain
this->write16_(ATM90E32_REGISTER_IGAINC, this->phase_[2].ct_gain_); // C line current gain
// Setup voltage and current calibration offsets for PHASE A
this->phase_[PHASEA].voltage_offset_ = calibrate_voltage_offset_phase(PHASEA);
this->write16_(ATM90E32_REGISTER_UOFFSETA, this->phase_[PHASEA].voltage_offset_); // A Voltage offset
this->phase_[PHASEA].current_offset_ = calibrate_current_offset_phase(PHASEA);
this->write16_(ATM90E32_REGISTER_IOFFSETA, this->phase_[PHASEA].current_offset_); // A Current offset
// Setup voltage and current gain for PHASE A
this->write16_(ATM90E32_REGISTER_UGAINA, this->phase_[PHASEA].voltage_gain_); // A Voltage rms gain
this->write16_(ATM90E32_REGISTER_IGAINA, this->phase_[PHASEA].ct_gain_); // A line current gain
// Setup voltage and current calibration offsets for PHASE B
this->phase_[PHASEB].voltage_offset_ = calibrate_voltage_offset_phase(PHASEB);
this->write16_(ATM90E32_REGISTER_UOFFSETB, this->phase_[PHASEB].voltage_offset_); // B Voltage offset
this->phase_[PHASEB].current_offset_ = calibrate_current_offset_phase(PHASEB);
this->write16_(ATM90E32_REGISTER_IOFFSETB, this->phase_[PHASEB].current_offset_); // B Current offset
// Setup voltage and current gain for PHASE B
this->write16_(ATM90E32_REGISTER_UGAINB, this->phase_[PHASEB].voltage_gain_); // B Voltage rms gain
this->write16_(ATM90E32_REGISTER_IGAINB, this->phase_[PHASEB].ct_gain_); // B line current gain
// Setup voltage and current calibration offsets for PHASE C
this->phase_[PHASEC].voltage_offset_ = calibrate_voltage_offset_phase(PHASEC);
this->write16_(ATM90E32_REGISTER_UOFFSETC, this->phase_[PHASEC].voltage_offset_); // C Voltage offset
this->phase_[PHASEC].current_offset_ = calibrate_current_offset_phase(PHASEC);
this->write16_(ATM90E32_REGISTER_IOFFSETC, this->phase_[PHASEC].current_offset_); // C Current offset
// Setup voltage and current gain for PHASE C
this->write16_(ATM90E32_REGISTER_UGAINC, this->phase_[PHASEC].voltage_gain_); // C Voltage rms gain
this->write16_(ATM90E32_REGISTER_IGAINC, this->phase_[PHASEC].ct_gain_); // C line current gain
this->write16_(ATM90E32_REGISTER_CFGREGACCEN, 0x0000); // end configuration
}
@ -133,43 +201,54 @@ void ATM90E32Component::dump_config() {
ESP_LOGE(TAG, "Communication with ATM90E32 failed!");
}
LOG_UPDATE_INTERVAL(this);
LOG_SENSOR(" ", "Voltage A", this->phase_[0].voltage_sensor_);
LOG_SENSOR(" ", "Current A", this->phase_[0].current_sensor_);
LOG_SENSOR(" ", "Power A", this->phase_[0].power_sensor_);
LOG_SENSOR(" ", "Reactive Power A", this->phase_[0].reactive_power_sensor_);
LOG_SENSOR(" ", "PF A", this->phase_[0].power_factor_sensor_);
LOG_SENSOR(" ", "Active Forward Energy A", this->phase_[0].forward_active_energy_sensor_);
LOG_SENSOR(" ", "Active Reverse Energy A", this->phase_[0].reverse_active_energy_sensor_);
LOG_SENSOR(" ", "Voltage B", this->phase_[1].voltage_sensor_);
LOG_SENSOR(" ", "Current B", this->phase_[1].current_sensor_);
LOG_SENSOR(" ", "Power B", this->phase_[1].power_sensor_);
LOG_SENSOR(" ", "Reactive Power B", this->phase_[1].reactive_power_sensor_);
LOG_SENSOR(" ", "PF B", this->phase_[1].power_factor_sensor_);
LOG_SENSOR(" ", "Active Forward Energy B", this->phase_[1].forward_active_energy_sensor_);
LOG_SENSOR(" ", "Active Reverse Energy B", this->phase_[1].reverse_active_energy_sensor_);
LOG_SENSOR(" ", "Voltage C", this->phase_[2].voltage_sensor_);
LOG_SENSOR(" ", "Current C", this->phase_[2].current_sensor_);
LOG_SENSOR(" ", "Power C", this->phase_[2].power_sensor_);
LOG_SENSOR(" ", "Reactive Power C", this->phase_[2].reactive_power_sensor_);
LOG_SENSOR(" ", "PF C", this->phase_[2].power_factor_sensor_);
LOG_SENSOR(" ", "Active Forward Energy C", this->phase_[2].forward_active_energy_sensor_);
LOG_SENSOR(" ", "Active Reverse Energy C", this->phase_[2].reverse_active_energy_sensor_);
LOG_SENSOR(" ", "Voltage A", this->phase_[PHASEA].voltage_sensor_);
LOG_SENSOR(" ", "Current A", this->phase_[PHASEA].current_sensor_);
LOG_SENSOR(" ", "Power A", this->phase_[PHASEA].power_sensor_);
LOG_SENSOR(" ", "Reactive Power A", this->phase_[PHASEA].reactive_power_sensor_);
LOG_SENSOR(" ", "PF A", this->phase_[PHASEA].power_factor_sensor_);
LOG_SENSOR(" ", "Active Forward Energy A", this->phase_[PHASEA].forward_active_energy_sensor_);
LOG_SENSOR(" ", "Active Reverse Energy A", this->phase_[PHASEA].reverse_active_energy_sensor_);
LOG_SENSOR(" ", "Harmonic Power A", this->phase_[PHASEA].harmonic_active_power_sensor_);
LOG_SENSOR(" ", "Phase Angle A", this->phase_[PHASEA].phase_angle_sensor_);
LOG_SENSOR(" ", "Peak Current A", this->phase_[PHASEA].peak_current_sensor_);
LOG_SENSOR(" ", "Voltage B", this->phase_[PHASEB].voltage_sensor_);
LOG_SENSOR(" ", "Current B", this->phase_[PHASEB].current_sensor_);
LOG_SENSOR(" ", "Power B", this->phase_[PHASEB].power_sensor_);
LOG_SENSOR(" ", "Reactive Power B", this->phase_[PHASEB].reactive_power_sensor_);
LOG_SENSOR(" ", "PF B", this->phase_[PHASEB].power_factor_sensor_);
LOG_SENSOR(" ", "Active Forward Energy B", this->phase_[PHASEB].forward_active_energy_sensor_);
LOG_SENSOR(" ", "Active Reverse Energy B", this->phase_[PHASEB].reverse_active_energy_sensor_);
LOG_SENSOR(" ", "Harmonic Power A", this->phase_[PHASEB].harmonic_active_power_sensor_);
LOG_SENSOR(" ", "Phase Angle A", this->phase_[PHASEB].phase_angle_sensor_);
LOG_SENSOR(" ", "Peak Current A", this->phase_[PHASEB].peak_current_sensor_);
LOG_SENSOR(" ", "Voltage C", this->phase_[PHASEC].voltage_sensor_);
LOG_SENSOR(" ", "Current C", this->phase_[PHASEC].current_sensor_);
LOG_SENSOR(" ", "Power C", this->phase_[PHASEC].power_sensor_);
LOG_SENSOR(" ", "Reactive Power C", this->phase_[PHASEC].reactive_power_sensor_);
LOG_SENSOR(" ", "PF C", this->phase_[PHASEC].power_factor_sensor_);
LOG_SENSOR(" ", "Active Forward Energy C", this->phase_[PHASEC].forward_active_energy_sensor_);
LOG_SENSOR(" ", "Active Reverse Energy C", this->phase_[PHASEC].reverse_active_energy_sensor_);
LOG_SENSOR(" ", "Harmonic Power A", this->phase_[PHASEC].harmonic_active_power_sensor_);
LOG_SENSOR(" ", "Phase Angle A", this->phase_[PHASEC].phase_angle_sensor_);
LOG_SENSOR(" ", "Peak Current A", this->phase_[PHASEC].peak_current_sensor_);
LOG_SENSOR(" ", "Frequency", this->freq_sensor_);
LOG_SENSOR(" ", "Chip Temp", this->chip_temperature_sensor_);
}
float ATM90E32Component::get_setup_priority() const { return setup_priority::DATA; }
float ATM90E32Component::get_setup_priority() const { return setup_priority::IO; }
// R/C registers can conly be cleared after the LastSPIData register is updated (register 78H)
// Peakdetect period: 05H. Bit 15:8 are PeakDet_period in ms. 7:0 are Sag_period
// Default is 143FH (20ms, 63ms)
uint16_t ATM90E32Component::read16_(uint16_t a_register) {
uint8_t addrh = (1 << 7) | ((a_register >> 8) & 0x03);
uint8_t addrl = (a_register & 0xFF);
uint8_t data[2];
uint16_t output;
this->enable();
delayMicroseconds(10);
delay_microseconds_safe(10);
this->write_byte(addrh);
this->write_byte(addrl);
delayMicroseconds(4);
this->read_array(data, 2);
this->disable();
@ -179,9 +258,9 @@ uint16_t ATM90E32Component::read16_(uint16_t a_register) {
}
int ATM90E32Component::read32_(uint16_t addr_h, uint16_t addr_l) {
uint16_t val_h = this->read16_(addr_h);
uint16_t val_l = this->read16_(addr_l);
int32_t val = (val_h << 16) | val_l;
const uint16_t val_h = this->read16_(addr_h);
const uint16_t val_l = this->read16_(addr_l);
const int32_t val = (val_h << 16) | val_l;
ESP_LOGVV(TAG,
"read32_ addr_h 0x%04" PRIX16 " val_h 0x%04" PRIX16 " addr_l 0x%04" PRIX16 " val_l 0x%04" PRIX16
@ -192,141 +271,174 @@ int ATM90E32Component::read32_(uint16_t addr_h, uint16_t addr_l) {
}
void ATM90E32Component::write16_(uint16_t a_register, uint16_t val) {
uint8_t addrh = (a_register >> 8) & 0x03;
uint8_t addrl = (a_register & 0xFF);
ESP_LOGVV(TAG, "write16_ 0x%04" PRIX16 " val 0x%04" PRIX16, a_register, val);
this->enable();
delayMicroseconds(10);
this->write_byte(addrh);
this->write_byte(addrl);
delayMicroseconds(4);
this->write_byte((val >> 8) & 0xff);
this->write_byte(val & 0xFF);
this->write_byte16(a_register);
this->write_byte16(val);
this->disable();
if (this->read16_(ATM90E32_REGISTER_LASTSPIDATA) != val)
ESP_LOGW(TAG, "SPI write error 0x%04X val 0x%04X", a_register, val);
}
float ATM90E32Component::get_line_voltage_a_() {
uint16_t voltage = this->read16_(ATM90E32_REGISTER_URMSA);
float ATM90E32Component::get_local_phase_voltage_(uint8_t phase) { return this->phase_[phase].voltage_; }
float ATM90E32Component::get_local_phase_current_(uint8_t phase) { return this->phase_[phase].current_; }
float ATM90E32Component::get_local_phase_active_power_(uint8_t phase) { return this->phase_[phase].active_power_; }
float ATM90E32Component::get_local_phase_reactive_power_(uint8_t phase) { return this->phase_[phase].reactive_power_; }
float ATM90E32Component::get_local_phase_power_factor_(uint8_t phase) { return this->phase_[phase].power_factor_; }
float ATM90E32Component::get_local_phase_forward_active_energy_(uint8_t phase) {
return this->phase_[phase].forward_active_energy_;
}
float ATM90E32Component::get_local_phase_reverse_active_energy_(uint8_t phase) {
return this->phase_[phase].reverse_active_energy_;
}
float ATM90E32Component::get_local_phase_angle_(uint8_t phase) { return this->phase_[phase].phase_angle_; }
float ATM90E32Component::get_local_phase_harmonic_active_power_(uint8_t phase) {
return this->phase_[phase].harmonic_active_power_;
}
float ATM90E32Component::get_local_phase_peak_current_(uint8_t phase) { return this->phase_[phase].peak_current_; }
float ATM90E32Component::get_phase_voltage_(uint8_t phase) {
const uint16_t voltage = this->read16_(ATM90E32_REGISTER_URMS + phase);
if (this->read16_(ATM90E32_REGISTER_LASTSPIDATA) != voltage)
ESP_LOGW(TAG, "SPI URMS voltage register read error.");
return (float) voltage / 100;
}
float ATM90E32Component::get_line_voltage_b_() {
uint16_t voltage = this->read16_(ATM90E32_REGISTER_URMSB);
return (float) voltage / 100;
float ATM90E32Component::get_phase_voltage_avg_(uint8_t phase) {
const uint8_t reads = 10;
uint32_t accumulation = 0;
uint16_t voltage = 0;
for (uint8_t i = 0; i < reads; i++) {
voltage = this->read16_(ATM90E32_REGISTER_URMS + phase);
if (this->read16_(ATM90E32_REGISTER_LASTSPIDATA) != voltage)
ESP_LOGW(TAG, "SPI URMS voltage register read error.");
accumulation += voltage;
}
float ATM90E32Component::get_line_voltage_c_() {
uint16_t voltage = this->read16_(ATM90E32_REGISTER_URMSC);
return (float) voltage / 100;
voltage = accumulation / reads;
this->phase_[phase].voltage_ = (float) voltage / 100;
return this->phase_[phase].voltage_;
}
float ATM90E32Component::get_line_current_a_() {
uint16_t current = this->read16_(ATM90E32_REGISTER_IRMSA);
float ATM90E32Component::get_phase_current_avg_(uint8_t phase) {
const uint8_t reads = 10;
uint32_t accumulation = 0;
uint16_t current = 0;
for (uint8_t i = 0; i < reads; i++) {
current = this->read16_(ATM90E32_REGISTER_IRMS + phase);
if (this->read16_(ATM90E32_REGISTER_LASTSPIDATA) != current)
ESP_LOGW(TAG, "SPI IRMS current register read error.");
accumulation += current;
}
current = accumulation / reads;
this->phase_[phase].current_ = (float) current / 1000;
return this->phase_[phase].current_;
}
float ATM90E32Component::get_phase_current_(uint8_t phase) {
const uint16_t current = this->read16_(ATM90E32_REGISTER_IRMS + phase);
if (this->read16_(ATM90E32_REGISTER_LASTSPIDATA) != current)
ESP_LOGW(TAG, "SPI IRMS current register read error.");
return (float) current / 1000;
}
float ATM90E32Component::get_line_current_b_() {
uint16_t current = this->read16_(ATM90E32_REGISTER_IRMSB);
return (float) current / 1000;
}
float ATM90E32Component::get_line_current_c_() {
uint16_t current = this->read16_(ATM90E32_REGISTER_IRMSC);
return (float) current / 1000;
}
float ATM90E32Component::get_active_power_a_() {
int val = this->read32_(ATM90E32_REGISTER_PMEANA, ATM90E32_REGISTER_PMEANALSB);
float ATM90E32Component::get_phase_active_power_(uint8_t phase) {
const int val = this->read32_(ATM90E32_REGISTER_PMEAN + phase, ATM90E32_REGISTER_PMEANLSB + phase);
return val * 0.00032f;
}
float ATM90E32Component::get_active_power_b_() {
int val = this->read32_(ATM90E32_REGISTER_PMEANB, ATM90E32_REGISTER_PMEANBLSB);
float ATM90E32Component::get_phase_reactive_power_(uint8_t phase) {
const int val = this->read32_(ATM90E32_REGISTER_QMEAN + phase, ATM90E32_REGISTER_QMEANLSB + phase);
return val * 0.00032f;
}
float ATM90E32Component::get_active_power_c_() {
int val = this->read32_(ATM90E32_REGISTER_PMEANC, ATM90E32_REGISTER_PMEANCLSB);
float ATM90E32Component::get_phase_power_factor_(uint8_t phase) {
const int16_t powerfactor = this->read16_(ATM90E32_REGISTER_PFMEAN + phase);
if (this->read16_(ATM90E32_REGISTER_LASTSPIDATA) != powerfactor)
ESP_LOGW(TAG, "SPI power factor read error.");
return (float) powerfactor / 1000;
}
float ATM90E32Component::get_phase_forward_active_energy_(uint8_t phase) {
const uint16_t val = this->read16_(ATM90E32_REGISTER_APENERGY + phase);
if ((UINT32_MAX - this->phase_[phase].cumulative_forward_active_energy_) > val) {
this->phase_[phase].cumulative_forward_active_energy_ += val;
} else {
this->phase_[phase].cumulative_forward_active_energy_ = val;
}
return ((float) this->phase_[phase].cumulative_forward_active_energy_ * 10 / 3200);
}
float ATM90E32Component::get_phase_reverse_active_energy_(uint8_t phase) {
const uint16_t val = this->read16_(ATM90E32_REGISTER_ANENERGY);
if (UINT32_MAX - this->phase_[phase].cumulative_reverse_active_energy_ > val) {
this->phase_[phase].cumulative_reverse_active_energy_ += val;
} else {
this->phase_[phase].cumulative_reverse_active_energy_ = val;
}
return ((float) this->phase_[phase].cumulative_reverse_active_energy_ * 10 / 3200);
}
float ATM90E32Component::get_phase_harmonic_active_power_(uint8_t phase) {
int val = this->read32_(ATM90E32_REGISTER_PMEANH + phase, ATM90E32_REGISTER_PMEANHLSB + phase);
return val * 0.00032f;
}
float ATM90E32Component::get_reactive_power_a_() {
int val = this->read32_(ATM90E32_REGISTER_QMEANA, ATM90E32_REGISTER_QMEANALSB);
return val * 0.00032f;
float ATM90E32Component::get_phase_angle_(uint8_t phase) {
uint16_t val = this->read16_(ATM90E32_REGISTER_PANGLE + phase) / 10.0;
return (float) (val > 180) ? val - 360.0 : val;
}
float ATM90E32Component::get_reactive_power_b_() {
int val = this->read32_(ATM90E32_REGISTER_QMEANB, ATM90E32_REGISTER_QMEANBLSB);
return val * 0.00032f;
}
float ATM90E32Component::get_reactive_power_c_() {
int val = this->read32_(ATM90E32_REGISTER_QMEANC, ATM90E32_REGISTER_QMEANCLSB);
return val * 0.00032f;
}
float ATM90E32Component::get_power_factor_a_() {
int16_t pf = this->read16_(ATM90E32_REGISTER_PFMEANA);
return (float) pf / 1000;
}
float ATM90E32Component::get_power_factor_b_() {
int16_t pf = this->read16_(ATM90E32_REGISTER_PFMEANB);
return (float) pf / 1000;
}
float ATM90E32Component::get_power_factor_c_() {
int16_t pf = this->read16_(ATM90E32_REGISTER_PFMEANC);
return (float) pf / 1000;
}
float ATM90E32Component::get_forward_active_energy_a_() {
uint16_t val = this->read16_(ATM90E32_REGISTER_APENERGYA);
if ((UINT32_MAX - this->phase_[0].cumulative_forward_active_energy_) > val) {
this->phase_[0].cumulative_forward_active_energy_ += val;
} else {
this->phase_[0].cumulative_forward_active_energy_ = val;
}
return ((float) this->phase_[0].cumulative_forward_active_energy_ * 10 / 3200);
}
float ATM90E32Component::get_forward_active_energy_b_() {
uint16_t val = this->read16_(ATM90E32_REGISTER_APENERGYB);
if (UINT32_MAX - this->phase_[1].cumulative_forward_active_energy_ > val) {
this->phase_[1].cumulative_forward_active_energy_ += val;
} else {
this->phase_[1].cumulative_forward_active_energy_ = val;
}
return ((float) this->phase_[1].cumulative_forward_active_energy_ * 10 / 3200);
}
float ATM90E32Component::get_forward_active_energy_c_() {
uint16_t val = this->read16_(ATM90E32_REGISTER_APENERGYC);
if (UINT32_MAX - this->phase_[2].cumulative_forward_active_energy_ > val) {
this->phase_[2].cumulative_forward_active_energy_ += val;
} else {
this->phase_[2].cumulative_forward_active_energy_ = val;
}
return ((float) this->phase_[2].cumulative_forward_active_energy_ * 10 / 3200);
}
float ATM90E32Component::get_reverse_active_energy_a_() {
uint16_t val = this->read16_(ATM90E32_REGISTER_ANENERGYA);
if (UINT32_MAX - this->phase_[0].cumulative_reverse_active_energy_ > val) {
this->phase_[0].cumulative_reverse_active_energy_ += val;
} else {
this->phase_[0].cumulative_reverse_active_energy_ = val;
}
return ((float) this->phase_[0].cumulative_reverse_active_energy_ * 10 / 3200);
}
float ATM90E32Component::get_reverse_active_energy_b_() {
uint16_t val = this->read16_(ATM90E32_REGISTER_ANENERGYB);
if (UINT32_MAX - this->phase_[1].cumulative_reverse_active_energy_ > val) {
this->phase_[1].cumulative_reverse_active_energy_ += val;
} else {
this->phase_[1].cumulative_reverse_active_energy_ = val;
}
return ((float) this->phase_[1].cumulative_reverse_active_energy_ * 10 / 3200);
}
float ATM90E32Component::get_reverse_active_energy_c_() {
uint16_t val = this->read16_(ATM90E32_REGISTER_ANENERGYC);
if (UINT32_MAX - this->phase_[2].cumulative_reverse_active_energy_ > val) {
this->phase_[2].cumulative_reverse_active_energy_ += val;
} else {
this->phase_[2].cumulative_reverse_active_energy_ = val;
}
return ((float) this->phase_[2].cumulative_reverse_active_energy_ * 10 / 3200);
float ATM90E32Component::get_phase_peak_current_(uint8_t phase) {
int16_t val = (float) this->read16_(ATM90E32_REGISTER_IPEAK + phase);
if (!this->peak_current_signed_)
val = abs(val);
// phase register * phase current gain value / 1000 * 2^13
return (float) (val * this->phase_[phase].ct_gain_ / 8192000.0);
}
float ATM90E32Component::get_frequency_() {
uint16_t freq = this->read16_(ATM90E32_REGISTER_FREQ);
const uint16_t freq = this->read16_(ATM90E32_REGISTER_FREQ);
return (float) freq / 100;
}
float ATM90E32Component::get_chip_temperature_() {
uint16_t ctemp = this->read16_(ATM90E32_REGISTER_TEMP);
const uint16_t ctemp = this->read16_(ATM90E32_REGISTER_TEMP);
return (float) ctemp;
}
uint16_t ATM90E32Component::calibrate_voltage_offset_phase(uint8_t phase) {
const uint8_t num_reads = 5;
uint64_t total_value = 0;
for (int i = 0; i < num_reads; ++i) {
const uint32_t measurement_value = read32_(ATM90E32_REGISTER_URMS + phase, ATM90E32_REGISTER_URMSLSB + phase);
total_value += measurement_value;
}
const uint32_t average_value = total_value / num_reads;
const uint32_t shifted_value = average_value >> 7;
const uint32_t voltage_offset = ~shifted_value + 1;
return voltage_offset & 0xFFFF; // Take the lower 16 bits
}
uint16_t ATM90E32Component::calibrate_current_offset_phase(uint8_t phase) {
const uint8_t num_reads = 5;
uint64_t total_value = 0;
for (int i = 0; i < num_reads; ++i) {
const uint32_t measurement_value = read32_(ATM90E32_REGISTER_IRMS + phase, ATM90E32_REGISTER_IRMSLSB + phase);
total_value += measurement_value;
}
const uint32_t average_value = total_value / num_reads;
const uint32_t current_offset = ~average_value + 1;
return current_offset & 0xFFFF; // Take the lower 16 bits
}
} // namespace atm90e32
} // namespace esphome

View File

@ -3,14 +3,19 @@
#include "esphome/core/component.h"
#include "esphome/components/sensor/sensor.h"
#include "esphome/components/spi/spi.h"
#include "atm90e32_reg.h"
namespace esphome {
namespace atm90e32 {
class ATM90E32Component : public PollingComponent,
public spi::SPIDevice<spi::BIT_ORDER_MSB_FIRST, spi::CLOCK_POLARITY_HIGH,
spi::CLOCK_PHASE_TRAILING, spi::DATA_RATE_200KHZ> {
spi::CLOCK_PHASE_TRAILING, spi::DATA_RATE_1MHZ> {
public:
static const uint8_t PHASEA = 0;
static const uint8_t PHASEB = 1;
static const uint8_t PHASEC = 2;
void loop() override;
void setup() override;
void dump_config() override;
float get_setup_priority() const override;
@ -20,6 +25,7 @@ class ATM90E32Component : public PollingComponent,
void set_current_sensor(int phase, sensor::Sensor *obj) { this->phase_[phase].current_sensor_ = obj; }
void set_power_sensor(int phase, sensor::Sensor *obj) { this->phase_[phase].power_sensor_ = obj; }
void set_reactive_power_sensor(int phase, sensor::Sensor *obj) { this->phase_[phase].reactive_power_sensor_ = obj; }
void set_apparent_power_sensor(int phase, sensor::Sensor *obj) { this->phase_[phase].apparent_power_sensor_ = obj; }
void set_forward_active_energy_sensor(int phase, sensor::Sensor *obj) {
this->phase_[phase].forward_active_energy_sensor_ = obj;
}
@ -27,64 +33,94 @@ class ATM90E32Component : public PollingComponent,
this->phase_[phase].reverse_active_energy_sensor_ = obj;
}
void set_power_factor_sensor(int phase, sensor::Sensor *obj) { this->phase_[phase].power_factor_sensor_ = obj; }
void set_volt_gain(int phase, uint16_t gain) { this->phase_[phase].volt_gain_ = gain; }
void set_phase_angle_sensor(int phase, sensor::Sensor *obj) { this->phase_[phase].phase_angle_sensor_ = obj; }
void set_harmonic_active_power_sensor(int phase, sensor::Sensor *obj) {
this->phase_[phase].harmonic_active_power_sensor_ = obj;
}
void set_peak_current_sensor(int phase, sensor::Sensor *obj) { this->phase_[phase].peak_current_sensor_ = obj; }
void set_volt_gain(int phase, uint16_t gain) { this->phase_[phase].voltage_gain_ = gain; }
void set_ct_gain(int phase, uint16_t gain) { this->phase_[phase].ct_gain_ = gain; }
void set_freq_sensor(sensor::Sensor *freq_sensor) { freq_sensor_ = freq_sensor; }
void set_peak_current_signed(bool flag) { peak_current_signed_ = flag; }
void set_chip_temperature_sensor(sensor::Sensor *chip_temperature_sensor) {
chip_temperature_sensor_ = chip_temperature_sensor;
}
void set_line_freq(int freq) { line_freq_ = freq; }
void set_current_phases(int phases) { current_phases_ = phases; }
void set_pga_gain(uint16_t gain) { pga_gain_ = gain; }
uint16_t calibrate_voltage_offset_phase(uint8_t /*phase*/);
uint16_t calibrate_current_offset_phase(uint8_t /*phase*/);
int32_t last_periodic_millis = millis();
protected:
uint16_t read16_(uint16_t a_register);
int read32_(uint16_t addr_h, uint16_t addr_l);
void write16_(uint16_t a_register, uint16_t val);
float get_line_voltage_a_();
float get_line_voltage_b_();
float get_line_voltage_c_();
float get_line_current_a_();
float get_line_current_b_();
float get_line_current_c_();
float get_active_power_a_();
float get_active_power_b_();
float get_active_power_c_();
float get_reactive_power_a_();
float get_reactive_power_b_();
float get_reactive_power_c_();
float get_power_factor_a_();
float get_power_factor_b_();
float get_power_factor_c_();
float get_forward_active_energy_a_();
float get_forward_active_energy_b_();
float get_forward_active_energy_c_();
float get_reverse_active_energy_a_();
float get_reverse_active_energy_b_();
float get_reverse_active_energy_c_();
float get_local_phase_voltage_(uint8_t /*phase*/);
float get_local_phase_current_(uint8_t /*phase*/);
float get_local_phase_active_power_(uint8_t /*phase*/);
float get_local_phase_reactive_power_(uint8_t /*phase*/);
float get_local_phase_power_factor_(uint8_t /*phase*/);
float get_local_phase_forward_active_energy_(uint8_t /*phase*/);
float get_local_phase_reverse_active_energy_(uint8_t /*phase*/);
float get_local_phase_angle_(uint8_t /*phase*/);
float get_local_phase_harmonic_active_power_(uint8_t /*phase*/);
float get_local_phase_peak_current_(uint8_t /*phase*/);
float get_phase_voltage_(uint8_t /*phase*/);
float get_phase_voltage_avg_(uint8_t /*phase*/);
float get_phase_current_(uint8_t /*phase*/);
float get_phase_current_avg_(uint8_t /*phase*/);
float get_phase_active_power_(uint8_t /*phase*/);
float get_phase_reactive_power_(uint8_t /*phase*/);
float get_phase_power_factor_(uint8_t /*phase*/);
float get_phase_forward_active_energy_(uint8_t /*phase*/);
float get_phase_reverse_active_energy_(uint8_t /*phase*/);
float get_phase_angle_(uint8_t /*phase*/);
float get_phase_harmonic_active_power_(uint8_t /*phase*/);
float get_phase_peak_current_(uint8_t /*phase*/);
float get_frequency_();
float get_chip_temperature_();
bool get_publish_interval_flag_() { return publish_interval_flag_; };
void set_publish_interval_flag_(bool flag) { publish_interval_flag_ = flag; };
struct ATM90E32Phase {
uint16_t volt_gain_{7305};
uint16_t voltage_gain_{7305};
uint16_t ct_gain_{27961};
uint16_t voltage_offset_{0};
uint16_t current_offset_{0};
float voltage_{0};
float current_{0};
float active_power_{0};
float reactive_power_{0};
float power_factor_{0};
float forward_active_energy_{0};
float reverse_active_energy_{0};
float phase_angle_{0};
float harmonic_active_power_{0};
float peak_current_{0};
sensor::Sensor *voltage_sensor_{nullptr};
sensor::Sensor *current_sensor_{nullptr};
sensor::Sensor *power_sensor_{nullptr};
sensor::Sensor *reactive_power_sensor_{nullptr};
sensor::Sensor *apparent_power_sensor_{nullptr};
sensor::Sensor *power_factor_sensor_{nullptr};
sensor::Sensor *forward_active_energy_sensor_{nullptr};
sensor::Sensor *reverse_active_energy_sensor_{nullptr};
sensor::Sensor *phase_angle_sensor_{nullptr};
sensor::Sensor *harmonic_active_power_sensor_{nullptr};
sensor::Sensor *peak_current_sensor_{nullptr};
uint32_t cumulative_forward_active_energy_{0};
uint32_t cumulative_reverse_active_energy_{0};
} phase_[3];
sensor::Sensor *freq_sensor_{nullptr};
sensor::Sensor *chip_temperature_sensor_{nullptr};
uint16_t pga_gain_{0x15};
int line_freq_{60};
int current_phases_{3};
bool publish_interval_flag_{true};
bool peak_current_signed_{false};
};
} // namespace atm90e32

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@ -131,10 +131,12 @@ static const uint16_t ATM90E32_REGISTER_IOFFSETN = 0x6E; // N Current Offset
/* ENERGY REGISTERS */
static const uint16_t ATM90E32_REGISTER_APENERGYT = 0x80; // Total Forward Active
static const uint16_t ATM90E32_REGISTER_APENERGY = 0x81; // Forward Active Reg Base
static const uint16_t ATM90E32_REGISTER_APENERGYA = 0x81; // A Forward Active
static const uint16_t ATM90E32_REGISTER_APENERGYB = 0x82; // B Forward Active
static const uint16_t ATM90E32_REGISTER_APENERGYC = 0x83; // C Forward Active
static const uint16_t ATM90E32_REGISTER_ANENERGYT = 0x84; // Total Reverse Active
static const uint16_t ATM90E32_REGISTER_ANENERGY = 0x85; // Reverse Active Reg Base
static const uint16_t ATM90E32_REGISTER_ANENERGYA = 0x85; // A Reverse Active
static const uint16_t ATM90E32_REGISTER_ANENERGYB = 0x86; // B Reverse Active
static const uint16_t ATM90E32_REGISTER_ANENERGYC = 0x87; // C Reverse Active
@ -172,10 +174,12 @@ static const uint16_t ATM90E32_REGISTER_ANENERGYCH = 0xAF; // C Reverse Harm. E
/* POWER & P.F. REGISTERS */
static const uint16_t ATM90E32_REGISTER_PMEANT = 0xB0; // Total Mean Power (P)
static const uint16_t ATM90E32_REGISTER_PMEAN = 0xB1; // Mean Power Reg Base (P)
static const uint16_t ATM90E32_REGISTER_PMEANA = 0xB1; // A Mean Power (P)
static const uint16_t ATM90E32_REGISTER_PMEANB = 0xB2; // B Mean Power (P)
static const uint16_t ATM90E32_REGISTER_PMEANC = 0xB3; // C Mean Power (P)
static const uint16_t ATM90E32_REGISTER_QMEANT = 0xB4; // Total Mean Power (Q)
static const uint16_t ATM90E32_REGISTER_QMEAN = 0xB5; // Mean Power Reg Base (Q)
static const uint16_t ATM90E32_REGISTER_QMEANA = 0xB5; // A Mean Power (Q)
static const uint16_t ATM90E32_REGISTER_QMEANB = 0xB6; // B Mean Power (Q)
static const uint16_t ATM90E32_REGISTER_QMEANC = 0xB7; // C Mean Power (Q)
@ -184,15 +188,18 @@ static const uint16_t ATM90E32_REGISTER_SMEANA = 0xB9; // A Mean Power (S)
static const uint16_t ATM90E32_REGISTER_SMEANB = 0xBA; // B Mean Power (S)
static const uint16_t ATM90E32_REGISTER_SMEANC = 0xBB; // C Mean Power (S)
static const uint16_t ATM90E32_REGISTER_PFMEANT = 0xBC; // Mean Power Factor
static const uint16_t ATM90E32_REGISTER_PFMEAN = 0xBD; // Power Factor Reg Base
static const uint16_t ATM90E32_REGISTER_PFMEANA = 0xBD; // A Power Factor
static const uint16_t ATM90E32_REGISTER_PFMEANB = 0xBE; // B Power Factor
static const uint16_t ATM90E32_REGISTER_PFMEANC = 0xBF; // C Power Factor
static const uint16_t ATM90E32_REGISTER_PMEANTLSB = 0xC0; // Lower Word (Tot. Act. Power)
static const uint16_t ATM90E32_REGISTER_PMEANLSB = 0xC1; // Lower Word Reg Base (Active Power)
static const uint16_t ATM90E32_REGISTER_PMEANALSB = 0xC1; // Lower Word (A Act. Power)
static const uint16_t ATM90E32_REGISTER_PMEANBLSB = 0xC2; // Lower Word (B Act. Power)
static const uint16_t ATM90E32_REGISTER_PMEANCLSB = 0xC3; // Lower Word (C Act. Power)
static const uint16_t ATM90E32_REGISTER_QMEANTLSB = 0xC4; // Lower Word (Tot. React. Power)
static const uint16_t ATM90E32_REGISTER_QMEANLSB = 0xC5; // Lower Word Reg Base (Reactive Power)
static const uint16_t ATM90E32_REGISTER_QMEANALSB = 0xC5; // Lower Word (A React. Power)
static const uint16_t ATM90E32_REGISTER_QMEANBLSB = 0xC6; // Lower Word (B React. Power)
static const uint16_t ATM90E32_REGISTER_QMEANCLSB = 0xC7; // Lower Word (C React. Power)
@ -207,12 +214,15 @@ static const uint16_t ATM90E32_REGISTER_PMEANAF = 0xD1; // A Active Fund. Power
static const uint16_t ATM90E32_REGISTER_PMEANBF = 0xD2; // B Active Fund. Power
static const uint16_t ATM90E32_REGISTER_PMEANCF = 0xD3; // C Active Fund. Power
static const uint16_t ATM90E32_REGISTER_PMEANTH = 0xD4; // Total Active Harm. Power
static const uint16_t ATM90E32_REGISTER_PMEANH = 0xD5; // Active Harm. Power Reg Base
static const uint16_t ATM90E32_REGISTER_PMEANAH = 0xD5; // A Active Harm. Power
static const uint16_t ATM90E32_REGISTER_PMEANBH = 0xD6; // B Active Harm. Power
static const uint16_t ATM90E32_REGISTER_PMEANCH = 0xD7; // C Active Harm. Power
static const uint16_t ATM90E32_REGISTER_URMS = 0xD9; // RMS Voltage Reg Base
static const uint16_t ATM90E32_REGISTER_URMSA = 0xD9; // A RMS Voltage
static const uint16_t ATM90E32_REGISTER_URMSB = 0xDA; // B RMS Voltage
static const uint16_t ATM90E32_REGISTER_URMSC = 0xDB; // C RMS Voltage
static const uint16_t ATM90E32_REGISTER_IRMS = 0xDD; // RMS Current Reg Base
static const uint16_t ATM90E32_REGISTER_IRMSA = 0xDD; // A RMS Current
static const uint16_t ATM90E32_REGISTER_IRMSB = 0xDE; // B RMS Current
static const uint16_t ATM90E32_REGISTER_IRMSC = 0xDF; // C RMS Current
@ -223,12 +233,15 @@ static const uint16_t ATM90E32_REGISTER_PMEANAFLSB = 0xE1; // Lower Word (A Act
static const uint16_t ATM90E32_REGISTER_PMEANBFLSB = 0xE2; // Lower Word (B Act. Fund. Power)
static const uint16_t ATM90E32_REGISTER_PMEANCFLSB = 0xE3; // Lower Word (C Act. Fund. Power)
static const uint16_t ATM90E32_REGISTER_PMEANTHLSB = 0xE4; // Lower Word (Tot. Act. Harm. Power)
static const uint16_t ATM90E32_REGISTER_PMEANHLSB = 0xE5; // Lower Word (A Act. Harm. Power) Reg Base
static const uint16_t ATM90E32_REGISTER_PMEANAHLSB = 0xE5; // Lower Word (A Act. Harm. Power)
static const uint16_t ATM90E32_REGISTER_PMEANBHLSB = 0xE6; // Lower Word (B Act. Harm. Power)
static const uint16_t ATM90E32_REGISTER_PMEANCHLSB = 0xE7; // Lower Word (C Act. Harm. Power)
static const uint16_t ATM90E32_REGISTER_URMSLSB = 0xE9; // Lower Word RMS Voltage Reg Base
static const uint16_t ATM90E32_REGISTER_URMSALSB = 0xE9; // Lower Word (A RMS Voltage)
static const uint16_t ATM90E32_REGISTER_URMSBLSB = 0xEA; // Lower Word (B RMS Voltage)
static const uint16_t ATM90E32_REGISTER_URMSCLSB = 0xEB; // Lower Word (C RMS Voltage)
static const uint16_t ATM90E32_REGISTER_IRMSLSB = 0xED; // Lower Word RMS Current Reg Base
static const uint16_t ATM90E32_REGISTER_IRMSALSB = 0xED; // Lower Word (A RMS Current)
static const uint16_t ATM90E32_REGISTER_IRMSBLSB = 0xEE; // Lower Word (B RMS Current)
static const uint16_t ATM90E32_REGISTER_IRMSCLSB = 0xEF; // Lower Word (C RMS Current)
@ -237,10 +250,12 @@ static const uint16_t ATM90E32_REGISTER_IRMSCLSB = 0xEF; // Lower Word (C RMS
static const uint16_t ATM90E32_REGISTER_UPEAKA = 0xF1; // A Voltage Peak
static const uint16_t ATM90E32_REGISTER_UPEAKB = 0xF2; // B Voltage Peak
static const uint16_t ATM90E32_REGISTER_UPEAKC = 0xF3; // C Voltage Peak
static const uint16_t ATM90E32_REGISTER_IPEAK = 0xF5; // Peak Current Reg Base
static const uint16_t ATM90E32_REGISTER_IPEAKA = 0xF5; // A Current Peak
static const uint16_t ATM90E32_REGISTER_IPEAKB = 0xF6; // B Current Peak
static const uint16_t ATM90E32_REGISTER_IPEAKC = 0xF7; // C Current Peak
static const uint16_t ATM90E32_REGISTER_FREQ = 0xF8; // Frequency
static const uint16_t ATM90E32_REGISTER_PANGLE = 0xF9; // Mean Phase Angle Reg Base
static const uint16_t ATM90E32_REGISTER_PANGLEA = 0xF9; // A Mean Phase Angle
static const uint16_t ATM90E32_REGISTER_PANGLEB = 0xFA; // B Mean Phase Angle
static const uint16_t ATM90E32_REGISTER_PANGLEC = 0xFB; // C Mean Phase Angle

View File

@ -9,8 +9,10 @@ from esphome.const import (
CONF_PHASE_A,
CONF_PHASE_B,
CONF_PHASE_C,
CONF_PHASE_ANGLE,
CONF_POWER,
CONF_POWER_FACTOR,
CONF_APPARENT_POWER,
CONF_FREQUENCY,
CONF_FORWARD_ACTIVE_ENERGY,
CONF_REVERSE_ACTIVE_ENERGY,
@ -25,12 +27,13 @@ from esphome.const import (
ICON_CURRENT_AC,
STATE_CLASS_MEASUREMENT,
STATE_CLASS_TOTAL_INCREASING,
UNIT_AMPERE,
UNIT_DEGREES,
UNIT_CELSIUS,
UNIT_HERTZ,
UNIT_VOLT,
UNIT_AMPERE,
UNIT_WATT,
UNIT_CELSIUS,
UNIT_VOLT_AMPS_REACTIVE,
UNIT_WATT,
UNIT_WATT_HOURS,
)
@ -40,6 +43,10 @@ CONF_GAIN_PGA = "gain_pga"
CONF_CURRENT_PHASES = "current_phases"
CONF_GAIN_VOLTAGE = "gain_voltage"
CONF_GAIN_CT = "gain_ct"
CONF_HARMONIC_POWER = "harmonic_power"
CONF_PEAK_CURRENT = "peak_current"
CONF_PEAK_CURRENT_SIGNED = "peak_current_signed"
UNIT_DEG = "degrees"
LINE_FREQS = {
"50HZ": 50,
"60HZ": 60,
@ -85,6 +92,12 @@ ATM90E32_PHASE_SCHEMA = cv.Schema(
accuracy_decimals=2,
state_class=STATE_CLASS_MEASUREMENT,
),
cv.Optional(CONF_APPARENT_POWER): sensor.sensor_schema(
unit_of_measurement=UNIT_WATT,
accuracy_decimals=2,
device_class=DEVICE_CLASS_POWER,
state_class=STATE_CLASS_MEASUREMENT,
),
cv.Optional(CONF_POWER_FACTOR): sensor.sensor_schema(
accuracy_decimals=2,
device_class=DEVICE_CLASS_POWER_FACTOR,
@ -102,6 +115,24 @@ ATM90E32_PHASE_SCHEMA = cv.Schema(
device_class=DEVICE_CLASS_ENERGY,
state_class=STATE_CLASS_TOTAL_INCREASING,
),
cv.Optional(CONF_PHASE_ANGLE): sensor.sensor_schema(
unit_of_measurement=UNIT_DEGREES,
accuracy_decimals=2,
device_class=DEVICE_CLASS_POWER,
state_class=STATE_CLASS_MEASUREMENT,
),
cv.Optional(CONF_HARMONIC_POWER): sensor.sensor_schema(
unit_of_measurement=UNIT_WATT,
accuracy_decimals=2,
device_class=DEVICE_CLASS_POWER,
state_class=STATE_CLASS_MEASUREMENT,
),
cv.Optional(CONF_PEAK_CURRENT): sensor.sensor_schema(
unit_of_measurement=UNIT_AMPERE,
accuracy_decimals=2,
device_class=DEVICE_CLASS_CURRENT,
state_class=STATE_CLASS_MEASUREMENT,
),
cv.Optional(CONF_GAIN_VOLTAGE, default=7305): cv.uint16_t,
cv.Optional(CONF_GAIN_CT, default=27961): cv.uint16_t,
}
@ -132,6 +163,7 @@ CONFIG_SCHEMA = (
CURRENT_PHASES, upper=True
),
cv.Optional(CONF_GAIN_PGA, default="2X"): cv.enum(PGA_GAINS, upper=True),
cv.Optional(CONF_PEAK_CURRENT_SIGNED, default=False): cv.boolean,
}
)
.extend(cv.polling_component_schema("60s"))
@ -162,6 +194,9 @@ async def to_code(config):
if reactive_power_config := conf.get(CONF_REACTIVE_POWER):
sens = await sensor.new_sensor(reactive_power_config)
cg.add(var.set_reactive_power_sensor(i, sens))
if apparent_power_config := conf.get(CONF_APPARENT_POWER):
sens = await sensor.new_sensor(apparent_power_config)
cg.add(var.set_apparent_power_sensor(i, sens))
if power_factor_config := conf.get(CONF_POWER_FACTOR):
sens = await sensor.new_sensor(power_factor_config)
cg.add(var.set_power_factor_sensor(i, sens))
@ -171,6 +206,15 @@ async def to_code(config):
if reverse_active_energy_config := conf.get(CONF_REVERSE_ACTIVE_ENERGY):
sens = await sensor.new_sensor(reverse_active_energy_config)
cg.add(var.set_reverse_active_energy_sensor(i, sens))
if phase_angle_config := conf.get(CONF_PHASE_ANGLE):
sens = await sensor.new_sensor(phase_angle_config)
cg.add(var.set_phase_angle_sensor(i, sens))
if harmonic_active_power_config := conf.get(CONF_HARMONIC_POWER):
sens = await sensor.new_sensor(harmonic_active_power_config)
cg.add(var.set_harmonic_active_power_sensor(i, sens))
if peak_current_config := conf.get(CONF_PEAK_CURRENT):
sens = await sensor.new_sensor(peak_current_config)
cg.add(var.set_peak_current_sensor(i, sens))
if frequency_config := config.get(CONF_FREQUENCY):
sens = await sensor.new_sensor(frequency_config)
@ -182,3 +226,4 @@ async def to_code(config):
cg.add(var.set_line_freq(config[CONF_LINE_FREQUENCY]))
cg.add(var.set_current_phases(config[CONF_CURRENT_PHASES]))
cg.add(var.set_pga_gain(config[CONF_GAIN_PGA]))
cg.add(var.set_peak_current_signed(config[CONF_PEAK_CURRENT_SIGNED]))

View File

@ -194,8 +194,8 @@ void BangBangClimate::dump_config() {
ESP_LOGCONFIG(TAG, " Supports HEAT: %s", YESNO(this->supports_heat_));
ESP_LOGCONFIG(TAG, " Supports COOL: %s", YESNO(this->supports_cool_));
ESP_LOGCONFIG(TAG, " Supports AWAY mode: %s", YESNO(this->supports_away_));
ESP_LOGCONFIG(TAG, " Default Target Temperature Low: %.1f°C", this->normal_config_.default_temperature_low);
ESP_LOGCONFIG(TAG, " Default Target Temperature High: %.1f°C", this->normal_config_.default_temperature_high);
ESP_LOGCONFIG(TAG, " Default Target Temperature Low: %.2f°C", this->normal_config_.default_temperature_low);
ESP_LOGCONFIG(TAG, " Default Target Temperature High: %.2f°C", this->normal_config_.default_temperature_high);
}
BangBangClimateTargetTempConfig::BangBangClimateTargetTempConfig() = default;

View File

@ -8,8 +8,11 @@ from esphome.const import (
CONF_IBEACON_MINOR,
CONF_IBEACON_UUID,
CONF_MIN_RSSI,
CONF_TIMEOUT,
)
CONF_IRK = "irk"
DEPENDENCIES = ["esp32_ble_tracker"]
ble_presence_ns = cg.esphome_ns.namespace("ble_presence")
@ -34,10 +37,12 @@ CONFIG_SCHEMA = cv.All(
.extend(
{
cv.Optional(CONF_MAC_ADDRESS): cv.mac_address,
cv.Optional(CONF_IRK): cv.uuid,
cv.Optional(CONF_SERVICE_UUID): esp32_ble_tracker.bt_uuid,
cv.Optional(CONF_IBEACON_MAJOR): cv.uint16_t,
cv.Optional(CONF_IBEACON_MINOR): cv.uint16_t,
cv.Optional(CONF_IBEACON_UUID): cv.uuid,
cv.Optional(CONF_TIMEOUT, default="5min"): cv.positive_time_period,
cv.Optional(CONF_MIN_RSSI): cv.All(
cv.decibel, cv.int_range(min=-100, max=-30)
),
@ -45,7 +50,9 @@ CONFIG_SCHEMA = cv.All(
)
.extend(esp32_ble_tracker.ESP_BLE_DEVICE_SCHEMA)
.extend(cv.COMPONENT_SCHEMA),
cv.has_exactly_one_key(CONF_MAC_ADDRESS, CONF_SERVICE_UUID, CONF_IBEACON_UUID),
cv.has_exactly_one_key(
CONF_MAC_ADDRESS, CONF_IRK, CONF_SERVICE_UUID, CONF_IBEACON_UUID
),
_validate,
)
@ -55,12 +62,17 @@ async def to_code(config):
await cg.register_component(var, config)
await esp32_ble_tracker.register_ble_device(var, config)
cg.add(var.set_timeout(config[CONF_TIMEOUT].total_milliseconds))
if min_rssi := config.get(CONF_MIN_RSSI):
cg.add(var.set_minimum_rssi(min_rssi))
if mac_address := config.get(CONF_MAC_ADDRESS):
cg.add(var.set_address(mac_address.as_hex))
if irk := config.get(CONF_IRK):
irk = esp32_ble_tracker.as_hex_array(str(irk))
cg.add(var.set_irk(irk))
if service_uuid := config.get(CONF_SERVICE_UUID):
if len(service_uuid) == len(esp32_ble_tracker.bt_uuid16_format):
cg.add(var.set_service_uuid16(esp32_ble_tracker.as_hex(service_uuid)))

View File

@ -6,6 +6,16 @@
#ifdef USE_ESP32
#ifdef USE_ARDUINO
#include "mbedtls/aes.h"
#include "mbedtls/base64.h"
#endif
#ifdef USE_ESP_IDF
#define MBEDTLS_AES_ALT
#include <aes_alt.h>
#endif
namespace esphome {
namespace ble_presence {
@ -17,6 +27,10 @@ class BLEPresenceDevice : public binary_sensor::BinarySensorInitiallyOff,
this->match_by_ = MATCH_BY_MAC_ADDRESS;
this->address_ = address;
}
void set_irk(uint8_t *irk) {
this->match_by_ = MATCH_BY_IRK;
this->irk_ = irk;
}
void set_service_uuid16(uint16_t uuid) {
this->match_by_ = MATCH_BY_SERVICE_UUID;
this->uuid_ = esp32_ble_tracker::ESPBTUUID::from_uint16(uuid);
@ -45,11 +59,7 @@ class BLEPresenceDevice : public binary_sensor::BinarySensorInitiallyOff,
this->check_minimum_rssi_ = true;
this->minimum_rssi_ = rssi;
}
void on_scan_end() override {
if (!this->found_)
this->publish_state(false);
this->found_ = false;
}
void set_timeout(uint32_t timeout) { this->timeout_ = timeout; }
bool parse_device(const esp32_ble_tracker::ESPBTDevice &device) override {
if (this->check_minimum_rssi_ && this->minimum_rssi_ > device.get_rssi()) {
return false;
@ -57,6 +67,12 @@ class BLEPresenceDevice : public binary_sensor::BinarySensorInitiallyOff,
switch (this->match_by_) {
case MATCH_BY_MAC_ADDRESS:
if (device.address_uint64() == this->address_) {
this->set_found_(true);
return true;
}
break;
case MATCH_BY_IRK:
if (resolve_irk_(device.address_uint64(), this->irk_)) {
this->publish_state(true);
this->found_ = true;
return true;
@ -65,8 +81,7 @@ class BLEPresenceDevice : public binary_sensor::BinarySensorInitiallyOff,
case MATCH_BY_SERVICE_UUID:
for (auto uuid : device.get_service_uuids()) {
if (this->uuid_ == uuid) {
this->publish_state(true);
this->found_ = true;
this->set_found_(true);
return true;
}
}
@ -90,20 +105,31 @@ class BLEPresenceDevice : public binary_sensor::BinarySensorInitiallyOff,
return false;
}
this->publish_state(true);
this->found_ = true;
this->set_found_(true);
return true;
}
return false;
}
void loop() override {
if (this->found_ && this->last_seen_ + this->timeout_ < millis())
this->set_found_(false);
}
void dump_config() override;
float get_setup_priority() const override { return setup_priority::DATA; }
protected:
enum MatchType { MATCH_BY_MAC_ADDRESS, MATCH_BY_SERVICE_UUID, MATCH_BY_IBEACON_UUID };
void set_found_(bool state) {
this->found_ = state;
if (state)
this->last_seen_ = millis();
this->publish_state(state);
}
enum MatchType { MATCH_BY_MAC_ADDRESS, MATCH_BY_IRK, MATCH_BY_SERVICE_UUID, MATCH_BY_IBEACON_UUID };
MatchType match_by_;
uint64_t address_;
uint8_t *irk_;
esp32_ble_tracker::ESPBTUUID uuid_;
@ -117,7 +143,46 @@ class BLEPresenceDevice : public binary_sensor::BinarySensorInitiallyOff,
bool check_ibeacon_minor_{false};
bool check_minimum_rssi_{false};
bool resolve_irk_(uint64_t addr64, const uint8_t *irk) {
uint8_t ecb_key[16];
uint8_t ecb_plaintext[16];
uint8_t ecb_ciphertext[16];
memcpy(&ecb_key, irk, 16);
memset(&ecb_plaintext, 0, 16);
ecb_plaintext[13] = (addr64 >> 40) & 0xff;
ecb_plaintext[14] = (addr64 >> 32) & 0xff;
ecb_plaintext[15] = (addr64 >> 24) & 0xff;
mbedtls_aes_context ctx = {0, 0, {0}};
mbedtls_aes_init(&ctx);
if (mbedtls_aes_setkey_enc(&ctx, ecb_key, 128) != 0) {
mbedtls_aes_free(&ctx);
return false;
}
if (mbedtls_aes_crypt_ecb(&ctx,
#ifdef USE_ARDUINO
MBEDTLS_AES_ENCRYPT,
#elif defined(USE_ESP_IDF)
ESP_AES_ENCRYPT,
#endif
ecb_plaintext, ecb_ciphertext) != 0) {
mbedtls_aes_free(&ctx);
return false;
}
mbedtls_aes_free(&ctx);
return ecb_ciphertext[15] == (addr64 & 0xff) && ecb_ciphertext[14] == ((addr64 >> 8) & 0xff) &&
ecb_ciphertext[13] == ((addr64 >> 16) & 0xff);
}
bool found_{false};
uint32_t last_seen_{};
uint32_t timeout_{};
};
} // namespace ble_presence

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@ -118,7 +118,7 @@ void CSE7766Component::parse_data_() {
uint32_t power_coeff = this->get_24_bit_uint_(14);
uint32_t power_cycle = this->get_24_bit_uint_(17);
uint8_t adj = this->raw_data_[20];
uint32_t cf_pulses = (this->raw_data_[21] << 8) + this->raw_data_[22];
uint16_t cf_pulses = (this->raw_data_[21] << 8) + this->raw_data_[22];
bool have_power = adj & 0x10;
bool have_current = adj & 0x20;
@ -132,8 +132,19 @@ void CSE7766Component::parse_data_() {
}
}
float energy = 0.0;
if (this->energy_sensor_ != nullptr) {
if (this->cf_pulses_last_ == 0 && !this->energy_sensor_->has_state()) {
this->cf_pulses_last_ = cf_pulses;
}
uint16_t cf_diff = cf_pulses - this->cf_pulses_last_;
this->cf_pulses_total_ += cf_diff;
this->cf_pulses_last_ = cf_pulses;
energy = this->cf_pulses_total_ * float(power_coeff) / 1000000.0f / 3600.0f;
this->energy_sensor_->publish_state(energy);
}
float power = 0.0f;
float energy = 0.0f;
if (power_cycle_exceeds_range) {
// Datasheet: power cycle exceeding range means active power is 0
if (this->power_sensor_ != nullptr) {
@ -144,27 +155,6 @@ void CSE7766Component::parse_data_() {
if (this->power_sensor_ != nullptr) {
this->power_sensor_->publish_state(power);
}
// Add CF pulses to the total energy only if we have Power coefficient to multiply by
if (this->cf_pulses_last_ == 0) {
this->cf_pulses_last_ = cf_pulses;
}
uint32_t cf_diff;
if (cf_pulses < this->cf_pulses_last_) {
cf_diff = cf_pulses + (0x10000 - this->cf_pulses_last_);
} else {
cf_diff = cf_pulses - this->cf_pulses_last_;
}
this->cf_pulses_last_ = cf_pulses;
energy = cf_diff * float(power_coeff) / 1000000.0f / 3600.0f;
this->energy_total_ += energy;
if (this->energy_sensor_ != nullptr)
this->energy_sensor_->publish_state(this->energy_total_);
} else if ((this->energy_sensor_ != nullptr) && !this->energy_sensor_->has_state()) {
this->energy_sensor_->publish_state(0);
}
float current = 0.0f;
@ -183,6 +173,32 @@ void CSE7766Component::parse_data_() {
}
}
if (have_voltage && have_current) {
const float apparent_power = voltage * current;
if (this->apparent_power_sensor_ != nullptr) {
this->apparent_power_sensor_->publish_state(apparent_power);
}
if (this->power_factor_sensor_ != nullptr && (have_power || power_cycle_exceeds_range)) {
float pf = NAN;
if (apparent_power > 0) {
pf = power / apparent_power;
if (pf < 0 || pf > 1) {
ESP_LOGD(TAG, "Impossible power factor: %.4f not in interval [0, 1]", pf);
pf = NAN;
}
} else if (apparent_power == 0 && power == 0) {
// No load, report ideal power factor
pf = 1.0f;
} else if (current == 0 && calculated_current <= 0.05f) {
// Datasheet: minimum measured current is 50mA
ESP_LOGV(TAG, "Can't calculate power factor (current below minimum for CSE7766)");
} else {
ESP_LOGW(TAG, "Can't calculate power factor from P = %.4f W, S = %.4f VA", power, apparent_power);
}
this->power_factor_sensor_->publish_state(pf);
}
}
#if ESPHOME_LOG_LEVEL >= ESPHOME_LOG_LEVEL_VERY_VERBOSE
{
std::stringstream ss;
@ -215,6 +231,8 @@ void CSE7766Component::dump_config() {
LOG_SENSOR(" ", "Current", this->current_sensor_);
LOG_SENSOR(" ", "Power", this->power_sensor_);
LOG_SENSOR(" ", "Energy", this->energy_sensor_);
LOG_SENSOR(" ", "Apparent Power", this->apparent_power_sensor_);
LOG_SENSOR(" ", "Power Factor", this->power_factor_sensor_);
this->check_uart_settings(4800);
}

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@ -13,6 +13,10 @@ class CSE7766Component : public Component, public uart::UARTDevice {
void set_current_sensor(sensor::Sensor *current_sensor) { current_sensor_ = current_sensor; }
void set_power_sensor(sensor::Sensor *power_sensor) { power_sensor_ = power_sensor; }
void set_energy_sensor(sensor::Sensor *energy_sensor) { energy_sensor_ = energy_sensor; }
void set_apparent_power_sensor(sensor::Sensor *apparent_power_sensor) {
apparent_power_sensor_ = apparent_power_sensor;
}
void set_power_factor_sensor(sensor::Sensor *power_factor_sensor) { power_factor_sensor_ = power_factor_sensor; }
void loop() override;
float get_setup_priority() const override;
@ -30,8 +34,10 @@ class CSE7766Component : public Component, public uart::UARTDevice {
sensor::Sensor *current_sensor_{nullptr};
sensor::Sensor *power_sensor_{nullptr};
sensor::Sensor *energy_sensor_{nullptr};
float energy_total_{0.0f};
uint32_t cf_pulses_last_{0};
sensor::Sensor *apparent_power_sensor_{nullptr};
sensor::Sensor *power_factor_sensor_{nullptr};
uint32_t cf_pulses_total_{0};
uint16_t cf_pulses_last_{0};
};
} // namespace cse7766

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@ -2,19 +2,24 @@ import esphome.codegen as cg
import esphome.config_validation as cv
from esphome.components import sensor, uart
from esphome.const import (
CONF_APPARENT_POWER,
CONF_CURRENT,
CONF_ENERGY,
CONF_ID,
CONF_POWER,
CONF_POWER_FACTOR,
CONF_VOLTAGE,
DEVICE_CLASS_APPARENT_POWER,
DEVICE_CLASS_CURRENT,
DEVICE_CLASS_ENERGY,
DEVICE_CLASS_POWER,
DEVICE_CLASS_POWER_FACTOR,
DEVICE_CLASS_VOLTAGE,
STATE_CLASS_MEASUREMENT,
STATE_CLASS_TOTAL_INCREASING,
UNIT_VOLT,
UNIT_AMPERE,
UNIT_VOLT,
UNIT_VOLT_AMPS,
UNIT_WATT,
UNIT_WATT_HOURS,
)
@ -51,6 +56,17 @@ CONFIG_SCHEMA = cv.Schema(
device_class=DEVICE_CLASS_ENERGY,
state_class=STATE_CLASS_TOTAL_INCREASING,
),
cv.Optional(CONF_APPARENT_POWER): sensor.sensor_schema(
unit_of_measurement=UNIT_VOLT_AMPS,
accuracy_decimals=1,
device_class=DEVICE_CLASS_APPARENT_POWER,
state_class=STATE_CLASS_MEASUREMENT,
),
cv.Optional(CONF_POWER_FACTOR): sensor.sensor_schema(
accuracy_decimals=2,
device_class=DEVICE_CLASS_POWER_FACTOR,
state_class=STATE_CLASS_MEASUREMENT,
),
}
).extend(uart.UART_DEVICE_SCHEMA)
FINAL_VALIDATE_SCHEMA = uart.final_validate_device_schema(
@ -75,3 +91,9 @@ async def to_code(config):
if energy_config := config.get(CONF_ENERGY):
sens = await sensor.new_sensor(energy_config)
cg.add(var.set_energy_sensor(sens))
if apparent_power_config := config.get(CONF_APPARENT_POWER):
sens = await sensor.new_sensor(apparent_power_config)
cg.add(var.set_apparent_power_sensor(sens))
if power_factor_config := config.get(CONF_POWER_FACTOR):
sens = await sensor.new_sensor(power_factor_config)
cg.add(var.set_power_factor_sensor(sens))

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@ -0,0 +1,6 @@
import esphome.codegen as cg
CODEOWNERS = ["@clydebarrow"]
DEPENDENCIES = ["i2c"]
cst226_ns = cg.esphome_ns.namespace("cst226")

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@ -0,0 +1,38 @@
import esphome.codegen as cg
import esphome.config_validation as cv
from esphome import pins
from esphome.components import i2c, touchscreen
from esphome.const import CONF_INTERRUPT_PIN, CONF_ID, CONF_RESET_PIN
from .. import cst226_ns
CST226Touchscreen = cst226_ns.class_(
"CST226Touchscreen",
touchscreen.Touchscreen,
i2c.I2CDevice,
)
CST226ButtonListener = cst226_ns.class_("CST226ButtonListener")
CONFIG_SCHEMA = (
touchscreen.touchscreen_schema("100ms")
.extend(
{
cv.GenerateID(): cv.declare_id(CST226Touchscreen),
cv.Optional(CONF_INTERRUPT_PIN): pins.internal_gpio_input_pin_schema,
cv.Optional(CONF_RESET_PIN): pins.gpio_output_pin_schema,
}
)
.extend(i2c.i2c_device_schema(0x5A))
)
async def to_code(config):
var = cg.new_Pvariable(config[CONF_ID])
await touchscreen.register_touchscreen(var, config)
await i2c.register_i2c_device(var, config)
if interrupt_pin := config.get(CONF_INTERRUPT_PIN):
cg.add(var.set_interrupt_pin(await cg.gpio_pin_expression(interrupt_pin)))
if reset_pin := config.get(CONF_RESET_PIN):
cg.add(var.set_reset_pin(await cg.gpio_pin_expression(reset_pin)))

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@ -0,0 +1,92 @@
#include "cst226_touchscreen.h"
namespace esphome {
namespace cst226 {
void CST226Touchscreen::setup() {
esph_log_config(TAG, "Setting up CST226 Touchscreen...");
if (this->reset_pin_ != nullptr) {
this->reset_pin_->setup();
this->reset_pin_->digital_write(true);
delay(5);
this->reset_pin_->digital_write(false);
delay(5);
this->reset_pin_->digital_write(true);
this->set_timeout(30, [this] { this->continue_setup_(); });
} else {
this->continue_setup_();
}
}
void CST226Touchscreen::update_touches() {
uint8_t data[28];
if (!this->read_bytes(CST226_REG_STATUS, data, sizeof data)) {
this->status_set_warning();
this->skip_update_ = true;
return;
}
this->status_clear_warning();
if (data[6] != 0xAB || data[0] == 0xAB || data[5] == 0x80) {
this->skip_update_ = true;
return;
}
uint8_t num_of_touches = data[5] & 0x7F;
if (num_of_touches == 0 || num_of_touches > 5) {
this->write_byte(0, 0xAB);
return;
}
size_t index = 0;
for (uint8_t i = 0; i != num_of_touches; i++) {
uint8_t id = data[index] >> 4;
int16_t x = (data[index + 1] << 4) | ((data[index + 3] >> 4) & 0x0F);
int16_t y = (data[index + 2] << 4) | (data[index + 3] & 0x0F);
int16_t z = data[index + 4];
this->add_raw_touch_position_(id, x, y, z);
esph_log_v(TAG, "Read touch %d: %d/%d", id, x, y);
index += 5;
if (i == 0)
index += 2;
}
}
void CST226Touchscreen::continue_setup_() {
uint8_t buffer[8];
if (this->interrupt_pin_ != nullptr) {
this->interrupt_pin_->setup();
this->attach_interrupt_(this->interrupt_pin_, gpio::INTERRUPT_FALLING_EDGE);
}
buffer[0] = 0xD1;
if (this->write_register16(0xD1, buffer, 1) != i2c::ERROR_OK) {
esph_log_e(TAG, "Write byte to 0xD1 failed");
this->mark_failed();
return;
}
delay(10);
if (this->read16_(0xD204, buffer, 4)) {
uint16_t chip_id = buffer[2] + (buffer[3] << 8);
uint16_t project_id = buffer[0] + (buffer[1] << 8);
esph_log_config(TAG, "Chip ID %X, project ID %x", chip_id, project_id);
}
if (this->x_raw_max_ == 0 || this->y_raw_max_ == 0) {
if (this->read16_(0xD1F8, buffer, 4)) {
this->x_raw_max_ = buffer[0] + (buffer[1] << 8);
this->y_raw_max_ = buffer[2] + (buffer[3] << 8);
} else {
this->x_raw_max_ = this->display_->get_native_width();
this->y_raw_max_ = this->display_->get_native_height();
}
}
this->setup_complete_ = true;
esph_log_config(TAG, "CST226 Touchscreen setup complete");
}
void CST226Touchscreen::dump_config() {
ESP_LOGCONFIG(TAG, "CST226 Touchscreen:");
LOG_I2C_DEVICE(this);
LOG_PIN(" Interrupt Pin: ", this->interrupt_pin_);
LOG_PIN(" Reset Pin: ", this->reset_pin_);
}
} // namespace cst226
} // namespace esphome

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@ -0,0 +1,44 @@
#pragma once
#include "esphome/components/i2c/i2c.h"
#include "esphome/components/touchscreen/touchscreen.h"
#include "esphome/core/component.h"
#include "esphome/core/hal.h"
#include "esphome/core/log.h"
namespace esphome {
namespace cst226 {
static const char *const TAG = "cst226.touchscreen";
static const uint8_t CST226_REG_STATUS = 0x00;
class CST226Touchscreen : public touchscreen::Touchscreen, public i2c::I2CDevice {
public:
void setup() override;
void update_touches() override;
void dump_config() override;
void set_interrupt_pin(InternalGPIOPin *pin) { this->interrupt_pin_ = pin; }
void set_reset_pin(GPIOPin *pin) { this->reset_pin_ = pin; }
bool can_proceed() override { return this->setup_complete_ || this->is_failed(); }
protected:
bool read16_(uint16_t addr, uint8_t *data, size_t len) {
if (this->read_register16(addr, data, len) != i2c::ERROR_OK) {
esph_log_e(TAG, "Read data from 0x%04X failed", addr);
this->mark_failed();
return false;
}
return true;
}
void continue_setup_();
InternalGPIOPin *interrupt_pin_{};
GPIOPin *reset_pin_{};
uint8_t chip_id_{};
bool setup_complete_{};
};
} // namespace cst226
} // namespace esphome

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@ -0,0 +1,6 @@
import esphome.codegen as cg
CODEOWNERS = ["@clydebarrow"]
DEPENDENCIES = ["i2c"]
cst816_ns = cg.esphome_ns.namespace("cst816")

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@ -0,0 +1,28 @@
import esphome.codegen as cg
import esphome.config_validation as cv
from esphome.components import binary_sensor
from .. import cst816_ns
from ..touchscreen import CST816Touchscreen, CST816ButtonListener
CONF_CST816_ID = "cst816_id"
CST816Button = cst816_ns.class_(
"CST816Button",
binary_sensor.BinarySensor,
cg.Component,
CST816ButtonListener,
cg.Parented.template(CST816Touchscreen),
)
CONFIG_SCHEMA = binary_sensor.binary_sensor_schema(CST816Button).extend(
{
cv.GenerateID(CONF_CST816_ID): cv.use_id(CST816Touchscreen),
}
)
async def to_code(config):
var = await binary_sensor.new_binary_sensor(config)
await cg.register_component(var, config)
await cg.register_parented(var, config[CONF_CST816_ID])

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@ -0,0 +1,27 @@
#pragma once
#include "esphome/components/binary_sensor/binary_sensor.h"
#include "esphome/components/cst816/touchscreen/cst816_touchscreen.h"
#include "esphome/core/component.h"
#include "esphome/core/helpers.h"
namespace esphome {
namespace cst816 {
class CST816Button : public binary_sensor::BinarySensor,
public Component,
public CST816ButtonListener,
public Parented<CST816Touchscreen> {
public:
void setup() override {
this->parent_->register_button_listener(this);
this->publish_initial_state(false);
}
void dump_config() override { LOG_BINARY_SENSOR("", "CST816 Button", this); }
void update_button(bool state) override { this->publish_state(state); }
};
} // namespace cst816
} // namespace esphome

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@ -0,0 +1,34 @@
import esphome.codegen as cg
import esphome.config_validation as cv
from esphome import pins
from esphome.components import i2c, touchscreen
from esphome.const import CONF_INTERRUPT_PIN, CONF_ID, CONF_RESET_PIN
from .. import cst816_ns
CST816Touchscreen = cst816_ns.class_(
"CST816Touchscreen",
touchscreen.Touchscreen,
i2c.I2CDevice,
)
CST816ButtonListener = cst816_ns.class_("CST816ButtonListener")
CONFIG_SCHEMA = touchscreen.TOUCHSCREEN_SCHEMA.extend(
{
cv.GenerateID(): cv.declare_id(CST816Touchscreen),
cv.Optional(CONF_INTERRUPT_PIN): pins.internal_gpio_input_pin_schema,
cv.Optional(CONF_RESET_PIN): pins.gpio_output_pin_schema,
}
).extend(i2c.i2c_device_schema(0x15))
async def to_code(config):
var = cg.new_Pvariable(config[CONF_ID])
await touchscreen.register_touchscreen(var, config)
await i2c.register_i2c_device(var, config)
if interrupt_pin := config.get(CONF_INTERRUPT_PIN):
cg.add(var.set_interrupt_pin(await cg.gpio_pin_expression(interrupt_pin)))
if reset_pin := config.get(CONF_RESET_PIN):
cg.add(var.set_reset_pin(await cg.gpio_pin_expression(reset_pin)))

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@ -0,0 +1,113 @@
#include "cst816_touchscreen.h"
namespace esphome {
namespace cst816 {
void CST816Touchscreen::continue_setup_() {
if (this->interrupt_pin_ != nullptr) {
this->interrupt_pin_->setup();
this->attach_interrupt_(this->interrupt_pin_, gpio::INTERRUPT_FALLING_EDGE);
}
if (!this->read_byte(REG_CHIP_ID, &this->chip_id_)) {
this->mark_failed();
esph_log_e(TAG, "Failed to read chip id");
return;
}
switch (this->chip_id_) {
case CST820_CHIP_ID:
case CST716_CHIP_ID:
case CST816S_CHIP_ID:
case CST816D_CHIP_ID:
case CST816T_CHIP_ID:
break;
default:
this->mark_failed();
esph_log_e(TAG, "Unknown chip ID 0x%02X", this->chip_id_);
return;
}
this->write_byte(REG_IRQ_CTL, IRQ_EN_MOTION);
if (this->x_raw_max_ == this->x_raw_min_) {
this->x_raw_max_ = this->display_->get_native_width();
}
if (this->y_raw_max_ == this->y_raw_min_) {
this->y_raw_max_ = this->display_->get_native_height();
}
esph_log_config(TAG, "CST816 Touchscreen setup complete");
}
void CST816Touchscreen::update_button_state_(bool state) {
if (this->button_touched_ == state)
return;
this->button_touched_ = state;
for (auto *listener : this->button_listeners_)
listener->update_button(state);
}
void CST816Touchscreen::setup() {
esph_log_config(TAG, "Setting up CST816 Touchscreen...");
if (this->reset_pin_ != nullptr) {
this->reset_pin_->setup();
this->reset_pin_->digital_write(true);
delay(5);
this->reset_pin_->digital_write(false);
delay(5);
this->reset_pin_->digital_write(true);
this->set_timeout(30, [this] { this->continue_setup_(); });
} else {
this->continue_setup_();
}
}
void CST816Touchscreen::update_touches() {
uint8_t data[13];
if (!this->read_bytes(REG_STATUS, data, sizeof data)) {
this->status_set_warning();
return;
}
uint8_t num_of_touches = data[REG_TOUCH_NUM] & 3;
if (num_of_touches == 0) {
this->update_button_state_(false);
return;
}
uint16_t x = encode_uint16(data[REG_XPOS_HIGH] & 0xF, data[REG_XPOS_LOW]);
uint16_t y = encode_uint16(data[REG_YPOS_HIGH] & 0xF, data[REG_YPOS_LOW]);
esph_log_v(TAG, "Read touch %d/%d", x, y);
if (x >= this->x_raw_max_) {
this->update_button_state_(true);
} else {
this->add_raw_touch_position_(0, x, y);
}
}
void CST816Touchscreen::dump_config() {
ESP_LOGCONFIG(TAG, "CST816 Touchscreen:");
LOG_I2C_DEVICE(this);
LOG_PIN(" Interrupt Pin: ", this->interrupt_pin_);
LOG_PIN(" Reset Pin: ", this->reset_pin_);
const char *name;
switch (this->chip_id_) {
case CST820_CHIP_ID:
name = "CST820";
break;
case CST816S_CHIP_ID:
name = "CST816S";
break;
case CST816D_CHIP_ID:
name = "CST816D";
break;
case CST716_CHIP_ID:
name = "CST716";
break;
case CST816T_CHIP_ID:
name = "CST816T";
break;
default:
name = "Unknown";
break;
}
ESP_LOGCONFIG(TAG, " Chip type: %s", name);
}
} // namespace cst816
} // namespace esphome

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@ -0,0 +1,60 @@
#pragma once
#include "esphome/components/i2c/i2c.h"
#include "esphome/components/touchscreen/touchscreen.h"
#include "esphome/core/component.h"
#include "esphome/core/hal.h"
#include "esphome/core/log.h"
namespace esphome {
namespace cst816 {
static const char *const TAG = "cst816.touchscreen";
static const uint8_t REG_STATUS = 0x00;
static const uint8_t REG_TOUCH_NUM = 0x02;
static const uint8_t REG_XPOS_HIGH = 0x03;
static const uint8_t REG_XPOS_LOW = 0x04;
static const uint8_t REG_YPOS_HIGH = 0x05;
static const uint8_t REG_YPOS_LOW = 0x06;
static const uint8_t REG_DIS_AUTOSLEEP = 0xFE;
static const uint8_t REG_CHIP_ID = 0xA7;
static const uint8_t REG_FW_VERSION = 0xA9;
static const uint8_t REG_SLEEP = 0xE5;
static const uint8_t REG_IRQ_CTL = 0xFA;
static const uint8_t IRQ_EN_MOTION = 0x70;
static const uint8_t CST820_CHIP_ID = 0xB7;
static const uint8_t CST816S_CHIP_ID = 0xB4;
static const uint8_t CST816D_CHIP_ID = 0xB6;
static const uint8_t CST816T_CHIP_ID = 0xB5;
static const uint8_t CST716_CHIP_ID = 0x20;
class CST816ButtonListener {
public:
virtual void update_button(bool state) = 0;
};
class CST816Touchscreen : public touchscreen::Touchscreen, public i2c::I2CDevice {
public:
void setup() override;
void update_touches() override;
void register_button_listener(CST816ButtonListener *listener) { this->button_listeners_.push_back(listener); }
void dump_config() override;
void set_interrupt_pin(InternalGPIOPin *pin) { this->interrupt_pin_ = pin; }
void set_reset_pin(GPIOPin *pin) { this->reset_pin_ = pin; }
protected:
void continue_setup_();
void update_button_state_(bool state);
InternalGPIOPin *interrupt_pin_{};
GPIOPin *reset_pin_{};
uint8_t chip_id_{};
std::vector<CST816ButtonListener *> button_listeners_;
bool button_touched_{};
};
} // namespace cst816
} // namespace esphome

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@ -0,0 +1,146 @@
import esphome.codegen as cg
# import cpp_generator as cpp
import esphome.config_validation as cv
from esphome import automation
from esphome.components import mqtt
from esphome.const import (
CONF_ID,
CONF_ON_VALUE,
CONF_TRIGGER_ID,
CONF_TYPE,
CONF_MQTT_ID,
CONF_DATE,
CONF_YEAR,
CONF_MONTH,
CONF_DAY,
)
from esphome.core import CORE, coroutine_with_priority
from esphome.cpp_generator import MockObjClass
from esphome.cpp_helpers import setup_entity
CODEOWNERS = ["@rfdarter"]
IS_PLATFORM_COMPONENT = True
datetime_ns = cg.esphome_ns.namespace("datetime")
DateTimeBase = datetime_ns.class_("DateTimeBase", cg.EntityBase)
DateEntity = datetime_ns.class_("DateEntity", DateTimeBase)
# Actions
DateSetAction = datetime_ns.class_("DateSetAction", automation.Action)
DateTimeStateTrigger = datetime_ns.class_(
"DateTimeStateTrigger", automation.Trigger.template(cg.ESPTime)
)
DATETIME_MODES = [
"DATE",
"TIME",
"DATETIME",
]
_DATETIME_SCHEMA = cv.Schema(
{
cv.OnlyWith(CONF_MQTT_ID, "mqtt"): cv.declare_id(mqtt.MQTTDatetimeComponent),
cv.Optional(CONF_ON_VALUE): automation.validate_automation(
{
cv.GenerateID(CONF_TRIGGER_ID): cv.declare_id(DateTimeStateTrigger),
}
),
}
).extend(cv.ENTITY_BASE_SCHEMA.extend(cv.MQTT_COMMAND_COMPONENT_SCHEMA))
def date_schema(class_: MockObjClass) -> cv.Schema:
schema = {
cv.GenerateID(): cv.declare_id(class_),
cv.Optional(CONF_TYPE, default="DATE"): cv.one_of("DATE", upper=True),
}
return _DATETIME_SCHEMA.extend(schema)
def time_schema(class_: MockObjClass) -> cv.Schema:
schema = {
cv.GenerateID(): cv.declare_id(class_),
cv.Optional(CONF_TYPE, default="TIME"): cv.one_of("TIME", upper=True),
}
return _DATETIME_SCHEMA.extend(schema)
def datetime_schema(class_: MockObjClass) -> cv.Schema:
schema = {
cv.GenerateID(): cv.declare_id(class_),
cv.Optional(CONF_TYPE, default="DATETIME"): cv.one_of("DATETIME", upper=True),
}
return _DATETIME_SCHEMA.extend(schema)
async def setup_datetime_core_(var, config):
await setup_entity(var, config)
if CONF_MQTT_ID in config:
mqtt_ = cg.new_Pvariable(config[CONF_MQTT_ID], var)
await mqtt.register_mqtt_component(mqtt_, config)
for conf in config.get(CONF_ON_VALUE, []):
trigger = cg.new_Pvariable(conf[CONF_TRIGGER_ID], var)
await automation.build_automation(trigger, [(cg.ESPTime, "x")], conf)
async def register_datetime(var, config):
if not CORE.has_id(config[CONF_ID]):
var = cg.Pvariable(config[CONF_ID], var)
cg.add(getattr(cg.App, f"register_{config[CONF_TYPE].lower()}")(var))
await setup_datetime_core_(var, config)
cg.add_define(f"USE_DATETIME_{config[CONF_TYPE]}")
async def new_datetime(config, *args):
var = cg.new_Pvariable(config[CONF_ID], *args)
await register_datetime(var, config)
return var
@coroutine_with_priority(40.0)
async def to_code(config):
cg.add_define("USE_DATETIME")
cg.add_global(datetime_ns.using)
OPERATION_BASE_SCHEMA = cv.Schema(
{
cv.Required(CONF_ID): cv.use_id(DateEntity),
}
)
@automation.register_action(
"datetime.date.set",
DateSetAction,
OPERATION_BASE_SCHEMA.extend(
{
cv.Required(CONF_DATE): cv.Any(
cv.returning_lambda, cv.date_time(allowed_time=False)
),
}
),
)
async def datetime_date_set_to_code(config, action_id, template_arg, args):
action_var = cg.new_Pvariable(action_id, template_arg)
await cg.register_parented(action_var, config[CONF_ID])
date = config[CONF_DATE]
if cg.is_template(date):
template_ = await cg.templatable(config[CONF_DATE], [], cg.ESPTime)
cg.add(action_var.set_date(template_))
else:
date_struct = cg.StructInitializer(
cg.ESPTime,
("day_of_month", date[CONF_DAY]),
("month", date[CONF_MONTH]),
("year", date[CONF_YEAR]),
)
cg.add(action_var.set_date(date_struct))
return action_var

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@ -0,0 +1,117 @@
#include "date_entity.h"
#ifdef USE_DATETIME_DATE
#include "esphome/core/log.h"
namespace esphome {
namespace datetime {
static const char *const TAG = "datetime.date_entity";
void DateEntity::publish_state() {
if (this->year_ == 0 || this->month_ == 0 || this->day_ == 0) {
this->has_state_ = false;
return;
}
if (this->year_ < 1970 || this->year_ > 3000) {
this->has_state_ = false;
ESP_LOGE(TAG, "Year must be between 1970 and 3000");
return;
}
if (this->month_ < 1 || this->month_ > 12) {
this->has_state_ = false;
ESP_LOGE(TAG, "Month must be between 1 and 12");
return;
}
if (this->day_ > days_in_month(this->month_, this->year_)) {
this->has_state_ = false;
ESP_LOGE(TAG, "Day must be between 1 and %d for month %d", days_in_month(this->month_, this->year_), this->month_);
return;
}
this->has_state_ = true;
ESP_LOGD(TAG, "'%s': Sending date %d-%d-%d", this->get_name().c_str(), this->year_, this->month_, this->day_);
this->state_callback_.call();
}
DateCall DateEntity::make_call() { return DateCall(this); }
void DateCall::validate_() {
if (this->year_.has_value() && (this->year_ < 1970 || this->year_ > 3000)) {
ESP_LOGE(TAG, "Year must be between 1970 and 3000");
this->year_.reset();
}
if (this->month_.has_value() && (this->month_ < 1 || this->month_ > 12)) {
ESP_LOGE(TAG, "Month must be between 1 and 12");
this->month_.reset();
}
if (this->day_.has_value()) {
uint16_t year = 0;
uint8_t month = 0;
if (this->month_.has_value()) {
month = *this->month_;
} else {
if (this->parent_->month != 0) {
month = this->parent_->month;
} else {
ESP_LOGE(TAG, "Month must be set to validate day");
this->day_.reset();
}
}
if (this->year_.has_value()) {
year = *this->year_;
} else {
if (this->parent_->year != 0) {
year = this->parent_->year;
} else {
ESP_LOGE(TAG, "Year must be set to validate day");
this->day_.reset();
}
}
if (this->day_.has_value() && *this->day_ > days_in_month(month, year)) {
ESP_LOGE(TAG, "Day must be between 1 and %d for month %d", days_in_month(month, year), month);
this->day_.reset();
}
}
}
void DateCall::perform() {
this->validate_();
this->parent_->control(*this);
}
DateCall &DateCall::set_date(uint16_t year, uint8_t month, uint8_t day) {
this->year_ = year;
this->month_ = month;
this->day_ = day;
return *this;
};
DateCall &DateCall::set_date(ESPTime time) { return this->set_date(time.year, time.month, time.day_of_month); };
DateCall &DateCall::set_date(const std::string &date) {
ESPTime val{};
if (!ESPTime::strptime(date, val)) {
ESP_LOGE(TAG, "Could not convert the date string to an ESPTime object");
return *this;
}
return this->set_date(val);
}
DateCall DateEntityRestoreState::to_call(DateEntity *date) {
DateCall call = date->make_call();
call.set_date(this->year, this->month, this->day);
return call;
}
void DateEntityRestoreState::apply(DateEntity *date) {
date->year_ = this->year;
date->month_ = this->month;
date->day_ = this->day;
date->publish_state();
}
} // namespace datetime
} // namespace esphome
#endif // USE_DATETIME_DATE

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@ -0,0 +1,117 @@
#pragma once
#include "esphome/core/defines.h"
#ifdef USE_DATETIME_DATE
#include "esphome/core/automation.h"
#include "esphome/core/helpers.h"
#include "esphome/core/time.h"
#include "datetime_base.h"
namespace esphome {
namespace datetime {
#define LOG_DATETIME_DATE(prefix, type, obj) \
if ((obj) != nullptr) { \
ESP_LOGCONFIG(TAG, "%s%s '%s'", prefix, LOG_STR_LITERAL(type), (obj)->get_name().c_str()); \
if (!(obj)->get_icon().empty()) { \
ESP_LOGCONFIG(TAG, "%s Icon: '%s'", prefix, (obj)->get_icon().c_str()); \
} \
}
class DateCall;
class DateEntity;
struct DateEntityRestoreState {
uint16_t year;
uint8_t month;
uint8_t day;
DateCall to_call(DateEntity *date);
void apply(DateEntity *date);
} __attribute__((packed));
class DateEntity : public DateTimeBase {
protected:
uint16_t year_;
uint8_t month_;
uint8_t day_;
public:
void publish_state();
DateCall make_call();
ESPTime state_as_esptime() const override {
ESPTime obj;
obj.year = this->year_;
obj.month = this->month_;
obj.day_of_month = this->day_;
return obj;
}
const uint16_t &year = year_;
const uint8_t &month = month_;
const uint8_t &day = day_;
protected:
friend class DateCall;
friend struct DateEntityRestoreState;
virtual void control(const DateCall &call) = 0;
};
class DateCall {
public:
explicit DateCall(DateEntity *parent) : parent_(parent) {}
void perform();
DateCall &set_date(uint16_t year, uint8_t month, uint8_t day);
DateCall &set_date(ESPTime time);
DateCall &set_date(const std::string &date);
DateCall &set_year(uint16_t year) {
this->year_ = year;
return *this;
}
DateCall &set_month(uint8_t month) {
this->month_ = month;
return *this;
}
DateCall &set_day(uint8_t day) {
this->day_ = day;
return *this;
}
optional<uint16_t> get_year() const { return this->year_; }
optional<uint8_t> get_month() const { return this->month_; }
optional<uint8_t> get_day() const { return this->day_; }
protected:
void validate_();
DateEntity *parent_;
optional<int16_t> year_;
optional<uint8_t> month_;
optional<uint8_t> day_;
};
template<typename... Ts> class DateSetAction : public Action<Ts...>, public Parented<DateEntity> {
public:
TEMPLATABLE_VALUE(ESPTime, date)
void play(Ts... x) override {
auto call = this->parent_->make_call();
if (this->date_.has_value()) {
call.set_date(this->date_.value(x...));
}
call.perform();
}
};
} // namespace datetime
} // namespace esphome
#endif // USE_DATETIME_DATE

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@ -0,0 +1,34 @@
#pragma once
#include "esphome/core/automation.h"
#include "esphome/core/component.h"
#include "esphome/core/entity_base.h"
#include "esphome/core/time.h"
namespace esphome {
namespace datetime {
class DateTimeBase : public EntityBase {
public:
/// Return whether this Datetime has gotten a full state yet.
bool has_state() const { return this->has_state_; }
virtual ESPTime state_as_esptime() const = 0;
void add_on_state_callback(std::function<void()> &&callback) { this->state_callback_.add(std::move(callback)); }
protected:
CallbackManager<void()> state_callback_;
bool has_state_{false};
};
class DateTimeStateTrigger : public Trigger<ESPTime> {
public:
explicit DateTimeStateTrigger(DateTimeBase *parent) {
parent->add_on_state_callback([this, parent]() { this->trigger(parent->state_as_esptime()); });
}
};
} // namespace datetime
} // namespace esphome

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@ -6,6 +6,7 @@
#include "esphome/core/helpers.h"
#include "esphome/core/version.h"
#include <cinttypes>
#include <climits>
#ifdef USE_ESP32
@ -49,6 +50,8 @@ static uint32_t get_free_heap() {
return rp2040.getFreeHeap();
#elif defined(USE_LIBRETINY)
return lt_heap_get_free();
#elif defined(USE_HOST)
return INT_MAX;
#endif
}

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@ -1,7 +1,7 @@
import esphome.codegen as cg
import esphome.config_validation as cv
from esphome import automation
from esphome.const import CONF_ID, CONF_TRIGGER_ID, CONF_FILE, CONF_DEVICE
from esphome.const import CONF_ID, CONF_TRIGGER_ID, CONF_FILE, CONF_DEVICE, CONF_VOLUME
from esphome.components import uart
DEPENDENCIES = ["uart"]
@ -19,7 +19,6 @@ DFPlayerIsPlayingCondition = dfplayer_ns.class_(
MULTI_CONF = True
CONF_FOLDER = "folder"
CONF_LOOP = "loop"
CONF_VOLUME = "volume"
CONF_EQ_PRESET = "eq_preset"
CONF_ON_FINISHED_PLAYBACK = "on_finished_playback"

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@ -7,10 +7,10 @@ namespace dfplayer {
static const char *const TAG = "dfplayer";
void DFPlayer::play_folder(uint16_t folder, uint16_t file) {
if (folder <= 10 && file <= 1000) {
if (folder < 100 && file < 256) {
this->ack_set_is_playing_ = true;
this->send_cmd_(0x0F, (uint8_t) folder, (uint8_t) file);
} else if (folder < 100 && file < 256) {
} else if (folder <= 15 && file <= 3000) {
this->ack_set_is_playing_ = true;
this->send_cmd_(0x14, (((uint16_t) folder) << 12) | file);
} else {

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@ -257,18 +257,81 @@ void Display::filled_triangle(int x1, int y1, int x2, int y2, int x3, int y3, Co
this->filled_flat_side_triangle_(x3, y3, x2, y2, x_temp, y_temp, color);
}
}
void HOT Display::get_regular_polygon_vertex(int vertex_id, int *vertex_x, int *vertex_y, int center_x, int center_y,
int radius, int edges, RegularPolygonVariation variation,
float rotation_degrees) {
if (edges >= 2) {
// Given the orientation of the display component, an angle is measured clockwise from the x axis.
// For a regular polygon, the human reference would be the top of the polygon,
// hence we rotate the shape by 270° to orient the polygon up.
rotation_degrees += ROTATION_270_DEGREES;
// Convert the rotation to radians, easier to use in trigonometrical calculations
float rotation_radians = rotation_degrees * PI / 180;
// A pointy top variation means the first vertex of the polygon is at the top center of the shape, this requires no
// additional rotation of the shape.
// A flat top variation means the first point of the polygon has to be rotated so that the first edge is horizontal,
// this requires to rotate the shape by π/edges radians counter-clockwise so that the first point is located on the
// left side of the first horizontal edge.
rotation_radians -= (variation == VARIATION_FLAT_TOP) ? PI / edges : 0.0;
void Display::print(int x, int y, BaseFont *font, Color color, TextAlign align, const char *text) {
float vertex_angle = ((float) vertex_id) / edges * 2 * PI + rotation_radians;
*vertex_x = (int) round(cos(vertex_angle) * radius) + center_x;
*vertex_y = (int) round(sin(vertex_angle) * radius) + center_y;
}
}
void HOT Display::regular_polygon(int x, int y, int radius, int edges, RegularPolygonVariation variation,
float rotation_degrees, Color color, RegularPolygonDrawing drawing) {
if (edges >= 2) {
int previous_vertex_x, previous_vertex_y;
for (int current_vertex_id = 0; current_vertex_id <= edges; current_vertex_id++) {
int current_vertex_x, current_vertex_y;
get_regular_polygon_vertex(current_vertex_id, &current_vertex_x, &current_vertex_y, x, y, radius, edges,
variation, rotation_degrees);
if (current_vertex_id > 0) { // Start drawing after the 2nd vertex coordinates has been calculated
if (drawing == DRAWING_FILLED) {
this->filled_triangle(x, y, previous_vertex_x, previous_vertex_y, current_vertex_x, current_vertex_y, color);
} else if (drawing == DRAWING_OUTLINE) {
this->line(previous_vertex_x, previous_vertex_y, current_vertex_x, current_vertex_y, color);
}
}
previous_vertex_x = current_vertex_x;
previous_vertex_y = current_vertex_y;
}
}
}
void HOT Display::regular_polygon(int x, int y, int radius, int edges, RegularPolygonVariation variation, Color color,
RegularPolygonDrawing drawing) {
regular_polygon(x, y, radius, edges, variation, ROTATION_0_DEGREES, color, drawing);
}
void HOT Display::regular_polygon(int x, int y, int radius, int edges, Color color, RegularPolygonDrawing drawing) {
regular_polygon(x, y, radius, edges, VARIATION_POINTY_TOP, ROTATION_0_DEGREES, color, drawing);
}
void Display::filled_regular_polygon(int x, int y, int radius, int edges, RegularPolygonVariation variation,
float rotation_degrees, Color color) {
regular_polygon(x, y, radius, edges, variation, rotation_degrees, color, DRAWING_FILLED);
}
void Display::filled_regular_polygon(int x, int y, int radius, int edges, RegularPolygonVariation variation,
Color color) {
regular_polygon(x, y, radius, edges, variation, ROTATION_0_DEGREES, color, DRAWING_FILLED);
}
void Display::filled_regular_polygon(int x, int y, int radius, int edges, Color color) {
regular_polygon(x, y, radius, edges, VARIATION_POINTY_TOP, ROTATION_0_DEGREES, color, DRAWING_FILLED);
}
void Display::print(int x, int y, BaseFont *font, Color color, TextAlign align, const char *text, Color background) {
int x_start, y_start;
int width, height;
this->get_text_bounds(x, y, text, font, align, &x_start, &y_start, &width, &height);
font->print(x_start, y_start, this, color, text);
font->print(x_start, y_start, this, color, text, background);
}
void Display::vprintf_(int x, int y, BaseFont *font, Color color, TextAlign align, const char *format, va_list arg) {
void Display::vprintf_(int x, int y, BaseFont *font, Color color, Color background, TextAlign align, const char *format,
va_list arg) {
char buffer[256];
int ret = vsnprintf(buffer, sizeof(buffer), format, arg);
if (ret > 0)
this->print(x, y, font, color, align, buffer);
this->print(x, y, font, color, align, buffer, background);
}
void Display::image(int x, int y, BaseImage *image, Color color_on, Color color_off) {
@ -362,8 +425,8 @@ void Display::get_text_bounds(int x, int y, const char *text, BaseFont *font, Te
break;
}
}
void Display::print(int x, int y, BaseFont *font, Color color, const char *text) {
this->print(x, y, font, color, TextAlign::TOP_LEFT, text);
void Display::print(int x, int y, BaseFont *font, Color color, const char *text, Color background) {
this->print(x, y, font, color, TextAlign::TOP_LEFT, text, background);
}
void Display::print(int x, int y, BaseFont *font, TextAlign align, const char *text) {
this->print(x, y, font, COLOR_ON, align, text);
@ -371,28 +434,35 @@ void Display::print(int x, int y, BaseFont *font, TextAlign align, const char *t
void Display::print(int x, int y, BaseFont *font, const char *text) {
this->print(x, y, font, COLOR_ON, TextAlign::TOP_LEFT, text);
}
void Display::printf(int x, int y, BaseFont *font, Color color, Color background, TextAlign align, const char *format,
...) {
va_list arg;
va_start(arg, format);
this->vprintf_(x, y, font, color, background, align, format, arg);
va_end(arg);
}
void Display::printf(int x, int y, BaseFont *font, Color color, TextAlign align, const char *format, ...) {
va_list arg;
va_start(arg, format);
this->vprintf_(x, y, font, color, align, format, arg);
this->vprintf_(x, y, font, color, COLOR_OFF, align, format, arg);
va_end(arg);
}
void Display::printf(int x, int y, BaseFont *font, Color color, const char *format, ...) {
va_list arg;
va_start(arg, format);
this->vprintf_(x, y, font, color, TextAlign::TOP_LEFT, format, arg);
this->vprintf_(x, y, font, color, COLOR_OFF, TextAlign::TOP_LEFT, format, arg);
va_end(arg);
}
void Display::printf(int x, int y, BaseFont *font, TextAlign align, const char *format, ...) {
va_list arg;
va_start(arg, format);
this->vprintf_(x, y, font, COLOR_ON, align, format, arg);
this->vprintf_(x, y, font, COLOR_ON, COLOR_OFF, align, format, arg);
va_end(arg);
}
void Display::printf(int x, int y, BaseFont *font, const char *format, ...) {
va_list arg;
va_start(arg, format);
this->vprintf_(x, y, font, COLOR_ON, TextAlign::TOP_LEFT, format, arg);
this->vprintf_(x, y, font, COLOR_ON, COLOR_OFF, TextAlign::TOP_LEFT, format, arg);
va_end(arg);
}
void Display::set_writer(display_writer_t &&writer) { this->writer_ = writer; }

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@ -137,6 +137,42 @@ enum DisplayRotation {
DISPLAY_ROTATION_270_DEGREES = 270,
};
#define PI 3.1415926535897932384626433832795
const int EDGES_TRIGON = 3;
const int EDGES_TRIANGLE = 3;
const int EDGES_TETRAGON = 4;
const int EDGES_QUADRILATERAL = 4;
const int EDGES_PENTAGON = 5;
const int EDGES_HEXAGON = 6;
const int EDGES_HEPTAGON = 7;
const int EDGES_OCTAGON = 8;
const int EDGES_NONAGON = 9;
const int EDGES_ENNEAGON = 9;
const int EDGES_DECAGON = 10;
const int EDGES_HENDECAGON = 11;
const int EDGES_DODECAGON = 12;
const int EDGES_TRIDECAGON = 13;
const int EDGES_TETRADECAGON = 14;
const int EDGES_PENTADECAGON = 15;
const int EDGES_HEXADECAGON = 16;
const float ROTATION_0_DEGREES = 0.0;
const float ROTATION_45_DEGREES = 45.0;
const float ROTATION_90_DEGREES = 90.0;
const float ROTATION_180_DEGREES = 180.0;
const float ROTATION_270_DEGREES = 270.0;
enum RegularPolygonVariation {
VARIATION_POINTY_TOP = 0,
VARIATION_FLAT_TOP = 1,
};
enum RegularPolygonDrawing {
DRAWING_OUTLINE = 0,
DRAWING_FILLED = 1,
};
class Display;
class DisplayPage;
class DisplayOnPageChangeTrigger;
@ -164,7 +200,7 @@ class BaseImage {
class BaseFont {
public:
virtual void print(int x, int y, Display *display, Color color, const char *text) = 0;
virtual void print(int x, int y, Display *display, Color color, const char *text, Color background) = 0;
virtual void measure(const char *str, int *width, int *x_offset, int *baseline, int *height) = 0;
};
@ -175,10 +211,15 @@ class Display : public PollingComponent {
/// Clear the entire screen by filling it with OFF pixels.
void clear();
/// Get the width of the image in pixels with rotation applied.
virtual int get_width() = 0;
/// Get the height of the image in pixels with rotation applied.
virtual int get_height() = 0;
/// Get the calculated width of the display in pixels with rotation applied.
virtual int get_width() { return this->get_width_internal(); }
/// Get the calculated height of the display in pixels with rotation applied.
virtual int get_height() { return this->get_height_internal(); }
/// Get the native (original) width of the display in pixels.
int get_native_width() { return this->get_width_internal(); }
/// Get the native (original) height of the display in pixels.
int get_native_height() { return this->get_height_internal(); }
/// Set a single pixel at the specified coordinates to default color.
inline void draw_pixel_at(int x, int y) { this->draw_pixel_at(x, y, COLOR_ON); }
@ -242,6 +283,42 @@ class Display : public PollingComponent {
/// Fill a triangle contained between the points [x1,y1], [x2,y2] and [x3,y3] with the given color.
void filled_triangle(int x1, int y1, int x2, int y2, int x3, int y3, Color color = COLOR_ON);
/// Get the specified vertex (x,y) coordinates for the regular polygon inscribed in the circle centered on
/// [center_x,center_y] with the given radius. Vertex id are 0-indexed and rotate clockwise. In a pointy-topped
/// variation of a polygon with a 0° rotation, the vertex #0 is located at the top of the polygon. In a flat-topped
/// variation of a polygon with a 0° rotation, the vertex #0 is located on the left-side of the horizontal top
/// edge, and the vertex #1 is located on the right-side of the horizontal top edge.
/// Use the edges constants (e.g.: EDGES_HEXAGON) or any integer to specify the number of edges of the polygon.
/// Use the variation to switch between the flat-topped or the pointy-topped variation of the polygon.
/// Use the rotation in degrees to rotate the shape clockwise.
void get_regular_polygon_vertex(int vertex_id, int *vertex_x, int *vertex_y, int center_x, int center_y, int radius,
int edges, RegularPolygonVariation variation = VARIATION_POINTY_TOP,
float rotation_degrees = ROTATION_0_DEGREES);
/// Draw the outline of a regular polygon inscribed in the circle centered on [x,y] with the given
/// radius and color.
/// Use the edges constants (e.g.: EDGES_HEXAGON) or any integer to specify the number of edges of the polygon.
/// Use the variation to switch between the flat-topped or the pointy-topped variation of the polygon.
/// Use the rotation in degrees to rotate the shape clockwise.
/// Use the drawing to switch between outlining or filling the polygon.
void regular_polygon(int x, int y, int radius, int edges, RegularPolygonVariation variation = VARIATION_POINTY_TOP,
float rotation_degrees = ROTATION_0_DEGREES, Color color = COLOR_ON,
RegularPolygonDrawing drawing = DRAWING_OUTLINE);
void regular_polygon(int x, int y, int radius, int edges, RegularPolygonVariation variation, Color color,
RegularPolygonDrawing drawing = DRAWING_OUTLINE);
void regular_polygon(int x, int y, int radius, int edges, Color color,
RegularPolygonDrawing drawing = DRAWING_OUTLINE);
/// Fill a regular polygon inscribed in the circle centered on [x,y] with the given radius and color.
/// Use the edges constants (e.g.: EDGES_HEXAGON) or any integer to specify the number of edges of the polygon.
/// Use the variation to switch between the flat-topped or the pointy-topped variation of the polygon.
/// Use the rotation in degrees to rotate the shape clockwise.
void filled_regular_polygon(int x, int y, int radius, int edges,
RegularPolygonVariation variation = VARIATION_POINTY_TOP,
float rotation_degrees = ROTATION_0_DEGREES, Color color = COLOR_ON);
void filled_regular_polygon(int x, int y, int radius, int edges, RegularPolygonVariation variation, Color color);
void filled_regular_polygon(int x, int y, int radius, int edges, Color color);
/** Print `text` with the anchor point at [x,y] with `font`.
*
* @param x The x coordinate of the text alignment anchor point.
@ -250,8 +327,10 @@ class Display : public PollingComponent {
* @param color The color to draw the text with.
* @param align The alignment of the text.
* @param text The text to draw.
* @param background When using multi-bit (anti-aliased) fonts, blend this background color into pixels
*/
void print(int x, int y, BaseFont *font, Color color, TextAlign align, const char *text);
void print(int x, int y, BaseFont *font, Color color, TextAlign align, const char *text,
Color background = COLOR_OFF);
/** Print `text` with the top left at [x,y] with `font`.
*
@ -260,8 +339,9 @@ class Display : public PollingComponent {
* @param font The font to draw the text with.
* @param color The color to draw the text with.
* @param text The text to draw.
* @param background When using multi-bit (anti-aliased) fonts, blend this background color into pixels
*/
void print(int x, int y, BaseFont *font, Color color, const char *text);
void print(int x, int y, BaseFont *font, Color color, const char *text, Color background = COLOR_OFF);
/** Print `text` with the anchor point at [x,y] with `font`.
*
@ -282,6 +362,20 @@ class Display : public PollingComponent {
*/
void print(int x, int y, BaseFont *font, const char *text);
/** Evaluate the printf-format `format` and print the result with the anchor point at [x,y] with `font`.
*
* @param x The x coordinate of the text alignment anchor point.
* @param y The y coordinate of the text alignment anchor point.
* @param font The font to draw the text with.
* @param color The color to draw the text with.
* @param background The background color to use for anti-aliasing
* @param align The alignment of the text.
* @param format The format to use.
* @param ... The arguments to use for the text formatting.
*/
void printf(int x, int y, BaseFont *font, Color color, Color background, TextAlign align, const char *format, ...)
__attribute__((format(printf, 8, 9)));
/** Evaluate the printf-format `format` and print the result with the anchor point at [x,y] with `font`.
*
* @param x The x coordinate of the text alignment anchor point.
@ -533,11 +627,15 @@ class Display : public PollingComponent {
protected:
bool clamp_x_(int x, int w, int &min_x, int &max_x);
bool clamp_y_(int y, int h, int &min_y, int &max_y);
void vprintf_(int x, int y, BaseFont *font, Color color, TextAlign align, const char *format, va_list arg);
void vprintf_(int x, int y, BaseFont *font, Color color, Color background, TextAlign align, const char *format,
va_list arg);
void do_update_();
void clear_clipping_();
virtual int get_height_internal() = 0;
virtual int get_width_internal() = 0;
/**
* This method fills a triangle using only integer variables by using a
* modified bresenham algorithm.

View File

@ -22,9 +22,6 @@ class DisplayBuffer : public Display {
/// Set a single pixel at the specified coordinates to the given color.
void draw_pixel_at(int x, int y, Color color) override;
virtual int get_height_internal() = 0;
virtual int get_width_internal() = 0;
protected:
virtual void draw_absolute_pixel_internal(int x, int y, Color color) = 0;

View File

@ -34,6 +34,7 @@ void EKTF2232Touchscreen::setup() {
// Get touch resolution
uint8_t received[4];
if (this->x_raw_max_ == this->x_raw_min_) {
this->write(GET_X_RES, 4);
if (this->read(received, 4)) {
ESP_LOGE(TAG, "Failed to read X resolution!");
@ -42,7 +43,9 @@ void EKTF2232Touchscreen::setup() {
return;
}
this->x_raw_max_ = ((received[2])) | ((received[3] & 0xf0) << 4);
}
if (this->y_raw_max_ == this->y_raw_min_) {
this->write(GET_Y_RES, 4);
if (this->read(received, 4)) {
ESP_LOGE(TAG, "Failed to read Y resolution!");
@ -51,7 +54,7 @@ void EKTF2232Touchscreen::setup() {
return;
}
this->y_raw_max_ = ((received[2])) | ((received[3] & 0xf0) << 4);
}
this->set_power_state(true);
}

View File

View File

@ -0,0 +1,21 @@
import esphome.codegen as cg
import esphome.config_validation as cv
from esphome.components import climate_ir
from esphome.const import CONF_ID
CODEOWNERS = ["@E440QF"]
AUTO_LOAD = ["climate_ir"]
emmeti_ns = cg.esphome_ns.namespace("emmeti")
EmmetiClimate = emmeti_ns.class_("EmmetiClimate", climate_ir.ClimateIR)
CONFIG_SCHEMA = climate_ir.CLIMATE_IR_WITH_RECEIVER_SCHEMA.extend(
{
cv.GenerateID(): cv.declare_id(EmmetiClimate),
}
)
async def to_code(config):
var = cg.new_Pvariable(config[CONF_ID])
await climate_ir.register_climate_ir(var, config)

View File

@ -0,0 +1,316 @@
#include "emmeti.h"
#include "esphome/components/remote_base/remote_base.h"
namespace esphome {
namespace emmeti {
static const char *const TAG = "emmeti.climate";
// setters
uint8_t EmmetiClimate::set_temp_() {
return (uint8_t) roundf(clamp<float>(this->target_temperature, EMMETI_TEMP_MIN, EMMETI_TEMP_MAX) - EMMETI_TEMP_MIN);
}
uint8_t EmmetiClimate::set_mode_() {
switch (this->mode) {
case climate::CLIMATE_MODE_COOL:
return EMMETI_MODE_COOL;
case climate::CLIMATE_MODE_DRY:
return EMMETI_MODE_DRY;
case climate::CLIMATE_MODE_HEAT:
return EMMETI_MODE_HEAT;
case climate::CLIMATE_MODE_FAN_ONLY:
return EMMETI_MODE_FAN;
case climate::CLIMATE_MODE_HEAT_COOL:
default:
return EMMETI_MODE_HEAT_COOL;
}
}
uint8_t EmmetiClimate::set_fan_speed_() {
switch (this->fan_mode.value()) {
case climate::CLIMATE_FAN_LOW:
return EMMETI_FAN_1;
case climate::CLIMATE_FAN_MEDIUM:
return EMMETI_FAN_2;
case climate::CLIMATE_FAN_HIGH:
return EMMETI_FAN_3;
case climate::CLIMATE_FAN_AUTO:
default:
return EMMETI_FAN_AUTO;
}
}
uint8_t EmmetiClimate::set_blades_() {
if (this->swing_mode == climate::CLIMATE_SWING_VERTICAL) {
switch (this->blades_) {
case EMMETI_BLADES_1:
case EMMETI_BLADES_2:
case EMMETI_BLADES_HIGH:
this->blades_ = EMMETI_BLADES_HIGH;
break;
case EMMETI_BLADES_3:
case EMMETI_BLADES_MID:
this->blades_ = EMMETI_BLADES_MID;
break;
case EMMETI_BLADES_4:
case EMMETI_BLADES_5:
case EMMETI_BLADES_LOW:
this->blades_ = EMMETI_BLADES_LOW;
break;
default:
this->blades_ = EMMETI_BLADES_FULL;
break;
}
} else {
switch (this->blades_) {
case EMMETI_BLADES_1:
case EMMETI_BLADES_2:
case EMMETI_BLADES_HIGH:
this->blades_ = EMMETI_BLADES_1;
break;
case EMMETI_BLADES_3:
case EMMETI_BLADES_MID:
this->blades_ = EMMETI_BLADES_3;
break;
case EMMETI_BLADES_4:
case EMMETI_BLADES_5:
case EMMETI_BLADES_LOW:
this->blades_ = EMMETI_BLADES_5;
break;
default:
this->blades_ = EMMETI_BLADES_STOP;
break;
}
}
return this->blades_;
}
uint8_t EmmetiClimate::gen_checksum_() { return (this->set_temp_() + this->set_mode_() + 2) % 16; }
// getters
float EmmetiClimate::get_temp_(uint8_t temp) { return (float) (temp + EMMETI_TEMP_MIN); }
climate::ClimateMode EmmetiClimate::get_mode_(uint8_t mode) {
switch (mode) {
case EMMETI_MODE_COOL:
return climate::CLIMATE_MODE_COOL;
case EMMETI_MODE_DRY:
return climate::CLIMATE_MODE_DRY;
case EMMETI_MODE_HEAT:
return climate::CLIMATE_MODE_HEAT;
case EMMETI_MODE_HEAT_COOL:
return climate::CLIMATE_MODE_HEAT_COOL;
case EMMETI_MODE_FAN:
return climate::CLIMATE_MODE_FAN_ONLY;
default:
return climate::CLIMATE_MODE_HEAT_COOL;
}
}
climate::ClimateFanMode EmmetiClimate::get_fan_speed_(uint8_t fan_speed) {
switch (fan_speed) {
case EMMETI_FAN_1:
return climate::CLIMATE_FAN_LOW;
case EMMETI_FAN_2:
return climate::CLIMATE_FAN_MEDIUM;
case EMMETI_FAN_3:
return climate::CLIMATE_FAN_HIGH;
case EMMETI_FAN_AUTO:
default:
return climate::CLIMATE_FAN_AUTO;
}
}
climate::ClimateSwingMode EmmetiClimate::get_swing_(uint8_t bitmap) {
return (bitmap >> 1) & 0x01 ? climate::CLIMATE_SWING_VERTICAL : climate::CLIMATE_SWING_OFF;
}
template<typename T> T EmmetiClimate::reverse_(T val, size_t len) {
T result = 0;
for (size_t i = 0; i < len; i++) {
result |= ((val & 1 << i) != 0) << (len - 1 - i);
}
return result;
}
template<typename T> void EmmetiClimate::add_(T val, size_t len, esphome::remote_base::RemoteTransmitData *data) {
for (size_t i = len; i > 0; i--) {
data->mark(EMMETI_BIT_MARK);
data->space((val & (1 << (i - 1))) ? EMMETI_ONE_SPACE : EMMETI_ZERO_SPACE);
}
}
template<typename T> void EmmetiClimate::add_(T val, esphome::remote_base::RemoteTransmitData *data) {
data->mark(EMMETI_BIT_MARK);
data->space((val & 1) ? EMMETI_ONE_SPACE : EMMETI_ZERO_SPACE);
}
template<typename T>
void EmmetiClimate::reverse_add_(T val, size_t len, esphome::remote_base::RemoteTransmitData *data) {
this->add_(this->reverse_(val, len), len, data);
}
bool EmmetiClimate::check_checksum_(uint8_t checksum) {
uint8_t expected = this->gen_checksum_();
ESP_LOGV(TAG, "Expected checksum: %X", expected);
ESP_LOGV(TAG, "Checksum received: %X", checksum);
return checksum == expected;
}
void EmmetiClimate::transmit_state() {
auto transmit = this->transmitter_->transmit();
auto *data = transmit.get_data();
data->set_carrier_frequency(EMMETI_IR_FREQUENCY);
data->mark(EMMETI_HEADER_MARK);
data->space(EMMETI_HEADER_SPACE);
if (this->mode != climate::CLIMATE_MODE_OFF) {
this->reverse_add_(this->set_mode_(), 3, data);
this->add_(1, data);
this->reverse_add_(this->set_fan_speed_(), 2, data);
this->add_(this->swing_mode != climate::CLIMATE_SWING_OFF, data);
this->add_(0, data); // sleep mode
this->reverse_add_(this->set_temp_(), 4, data);
this->add_(0, 8, data); // zeros
this->add_(0, data); // turbo mode
this->add_(1, data); // light
this->add_(1, data); // tree icon thingy
this->add_(0, data); // blow mode
this->add_(0x52, 11, data); // idk
data->mark(EMMETI_BIT_MARK);
data->space(EMMETI_MESSAGE_SPACE);
this->reverse_add_(this->set_blades_(), 4, data);
this->add_(0, 4, data); // zeros
this->reverse_add_(2, 2, data); // thermometer
this->add_(0, 18, data); // zeros
this->reverse_add_(this->gen_checksum_(), 4, data);
} else {
this->add_(9, 12, data);
this->add_(0, 8, data);
this->add_(0x2052, 15, data);
data->mark(EMMETI_BIT_MARK);
data->space(EMMETI_MESSAGE_SPACE);
this->add_(0, 8, data);
this->add_(1, 2, data);
this->add_(0, 18, data);
this->add_(0x0C, 4, data);
}
data->mark(EMMETI_BIT_MARK);
data->space(0);
transmit.perform();
}
bool EmmetiClimate::parse_state_frame_(EmmetiState curr_state) {
this->mode = this->get_mode_(curr_state.mode);
this->fan_mode = this->get_fan_speed_(curr_state.fan_speed);
this->target_temperature = this->get_temp_(curr_state.temp);
this->swing_mode = this->get_swing_(curr_state.bitmap);
// this->blades_ = curr_state.fan_pos;
if (!(curr_state.bitmap & 0x01)) {
this->mode = climate::CLIMATE_MODE_OFF;
}
this->publish_state();
return true;
}
bool EmmetiClimate::on_receive(remote_base::RemoteReceiveData data) {
if (!data.expect_item(EMMETI_HEADER_MARK, EMMETI_HEADER_SPACE)) {
return false;
}
ESP_LOGD(TAG, "Received emmeti frame");
EmmetiState curr_state;
for (size_t pos = 0; pos < 3; pos++) {
if (data.expect_item(EMMETI_BIT_MARK, EMMETI_ONE_SPACE)) {
curr_state.mode |= 1 << pos;
} else if (!data.expect_item(EMMETI_BIT_MARK, EMMETI_ZERO_SPACE)) {
return false;
}
}
ESP_LOGD(TAG, "Mode: %d", curr_state.mode);
if (data.expect_item(EMMETI_BIT_MARK, EMMETI_ONE_SPACE)) {
curr_state.bitmap |= 1 << 0;
} else if (!data.expect_item(EMMETI_BIT_MARK, EMMETI_ZERO_SPACE)) {
return false;
}
ESP_LOGD(TAG, "On: %d", curr_state.bitmap & 0x01);
for (size_t pos = 0; pos < 2; pos++) {
if (data.expect_item(EMMETI_BIT_MARK, EMMETI_ONE_SPACE)) {
curr_state.fan_speed |= 1 << pos;
} else if (!data.expect_item(EMMETI_BIT_MARK, EMMETI_ZERO_SPACE)) {
return false;
}
}
ESP_LOGD(TAG, "Fan speed: %d", curr_state.fan_speed);
for (size_t pos = 0; pos < 2; pos++) {
if (data.expect_item(EMMETI_BIT_MARK, EMMETI_ONE_SPACE)) {
curr_state.bitmap |= 1 << (pos + 1);
} else if (!data.expect_item(EMMETI_BIT_MARK, EMMETI_ZERO_SPACE)) {
return false;
}
}
ESP_LOGD(TAG, "Swing: %d", (curr_state.bitmap >> 1) & 0x01);
ESP_LOGD(TAG, "Sleep: %d", (curr_state.bitmap >> 2) & 0x01);
for (size_t pos = 0; pos < 4; pos++) {
if (data.expect_item(EMMETI_BIT_MARK, EMMETI_ONE_SPACE)) {
curr_state.temp |= 1 << pos;
} else if (!data.expect_item(EMMETI_BIT_MARK, EMMETI_ZERO_SPACE)) {
return false;
}
}
ESP_LOGD(TAG, "Temp: %d", curr_state.temp);
for (size_t pos = 0; pos < 8; pos++) {
if (!data.expect_item(EMMETI_BIT_MARK, EMMETI_ZERO_SPACE)) {
return false;
}
}
for (size_t pos = 0; pos < 4; pos++) {
if (data.expect_item(EMMETI_BIT_MARK, EMMETI_ONE_SPACE)) {
curr_state.bitmap |= 1 << (pos + 3);
} else if (!data.expect_item(EMMETI_BIT_MARK, EMMETI_ZERO_SPACE)) {
return false;
}
}
ESP_LOGD(TAG, "Turbo: %d", (curr_state.bitmap >> 3) & 0x01);
ESP_LOGD(TAG, "Light: %d", (curr_state.bitmap >> 4) & 0x01);
ESP_LOGD(TAG, "Tree: %d", (curr_state.bitmap >> 5) & 0x01);
ESP_LOGD(TAG, "Blow: %d", (curr_state.bitmap >> 6) & 0x01);
uint16_t control_data = 0;
for (size_t pos = 0; pos < 11; pos++) {
if (data.expect_item(EMMETI_BIT_MARK, EMMETI_ONE_SPACE)) {
control_data |= 1 << pos;
} else if (!data.expect_item(EMMETI_BIT_MARK, EMMETI_ZERO_SPACE)) {
return false;
}
}
if (control_data != 0x250) {
return false;
}
return this->parse_state_frame_(curr_state);
}
} // namespace emmeti
} // namespace esphome

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@ -0,0 +1,109 @@
#pragma once
#include "esphome/components/climate_ir/climate_ir.h"
namespace esphome {
namespace emmeti {
const uint8_t EMMETI_TEMP_MIN = 16; // Celsius
const uint8_t EMMETI_TEMP_MAX = 30; // Celsius
// Modes
enum EmmetiMode : uint8_t {
EMMETI_MODE_HEAT_COOL = 0x00,
EMMETI_MODE_COOL = 0x01,
EMMETI_MODE_DRY = 0x02,
EMMETI_MODE_FAN = 0x03,
EMMETI_MODE_HEAT = 0x04,
};
// Fan Speed
enum EmmetiFanMode : uint8_t {
EMMETI_FAN_AUTO = 0x00,
EMMETI_FAN_1 = 0x01,
EMMETI_FAN_2 = 0x02,
EMMETI_FAN_3 = 0x03,
};
// Fan Position
enum EmmetiBlades : uint8_t {
EMMETI_BLADES_STOP = 0x00,
EMMETI_BLADES_FULL = 0x01,
EMMETI_BLADES_1 = 0x02,
EMMETI_BLADES_2 = 0x03,
EMMETI_BLADES_3 = 0x04,
EMMETI_BLADES_4 = 0x05,
EMMETI_BLADES_5 = 0x06,
EMMETI_BLADES_LOW = 0x07,
EMMETI_BLADES_MID = 0x09,
EMMETI_BLADES_HIGH = 0x11,
};
// IR Transmission
const uint32_t EMMETI_IR_FREQUENCY = 38000;
const uint32_t EMMETI_HEADER_MARK = 9076;
const uint32_t EMMETI_HEADER_SPACE = 4408;
const uint32_t EMMETI_BIT_MARK = 660;
const uint32_t EMMETI_ONE_SPACE = 1630;
const uint32_t EMMETI_ZERO_SPACE = 530;
const uint32_t EMMETI_MESSAGE_SPACE = 20000;
struct EmmetiState {
uint8_t mode = 0;
uint8_t bitmap = 0;
uint8_t fan_speed = 0;
uint8_t temp = 0;
uint8_t fan_pos = 0;
uint8_t th = 0;
uint8_t checksum = 0;
};
class EmmetiClimate : public climate_ir::ClimateIR {
public:
EmmetiClimate()
: climate_ir::ClimateIR(EMMETI_TEMP_MIN, EMMETI_TEMP_MAX, 1.0f, true, true,
{climate::CLIMATE_FAN_AUTO, climate::CLIMATE_FAN_LOW, climate::CLIMATE_FAN_MEDIUM,
climate::CLIMATE_FAN_HIGH},
{climate::CLIMATE_SWING_OFF, climate::CLIMATE_SWING_VERTICAL}) {}
protected:
// Transmit via IR the state of this climate controller
void transmit_state() override;
// Handle received IR Buffer
bool on_receive(remote_base::RemoteReceiveData data) override;
bool parse_state_frame_(EmmetiState curr_state);
// setters
uint8_t set_mode_();
uint8_t set_temp_();
uint8_t set_fan_speed_();
uint8_t gen_checksum_();
uint8_t set_blades_();
// getters
climate::ClimateMode get_mode_(uint8_t mode);
climate::ClimateFanMode get_fan_speed_(uint8_t fan);
void get_blades_(uint8_t fanpos);
// get swing
climate::ClimateSwingMode get_swing_(uint8_t bitmap);
float get_temp_(uint8_t temp);
// check if the received frame is valid
bool check_checksum_(uint8_t checksum);
template<typename T> T reverse_(T val, size_t len);
template<typename T> void add_(T val, size_t len, esphome::remote_base::RemoteTransmitData *ata);
template<typename T> void add_(T val, esphome::remote_base::RemoteTransmitData *data);
template<typename T> void reverse_add_(T val, size_t len, esphome::remote_base::RemoteTransmitData *data);
uint8_t blades_ = EMMETI_BLADES_STOP;
};
} // namespace emmeti
} // namespace esphome

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@ -141,9 +141,13 @@ void ESP32ImprovComponent::loop() {
std::vector<std::string> urls = {ESPHOME_MY_LINK};
#ifdef USE_WEBSERVER
auto ip = wifi::global_wifi_component->wifi_sta_ip();
for (auto &ip : wifi::global_wifi_component->wifi_sta_ip_addresses()) {
if (ip.is_ip4()) {
std::string webserver_url = "http://" + ip.str() + ":" + to_string(USE_WEBSERVER_PORT);
urls.push_back(webserver_url);
break;
}
}
#endif
std::vector<uint8_t> data = improv::build_rpc_response(improv::WIFI_SETTINGS, urls);
this->send_response_(data);
@ -289,7 +293,7 @@ void ESP32ImprovComponent::process_incoming_data_() {
this->connecting_sta_ = sta;
wifi::global_wifi_component->set_sta(sta);
wifi::global_wifi_component->start_scanning();
wifi::global_wifi_component->start_connecting(sta, false);
this->set_state_(improv::STATE_PROVISIONING);
ESP_LOGD(TAG, "Received Improv wifi settings ssid=%s, password=" LOG_SECRET("%s"), command.ssid.c_str(),
command.password.c_str());

View File

@ -1,6 +1,13 @@
from esphome import pins
import esphome.config_validation as cv
import esphome.final_validate as fv
import esphome.codegen as cg
from esphome.components.esp32 import add_idf_sdkconfig_option, get_esp32_variant
from esphome.components.esp32.const import (
VARIANT_ESP32C3,
VARIANT_ESP32S2,
VARIANT_ESP32S3,
)
from esphome.const import (
CONF_DOMAIN,
CONF_ID,
@ -12,9 +19,17 @@ from esphome.const import (
CONF_SUBNET,
CONF_DNS1,
CONF_DNS2,
CONF_CLK_PIN,
CONF_MISO_PIN,
CONF_MOSI_PIN,
CONF_CS_PIN,
CONF_INTERRUPT_PIN,
CONF_RESET_PIN,
CONF_SPI,
)
from esphome.core import CORE, coroutine_with_priority
from esphome.components.network import IPAddress
from esphome.components.spi import get_spi_interface, CONF_INTERFACE_INDEX
CONFLICTS_WITH = ["wifi"]
DEPENDENCIES = ["esp32"]
@ -27,6 +42,8 @@ CONF_MDIO_PIN = "mdio_pin"
CONF_CLK_MODE = "clk_mode"
CONF_POWER_PIN = "power_pin"
CONF_CLOCK_SPEED = "clock_speed"
EthernetType = ethernet_ns.enum("EthernetType")
ETHERNET_TYPES = {
"LAN8720": EthernetType.ETHERNET_TYPE_LAN8720,
@ -36,8 +53,11 @@ ETHERNET_TYPES = {
"JL1101": EthernetType.ETHERNET_TYPE_JL1101,
"KSZ8081": EthernetType.ETHERNET_TYPE_KSZ8081,
"KSZ8081RNA": EthernetType.ETHERNET_TYPE_KSZ8081RNA,
"W5500": EthernetType.ETHERNET_TYPE_W5500,
}
SPI_ETHERNET_TYPES = ["W5500"]
emac_rmii_clock_mode_t = cg.global_ns.enum("emac_rmii_clock_mode_t")
emac_rmii_clock_gpio_t = cg.global_ns.enum("emac_rmii_clock_gpio_t")
CLK_MODES = {
@ -84,18 +104,9 @@ def _validate(config):
return config
CONFIG_SCHEMA = cv.All(
cv.Schema(
BASE_SCHEMA = cv.Schema(
{
cv.GenerateID(): cv.declare_id(EthernetComponent),
cv.Required(CONF_TYPE): cv.enum(ETHERNET_TYPES, upper=True),
cv.Required(CONF_MDC_PIN): pins.internal_gpio_output_pin_number,
cv.Required(CONF_MDIO_PIN): pins.internal_gpio_output_pin_number,
cv.Optional(CONF_CLK_MODE, default="GPIO0_IN"): cv.enum(
CLK_MODES, upper=True, space="_"
),
cv.Optional(CONF_PHY_ADDR, default=0): cv.int_range(min=0, max=31),
cv.Optional(CONF_POWER_PIN): pins.internal_gpio_output_pin_number,
cv.Optional(CONF_MANUAL_IP): MANUAL_IP_SCHEMA,
cv.Optional(CONF_DOMAIN, default=".local"): cv.domain_name,
cv.Optional(CONF_USE_ADDRESS): cv.string_strict,
@ -104,11 +115,76 @@ CONFIG_SCHEMA = cv.All(
"new mdns component instead."
),
}
).extend(cv.COMPONENT_SCHEMA),
).extend(cv.COMPONENT_SCHEMA)
RMII_SCHEMA = BASE_SCHEMA.extend(
cv.Schema(
{
cv.Required(CONF_MDC_PIN): pins.internal_gpio_output_pin_number,
cv.Required(CONF_MDIO_PIN): pins.internal_gpio_output_pin_number,
cv.Optional(CONF_CLK_MODE, default="GPIO0_IN"): cv.enum(
CLK_MODES, upper=True, space="_"
),
cv.Optional(CONF_PHY_ADDR, default=0): cv.int_range(min=0, max=31),
cv.Optional(CONF_POWER_PIN): pins.internal_gpio_output_pin_number,
}
)
)
SPI_SCHEMA = BASE_SCHEMA.extend(
cv.Schema(
{
cv.Required(CONF_CLK_PIN): pins.internal_gpio_output_pin_number,
cv.Required(CONF_MISO_PIN): pins.internal_gpio_input_pin_number,
cv.Required(CONF_MOSI_PIN): pins.internal_gpio_output_pin_number,
cv.Required(CONF_CS_PIN): pins.internal_gpio_output_pin_number,
cv.Optional(CONF_INTERRUPT_PIN): pins.internal_gpio_input_pin_number,
cv.Optional(CONF_RESET_PIN): pins.internal_gpio_output_pin_number,
cv.Optional(CONF_CLOCK_SPEED, default="26.67MHz"): cv.All(
cv.frequency, cv.int_range(int(8e6), int(80e6))
),
}
),
)
CONFIG_SCHEMA = cv.All(
cv.typed_schema(
{
"LAN8720": RMII_SCHEMA,
"RTL8201": RMII_SCHEMA,
"DP83848": RMII_SCHEMA,
"IP101": RMII_SCHEMA,
"JL1101": RMII_SCHEMA,
"W5500": SPI_SCHEMA,
},
upper=True,
),
_validate,
)
def _final_validate(config):
if config[CONF_TYPE] not in SPI_ETHERNET_TYPES:
return
if spi_configs := fv.full_config.get().get(CONF_SPI):
variant = get_esp32_variant()
if variant in (VARIANT_ESP32C3, VARIANT_ESP32S2, VARIANT_ESP32S3):
spi_host = "SPI2_HOST"
else:
spi_host = "SPI3_HOST"
for spi_conf in spi_configs:
if (index := spi_conf.get(CONF_INTERFACE_INDEX)) is not None:
interface = get_spi_interface(index)
if interface == spi_host:
raise cv.Invalid(
f"`spi` component is using interface '{interface}'. "
f"To use {config[CONF_TYPE]}, you must change the `interface` on the `spi` component.",
)
FINAL_VALIDATE_SCHEMA = _final_validate
def manual_ip(config):
return cg.StructInitializer(
ManualIP,
@ -125,16 +201,32 @@ async def to_code(config):
var = cg.new_Pvariable(config[CONF_ID])
await cg.register_component(var, config)
if config[CONF_TYPE] == "W5500":
cg.add(var.set_clk_pin(config[CONF_CLK_PIN]))
cg.add(var.set_miso_pin(config[CONF_MISO_PIN]))
cg.add(var.set_mosi_pin(config[CONF_MOSI_PIN]))
cg.add(var.set_cs_pin(config[CONF_CS_PIN]))
if CONF_INTERRUPT_PIN in config:
cg.add(var.set_interrupt_pin(config[CONF_INTERRUPT_PIN]))
if CONF_RESET_PIN in config:
cg.add(var.set_reset_pin(config[CONF_RESET_PIN]))
cg.add(var.set_clock_speed(config[CONF_CLOCK_SPEED]))
cg.add_define("USE_ETHERNET_SPI")
if CORE.using_esp_idf:
add_idf_sdkconfig_option("CONFIG_ETH_USE_SPI_ETHERNET", True)
add_idf_sdkconfig_option("CONFIG_ETH_SPI_ETHERNET_W5500", True)
else:
cg.add(var.set_phy_addr(config[CONF_PHY_ADDR]))
cg.add(var.set_mdc_pin(config[CONF_MDC_PIN]))
cg.add(var.set_mdio_pin(config[CONF_MDIO_PIN]))
cg.add(var.set_type(config[CONF_TYPE]))
cg.add(var.set_clk_mode(*CLK_MODES[config[CONF_CLK_MODE]]))
cg.add(var.set_use_address(config[CONF_USE_ADDRESS]))
if CONF_POWER_PIN in config:
cg.add(var.set_power_pin(config[CONF_POWER_PIN]))
cg.add(var.set_type(ETHERNET_TYPES[config[CONF_TYPE]]))
cg.add(var.set_use_address(config[CONF_USE_ADDRESS]))
if CONF_MANUAL_IP in config:
cg.add(var.set_manual_ip(manual_ip(config[CONF_MANUAL_IP])))

View File

@ -9,6 +9,11 @@
#include <lwip/dns.h>
#include "esp_event.h"
#ifdef USE_ETHERNET_SPI
#include <driver/gpio.h>
#include <driver/spi_master.h>
#endif
namespace esphome {
namespace ethernet {
@ -33,6 +38,36 @@ void EthernetComponent::setup() {
}
esp_err_t err;
#ifdef USE_ETHERNET_SPI
// Install GPIO ISR handler to be able to service SPI Eth modules interrupts
gpio_install_isr_service(0);
spi_bus_config_t buscfg = {
.mosi_io_num = this->mosi_pin_,
.miso_io_num = this->miso_pin_,
.sclk_io_num = this->clk_pin_,
.quadwp_io_num = -1,
.quadhd_io_num = -1,
.data4_io_num = -1,
.data5_io_num = -1,
.data6_io_num = -1,
.data7_io_num = -1,
.max_transfer_sz = 0,
.flags = 0,
.intr_flags = 0,
};
#if defined(USE_ESP32_VARIANT_ESP32C3) || defined(USE_ESP32_VARIANT_ESP32S2) || defined(USE_ESP32_VARIANT_ESP32S3)
auto host = SPI2_HOST;
#else
auto host = SPI3_HOST;
#endif
err = spi_bus_initialize(host, &buscfg, SPI_DMA_CH_AUTO);
ESPHL_ERROR_CHECK(err, "SPI bus initialize error");
#endif
err = esp_netif_init();
ESPHL_ERROR_CHECK(err, "ETH netif init error");
err = esp_event_loop_create_default();
@ -43,10 +78,40 @@ void EthernetComponent::setup() {
// Init MAC and PHY configs to default
eth_phy_config_t phy_config = ETH_PHY_DEFAULT_CONFIG();
eth_mac_config_t mac_config = ETH_MAC_DEFAULT_CONFIG();
#ifdef USE_ETHERNET_SPI // Configure SPI interface and Ethernet driver for specific SPI module
spi_device_interface_config_t devcfg = {
.command_bits = 16, // Actually it's the address phase in W5500 SPI frame
.address_bits = 8, // Actually it's the control phase in W5500 SPI frame
.dummy_bits = 0,
.mode = 0,
.duty_cycle_pos = 0,
.cs_ena_pretrans = 0,
.cs_ena_posttrans = 0,
.clock_speed_hz = this->clock_speed_,
.input_delay_ns = 0,
.spics_io_num = this->cs_pin_,
.flags = 0,
.queue_size = 20,
.pre_cb = nullptr,
.post_cb = nullptr,
};
spi_device_handle_t spi_handle = nullptr;
err = spi_bus_add_device(host, &devcfg, &spi_handle);
ESPHL_ERROR_CHECK(err, "SPI bus add device error");
eth_w5500_config_t w5500_config = ETH_W5500_DEFAULT_CONFIG(spi_handle);
w5500_config.int_gpio_num = this->interrupt_pin_;
phy_config.phy_addr = this->phy_addr_spi_;
phy_config.reset_gpio_num = this->reset_pin_;
esp_eth_mac_t *mac = esp_eth_mac_new_w5500(&w5500_config, &mac_config);
#else
phy_config.phy_addr = this->phy_addr_;
phy_config.reset_gpio_num = this->power_pin_;
eth_mac_config_t mac_config = ETH_MAC_DEFAULT_CONFIG();
#if ESP_IDF_VERSION_MAJOR >= 5
eth_esp32_emac_config_t esp32_emac_config = ETH_ESP32_EMAC_DEFAULT_CONFIG();
esp32_emac_config.smi_mdc_gpio_num = this->mdc_pin_;
@ -62,9 +127,11 @@ void EthernetComponent::setup() {
mac_config.clock_config.rmii.clock_gpio = this->clk_gpio_;
esp_eth_mac_t *mac = esp_eth_mac_new_esp32(&mac_config);
#endif
#endif
switch (this->type_) {
#if CONFIG_ETH_USE_ESP32_EMAC
case ETHERNET_TYPE_LAN8720: {
this->phy_ = esp_eth_phy_new_lan87xx(&phy_config);
break;
@ -94,6 +161,13 @@ void EthernetComponent::setup() {
#endif
break;
}
#endif
#ifdef USE_ETHERNET_SPI
case ETHERNET_TYPE_W5500: {
this->phy_ = esp_eth_phy_new_w5500(&phy_config);
break;
}
#endif
default: {
this->mark_failed();
return;
@ -105,10 +179,18 @@ void EthernetComponent::setup() {
err = esp_eth_driver_install(&eth_config, &this->eth_handle_);
ESPHL_ERROR_CHECK(err, "ETH driver install error");
#ifndef USE_ETHERNET_SPI
if (this->type_ == ETHERNET_TYPE_KSZ8081RNA && this->clk_mode_ == EMAC_CLK_OUT) {
// KSZ8081RNA default is incorrect. It expects a 25MHz clock instead of the 50MHz we provide.
this->ksz8081_set_clock_reference_(mac);
}
#endif
// use ESP internal eth mac
uint8_t mac_addr[6];
esp_read_mac(mac_addr, ESP_MAC_ETH);
err = esp_eth_ioctl(this->eth_handle_, ETH_CMD_S_MAC_ADDR, mac_addr);
ESPHL_ERROR_CHECK(err, "set mac address error");
/* attach Ethernet driver to TCP/IP stack */
err = esp_netif_attach(this->eth_netif_, esp_eth_new_netif_glue(this->eth_handle_));
@ -119,10 +201,10 @@ void EthernetComponent::setup() {
ESPHL_ERROR_CHECK(err, "ETH event handler register error");
err = esp_event_handler_register(IP_EVENT, IP_EVENT_ETH_GOT_IP, &EthernetComponent::got_ip_event_handler, nullptr);
ESPHL_ERROR_CHECK(err, "GOT IP event handler register error");
#if ENABLE_IPV6
#if USE_NETWORK_IPV6
err = esp_event_handler_register(IP_EVENT, IP_EVENT_GOT_IP6, &EthernetComponent::got_ip6_event_handler, nullptr);
ESPHL_ERROR_CHECK(err, "GOT IP6 event handler register error");
#endif /* ENABLE_IPV6 */
ESPHL_ERROR_CHECK(err, "GOT IPv6 event handler register error");
#endif /* USE_NETWORK_IPV6 */
/* start Ethernet driver state machine */
err = esp_eth_start(this->eth_handle_);
@ -165,20 +247,6 @@ void EthernetComponent::loop() {
this->state_ = EthernetComponentState::CONNECTING;
this->start_connect_();
}
#if ENABLE_IPV6
else if (this->got_ipv6_) {
esp_ip6_addr_t ip6_addr;
if (esp_netif_get_ip6_global(this->eth_netif_, &ip6_addr) == 0 &&
esp_netif_ip6_get_addr_type(&ip6_addr) == ESP_IP6_ADDR_IS_GLOBAL) {
ESP_LOGCONFIG(TAG, "IPv6 Addr (Global): " IPV6STR, IPV62STR(ip6_addr));
} else {
esp_netif_get_ip6_linklocal(this->eth_netif_, &ip6_addr);
ESP_LOGCONFIG(TAG, " IPv6: " IPV6STR, IPV62STR(ip6_addr));
}
this->got_ipv6_ = false;
}
#endif /* ENABLE_IPV6 */
break;
}
}
@ -214,6 +282,10 @@ void EthernetComponent::dump_config() {
eth_type = "KSZ8081RNA";
break;
case ETHERNET_TYPE_W5500:
eth_type = "W5500";
break;
default:
eth_type = "Unknown";
break;
@ -221,23 +293,51 @@ void EthernetComponent::dump_config() {
ESP_LOGCONFIG(TAG, "Ethernet:");
this->dump_connect_params_();
#ifdef USE_ETHERNET_SPI
ESP_LOGCONFIG(TAG, " CLK Pin: %u", this->clk_pin_);
ESP_LOGCONFIG(TAG, " MISO Pin: %u", this->miso_pin_);
ESP_LOGCONFIG(TAG, " MOSI Pin: %u", this->mosi_pin_);
ESP_LOGCONFIG(TAG, " CS Pin: %u", this->cs_pin_);
ESP_LOGCONFIG(TAG, " IRQ Pin: %u", this->interrupt_pin_);
ESP_LOGCONFIG(TAG, " Reset Pin: %d", this->reset_pin_);
ESP_LOGCONFIG(TAG, " Clock Speed: %d MHz", this->clock_speed_ / 1000000);
#else
if (this->power_pin_ != -1) {
ESP_LOGCONFIG(TAG, " Power Pin: %u", this->power_pin_);
}
ESP_LOGCONFIG(TAG, " MDC Pin: %u", this->mdc_pin_);
ESP_LOGCONFIG(TAG, " MDIO Pin: %u", this->mdio_pin_);
ESP_LOGCONFIG(TAG, " Type: %s", eth_type);
ESP_LOGCONFIG(TAG, " PHY addr: %u", this->phy_addr_);
#endif
ESP_LOGCONFIG(TAG, " Type: %s", eth_type);
}
float EthernetComponent::get_setup_priority() const { return setup_priority::WIFI; }
bool EthernetComponent::can_proceed() { return this->is_connected(); }
network::IPAddress EthernetComponent::get_ip_address() {
network::IPAddresses EthernetComponent::get_ip_addresses() {
network::IPAddresses addresses;
esp_netif_ip_info_t ip;
esp_netif_get_ip_info(this->eth_netif_, &ip);
return network::IPAddress(&ip.ip);
esp_err_t err = esp_netif_get_ip_info(this->eth_netif_, &ip);
if (err != ESP_OK) {
ESP_LOGV(TAG, "esp_netif_get_ip_info failed: %s", esp_err_to_name(err));
// TODO: do something smarter
// return false;
} else {
addresses[0] = network::IPAddress(&ip.ip);
}
#if USE_NETWORK_IPV6
struct esp_ip6_addr if_ip6s[CONFIG_LWIP_IPV6_NUM_ADDRESSES];
uint8_t count = 0;
count = esp_netif_get_all_ip6(this->eth_netif_, if_ip6s);
assert(count <= CONFIG_LWIP_IPV6_NUM_ADDRESSES);
for (int i = 0; i < count; i++) {
addresses[i + 1] = network::IPAddress(&if_ip6s[i]);
}
#endif /* USE_NETWORK_IPV6 */
return addresses;
}
void EthernetComponent::eth_event_handler(void *arg, esp_event_base_t event_base, int32_t event, void *event_data) {
@ -269,20 +369,33 @@ void EthernetComponent::eth_event_handler(void *arg, esp_event_base_t event_base
void EthernetComponent::got_ip_event_handler(void *arg, esp_event_base_t event_base, int32_t event_id,
void *event_data) {
ip_event_got_ip_t *event = (ip_event_got_ip_t *) event_data;
const esp_netif_ip_info_t *ip_info = &event->ip_info;
ESP_LOGV(TAG, "[Ethernet event] ETH Got IP " IPSTR, IP2STR(&ip_info->ip));
global_eth_component->got_ipv4_address_ = true;
#if USE_NETWORK_IPV6
global_eth_component->connected_ = global_eth_component->ipv6_count_ >= USE_NETWORK_MIN_IPV6_ADDR_COUNT;
#else
global_eth_component->connected_ = true;
ESP_LOGV(TAG, "[Ethernet event] ETH Got IP (num=%" PRId32 ")", event_id);
#endif /* USE_NETWORK_IPV6 */
}
#if ENABLE_IPV6
#if USE_NETWORK_IPV6
void EthernetComponent::got_ip6_event_handler(void *arg, esp_event_base_t event_base, int32_t event_id,
void *event_data) {
ESP_LOGV(TAG, "[Ethernet event] ETH Got IP6 (num=%" PRId32 ")", event_id);
global_eth_component->got_ipv6_ = true;
ip_event_got_ip6_t *event = (ip_event_got_ip6_t *) event_data;
ESP_LOGV(TAG, "[Ethernet event] ETH Got IPv6: " IPV6STR, IPV62STR(event->ip6_info.ip));
global_eth_component->ipv6_count_ += 1;
global_eth_component->connected_ =
global_eth_component->got_ipv4_address_ && (global_eth_component->ipv6_count_ >= USE_NETWORK_MIN_IPV6_ADDR_COUNT);
}
#endif /* ENABLE_IPV6 */
#endif /* USE_NETWORK_IPV6 */
void EthernetComponent::start_connect_() {
global_eth_component->got_ipv4_address_ = false;
#if USE_NETWORK_IPV6
global_eth_component->ipv6_count_ = 0;
#endif /* USE_NETWORK_IPV6 */
this->connect_begin_ = millis();
this->status_set_warning();
@ -334,12 +447,12 @@ void EthernetComponent::start_connect_() {
if (err != ESP_ERR_ESP_NETIF_DHCP_ALREADY_STARTED) {
ESPHL_ERROR_CHECK(err, "DHCPC start error");
}
#if ENABLE_IPV6
#if USE_NETWORK_IPV6
err = esp_netif_create_ip6_linklocal(this->eth_netif_);
if (err != ESP_OK) {
ESPHL_ERROR_CHECK(err, "IPv6 local failed");
ESPHL_ERROR_CHECK(err, "Enable IPv6 link local failed");
}
#endif /* ENABLE_IPV6 */
#endif /* USE_NETWORK_IPV6 */
}
this->connect_begin_ = millis();
@ -362,18 +475,15 @@ void EthernetComponent::dump_connect_params_() {
ESP_LOGCONFIG(TAG, " DNS1: %s", network::IPAddress(dns_ip1).str().c_str());
ESP_LOGCONFIG(TAG, " DNS2: %s", network::IPAddress(dns_ip2).str().c_str());
#if ENABLE_IPV6
if (this->ipv6_count_ > 0) {
esp_ip6_addr_t ip6_addr;
esp_netif_get_ip6_linklocal(this->eth_netif_, &ip6_addr);
ESP_LOGCONFIG(TAG, " IPv6: " IPV6STR, IPV62STR(ip6_addr));
if (esp_netif_get_ip6_global(this->eth_netif_, &ip6_addr) == 0 &&
esp_netif_ip6_get_addr_type(&ip6_addr) == ESP_IP6_ADDR_IS_GLOBAL) {
ESP_LOGCONFIG(TAG, "IPv6 Addr (Global): " IPV6STR, IPV62STR(ip6_addr));
#if USE_NETWORK_IPV6
struct esp_ip6_addr if_ip6s[CONFIG_LWIP_IPV6_NUM_ADDRESSES];
uint8_t count = 0;
count = esp_netif_get_all_ip6(this->eth_netif_, if_ip6s);
assert(count <= CONFIG_LWIP_IPV6_NUM_ADDRESSES);
for (int i = 0; i < count; i++) {
ESP_LOGCONFIG(TAG, " IPv6: " IPV6STR, IPV62STR(if_ip6s[i]));
}
}
#endif /* ENABLE_IPV6 */
#endif /* USE_NETWORK_IPV6 */
esp_err_t err;
@ -393,15 +503,25 @@ void EthernetComponent::dump_connect_params_() {
ESP_LOGCONFIG(TAG, " Link Speed: %u", speed == ETH_SPEED_100M ? 100 : 10);
}
#ifdef USE_ETHERNET_SPI
void EthernetComponent::set_clk_pin(uint8_t clk_pin) { this->clk_pin_ = clk_pin; }
void EthernetComponent::set_miso_pin(uint8_t miso_pin) { this->miso_pin_ = miso_pin; }
void EthernetComponent::set_mosi_pin(uint8_t mosi_pin) { this->mosi_pin_ = mosi_pin; }
void EthernetComponent::set_cs_pin(uint8_t cs_pin) { this->cs_pin_ = cs_pin; }
void EthernetComponent::set_interrupt_pin(uint8_t interrupt_pin) { this->interrupt_pin_ = interrupt_pin; }
void EthernetComponent::set_reset_pin(uint8_t reset_pin) { this->reset_pin_ = reset_pin; }
void EthernetComponent::set_clock_speed(int clock_speed) { this->clock_speed_ = clock_speed; }
#else
void EthernetComponent::set_phy_addr(uint8_t phy_addr) { this->phy_addr_ = phy_addr; }
void EthernetComponent::set_power_pin(int power_pin) { this->power_pin_ = power_pin; }
void EthernetComponent::set_mdc_pin(uint8_t mdc_pin) { this->mdc_pin_ = mdc_pin; }
void EthernetComponent::set_mdio_pin(uint8_t mdio_pin) { this->mdio_pin_ = mdio_pin; }
void EthernetComponent::set_type(EthernetType type) { this->type_ = type; }
void EthernetComponent::set_clk_mode(emac_rmii_clock_mode_t clk_mode, emac_rmii_clock_gpio_t clk_gpio) {
this->clk_mode_ = clk_mode;
this->clk_gpio_ = clk_gpio;
}
#endif
void EthernetComponent::set_type(EthernetType type) { this->type_ = type; }
void EthernetComponent::set_manual_ip(const ManualIP &manual_ip) { this->manual_ip_ = manual_ip; }
std::string EthernetComponent::get_use_address() const {
@ -428,6 +548,7 @@ bool EthernetComponent::powerdown() {
return true;
}
#ifndef USE_ETHERNET_SPI
void EthernetComponent::ksz8081_set_clock_reference_(esp_eth_mac_t *mac) {
#define KSZ80XX_PC2R_REG_ADDR (0x1F)
@ -458,6 +579,7 @@ void EthernetComponent::ksz8081_set_clock_reference_(esp_eth_mac_t *mac) {
#undef KSZ80XX_PC2R_REG_ADDR
}
#endif
} // namespace ethernet
} // namespace esphome

View File

@ -23,6 +23,7 @@ enum EthernetType {
ETHERNET_TYPE_JL1101,
ETHERNET_TYPE_KSZ8081,
ETHERNET_TYPE_KSZ8081RNA,
ETHERNET_TYPE_W5500,
};
struct ManualIP {
@ -50,15 +51,25 @@ class EthernetComponent : public Component {
void on_shutdown() override { powerdown(); }
bool is_connected();
#ifdef USE_ETHERNET_SPI
void set_clk_pin(uint8_t clk_pin);
void set_miso_pin(uint8_t miso_pin);
void set_mosi_pin(uint8_t mosi_pin);
void set_cs_pin(uint8_t cs_pin);
void set_interrupt_pin(uint8_t interrupt_pin);
void set_reset_pin(uint8_t reset_pin);
void set_clock_speed(int clock_speed);
#else
void set_phy_addr(uint8_t phy_addr);
void set_power_pin(int power_pin);
void set_mdc_pin(uint8_t mdc_pin);
void set_mdio_pin(uint8_t mdio_pin);
void set_type(EthernetType type);
void set_clk_mode(emac_rmii_clock_mode_t clk_mode, emac_rmii_clock_gpio_t clk_gpio);
#endif
void set_type(EthernetType type);
void set_manual_ip(const ManualIP &manual_ip);
network::IPAddress get_ip_address();
network::IPAddresses get_ip_addresses();
std::string get_use_address() const;
void set_use_address(const std::string &use_address);
bool powerdown();
@ -76,19 +87,30 @@ class EthernetComponent : public Component {
void ksz8081_set_clock_reference_(esp_eth_mac_t *mac);
std::string use_address_;
#ifdef USE_ETHERNET_SPI
uint8_t clk_pin_;
uint8_t miso_pin_;
uint8_t mosi_pin_;
uint8_t cs_pin_;
uint8_t interrupt_pin_;
int reset_pin_{-1};
int phy_addr_spi_{-1};
int clock_speed_;
#else
uint8_t phy_addr_{0};
int power_pin_{-1};
uint8_t mdc_pin_{23};
uint8_t mdio_pin_{18};
EthernetType type_{ETHERNET_TYPE_UNKNOWN};
emac_rmii_clock_mode_t clk_mode_{EMAC_CLK_EXT_IN};
emac_rmii_clock_gpio_t clk_gpio_{EMAC_CLK_IN_GPIO};
#endif
EthernetType type_{ETHERNET_TYPE_UNKNOWN};
optional<ManualIP> manual_ip_{};
bool started_{false};
bool connected_{false};
bool got_ipv4_address_{false};
#if LWIP_IPV6
bool got_ipv6_{false};
uint8_t ipv6_count_{0};
#endif /* LWIP_IPV6 */
EthernetComponentState state_{EthernetComponentState::STOPPED};

View File

@ -12,19 +12,30 @@ namespace ethernet_info {
class IPAddressEthernetInfo : public PollingComponent, public text_sensor::TextSensor {
public:
void update() override {
auto ip = ethernet::global_eth_component->get_ip_address();
if (ip != this->last_ip_) {
this->last_ip_ = ip;
this->publish_state(network::IPAddress(ip).str());
auto ips = ethernet::global_eth_component->get_ip_addresses();
if (ips != this->last_ips_) {
this->last_ips_ = ips;
this->publish_state(ips[0].str());
uint8_t sensor = 0;
for (auto &ip : ips) {
if (ip.is_set()) {
if (this->ip_sensors_[sensor] != nullptr) {
this->ip_sensors_[sensor]->publish_state(ip.str());
}
sensor++;
}
}
}
}
float get_setup_priority() const override { return setup_priority::ETHERNET; }
std::string unique_id() override { return get_mac_address() + "-ethernetinfo"; }
void dump_config() override;
void add_ip_sensors(uint8_t index, text_sensor::TextSensor *s) { this->ip_sensors_[index] = s; }
protected:
network::IPAddress last_ip_;
network::IPAddresses last_ips_;
std::array<text_sensor::TextSensor *, 5> ip_sensors_;
};
} // namespace ethernet_info

View File

@ -18,17 +18,25 @@ CONFIG_SCHEMA = cv.Schema(
{
cv.Optional(CONF_IP_ADDRESS): text_sensor.text_sensor_schema(
IPAddressEsthernetInfo, entity_category=ENTITY_CATEGORY_DIAGNOSTIC
).extend(cv.polling_component_schema("1s"))
)
.extend(cv.polling_component_schema("1s"))
.extend(
{
cv.Optional(f"address_{x}"): text_sensor.text_sensor_schema(
entity_category=ENTITY_CATEGORY_DIAGNOSTIC,
)
for x in range(5)
}
)
}
)
async def setup_conf(config, key):
if key in config:
conf = config[key]
var = await text_sensor.new_text_sensor(conf)
await cg.register_component(var, conf)
async def to_code(config):
await setup_conf(config, CONF_IP_ADDRESS)
if conf := config.get(CONF_IP_ADDRESS):
ip_info = await text_sensor.new_text_sensor(config[CONF_IP_ADDRESS])
await cg.register_component(ip_info, config[CONF_IP_ADDRESS])
for x in range(5):
if sensor_conf := conf.get(f"address_{x}"):
sens = await text_sensor.new_text_sensor(sensor_conf)
cg.add(ip_info.add_ip_sensors(x, sens))

View File

@ -1,7 +1,13 @@
import esphome.codegen as cg
import esphome.config_validation as cv
from esphome.components import i2c
from esphome.const import CONF_ADDRESS, CONF_COMMAND, CONF_ID, CONF_DURATION
from esphome.const import (
CONF_ADDRESS,
CONF_COMMAND,
CONF_ID,
CONF_DURATION,
CONF_VOLUME,
)
from esphome import automation
from esphome.automation import maybe_simple_id
@ -9,7 +15,6 @@ CODEOWNERS = ["@carlos-sarmiento"]
DEPENDENCIES = ["i2c"]
MULTI_CONF = True
CONF_VOLUME = "volume"
CONF_VOLUME_PER_MINUTE = "volume_per_minute"
ezo_pmp_ns = cg.esphome_ns.namespace("ezo_pmp")

View File

@ -15,7 +15,10 @@ from esphome.const import (
CONF_SPEED_COMMAND_TOPIC,
CONF_SPEED_STATE_TOPIC,
CONF_OFF_SPEED_CYCLE,
CONF_ON_DIRECTION_SET,
CONF_ON_OSCILLATING_SET,
CONF_ON_SPEED_SET,
CONF_ON_STATE,
CONF_ON_TURN_OFF,
CONF_ON_TURN_ON,
CONF_ON_PRESET_SET,
@ -55,11 +58,22 @@ TurnOffAction = fan_ns.class_("TurnOffAction", automation.Action)
ToggleAction = fan_ns.class_("ToggleAction", automation.Action)
CycleSpeedAction = fan_ns.class_("CycleSpeedAction", automation.Action)
FanStateTrigger = fan_ns.class_(
"FanStateTrigger", automation.Trigger.template(Fan.operator("ptr"))
)
FanTurnOnTrigger = fan_ns.class_("FanTurnOnTrigger", automation.Trigger.template())
FanTurnOffTrigger = fan_ns.class_("FanTurnOffTrigger", automation.Trigger.template())
FanSpeedSetTrigger = fan_ns.class_("FanSpeedSetTrigger", automation.Trigger.template())
FanDirectionSetTrigger = fan_ns.class_(
"FanDirectionSetTrigger", automation.Trigger.template(FanDirection)
)
FanOscillatingSetTrigger = fan_ns.class_(
"FanOscillatingSetTrigger", automation.Trigger.template(cg.bool_)
)
FanSpeedSetTrigger = fan_ns.class_(
"FanSpeedSetTrigger", automation.Trigger.template(cg.int_)
)
FanPresetSetTrigger = fan_ns.class_(
"FanPresetSetTrigger", automation.Trigger.template()
"FanPresetSetTrigger", automation.Trigger.template(cg.std_string)
)
FanIsOnCondition = fan_ns.class_("FanIsOnCondition", automation.Condition.template())
@ -90,6 +104,11 @@ FAN_SCHEMA = cv.ENTITY_BASE_SCHEMA.extend(cv.MQTT_COMMAND_COMPONENT_SCHEMA).exte
cv.Optional(CONF_SPEED_COMMAND_TOPIC): cv.All(
cv.requires_component("mqtt"), cv.subscribe_topic
),
cv.Optional(CONF_ON_STATE): automation.validate_automation(
{
cv.GenerateID(CONF_TRIGGER_ID): cv.declare_id(FanStateTrigger),
}
),
cv.Optional(CONF_ON_TURN_ON): automation.validate_automation(
{
cv.GenerateID(CONF_TRIGGER_ID): cv.declare_id(FanTurnOnTrigger),
@ -100,6 +119,16 @@ FAN_SCHEMA = cv.ENTITY_BASE_SCHEMA.extend(cv.MQTT_COMMAND_COMPONENT_SCHEMA).exte
cv.GenerateID(CONF_TRIGGER_ID): cv.declare_id(FanTurnOffTrigger),
}
),
cv.Optional(CONF_ON_DIRECTION_SET): automation.validate_automation(
{
cv.GenerateID(CONF_TRIGGER_ID): cv.declare_id(FanDirectionSetTrigger),
}
),
cv.Optional(CONF_ON_OSCILLATING_SET): automation.validate_automation(
{
cv.GenerateID(CONF_TRIGGER_ID): cv.declare_id(FanOscillatingSetTrigger),
}
),
cv.Optional(CONF_ON_SPEED_SET): automation.validate_automation(
{
cv.GenerateID(CONF_TRIGGER_ID): cv.declare_id(FanSpeedSetTrigger),
@ -186,18 +215,27 @@ async def setup_fan_core_(var, config):
mqtt_.set_custom_speed_command_topic(config[CONF_SPEED_COMMAND_TOPIC])
)
for conf in config.get(CONF_ON_STATE, []):
trigger = cg.new_Pvariable(conf[CONF_TRIGGER_ID], var)
await automation.build_automation(trigger, [(Fan.operator("ptr"), "x")], conf)
for conf in config.get(CONF_ON_TURN_ON, []):
trigger = cg.new_Pvariable(conf[CONF_TRIGGER_ID], var)
await automation.build_automation(trigger, [], conf)
for conf in config.get(CONF_ON_TURN_OFF, []):
trigger = cg.new_Pvariable(conf[CONF_TRIGGER_ID], var)
await automation.build_automation(trigger, [], conf)
for conf in config.get(CONF_ON_DIRECTION_SET, []):
trigger = cg.new_Pvariable(conf[CONF_TRIGGER_ID], var)
await automation.build_automation(trigger, [(FanDirection, "x")], conf)
for conf in config.get(CONF_ON_OSCILLATING_SET, []):
trigger = cg.new_Pvariable(conf[CONF_TRIGGER_ID], var)
await automation.build_automation(trigger, [(cg.bool_, "x")], conf)
for conf in config.get(CONF_ON_SPEED_SET, []):
trigger = cg.new_Pvariable(conf[CONF_TRIGGER_ID], var)
await automation.build_automation(trigger, [], conf)
await automation.build_automation(trigger, [(cg.int_, "x")], conf)
for conf in config.get(CONF_ON_PRESET_SET, []):
trigger = cg.new_Pvariable(conf[CONF_TRIGGER_ID], var)
await automation.build_automation(trigger, [], conf)
await automation.build_automation(trigger, [(cg.std_string, "x")], conf)
async def register_fan(var, config):

View File

@ -111,6 +111,13 @@ template<typename... Ts> class FanIsOffCondition : public Condition<Ts...> {
Fan *state_;
};
class FanStateTrigger : public Trigger<Fan *> {
public:
FanStateTrigger(Fan *state) {
state->add_on_state_callback([this, state]() { this->trigger(state); });
}
};
class FanTurnOnTrigger : public Trigger<> {
public:
FanTurnOnTrigger(Fan *state) {
@ -147,15 +154,51 @@ class FanTurnOffTrigger : public Trigger<> {
bool last_on_;
};
class FanSpeedSetTrigger : public Trigger<> {
class FanDirectionSetTrigger : public Trigger<FanDirection> {
public:
FanDirectionSetTrigger(Fan *state) {
state->add_on_state_callback([this, state]() {
auto direction = state->direction;
auto should_trigger = direction != this->last_direction_;
this->last_direction_ = direction;
if (should_trigger) {
this->trigger(direction);
}
});
this->last_direction_ = state->direction;
}
protected:
FanDirection last_direction_;
};
class FanOscillatingSetTrigger : public Trigger<bool> {
public:
FanOscillatingSetTrigger(Fan *state) {
state->add_on_state_callback([this, state]() {
auto oscillating = state->oscillating;
auto should_trigger = oscillating != this->last_oscillating_;
this->last_oscillating_ = oscillating;
if (should_trigger) {
this->trigger(oscillating);
}
});
this->last_oscillating_ = state->oscillating;
}
protected:
bool last_oscillating_;
};
class FanSpeedSetTrigger : public Trigger<int> {
public:
FanSpeedSetTrigger(Fan *state) {
state->add_on_state_callback([this, state]() {
auto speed = state->speed;
auto should_trigger = speed != !this->last_speed_;
auto should_trigger = speed != this->last_speed_;
this->last_speed_ = speed;
if (should_trigger) {
this->trigger();
this->trigger(speed);
}
});
this->last_speed_ = state->speed;
@ -165,7 +208,7 @@ class FanSpeedSetTrigger : public Trigger<> {
int last_speed_;
};
class FanPresetSetTrigger : public Trigger<> {
class FanPresetSetTrigger : public Trigger<std::string> {
public:
FanPresetSetTrigger(Fan *state) {
state->add_on_state_callback([this, state]() {
@ -173,7 +216,7 @@ class FanPresetSetTrigger : public Trigger<> {
auto should_trigger = preset_mode != this->last_preset_mode_;
this->last_preset_mode_ = preset_mode;
if (should_trigger) {
this->trigger();
this->trigger(preset_mode);
}
});
this->last_preset_mode_ = state->preset_mode;

View File

@ -25,12 +25,14 @@ from esphome.const import (
CONF_TRIGGER_ID,
)
CODEOWNERS = ["@OnFreund", "@loongyh"]
CODEOWNERS = ["@OnFreund", "@loongyh", "@alexborro"]
DEPENDENCIES = ["uart"]
AUTO_LOAD = ["binary_sensor", "sensor"]
MULTI_CONF = True
CONF_FINGERPRINT_GROW_ID = "fingerprint_grow_id"
CONF_SENSOR_POWER_PIN = "sensor_power_pin"
CONF_IDLE_PERIOD_TO_SLEEP = "idle_period_to_sleep"
fingerprint_grow_ns = cg.esphome_ns.namespace("fingerprint_grow")
FingerprintGrowComponent = fingerprint_grow_ns.class_(
@ -102,11 +104,26 @@ AURA_LED_COLORS = {
}
validate_aura_led_colors = cv.enum(AURA_LED_COLORS, upper=True)
CONFIG_SCHEMA = (
def validate(config):
if CONF_SENSOR_POWER_PIN in config and CONF_SENSING_PIN not in config:
raise cv.Invalid("You cannot use the Sensor Power Pin without a Sensing Pin")
if CONF_IDLE_PERIOD_TO_SLEEP in config and CONF_SENSOR_POWER_PIN not in config:
raise cv.Invalid(
"You cannot have an Idle Period to Sleep without a Sensor Power Pin"
)
return config
CONFIG_SCHEMA = cv.All(
cv.Schema(
{
cv.GenerateID(): cv.declare_id(FingerprintGrowComponent),
cv.Optional(CONF_SENSING_PIN): pins.gpio_input_pin_schema,
cv.Optional(CONF_SENSOR_POWER_PIN): pins.gpio_output_pin_schema,
cv.Optional(
CONF_IDLE_PERIOD_TO_SLEEP
): cv.positive_time_period_milliseconds,
cv.Optional(CONF_PASSWORD): cv.uint32_t,
cv.Optional(CONF_NEW_PASSWORD): cv.uint32_t,
cv.Optional(CONF_ON_FINGER_SCAN_START): automation.validate_automation(
@ -168,7 +185,8 @@ CONFIG_SCHEMA = (
}
)
.extend(cv.polling_component_schema("500ms"))
.extend(uart.UART_DEVICE_SCHEMA)
.extend(uart.UART_DEVICE_SCHEMA),
validate,
)
@ -188,6 +206,14 @@ async def to_code(config):
sensing_pin = await cg.gpio_pin_expression(config[CONF_SENSING_PIN])
cg.add(var.set_sensing_pin(sensing_pin))
if CONF_SENSOR_POWER_PIN in config:
sensor_power_pin = await cg.gpio_pin_expression(config[CONF_SENSOR_POWER_PIN])
cg.add(var.set_sensor_power_pin(sensor_power_pin))
if CONF_IDLE_PERIOD_TO_SLEEP in config:
idle_period_to_sleep_ms = config[CONF_IDLE_PERIOD_TO_SLEEP]
cg.add(var.set_idle_period_to_sleep_ms(idle_period_to_sleep_ms))
for conf in config.get(CONF_ON_FINGER_SCAN_START, []):
trigger = cg.new_Pvariable(conf[CONF_TRIGGER_ID], var)
await automation.build_automation(trigger, [], conf)

View File

@ -16,9 +16,14 @@ void FingerprintGrowComponent::update() {
}
if (this->has_sensing_pin_) {
// A finger touch results in a low level (digital_read() == false)
if (this->sensing_pin_->digital_read()) {
ESP_LOGV(TAG, "No touch sensing");
this->waiting_removal_ = false;
if ((this->enrollment_image_ == 0) && // Not in enrolment process
(millis() - this->last_transfer_ms_ > this->idle_period_to_sleep_ms_) && (this->is_sensor_awake_)) {
this->sensor_sleep_();
}
return;
} else if (!this->waiting_removal_) {
this->finger_scan_start_callback_.call();
@ -53,7 +58,29 @@ void FingerprintGrowComponent::update() {
void FingerprintGrowComponent::setup() {
ESP_LOGCONFIG(TAG, "Setting up Grow Fingerprint Reader...");
this->has_sensing_pin_ = (this->sensing_pin_ != nullptr);
this->has_power_pin_ = (this->sensor_power_pin_ != nullptr);
// Call pins setup, so we effectively apply the config generated from the yaml file.
if (this->has_sensing_pin_) {
this->sensing_pin_->setup();
}
if (this->has_power_pin_) {
// Starts with output low (disabling power) to avoid glitches in the sensor
this->sensor_power_pin_->digital_write(false);
this->sensor_power_pin_->setup();
// If the user didn't specify an idle period to sleep, applies the default.
if (this->idle_period_to_sleep_ms_ == UINT32_MAX) {
this->idle_period_to_sleep_ms_ = DEFAULT_IDLE_PERIOD_TO_SLEEP_MS;
}
}
// Place the sensor in a known (sleep/off) state and sync internal var state.
this->sensor_sleep_();
delay(20); // This delay guarantees the sensor will in fact be powered power.
if (this->check_password_()) {
if (this->new_password_ != -1) {
if (this->set_password_())
@ -335,7 +362,7 @@ void FingerprintGrowComponent::aura_led_control(uint8_t state, uint8_t speed, ui
}
}
uint8_t FingerprintGrowComponent::send_command_() {
uint8_t FingerprintGrowComponent::transfer_(std::vector<uint8_t> *p_data_buffer) {
while (this->available())
this->read();
this->write((uint8_t) (START_CODE >> 8));
@ -346,12 +373,12 @@ uint8_t FingerprintGrowComponent::send_command_() {
this->write(this->address_[3]);
this->write(COMMAND);
uint16_t wire_length = this->data_.size() + 2;
uint16_t wire_length = p_data_buffer->size() + 2;
this->write((uint8_t) (wire_length >> 8));
this->write((uint8_t) (wire_length & 0xFF));
uint16_t sum = ((wire_length) >> 8) + ((wire_length) &0xFF) + COMMAND;
for (auto data : this->data_) {
for (auto data : *p_data_buffer) {
this->write(data);
sum += data;
}
@ -359,7 +386,7 @@ uint8_t FingerprintGrowComponent::send_command_() {
this->write((uint8_t) (sum >> 8));
this->write((uint8_t) (sum & 0xFF));
this->data_.clear();
p_data_buffer->clear();
uint8_t byte;
uint16_t idx = 0, length = 0;
@ -369,7 +396,9 @@ uint8_t FingerprintGrowComponent::send_command_() {
delay(1);
continue;
}
byte = this->read();
switch (idx) {
case 0:
if (byte != (uint8_t) (START_CODE >> 8))
@ -403,9 +432,9 @@ uint8_t FingerprintGrowComponent::send_command_() {
length |= byte;
break;
default:
this->data_.push_back(byte);
p_data_buffer->push_back(byte);
if ((idx - 8) == length) {
switch (this->data_[0]) {
switch ((*p_data_buffer)[0]) {
case OK:
case NO_FINGER:
case IMAGE_FAIL:
@ -425,39 +454,123 @@ uint8_t FingerprintGrowComponent::send_command_() {
ESP_LOGE(TAG, "Reader failed to process request");
break;
default:
ESP_LOGE(TAG, "Unknown response received from reader: %d", this->data_[0]);
ESP_LOGE(TAG, "Unknown response received from reader: 0x%.2X", (*p_data_buffer)[0]);
break;
}
return this->data_[0];
this->last_transfer_ms_ = millis();
return (*p_data_buffer)[0];
}
break;
}
idx++;
}
ESP_LOGE(TAG, "No response received from reader");
this->data_[0] = TIMEOUT;
(*p_data_buffer)[0] = TIMEOUT;
this->last_transfer_ms_ = millis();
return TIMEOUT;
}
uint8_t FingerprintGrowComponent::send_command_() {
this->sensor_wakeup_();
return this->transfer_(&this->data_);
}
void FingerprintGrowComponent::sensor_wakeup_() {
// Immediately return if there is no power pin or the sensor is already on
if ((!this->has_power_pin_) || (this->is_sensor_awake_))
return;
this->sensor_power_pin_->digital_write(true);
this->is_sensor_awake_ = true;
uint8_t byte = TIMEOUT;
// Wait for the byte HANDSHAKE_SIGN from the sensor meaning it is operational.
for (uint16_t timer = 0; timer < WAIT_FOR_WAKE_UP_MS; timer++) {
if (this->available() > 0) {
byte = this->read();
/* If the received byte is zero, the UART probably misinterpreted a raising edge on
* the RX pin due the power up as byte "zero" - I verified this behaviour using
* the esp32-arduino lib. So here we just ignore this fake byte.
*/
if (byte != 0)
break;
}
delay(1);
}
/* Lets check if the received by is a HANDSHAKE_SIGN, otherwise log an error
* message and try to continue on the best effort.
*/
if (byte == HANDSHAKE_SIGN) {
ESP_LOGD(TAG, "Sensor has woken up!");
} else if (byte == TIMEOUT) {
ESP_LOGE(TAG, "Timed out waiting for sensor wake-up");
} else {
ESP_LOGE(TAG, "Received wrong byte from the sensor during wake-up: 0x%.2X", byte);
}
/* Next step, we must authenticate with the password. We cannot call check_password_ here
* neither use data_ to store the command because it might be already in use by the caller
* of send_command_()
*/
std::vector<uint8_t> buffer = {VERIFY_PASSWORD, (uint8_t) (this->password_ >> 24), (uint8_t) (this->password_ >> 16),
(uint8_t) (this->password_ >> 8), (uint8_t) (this->password_ & 0xFF)};
if (this->transfer_(&buffer) != OK) {
ESP_LOGE(TAG, "Wrong password");
}
}
void FingerprintGrowComponent::sensor_sleep_() {
// Immediately return if the power pin feature is not implemented
if (!this->has_power_pin_)
return;
this->sensor_power_pin_->digital_write(false);
this->is_sensor_awake_ = false;
ESP_LOGD(TAG, "Fingerprint sensor is now in sleep mode.");
}
void FingerprintGrowComponent::dump_config() {
ESP_LOGCONFIG(TAG, "GROW_FINGERPRINT_READER:");
ESP_LOGCONFIG(TAG, " System Identifier Code: 0x%.4X", this->system_identifier_code_);
ESP_LOGCONFIG(TAG, " Touch Sensing Pin: %s",
this->has_sensing_pin_ ? this->sensing_pin_->dump_summary().c_str() : "None");
ESP_LOGCONFIG(TAG, " Sensor Power Pin: %s",
this->has_power_pin_ ? this->sensor_power_pin_->dump_summary().c_str() : "None");
if (this->idle_period_to_sleep_ms_ < UINT32_MAX) {
ESP_LOGCONFIG(TAG, " Idle Period to Sleep: %u ms", this->idle_period_to_sleep_ms_);
} else {
ESP_LOGCONFIG(TAG, " Idle Period to Sleep: Never");
}
LOG_UPDATE_INTERVAL(this);
if (this->fingerprint_count_sensor_) {
LOG_SENSOR(" ", "Fingerprint Count", this->fingerprint_count_sensor_);
ESP_LOGCONFIG(TAG, " Current Value: %d", (uint16_t) this->fingerprint_count_sensor_->get_state());
}
if (this->status_sensor_) {
LOG_SENSOR(" ", "Status", this->status_sensor_);
ESP_LOGCONFIG(TAG, " Current Value: %d", (uint8_t) this->status_sensor_->get_state());
}
if (this->capacity_sensor_) {
LOG_SENSOR(" ", "Capacity", this->capacity_sensor_);
ESP_LOGCONFIG(TAG, " Current Value: %d", (uint16_t) this->capacity_sensor_->get_state());
}
if (this->security_level_sensor_) {
LOG_SENSOR(" ", "Security Level", this->security_level_sensor_);
ESP_LOGCONFIG(TAG, " Current Value: %d", (uint8_t) this->security_level_sensor_->get_state());
}
if (this->last_finger_id_sensor_) {
LOG_SENSOR(" ", "Last Finger ID", this->last_finger_id_sensor_);
ESP_LOGCONFIG(TAG, " Current Value: %d", (uint32_t) this->last_finger_id_sensor_->get_state());
}
if (this->last_confidence_sensor_) {
LOG_SENSOR(" ", "Last Confidence", this->last_confidence_sensor_);
ESP_LOGCONFIG(TAG, " Current Value: %d", (uint32_t) this->last_confidence_sensor_->get_state());
}
}
} // namespace fingerprint_grow
} // namespace esphome

View File

@ -15,6 +15,11 @@ static const uint16_t START_CODE = 0xEF01;
static const uint16_t ENROLLMENT_SLOT_UNUSED = 0xFFFF;
// The datasheet says a max wake up time of of 200ms.
static const uint8_t WAIT_FOR_WAKE_UP_MS = 200;
static const uint32_t DEFAULT_IDLE_PERIOD_TO_SLEEP_MS = 5000;
enum GrowPacketType {
COMMAND = 0x01,
DATA = 0x02,
@ -63,6 +68,7 @@ enum GrowResponse {
INVALID_IMAGE = 0x15,
FLASH_ERR = 0x18,
INVALID_REG = 0x1A,
HANDSHAKE_SIGN = 0x55,
BAD_PACKET = 0xFE,
TIMEOUT = 0xFF,
};
@ -99,8 +105,10 @@ class FingerprintGrowComponent : public PollingComponent, public uart::UARTDevic
this->address_[3] = (uint8_t) (address & 0xFF);
}
void set_sensing_pin(GPIOPin *sensing_pin) { this->sensing_pin_ = sensing_pin; }
void set_sensor_power_pin(GPIOPin *sensor_power_pin) { this->sensor_power_pin_ = sensor_power_pin; }
void set_password(uint32_t password) { this->password_ = password; }
void set_new_password(uint32_t new_password) { this->new_password_ = new_password; }
void set_idle_period_to_sleep_ms(uint32_t period_ms) { this->idle_period_to_sleep_ms_ = period_ms; }
void set_fingerprint_count_sensor(sensor::Sensor *fingerprint_count_sensor) {
this->fingerprint_count_sensor_ = fingerprint_count_sensor;
}
@ -160,7 +168,10 @@ class FingerprintGrowComponent : public PollingComponent, public uart::UARTDevic
bool set_password_();
bool get_parameters_();
void get_fingerprint_count_();
uint8_t transfer_(std::vector<uint8_t> *p_data_buffer);
uint8_t send_command_();
void sensor_wakeup_();
void sensor_sleep_();
std::vector<uint8_t> data_ = {};
uint8_t address_[4] = {0xFF, 0xFF, 0xFF, 0xFF};
@ -168,14 +179,19 @@ class FingerprintGrowComponent : public PollingComponent, public uart::UARTDevic
uint32_t password_ = 0x0;
uint32_t new_password_ = -1;
GPIOPin *sensing_pin_{nullptr};
GPIOPin *sensor_power_pin_{nullptr};
uint8_t enrollment_image_ = 0;
uint16_t enrollment_slot_ = ENROLLMENT_SLOT_UNUSED;
uint8_t enrollment_buffers_ = 5;
bool waiting_removal_ = false;
bool has_sensing_pin_ = false;
bool has_power_pin_ = false;
bool is_sensor_awake_ = false;
uint32_t last_transfer_ms_ = 0;
uint32_t last_aura_led_control_ = 0;
uint16_t last_aura_led_duration_ = 0;
uint16_t system_identifier_code_ = 0;
uint32_t idle_period_to_sleep_ms_ = UINT32_MAX;
sensor::Sensor *fingerprint_count_sensor_{nullptr};
sensor::Sensor *status_sensor_{nullptr};
sensor::Sensor *capacity_sensor_{nullptr};

View File

@ -1,47 +1,60 @@
import hashlib
import logging
import functools
from pathlib import Path
import hashlib
import os
import re
from packaging import version
import requests
from esphome import core
from esphome import external_files
import esphome.config_validation as cv
import esphome.codegen as cg
from esphome.helpers import copy_file_if_changed
from esphome.helpers import (
copy_file_if_changed,
cpp_string_escape,
)
from esphome.const import (
__version__,
CONF_FAMILY,
CONF_FILE,
CONF_GLYPHS,
CONF_ID,
CONF_RAW_DATA_ID,
CONF_TYPE,
CONF_REFRESH,
CONF_SIZE,
CONF_PATH,
CONF_WEIGHT,
CONF_URL,
)
from esphome.core import (
CORE,
HexInt,
)
from esphome.core import CORE, HexInt
_LOGGER = logging.getLogger(__name__)
DOMAIN = "font"
DEPENDENCIES = ["display"]
MULTI_CONF = True
CODEOWNERS = ["@esphome/core", "@clydebarrow"]
font_ns = cg.esphome_ns.namespace("font")
Font = font_ns.class_("Font")
Glyph = font_ns.class_("Glyph")
GlyphData = font_ns.struct("GlyphData")
CONF_BPP = "bpp"
CONF_EXTRAS = "extras"
CONF_FONTS = "fonts"
def validate_glyphs(value):
if isinstance(value, list):
value = cv.Schema([cv.string])(value)
value = cv.Schema([cv.string])(list(value))
def comparator(x, y):
def glyph_comparator(x, y):
x_ = x.encode("utf-8")
y_ = y.encode("utf-8")
@ -57,10 +70,37 @@ def validate_glyphs(value):
return 1
raise cv.Invalid(f"Found duplicate glyph {x}")
value.sort(key=functools.cmp_to_key(comparator))
def validate_glyphs(value):
if isinstance(value, list):
value = cv.Schema([cv.string])(value)
value = cv.Schema([cv.string])(list(value))
value.sort(key=functools.cmp_to_key(glyph_comparator))
return value
font_map = {}
def merge_glyphs(config):
glyphs = []
glyphs.extend(config[CONF_GLYPHS])
font_list = [(EFont(config[CONF_FILE], config[CONF_SIZE], config[CONF_GLYPHS]))]
if extras := config.get(CONF_EXTRAS):
extra_fonts = list(
map(
lambda x: EFont(x[CONF_FILE], config[CONF_SIZE], x[CONF_GLYPHS]), extras
)
)
font_list.extend(extra_fonts)
for extra in extras:
glyphs.extend(extra[CONF_GLYPHS])
validate_glyphs(glyphs)
font_map[config[CONF_ID]] = font_list
return config
def validate_pillow_installed(value):
try:
import PIL
@ -79,33 +119,23 @@ def validate_pillow_installed(value):
return value
FONT_EXTENSIONS = (".ttf", ".woff", ".otf")
def validate_truetype_file(value):
if value.endswith(".zip"): # for Google Fonts downloads
if value.lower().endswith(".zip"): # for Google Fonts downloads
raise cv.Invalid(
f"Please unzip the font archive '{value}' first and then use the .ttf files inside."
)
if not value.endswith(".ttf"):
raise cv.Invalid(
"Only truetype (.ttf) files are supported. Please make sure you're "
"using the correct format or rename the extension to .ttf"
)
if not any(map(value.lower().endswith, FONT_EXTENSIONS)):
raise cv.Invalid(f"Only {FONT_EXTENSIONS} files are supported.")
return cv.file_(value)
def _compute_local_font_dir(name) -> Path:
h = hashlib.new("sha256")
h.update(name.encode())
return Path(CORE.data_dir) / DOMAIN / h.hexdigest()[:8]
def _compute_gfonts_local_path(value) -> Path:
name = f"{value[CONF_FAMILY]}@{value[CONF_WEIGHT]}@{value[CONF_ITALIC]}@v1"
return _compute_local_font_dir(name) / "font.ttf"
TYPE_LOCAL = "local"
TYPE_LOCAL_BITMAP = "local_bitmap"
TYPE_GFONTS = "gfonts"
TYPE_WEB = "web"
LOCAL_SCHEMA = cv.Schema(
{
cv.Required(CONF_PATH): validate_truetype_file,
@ -136,21 +166,64 @@ def validate_weight_name(value):
return FONT_WEIGHTS[cv.one_of(*FONT_WEIGHTS, lower=True, space="-")(value)]
def download_gfonts(value):
def _compute_local_font_path(value: dict) -> Path:
url = value[CONF_URL]
h = hashlib.new("sha256")
h.update(url.encode())
key = h.hexdigest()[:8]
base_dir = external_files.compute_local_file_dir(DOMAIN)
_LOGGER.debug("_compute_local_font_path: base_dir=%s", base_dir / key)
return base_dir / key
def get_font_path(value, type) -> Path:
if type == TYPE_GFONTS:
name = f"{value[CONF_FAMILY]}@{value[CONF_WEIGHT]}@{value[CONF_ITALIC]}@v1"
return external_files.compute_local_file_dir(DOMAIN) / f"{name}.ttf"
if type == TYPE_WEB:
return _compute_local_font_path(value) / "font.ttf"
return None
def download_content(url: str, path: Path) -> None:
if not external_files.has_remote_file_changed(url, path):
_LOGGER.debug("Remote file has not changed %s", url)
return
_LOGGER.debug(
"Remote file has changed, downloading from %s to %s",
url,
path,
)
try:
req = requests.get(
url,
timeout=external_files.NETWORK_TIMEOUT,
headers={"User-agent": f"ESPHome/{__version__} (https://esphome.io)"},
)
req.raise_for_status()
except requests.exceptions.RequestException as e:
raise cv.Invalid(f"Could not download from {url}: {e}")
path.parent.mkdir(parents=True, exist_ok=True)
path.write_bytes(req.content)
def download_gfont(value):
name = (
f"{value[CONF_FAMILY]}:ital,wght@{int(value[CONF_ITALIC])},{value[CONF_WEIGHT]}"
)
url = f"https://fonts.googleapis.com/css2?family={name}"
path = get_font_path(value, TYPE_GFONTS)
_LOGGER.debug("download_gfont: path=%s", path)
path = _compute_gfonts_local_path(value)
if path.is_file():
return value
try:
req = requests.get(url, timeout=30)
req = requests.get(url, timeout=external_files.NETWORK_TIMEOUT)
req.raise_for_status()
except requests.exceptions.RequestException as e:
raise cv.Invalid(
f"Could not download font for {name}, please check the fonts exists "
f"Could not download font at {url}, please check the fonts exists "
f"at google fonts ({e})"
)
match = re.search(r"src:\s+url\((.+)\)\s+format\('truetype'\);", req.text)
@ -161,26 +234,48 @@ def download_gfonts(value):
)
ttf_url = match.group(1)
try:
req = requests.get(ttf_url, timeout=30)
req.raise_for_status()
except requests.exceptions.RequestException as e:
raise cv.Invalid(f"Could not download ttf file for {name} ({ttf_url}): {e}")
_LOGGER.debug("download_gfont: ttf_url=%s", ttf_url)
path.parent.mkdir(exist_ok=True, parents=True)
path.write_bytes(req.content)
download_content(ttf_url, path)
return value
GFONTS_SCHEMA = cv.All(
def download_web_font(value):
url = value[CONF_URL]
path = get_font_path(value, TYPE_WEB)
download_content(url, path)
_LOGGER.debug("download_web_font: path=%s", path)
return value
EXTERNAL_FONT_SCHEMA = cv.Schema(
{
cv.Required(CONF_FAMILY): cv.string_strict,
cv.Optional(CONF_WEIGHT, default="regular"): cv.Any(
cv.int_, validate_weight_name
),
cv.Optional(CONF_ITALIC, default=False): cv.boolean,
},
download_gfonts,
cv.Optional(CONF_REFRESH, default="1d"): cv.All(cv.string, cv.source_refresh),
}
)
GFONTS_SCHEMA = cv.All(
EXTERNAL_FONT_SCHEMA.extend(
{
cv.Required(CONF_FAMILY): cv.string_strict,
}
),
download_gfont,
)
WEB_FONT_SCHEMA = cv.All(
EXTERNAL_FONT_SCHEMA.extend(
{
cv.Required(CONF_URL): cv.string_strict,
}
),
download_web_font,
)
@ -200,6 +295,14 @@ def validate_file_shorthand(value):
data[CONF_WEIGHT] = weight[1:]
return FILE_SCHEMA(data)
if value.startswith("http://") or value.startswith("https://"):
return FILE_SCHEMA(
{
CONF_TYPE: TYPE_WEB,
CONF_URL: value,
}
)
if value.endswith(".pcf") or value.endswith(".bdf"):
return FILE_SCHEMA(
{
@ -221,6 +324,7 @@ TYPED_FILE_SCHEMA = cv.typed_schema(
TYPE_LOCAL: LOCAL_SCHEMA,
TYPE_GFONTS: GFONTS_SCHEMA,
TYPE_LOCAL_BITMAP: LOCAL_BITMAP_SCHEMA,
TYPE_WEB: WEB_FONT_SCHEMA,
}
)
@ -231,8 +335,7 @@ def _file_schema(value):
return TYPED_FILE_SCHEMA(value)
FILE_SCHEMA = cv.Schema(_file_schema)
FILE_SCHEMA = cv.All(_file_schema)
DEFAULT_GLYPHS = (
' !"%()+=,-.:/?0123456789ABCDEFGHIJKLMNOPQRSTUVWXYZ_abcdefghijklmnopqrstuvwxyz°'
@ -245,12 +348,22 @@ FONT_SCHEMA = cv.Schema(
cv.Required(CONF_FILE): FILE_SCHEMA,
cv.Optional(CONF_GLYPHS, default=DEFAULT_GLYPHS): validate_glyphs,
cv.Optional(CONF_SIZE, default=20): cv.int_range(min=1),
cv.GenerateID(CONF_RAW_DATA_ID): cv.declare_id(cg.uint8),
cv.GenerateID(CONF_RAW_GLYPH_ID): cv.declare_id(GlyphData),
cv.Optional(CONF_BPP, default=1): cv.one_of(1, 2, 4, 8),
cv.Optional(CONF_EXTRAS): cv.ensure_list(
cv.Schema(
{
cv.Required(CONF_FILE): FILE_SCHEMA,
cv.Required(CONF_GLYPHS): validate_glyphs,
}
)
),
cv.GenerateID(CONF_RAW_DATA_ID): cv.declare_id(cg.uint8),
cv.GenerateID(CONF_RAW_GLYPH_ID): cv.declare_id(GlyphData),
},
)
CONFIG_SCHEMA = cv.All(validate_pillow_installed, FONT_SCHEMA, merge_glyphs)
CONFIG_SCHEMA = cv.All(validate_pillow_installed, FONT_SCHEMA)
# PIL doesn't provide a consistent interface for both TrueType and bitmap
# fonts. So, we use our own wrappers to give us the consistency that we need.
@ -292,13 +405,37 @@ class BitmapFontWrapper:
return (max_height, 0)
def convert_bitmap_to_pillow_font(filepath):
from PIL import PcfFontFile, BdfFontFile
class EFont:
def __init__(self, file, size, glyphs):
self.glyphs = glyphs
ftype = file[CONF_TYPE]
if ftype == TYPE_LOCAL_BITMAP:
font = load_bitmap_font(CORE.relative_config_path(file[CONF_PATH]))
elif ftype == TYPE_LOCAL:
path = CORE.relative_config_path(file[CONF_PATH])
font = load_ttf_font(path, size)
elif ftype in (TYPE_GFONTS, TYPE_WEB):
path = get_font_path(file, ftype)
font = load_ttf_font(path, size)
else:
raise cv.Invalid(f"Could not load font: unknown type: {ftype}")
self.font = font
self.ascent, self.descent = font.getmetrics(glyphs)
local_bitmap_font_file = _compute_local_font_dir(filepath) / os.path.basename(
filepath
def has_glyph(self, glyph):
return glyph in self.glyphs
def convert_bitmap_to_pillow_font(filepath):
from PIL import (
PcfFontFile,
BdfFontFile,
)
local_bitmap_font_file = external_files.compute_local_file_dir(
DOMAIN,
) / os.path.basename(filepath)
copy_file_if_changed(filepath, local_bitmap_font_file)
with open(local_bitmap_font_file, "rb") as fp:
@ -347,60 +484,82 @@ def load_ttf_font(path, size):
return TrueTypeFontWrapper(font)
class GlyphInfo:
def __init__(self, data_len, offset_x, offset_y, width, height):
self.data_len = data_len
self.offset_x = offset_x
self.offset_y = offset_y
self.width = width
self.height = height
async def to_code(config):
conf = config[CONF_FILE]
if conf[CONF_TYPE] == TYPE_LOCAL_BITMAP:
font = load_bitmap_font(CORE.relative_config_path(conf[CONF_PATH]))
elif conf[CONF_TYPE] == TYPE_LOCAL:
path = CORE.relative_config_path(conf[CONF_PATH])
font = load_ttf_font(path, config[CONF_SIZE])
elif conf[CONF_TYPE] == TYPE_GFONTS:
path = _compute_gfonts_local_path(conf)
font = load_ttf_font(path, config[CONF_SIZE])
else:
raise core.EsphomeError(f"Could not load font: unknown type: {conf[CONF_TYPE]}")
ascent, descent = font.getmetrics(config[CONF_GLYPHS])
glyph_to_font_map = {}
font_list = font_map[config[CONF_ID]]
glyphs = []
for font in font_list:
glyphs.extend(font.glyphs)
for glyph in font.glyphs:
glyph_to_font_map[glyph] = font
glyphs.sort(key=functools.cmp_to_key(glyph_comparator))
glyph_args = {}
data = []
for glyph in config[CONF_GLYPHS]:
mask = font.getmask(glyph, mode="1")
bpp = config[CONF_BPP]
if bpp == 1:
mode = "1"
scale = 1
else:
mode = "L"
scale = 256 // (1 << bpp)
for glyph in glyphs:
font = glyph_to_font_map[glyph].font
mask = font.getmask(glyph, mode=mode)
offset_x, offset_y = font.getoffset(glyph)
width, height = mask.size
width8 = ((width + 7) // 8) * 8
glyph_data = [0] * (height * width8 // 8)
glyph_data = [0] * ((height * width * bpp + 7) // 8)
pos = 0
for y in range(height):
for x in range(width):
if not mask.getpixel((x, y)):
continue
pos = x + y * width8
pixel = mask.getpixel((x, y)) // scale
for bit_num in range(bpp):
if pixel & (1 << (bpp - bit_num - 1)):
glyph_data[pos // 8] |= 0x80 >> (pos % 8)
glyph_args[glyph] = (len(data), offset_x, offset_y, width, height)
pos += 1
glyph_args[glyph] = GlyphInfo(len(data), offset_x, offset_y, width, height)
data += glyph_data
rhs = [HexInt(x) for x in data]
prog_arr = cg.progmem_array(config[CONF_RAW_DATA_ID], rhs)
glyph_initializer = []
for glyph in config[CONF_GLYPHS]:
for glyph in glyphs:
glyph_initializer.append(
cg.StructInitializer(
GlyphData,
("a_char", glyph),
(
"a_char",
cg.RawExpression(f"(const uint8_t *){cpp_string_escape(glyph)}"),
),
(
"data",
cg.RawExpression(f"{str(prog_arr)} + {str(glyph_args[glyph][0])}"),
cg.RawExpression(
f"{str(prog_arr)} + {str(glyph_args[glyph].data_len)}"
),
("offset_x", glyph_args[glyph][1]),
("offset_y", glyph_args[glyph][2]),
("width", glyph_args[glyph][3]),
("height", glyph_args[glyph][4]),
),
("offset_x", glyph_args[glyph].offset_x),
("offset_y", glyph_args[glyph].offset_y),
("width", glyph_args[glyph].width),
("height", glyph_args[glyph].height),
)
)
glyphs = cg.static_const_array(config[CONF_RAW_GLYPH_ID], glyph_initializer)
cg.new_Pvariable(
config[CONF_ID], glyphs, len(glyph_initializer), ascent, ascent + descent
config[CONF_ID],
glyphs,
len(glyph_initializer),
font_list[0].ascent,
font_list[0].ascent + font_list[0].descent,
bpp,
)

View File

@ -10,29 +10,10 @@ namespace font {
static const char *const TAG = "font";
void Glyph::draw(int x_at, int y_start, display::Display *display, Color color) const {
int scan_x1, scan_y1, scan_width, scan_height;
this->scan_area(&scan_x1, &scan_y1, &scan_width, &scan_height);
const unsigned char *data = this->glyph_data_->data;
const int max_x = x_at + scan_x1 + scan_width;
const int max_y = y_start + scan_y1 + scan_height;
for (int glyph_y = y_start + scan_y1; glyph_y < max_y; glyph_y++) {
for (int glyph_x = x_at + scan_x1; glyph_x < max_x; data++, glyph_x += 8) {
uint8_t pixel_data = progmem_read_byte(data);
const int pixel_max_x = std::min(max_x, glyph_x + 8);
for (int pixel_x = glyph_x; pixel_x < pixel_max_x && pixel_data; pixel_x++, pixel_data <<= 1) {
if (pixel_data & 0x80) {
display->draw_pixel_at(pixel_x, glyph_y, color);
}
}
}
}
}
const char *Glyph::get_char() const { return this->glyph_data_->a_char; }
bool Glyph::compare_to(const char *str) const {
const uint8_t *Glyph::get_char() const { return this->glyph_data_->a_char; }
// Compare the char at the string position with this char.
// Return true if this char is less than or equal the other.
bool Glyph::compare_to(const uint8_t *str) const {
// 1 -> this->char_
// 2 -> str
for (uint32_t i = 0;; i++) {
@ -48,7 +29,7 @@ bool Glyph::compare_to(const char *str) const {
// this should not happen
return false;
}
int Glyph::match_length(const char *str) const {
int Glyph::match_length(const uint8_t *str) const {
for (uint32_t i = 0;; i++) {
if (this->glyph_data_->a_char[i] == '\0')
return i;
@ -65,12 +46,13 @@ void Glyph::scan_area(int *x1, int *y1, int *width, int *height) const {
*height = this->glyph_data_->height;
}
Font::Font(const GlyphData *data, int data_nr, int baseline, int height) : baseline_(baseline), height_(height) {
Font::Font(const GlyphData *data, int data_nr, int baseline, int height, uint8_t bpp)
: baseline_(baseline), height_(height), bpp_(bpp) {
glyphs_.reserve(data_nr);
for (int i = 0; i < data_nr; ++i)
glyphs_.emplace_back(&data[i]);
}
int Font::match_next_glyph(const char *str, int *match_length) {
int Font::match_next_glyph(const uint8_t *str, int *match_length) {
int lo = 0;
int hi = this->glyphs_.size() - 1;
while (lo != hi) {
@ -95,7 +77,7 @@ void Font::measure(const char *str, int *width, int *x_offset, int *baseline, in
int x = 0;
while (str[i] != '\0') {
int match_length;
int glyph_n = this->match_next_glyph(str + i, &match_length);
int glyph_n = this->match_next_glyph((const uint8_t *) str + i, &match_length);
if (glyph_n < 0) {
// Unknown char, skip
if (!this->get_glyphs().empty())
@ -118,12 +100,13 @@ void Font::measure(const char *str, int *width, int *x_offset, int *baseline, in
*x_offset = min_x;
*width = x - min_x;
}
void Font::print(int x_start, int y_start, display::Display *display, Color color, const char *text) {
void Font::print(int x_start, int y_start, display::Display *display, Color color, const char *text, Color background) {
int i = 0;
int x_at = x_start;
int scan_x1, scan_y1, scan_width, scan_height;
while (text[i] != '\0') {
int match_length;
int glyph_n = this->match_next_glyph(text + i, &match_length);
int glyph_n = this->match_next_glyph((const uint8_t *) text + i, &match_length);
if (glyph_n < 0) {
// Unknown char, skip
ESP_LOGW(TAG, "Encountered character without representation in font: '%c'", text[i]);
@ -138,7 +121,41 @@ void Font::print(int x_start, int y_start, display::Display *display, Color colo
}
const Glyph &glyph = this->get_glyphs()[glyph_n];
glyph.draw(x_at, y_start, display, color);
glyph.scan_area(&scan_x1, &scan_y1, &scan_width, &scan_height);
const uint8_t *data = glyph.glyph_data_->data;
const int max_x = x_at + scan_x1 + scan_width;
const int max_y = y_start + scan_y1 + scan_height;
uint8_t bitmask = 0;
uint8_t pixel_data = 0;
float bpp_max = (1 << this->bpp_) - 1;
for (int glyph_y = y_start + scan_y1; glyph_y != max_y; glyph_y++) {
for (int glyph_x = x_at + scan_x1; glyph_x != max_x; glyph_x++) {
uint8_t pixel = 0;
for (int bit_num = 0; bit_num != this->bpp_; bit_num++) {
if (bitmask == 0) {
pixel_data = progmem_read_byte(data++);
bitmask = 0x80;
}
pixel <<= 1;
if ((pixel_data & bitmask) != 0)
pixel |= 1;
bitmask >>= 1;
}
if (pixel == bpp_max) {
display->draw_pixel_at(glyph_x, glyph_y, color);
} else if (pixel != 0) {
float on = (float) pixel / bpp_max;
float off = 1.0 - on;
Color blended;
blended.r = color.r * on + background.r * off;
blended.g = color.r * on + background.g * off;
blended.b = color.r * on + background.b * off;
display->draw_pixel_at(glyph_x, glyph_y, blended);
}
}
}
x_at += glyph.glyph_data_->width + glyph.glyph_data_->offset_x;
i += match_length;

View File

@ -10,7 +10,7 @@ namespace font {
class Font;
struct GlyphData {
const char *a_char;
const uint8_t *a_char;
const uint8_t *data;
int offset_x;
int offset_y;
@ -22,16 +22,16 @@ class Glyph {
public:
Glyph(const GlyphData *data) : glyph_data_(data) {}
void draw(int x, int y, display::Display *display, Color color) const;
const uint8_t *get_char() const;
const char *get_char() const;
bool compare_to(const uint8_t *str) const;
bool compare_to(const char *str) const;
int match_length(const char *str) const;
int match_length(const uint8_t *str) const;
void scan_area(int *x1, int *y1, int *width, int *height) const;
const GlyphData *get_glyph_data() const { return this->glyph_data_; }
protected:
friend Font;
@ -46,14 +46,16 @@ class Font : public display::BaseFont {
* @param baseline The y-offset from the top of the text to the baseline.
* @param bottom The y-offset from the top of the text to the bottom (i.e. height).
*/
Font(const GlyphData *data, int data_nr, int baseline, int height);
Font(const GlyphData *data, int data_nr, int baseline, int height, uint8_t bpp = 1);
int match_next_glyph(const char *str, int *match_length);
int match_next_glyph(const uint8_t *str, int *match_length);
void print(int x_start, int y_start, display::Display *display, Color color, const char *text) override;
void print(int x_start, int y_start, display::Display *display, Color color, const char *text,
Color background) override;
void measure(const char *str, int *width, int *x_offset, int *baseline, int *height) override;
inline int get_baseline() { return this->baseline_; }
inline int get_height() { return this->height_; }
inline int get_bpp() { return this->bpp_; }
const std::vector<Glyph, ExternalRAMAllocator<Glyph>> &get_glyphs() const { return glyphs_; }
@ -61,6 +63,7 @@ class Font : public display::BaseFont {
std::vector<Glyph, ExternalRAMAllocator<Glyph>> glyphs_;
int baseline_;
int height_;
uint8_t bpp_; // bits per pixel
};
} // namespace font

View File

@ -66,8 +66,14 @@ class FT5x06Touchscreen : public touchscreen::Touchscreen, public i2c::I2CDevice
return;
}
// reading the chip registers to get max x/y does not seem to work.
this->x_raw_max_ = this->display_->get_width();
this->y_raw_max_ = this->display_->get_height();
if (this->display_ != nullptr) {
if (this->x_raw_max_ == this->x_raw_min_) {
this->x_raw_max_ = this->display_->get_native_width();
}
if (this->y_raw_max_ == this->y_raw_min_) {
this->y_raw_max_ = this->display_->get_native_height();
}
}
esph_log_config(TAG, "FT5x06 Touchscreen setup complete");
}

View File

@ -12,21 +12,23 @@
// Reference: https://focuslcds.com/content/FT6236.pdf
namespace esphome {
namespace ft63x6 {
static const uint8_t FT6X36_ADDR_DEVICE_MODE = 0x00;
static const uint8_t FT63X6_ADDR_TD_STATUS = 0x02;
static const uint8_t FT63X6_ADDR_TOUCH1_STATE = 0x03;
static const uint8_t FT63X6_ADDR_TOUCH1_X = 0x03;
static const uint8_t FT63X6_ADDR_TOUCH1_ID = 0x05;
static const uint8_t FT63X6_ADDR_TOUCH1_Y = 0x05;
static const uint8_t FT63X6_ADDR_TOUCH1_WEIGHT = 0x07;
static const uint8_t FT63X6_ADDR_TOUCH1_MISC = 0x08;
static const uint8_t FT6X36_ADDR_THRESHHOLD = 0x80;
static const uint8_t FT6X36_ADDR_TOUCHRATE_ACTIVE = 0x88;
static const uint8_t FT63X6_ADDR_CHIP_ID = 0xA3;
static const uint8_t FT63X6_ADDR_TOUCH2_STATE = 0x09;
static const uint8_t FT63X6_ADDR_TOUCH2_X = 0x09;
static const uint8_t FT63X6_ADDR_TOUCH2_ID = 0x0B;
static const uint8_t FT63X6_ADDR_TOUCH2_Y = 0x0B;
static const char *const TAG = "FT63X6Touchscreen";
static const char *const TAG = "FT63X6";
void FT63X6Touchscreen::setup() {
ESP_LOGCONFIG(TAG, "Setting up FT63X6Touchscreen Touchscreen...");
ESP_LOGCONFIG(TAG, "Setting up FT63X6 Touchscreen...");
if (this->interrupt_pin_ != nullptr) {
this->interrupt_pin_->pin_mode(gpio::FLAG_INPUT | gpio::FLAG_PULLUP);
this->interrupt_pin_->setup();
@ -35,9 +37,8 @@ void FT63X6Touchscreen::setup() {
if (this->reset_pin_ != nullptr) {
this->reset_pin_->setup();
}
this->hard_reset_();
}
// Get touch resolution
if (this->x_raw_max_ == this->x_raw_min_) {
@ -46,6 +47,15 @@ void FT63X6Touchscreen::setup() {
if (this->y_raw_max_ == this->y_raw_min_) {
this->y_raw_max_ = 480;
}
uint8_t chip_id = this->read_byte_(FT63X6_ADDR_CHIP_ID);
if (chip_id != 0) {
ESP_LOGI(TAG, "FT6336U touch driver started chipid: %d", chip_id);
} else {
ESP_LOGE(TAG, "FT6336U touch driver failed to start");
}
this->write_byte(FT6X36_ADDR_DEVICE_MODE, 0x00);
this->write_byte(FT6X36_ADDR_THRESHHOLD, this->threshold_);
this->write_byte(FT6X36_ADDR_TOUCHRATE_ACTIVE, 0x0E);
}
void FT63X6Touchscreen::hard_reset_() {
@ -65,28 +75,61 @@ void FT63X6Touchscreen::dump_config() {
}
void FT63X6Touchscreen::update_touches() {
uint8_t data[15];
uint16_t touch_id, x, y;
if (!this->read_bytes(0x00, (uint8_t *) data, 15)) {
ESP_LOGE(TAG, "Failed to read touch data");
this->skip_update_ = true;
uint8_t touches = this->read_touch_number_();
if ((touches == 0x00) || (touches == 0xff)) {
// ESP_LOGD(TAG, "No touches detected");
return;
}
if (((data[FT63X6_ADDR_TOUCH1_STATE] >> 6) & 0x01) == 0) {
touch_id = data[FT63X6_ADDR_TOUCH1_ID] >> 4; // id1 = 0 or 1
x = encode_uint16(data[FT63X6_ADDR_TOUCH1_X] & 0x0F, data[FT63X6_ADDR_TOUCH1_X + 1]);
y = encode_uint16(data[FT63X6_ADDR_TOUCH1_Y] & 0x0F, data[FT63X6_ADDR_TOUCH1_Y + 1]);
this->add_raw_touch_position_(touch_id, x, y);
ESP_LOGV(TAG, "Touches found: %d", touches);
for (auto point = 0; point < touches; point++) {
if (((this->read_touch_event_(point)) & 0x01) == 0) { // checking event flag bit 6 if it is null
touch_id = this->read_touch_id_(point); // id1 = 0 or 1
x = this->read_touch_x_(point);
y = this->read_touch_y_(point);
if ((x == 0) && (y == 0)) {
ESP_LOGW(TAG, "Reporting a (0,0) touch on %d", touch_id);
}
if (((data[FT63X6_ADDR_TOUCH2_STATE] >> 6) & 0x01) == 0) {
touch_id = data[FT63X6_ADDR_TOUCH2_ID] >> 4; // id1 = 0 or 1
x = encode_uint16(data[FT63X6_ADDR_TOUCH2_X] & 0x0F, data[FT63X6_ADDR_TOUCH2_X + 1]);
y = encode_uint16(data[FT63X6_ADDR_TOUCH2_Y] & 0x0F, data[FT63X6_ADDR_TOUCH2_Y + 1]);
this->add_raw_touch_position_(touch_id, x, y);
this->add_raw_touch_position_(touch_id, x, y, this->read_touch_weight_(point));
}
}
}
uint8_t FT63X6Touchscreen::read_touch_number_() { return this->read_byte_(FT63X6_ADDR_TD_STATUS) & 0x0F; }
// Touch 1 functions
uint16_t FT63X6Touchscreen::read_touch_x_(uint8_t touch) {
uint8_t read_buf[2];
read_buf[0] = this->read_byte_(FT63X6_ADDR_TOUCH1_X + (touch * 6));
read_buf[1] = this->read_byte_(FT63X6_ADDR_TOUCH1_X + 1 + (touch * 6));
return ((read_buf[0] & 0x0f) << 8) | read_buf[1];
}
uint16_t FT63X6Touchscreen::read_touch_y_(uint8_t touch) {
uint8_t read_buf[2];
read_buf[0] = this->read_byte_(FT63X6_ADDR_TOUCH1_Y + (touch * 6));
read_buf[1] = this->read_byte_(FT63X6_ADDR_TOUCH1_Y + 1 + (touch * 6));
return ((read_buf[0] & 0x0f) << 8) | read_buf[1];
}
uint8_t FT63X6Touchscreen::read_touch_event_(uint8_t touch) {
return this->read_byte_(FT63X6_ADDR_TOUCH1_X + (touch * 6)) >> 6;
}
uint8_t FT63X6Touchscreen::read_touch_id_(uint8_t touch) {
return this->read_byte_(FT63X6_ADDR_TOUCH1_ID + (touch * 6)) >> 4;
}
uint8_t FT63X6Touchscreen::read_touch_weight_(uint8_t touch) {
return this->read_byte_(FT63X6_ADDR_TOUCH1_WEIGHT + (touch * 6));
}
uint8_t FT63X6Touchscreen::read_touch_misc_(uint8_t touch) {
return this->read_byte_(FT63X6_ADDR_TOUCH1_MISC + (touch * 6)) >> 4;
}
uint8_t FT63X6Touchscreen::read_byte_(uint8_t addr) {
uint8_t byte = 0;
this->read_byte(addr, &byte);
return byte;
}
} // namespace ft63x6
} // namespace esphome

View File

@ -16,6 +16,8 @@ namespace ft63x6 {
using namespace touchscreen;
static const uint8_t FT6X36_DEFAULT_THRESHOLD = 22;
class FT63X6Touchscreen : public Touchscreen, public i2c::I2CDevice {
public:
void setup() override;
@ -23,18 +25,26 @@ class FT63X6Touchscreen : public Touchscreen, public i2c::I2CDevice {
void set_interrupt_pin(InternalGPIOPin *pin) { this->interrupt_pin_ = pin; }
void set_reset_pin(GPIOPin *pin) { this->reset_pin_ = pin; }
void set_threshold(uint8_t threshold) { this->threshold_ = threshold; }
protected:
void hard_reset_();
uint8_t read_byte_(uint8_t addr);
void update_touches() override;
InternalGPIOPin *interrupt_pin_{nullptr};
GPIOPin *reset_pin_{nullptr};
uint8_t threshold_{FT6X36_DEFAULT_THRESHOLD};
uint8_t read_touch_count_();
uint16_t read_touch_coordinate_(uint8_t coordinate);
uint8_t read_touch_id_(uint8_t id_address);
uint8_t read_touch_number_();
uint16_t read_touch_x_(uint8_t touch);
uint16_t read_touch_y_(uint8_t touch);
uint8_t read_touch_event_(uint8_t touch);
uint8_t read_touch_id_(uint8_t touch);
uint8_t read_touch_weight_(uint8_t touch);
uint8_t read_touch_misc_(uint8_t touch);
uint8_t read_byte_(uint8_t addr);
};
} // namespace ft63x6

View File

@ -3,7 +3,7 @@ import esphome.config_validation as cv
from esphome import pins
from esphome.components import i2c, touchscreen
from esphome.const import CONF_ID, CONF_INTERRUPT_PIN, CONF_RESET_PIN
from esphome.const import CONF_ID, CONF_INTERRUPT_PIN, CONF_RESET_PIN, CONF_THRESHOLD
CODEOWNERS = ["@gpambrozio"]
DEPENDENCIES = ["i2c"]
@ -26,6 +26,7 @@ CONFIG_SCHEMA = touchscreen.TOUCHSCREEN_SCHEMA.extend(
pins.internal_gpio_input_pin_schema
),
cv.Optional(CONF_RESET_PIN): pins.gpio_output_pin_schema,
cv.Optional(CONF_THRESHOLD): cv.uint8_t,
}
).extend(i2c.i2c_device_schema(0x38))
)

View File

@ -48,9 +48,13 @@ void GT911Touchscreen::setup() {
if (err == i2c::ERROR_OK) {
err = this->read(data, sizeof(data));
if (err == i2c::ERROR_OK) {
if (this->x_raw_max_ == this->x_raw_min_) {
this->x_raw_max_ = encode_uint16(data[1], data[0]);
}
if (this->y_raw_max_ == this->y_raw_min_) {
this->y_raw_max_ = encode_uint16(data[3], data[2]);
esph_log_d(TAG, "Read max_x/max_y %d/%d", this->x_raw_max_, this->y_raw_max_);
}
esph_log_d(TAG, "calibration max_x/max_y %d/%d", this->x_raw_max_, this->y_raw_max_);
}
}
}

View File

@ -0,0 +1,70 @@
import esphome.codegen as cg
import esphome.config_validation as cv
from esphome.components import binary_sensor
from esphome.const import (
ENTITY_CATEGORY_DIAGNOSTIC,
ICON_FAN,
ICON_RADIATOR,
)
from ..climate import (
CONF_HAIER_ID,
HonClimate,
)
BinarySensorTypeEnum = HonClimate.enum("SubBinarySensorType", True)
# Haier sensors
CONF_OUTDOOR_FAN_STATUS = "outdoor_fan_status"
CONF_DEFROST_STATUS = "defrost_status"
CONF_COMPRESSOR_STATUS = "compressor_status"
CONF_INDOOR_FAN_STATUS = "indoor_fan_status"
CONF_FOUR_WAY_VALVE_STATUS = "four_way_valve_status"
CONF_INDOOR_ELECTRIC_HEATING_STATUS = "indoor_electric_heating_status"
# Additional icons
ICON_SNOWFLAKE_THERMOMETER = "mdi:snowflake-thermometer"
ICON_HVAC = "mdi:hvac"
ICON_VALVE = "mdi:valve"
SENSOR_TYPES = {
CONF_OUTDOOR_FAN_STATUS: binary_sensor.binary_sensor_schema(
icon=ICON_FAN,
entity_category=ENTITY_CATEGORY_DIAGNOSTIC,
),
CONF_DEFROST_STATUS: binary_sensor.binary_sensor_schema(
icon=ICON_SNOWFLAKE_THERMOMETER,
entity_category=ENTITY_CATEGORY_DIAGNOSTIC,
),
CONF_COMPRESSOR_STATUS: binary_sensor.binary_sensor_schema(
icon=ICON_HVAC,
entity_category=ENTITY_CATEGORY_DIAGNOSTIC,
),
CONF_INDOOR_FAN_STATUS: binary_sensor.binary_sensor_schema(
icon=ICON_FAN,
entity_category=ENTITY_CATEGORY_DIAGNOSTIC,
),
CONF_FOUR_WAY_VALVE_STATUS: binary_sensor.binary_sensor_schema(
icon=ICON_VALVE,
entity_category=ENTITY_CATEGORY_DIAGNOSTIC,
),
CONF_INDOOR_ELECTRIC_HEATING_STATUS: binary_sensor.binary_sensor_schema(
icon=ICON_RADIATOR,
entity_category=ENTITY_CATEGORY_DIAGNOSTIC,
),
}
CONFIG_SCHEMA = cv.Schema(
{
cv.Required(CONF_HAIER_ID): cv.use_id(HonClimate),
}
).extend({cv.Optional(type): schema for type, schema in SENSOR_TYPES.items()})
async def to_code(config):
paren = await cg.get_variable(config[CONF_HAIER_ID])
for type, _ in SENSOR_TYPES.items():
if conf := config.get(type):
sens = await binary_sensor.new_binary_sensor(conf)
binary_sensor_type = getattr(BinarySensorTypeEnum, type.upper())
cg.add(paren.set_sub_binary_sensor(binary_sensor_type, sens))

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